Species Accounts

Part II - Species Accounts

Published online by Cambridge University Press: 21 November 2017

Edited by

Mario Melletti and

Erik Meijaard

Show author details

Mario Melletti: Affiliation:
AfBIG (African Buffalo Initiative Group), IUCN SSC ASG
Erik Meijaard: Affiliation:
Australian National University, Canberra

Book contents

Get access

Summary

A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'

Type: Chapter
Information: Ecology, Conservation and Management of Wild Pigs and Peccaries , pp. 59 - 276

DOI: https://doi.org/10.1017/9781316941232 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2017

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abood, S. A., Lee, J. S. H., Burivalova, Z., Garcia-Ulloa, J. & Koh, L. P. (2015). Relative contributions of the logging, fiber, oil palm, and mining industries to forest loss in Indonesia. Conservation Letters 8: 58–67.CrossRef Google Scholar

Adnyane, I. K. M., McDonald, A. A., Winarto, A. & Agungpriyono, S. (2010). Studi mikroanatomi pankreas babirusa (Babyroussa babyroussa) menggunakan metode pewarnaan baku dan immunohistokimia. Jurnal Kedokteran Hewan 4(2): 49–52.Google Scholar

Agungpriyono, S., Macdonald, A. A., Leus, K. Y. G., et al. (2000). Immunohistochemical study on the distribution of endocrine cells in the gastrointestinal tract of the babirusa, Babyrousa babyrussa (Suidae). Anatomia Histologia Embryologia 29: 173–178.Google Scholar

Agungpriyono, S., Kurohmaru, M., Prasetyaningtyas, W. E., et al. (2007). A lectin histochemical study on the testis of the Babirusa, Babyrusa babyroussa (Suidae), Anatomia, Histologia, Embryologia 36: 343–348.Google Scholar

Aubert, M., Brumm, A., Ramli, M., et al. (2014). Pleistocene cave art from Sulawesi, Indonesia. Nature 514: 223–227.Google Scholar

Bartstra, G.-J. (1997). A fifty years commemoration: fossil vertebrates and stone tools in the Walane valley. Quartär. Internationales Jahrbuch zur Erforschung des Eiszeitalters und der Steinzeit 47/48: 29–50.Google Scholar

Berger, E. M., Leus, K., Vercammen, P. & Schwarzenberger, F. (2006). Faecal steroid metabolites for non-invasive assessment of reproduction in common warthogs (Phacochoerus africanus), red river hogs (Potamochoerus porcus) and babirusa (Babyrousa babyrussa). Animal Reproduction Science 91: 155–171.CrossRef Google Scholar PubMed

Blouch, R. (1990). Report from the field: Indonesia. Conservation and Research Center Newsletter. Washington, DC: Smithsonian Institution, 1: 6–8.Google Scholar

Bowles, D. (1986). Social behaviour and breeding of Babirusa (Babyrousa babyrussa) at the Jersey Widlife Preservation Trust. Dodo, Journal of the Jersey Wildlife Preservation Trust 23: 86–94.Google Scholar

Burton, J.A. & Macdonald, A. A. (2009). Variation in distribution and abundance of large mammals in Lore Lindu National Park, Central Sulawesi, Indonesia. Malay Nature Journal 61: 295–305.Google Scholar

Chaudhuri, M., Carrasco, E., Kalk, P. & Thau, R. B. (1990). Urinary oestrogen excretion during oestrus and pregnancy in the babirusa. International Zoo Yearbook 29: 188–192.Google Scholar

Clauss, M., Nijboer, J., Loermans, J. H. M., et al. (2008). Comparative digestion studies in wild pigs at Rotterdam Zoo. Zoo Biology 27: 305–319.CrossRef Google Scholar PubMed

Clayton, L. & MacDonald, D. W. (1999). Social organization of the babirusa (Babyrousa babyrussa) and their use of salt licks in Sulawesi, Indonesia. Journal of Mammalogy 80: 1147–1157.Google Scholar

Clayton, L. M., Keeling, M. & Milner-Gulland, E. J. (1997). Bringing home the bacon: a spatial model of wild pig hunting in North Sulawesi, Indonesia. Ecological Applications 7: 642–652.Google Scholar

Conklin, N. L., Dierenfeld, E. S. & Maclaughlin, K. (1994). Digestibility and passage of a zoo diet fed to Babirusa (Babyrousa babyrussa). Zoologische Garten 64: 357–365.Google Scholar

Deninger, K. (1909). Über Babirusa. Berichten der naturforschenden Gesellschaft zu Freiburg im Breisgau 17: 179–200.Google Scholar

Eriawati, Y. (2003). Lukisan di gua-gua karst Maros-Pangkep, Sulawesi Selatan: gambaran penghuni dan matapencahariannya : album seni budaya [= Rock paintings on Maros-Pangkep karst caves, South Sulawesi : a depiction of their inhabitants and subsistence : Album of Art and Culture]. Department of Preservation and Development of Culture Ministry of Cultural Media Development.Google Scholar

Frankham, R., Ballou, J. D. & Briscoe, D. A. (2010). Introduction to conservation genetics. Cambridge: Cambridge University Press.CrossRef Google Scholar

Guillemard, F. H. H. (1886). The cruise of the Marchesa to Kamschatka and New Guinea. London: John Murray, Vol 2, pp. 190–191, 200–205.Google Scholar

Hamerton, A. E. (1931). Report on the deaths occurring in the society's gardens during the year 1930. Proceedings of the Zoological Society of London 1931: 527–555.CrossRef Google Scholar

Hamerton, A. E. (1941). Report on the deaths occurring in the society's gardens during the years 1939–1940. Proceedings of the Zoological Society of London series B 3: 151–185.Google Scholar

Heekeren, H. R. van. (1952). Rock-paintings and other prehistoric discoveries near Maros (South West Celebes). Laporan Tahunan Dinas Purbakala 1950: 22–35.Google Scholar

Heekeren, H. R. van. (1972). The Stone Age of Indonesia. Verhandelingen van het Koninklijk Instituut voor Taal-, Land- en Volkenkunde 61: 1–311.Google Scholar

Hooijer, D. A. (1948). Pleistocene vertebrates from Celebes; III. Anoa depressicornis (Smith) subsp., and Babyroussa babirussa beruensis nov. subsp. Koninklijke Nederlandische Akademie van Wetenschappen 51: 1322–1330.Google Scholar

Hooijer, D. A. (1950). Man and other mammals from Toalian sites in south-western Celebes. Verhandelingen der Koninklijke Nederlandische Akademie van Wetenschappen 46(2): 1–164.Google Scholar

Hooijer, D. A. (1954). Pleistocene vertebrates from Celebes. VIII. Dentition and skeleton of Celebochoerus heekereni hooijer. Zoologische verhandelingen uitgegeven door het Rijksmuseum van Naturlijke Historie te Leiden 24: 1–52.Google Scholar

Indonesian Ministry of Forestry/IUCN (2013). National Conservation Strategy and Action Plan for Babirusa. [Strategi dan rencana aksi konservasi Babirusa (Babyrousa babyrussa) tahun 2013–2022. Peraturan Menteri Kehutanan Republik Indonesia Nomor: P.55/Menhut-II/2013].Google Scholar

Kneepkens, A. F. L. M. & Macdonald, A. A. (2010). Vertebral column, rib and sternal muscles of Sulawesi babirusa (Babyrousa celebensis). Anatomia, Histologia, Embryologia 40: 149–161.Google Scholar

Kneepkens, A. F. L. M., Badoux, D. M. & Macdonald, A. A. (1989). Descriptive and comparative myology of the forelimb of the babirusa (Babyrousa babyrussa L. 1758). Anatomia, Histologia, Embryologia 18: 349–365.Google Scholar

Lee, R. J., Gorog, A. J., Dwiyahreni, A., et al. (2005). Wildlife trade and implications for law enforcement in Indonesia: a case study from North Sulawesi. Biological Conservation 123: 477–488.Google Scholar

Leus, K. (1994). Foraging behaviour, food selection and diet digestion of Babyrousa babyrussa (Suidae, Mammalia). PhD thesis, The University of Edinburgh.Google Scholar

Leus, K. (1996). The habitat and diet of the Sulawesi babirusa (Babyrousa babyrussa). In Manansang, J., Macdonald, A. A., Siswomartono, D., Miller, P. & Seal, U. (eds.), Population and habitat viability assessment for the babirusa (Babyrousa babyrussa). Report. Apple Valley, MN: Conservation Breeding Specialist Group (SSC/IUCN), pp. 121–143.Google Scholar

Leus, K. (2000). Feeding babirusa (Babyrousa babyrussa) in captivity. In Nijboer, J., Hatt, J.M., Kaumans, W. & Gansloßer, U. (eds.), Zoo animal nutrition. Fürth: Filander, pp. 237–250.Google Scholar

Leus, K. & Macdonald, A. A. (1997). From babirusa to domestic pig: the nutrition of swine. Proceedings of the Nutrition Society 56: 1001–1012.CrossRef Google Scholar PubMed

Leus, K. & Vercammen, P. (1996). Behaviour of a male and female babirusa (Babyrousa babyrussa, Suidae, Mammalia) during the first five days after their move to a semi-natural enclosure. Der Zoologische Garten, N.F. 66(3): 133–155.Google Scholar

Leus, K., Bowles, D., Bell, J. & Macdonald, A. A. (1992). Behaviour of the babirusa (Babyrousa babyrussa) with suggestions for husbandry. Acta Zoologica et Pathologica Antverpiensia 82: 9–27.Google Scholar

Leus, K., Bland, K. P., Dhondt, A. A. & Macdonald, A. A. (1995). Ploughing behaviour of the babirusa (Babyrousa babyrussa) suggests a scent marking function. Journal of Zoology 238: 209–219.CrossRef Google Scholar

Leus, K., Goodall, G. P. & Macdonald, A. A. (1999). Anatomy and histology of the babirusa (Babyrousa babyrussa) stomach. Comptes Rendus de l'Académie des Sciences Série III – Sciences de la Vie 322: 1081–1092.Google Scholar PubMed

Leus, K., Morgan, C. A. & Dierenfeld, E. S. (2001). Nutrition. In Fischer, M. (ed.), Babirusa (Babyrousa babyrussa) husbandry manual. St Louis, MN: American Association of Zoos and Aquariums, pp. 11–28.Google Scholar

Leus, K., Macdonald, A. A., Goodall, G., Veitch, D., Mitchell, S. & Bauwens, L. (2004). Light and electron microscopy of the cardiac gland region of the stomach of the babirusa (Babyrousa babyrussa – Suidae, Mammalia). Comptes Rendus Biologies 327: 735–743.Google Scholar

Leus, K., Macdonald, A., Burton, J., & Rejeki, I. (2016). Babyrousa celebensis. The IUCN Red List of Threatened Species 2016: e.T136446A44142964.Google Scholar

Lopez Gonzales, M. & Taylor, D. C. (1998). Cutaneous aspergillosis in a Babirusa (Babyrousa babyrussa). Veterinary Record 143: 568.Google Scholar

Macdonald, A. A. (1991). Monographie des hirschebers (Babyrousa babyrussa). Bongo, Berlin 18: 69–84.Google Scholar

Macdonald, A. A. (1993). The babirusa (Babyrousa babyrussa). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 161–171.Google Scholar

Macdonald, A. A. (1994). The placenta and cardiac foramen ovale of the babirusa (Babyrousa babyrussa). Anatomy and Embryology 190: 489–494.CrossRef Google Scholar PubMed

Macdonald, A. A. (2008). Ökologie und Schutz des Hirschebers. In Macdonald, A. A. & Gansloßer, U. (eds.), Wilde Schweine und Flußpferde. Fürth: Filander Verlag, pp. 137–154.Google Scholar

Macdonald, A. A. & Kneepkens, A. F. L. M. (1995). Descriptive and comparative myology of the hindlimb of the babirusa (Babyrousa babyrussa L. 1758). Anatomia, Histologia, Embryologia 24: 197–207.Google Scholar

Macdonald, A. A. & Leus, K. (1995). Creating a public understanding of the biology of the babirusa (Babyrousa babyrussa) within a caring zoo environment. Ibex Journal of Mountain Ecology 3: 37–40.Google Scholar

Macdonald, A. A., Bell, J., Munro, S. A., et al. (1989). Observations on the behaviour and health of captive babirusa. In Prociding Simposium Nasional Penyakit Satwa Liar. Surabaya, Indonesia: Universitas Airlangga dan Kebun Binatang, pp. 244–253.Google Scholar

Macdonald, A. A., Bowles, D., Bell, J. & Leus, K. (1993). Agonistic behaviour in captive babirusa (Babyrousa babyrussa). Zeitschrift für Säugetierkunde 58: 18–30.Google Scholar

Macdonald, A. A., Leus, K., Florence, A., Clark, J. & Patry, M. (1996). Notes on the behaviour of Sulawesi warty pigs (Sus celebensis) in North Sulawesi, Indonesia. Malayan Nature Journal 50: 47–53.Google Scholar

Macdonald, A. A., Burton, J. & Leus, K. (2008a). Babyrousa celebensis. The IUCN Red List of Threatened Species 2008: e.T136446A4292795. http://dx.doi.org/10.2305/IUCN.UK.2008.RLTS.T136446A4292795.en.Downloaded 15 December 2015.Google Scholar

Macdonald, A. A., Mitchell, S., Signorella, A., & Leus, K. (2008b). Ultrastructural characterization of the epithelium that constitutes the cardiac gland epithelium ‘honeycomb’ in the stomach of the babirusa (Babyrousa babyrussa). Comptes Rendus Biologies 331: 32–41.CrossRef Google Scholar PubMed

Macdonald, A. A., Leus, K. & Hoare, H. (2016). Maxillary canine tooth growth in babirusa (genus Babyrousa). Journal of Zoo and Aquarium Research 4: 22–29.Google Scholar

MacKinnon, J. (1981). The structure and function of the tusks of the babirusa. Mammal Review 11: 37–40.Google Scholar

Maclaughlin, K., Ostro, L. E. T., Koontz, C. & Koontz, F. (2000). The ontogeny of nursing in Babyrousa babyrussa and a comparison with domestic pigs. Zoo Biology 19: 253–262.Google Scholar

Maklis, T. 1991. Rahasia harta yang hilang. Jakarta: Pustaka Utama Grafiti.Google Scholar

Melisch, R. (1994). Observation of swimming babirusa Babyrousa babyrussa in Lake Poso, Central Sulawesi, Indonesia. Malayan Nature Journal 47: 431–432.Google Scholar

Milner-Gulland, E. J. & Clayton, L. (2002). The trade in babirusa and wild pigs in North Sulawesi, Indonesia. Ecological Economics 42: 165–183.Google Scholar

Mohr, E. (1960). Wilde Schweine. Neue Brehm-Bucherei no. 247. Wittenberg-Lutherstadt: Ziemsen Verlag.Google Scholar

Munro, S. A., Kaspe, L., Sasmita, R. & Macdonald, A. A. (1990). Gastrointestinal helminthosis in the babirusa (Babyrousa babyrussa) and response to ‘Albendazole’. Veterinary Record 126: 16.Google Scholar

Ogle, S. (2010). Techniques to assist conservation breeding of the babirusa (Babyrousa babyrussa). PhD thesis, The University of Edinburgh.Google Scholar

Ogle, S. & Macdonald, A. A. (2008). Die Fortpflanzungsbiologie im Überblick [Biology of reproduction in wild pigs, peccaries and hippos: a review]. In Macdonald, A. A. & Gansloßer, U. (eds.), Wilde Schweine und Flußpferde. Fürth: Filander Verlag, pp. 33–66.Google Scholar

Patry, M. (1990). Babiroussa: une Vie Jusqu'an Bout du Reve. Paris: Fixot.Google Scholar

Patry, M., Leus, K. & Macdonald, A. A. (1995). Group structure and behaviour of babirusa (Babyrousa babyrussa) in Northern Sulawesi. Australian Journal of Zoology 43: 643–655.Google Scholar

Perry, G. (1811). Arcana; or the museum of natural history … Printed by George Smeeton for James Stratford, London.Google Scholar

Peters, C. T. M. (1985). De babiroesa: het hertzwijn. Dieren 5: 135–139.Google Scholar

Purchas, S. (1625). Hakluytus posthumus or Purchas his pilgrimes. London: Henry Fetherstone.Google Scholar

Reinhard, R. & Frädrich, H. (1983). Bemerkungen zur Zucht Hirschebern (Babyrousa babyrussa L.) im Zoo Berlin. Bongo, Berlin 7: 65–70.Google Scholar

Reksowardojo, D. H. (1995). Ringkasan disertasi studi kemampuan reproduksi dan produksi babirusa (Babyrousa babyrussa celebensis Deninger) melalui upaya budidaya. PhD thesis, Bogor, Indonesia.Google Scholar

Sarasin, P. & Sarasin, F. (1905). Materialien zur Naturgeschichte der Insel Celebes. Wiesbaden: C. W. Kreidels, Vol. 5, pp. 4–5, 36–43, 52–54.Google Scholar

Smiet, F. (1982). Threats to the spice islands. Oryx 14: 323–328.Google Scholar

Thenius, E. (1970). Zur Evolution und Verbreitungsgeschicht der Suidae (Artiodactyla, Mammalia). Zeitschrift fur Saugetierkunde 35: 321–342.Google Scholar

United States Department of the Interior. (1980). Republication of the lists of endangered and threatened species and correction of technical errors in final rules. Federal Register 45: 33768–33781.Google Scholar

Urbain, A., Bullier, P. & Nouvel, J. (1938). Au sujet d'une petite épizootie de Fièvre aphteuse ayant sévi sur des animaux sauvages en captivité. Bulletin de l'Académie Vétérinaire de France 11: 59–73.Google Scholar

Van den Bergh, G. D., de Vos, J. & Sondaar, P. Y. (2001). The late quaternary palaeogeography of mammal evolution in the Indonesian archipelago. Palaeogeography, Palaeoclimatology, Palaeoecology 171: 385–408.Google Scholar

Van Wees, S., Nujboer, J., Everts, H. & Beynen, A. C. (2000). Apparent digestibility of macronutrients in captive babirusa (Babyrousa babyrussa). Journal of Zoo and Wildlife Medicine 31: 508–511.Google Scholar

Vercammen, P. (1991). Ubersicht uber die haltung von hirschebern (Babirousa babyrussa celebensis L.) im Zoo Antwerpen. Bongo, Berlin 18: 244–249.Google Scholar

Whitmore, T. C., Tantra, I. G. M. & Sutisna, U. (1989). Tree flora of Indonesia: check list for Sulawesi. Bogor: Forest Research and Development Centre.Google Scholar

Whitten, A. J., Mustafa, M. & Henderson, G. S. (2002). The ecology of Sulawesi. Hong Kong: Periplus Editions.Google Scholar

Ziehmer, B., Ogle, S., Signorella, A., Knorr, C. & Macdonald, A. A. (2010). Anatomy and histology of the reproductive tract of the female Babirusa (Babyrousa celebensis). Theriogenology 74: 184–193.Google Scholar

Ziehmer, B., Signorella, A., Kneepkens, A. F. L. M., et al. (2013). The anatomy and histology of the reproductive tract of the male Babirusa (Babyrousa celebensis). Theriogenology 79: 1054–1064.Google Scholar

References

Akbar, S., Indrawan, M., Yasin, M. P., Burton, J. & Ivan, J. (2007). Status and conservation of Babyrousa babyrussa in the Togean Islands, based on direct observations and questionnaire surveys (intermittenly, 1990–2001). Suiform Soundings 7: 16–25.Google Scholar

Blouch, R. A. (1995). Conservation and research priorities for threatened suids of South and Southeast Asia. IBEX J. M. E. 3: 21–25.Google Scholar

Bosma, A. A. & de Haan, N. A. (1981). The karyotype of Babyrousa babyrussa (suidae, Mammalia). Acta Zoologica et Pathologica Antverpiensia 76: 17–27.Google Scholar

Bosma, A. A., de Haan, N. A. & Macdonald, A. A. (1991). The current status cytogenetics of the Suidae: a review. Bongo, Berlin 18: 258–272.Google Scholar

Bowles, D. (1986). Social behavior and breeding of babirusa (Babyrousa babyrussa) at the Jersy Wildlife Preservation Trust. Dodo 23: 86–94.Google Scholar

Clauss, M., Nijboer, J., Loermans, J. H. M., et al. (2008). Comparative digestion studies in wild suids at Rotterdam Zoo. Zoo Biology 27: 305–319.Google Scholar

Clayton, L. & Macdonald, D. W. (1999). Social organization of the Babirusa (Babyrousa babyrussa) and their use of salt licks in Sulawesi, Indonesia. American Society of Mammalogy 80: 1147–1157.Google Scholar

Clayton, L. M., Milner-Gulland, E. J., Sinaga, D. W. & Mustar, A. H. (1999). Effects of a proposed ex situ conservation program on in situ conservation of the Babirusa, an endangered suid. Conservation Biology 14: 382–385.Google Scholar

Corlett, R. T. (2007). The impact of hunting on the mammalian fauna of tropical Asian forests. Biotropica 39: 292–303.CrossRef Google Scholar

Curran, L.M. & Webb, C.O. (2000). Experimental tests of the spatiotemporal scale of seed predation in mast-fruiting dipterocarpaceae. Ecological Monographs 70(1): 129–168.Google Scholar

Davidson, P., Stones, T. & Lucking, R. (1995). The conservation status of key bird species on Taliabu and the Sula Islands, Indonesia. Bird Conservation International 5: 1–20.Google Scholar

Ellen, R. (1997). The human consequences of deforestation in the Moluccas. Civilisations 44: 176–193.CrossRef Google Scholar

Estes, R. D. (1991). The behavior guide to African mammals: including hoofed mammals, carnivores, primates. Berkeley, CA: University of California Press.Google Scholar

Groves, C. P. (1980). Notes on the systematics of Babyrousa (Artiodactyla, Suidae). Zoologische Mededelingen 55: 29–46.Google Scholar

Gui-Sheng, W. U., Pang, Jung-feng & Zhang, Ya-Ping. (2006). Molecular phylogeny and phylogeography of Suidae. Zoological Research 27(2): 197–201.Google Scholar

Leus, K. (2000). Feeding babirusa (Babyrousa babyrussa) in captivity. Available from www.era.lib.ed.ac.uk/handle/1842/993 (accessed 20 June 2015).Google Scholar

Leus, K. & Macdonald, A. A. (1997). From babirusa (Babyrousa babyrussa) to domestic pig: the nutrition of swine. Proceedings of the Nutrition Society 56: 1001–1012.CrossRef Google Scholar PubMed

Leus, K. & Morgan, C. A. (1995). Analyses of diets fed to Babirusa (Babyrousa babyrussa) in captivity with respect to their nutritional requirements. IBEX J. M. E. 3: 41–44.Google Scholar

Leus, K., Bowles, D., Bell, J. & Macdonald, A. A. (1992). Behaviour of the Babirusa (Babyrousa babyrussa) with suggestions for husbandry. Acta Zoologica et Pathologica Antiverpiensia 82: 9–27.Google Scholar

Leus, K., Bland, K. P., Dhondt, A. A. & Macdonald, A. A. (1996). Ploughing behaviour of Babyrousa babyrussa (Suidae, Mammalia) suggests a scent-marking function. Journal of Zoology 238: 209–219.Google Scholar

Leus, K., Goodall, G. P. & Macdonald, A. A. (1999). Anatomy and histology of the babirusa (Babyrousa babyrussa) stomach. Competes Rendus de l'Academie des Sciences-Series III-Sciences de la Vie 322: 1081–1092.Google Scholar

Macdonald, A. A. (1993). The Babirusa (Babyrousa babyrussa). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN, pp: 11–21.Google Scholar

Macdonald, A. A. (2005). The conservation of the Babirusa (Babyrousa babyrussa). In Sugiri, N., Mustari, A. H., Suwelo, I. S. & Djuwita, I. (eds.), Kumpulan Makalah Seminar Sehari Peduli Anoa dan Babirusa Indonesia (Proceeding of Seminar for Day of Anoa and Babirusa Indonesia Day). Bogor: Institut Pertanian Bogor, pp. 90–111. Available from: www.era.lib.ed.ac.uk/bitstream/handle/1842/2159/Conservation%20of%20the%20Babirusa.pdf?sequence=1 Google Scholar

Macdonald, A. A. & Leus, K. (1995). Creating a public understanding of the biology of the Babirusa (Babyrousa babyrussa) within a caring zoo environment. IBEX J. M. E. 3: 37–40.Google Scholar

Macdonald, A. A., Burton, J. & Leus, K. (2008). Babyrousa babyrussa. The IUCN Red List of Threatened Species 2008: e.T2461A9441445. Available from: http://dx.doi.org/10.2305/IUCN.UK.2008.RLTS.T2461A9441445.en (downloaded 25 June 2015).Google Scholar

Maclaughin, K., Ostro, L. E. T., Koontz, C. & Koontz, F. (2000). The ontogeny of nursing in Babyrousa babyrussa and a comparison with domestic pigs. Zoo Biology 19: 253–262.Google Scholar

Meijaard, E. & Groves, C. (2002). Upgrading three subspecies of babirusa (Babyrousa sp.) to full species level. Asian Wild Pig News 2(2): 33–39.Google Scholar

Meijaard, E. M., Meijaard, E., Macdonald, A. A. & Leus, K. (2016). First observations on Moluccan Babirusa (Babyrousa babirussa). A translation from a recently rediscovered 1770 book that describes the babirusa on Buru Island. Suiform Soundings 15(1): 16–19.Google Scholar

Melisch, R. (1994). Observations of swimming babirusa Babyrousa babyrussa in Lake Poso, Central Sulawesi, Indonesia. Malayan Nature Journal 47: 431–432.Google Scholar

Melisch, R. (1995). Babirusa skulls on sale in South Sulawesi. TRAFFIC Bulletin 15: 99.Google Scholar

Milner-Gulland, E. J. & Clayton, L. (2002). The trade in babirusas and wild pigs in North Sulawesi, Indonesia. Ecological Economics 42: 165–183.Google Scholar

Monk, K. A., Fretes de, Y. & Reksodiharjo-Lilley, G. (1997). The ecology of Nusa Tenggara and Maluku. Singapore: Periplus Editions.Google Scholar

Munro, S. A., Kaspe, L., Sasmita, R., & Macdonald, A. A. (1990). Gastrointestinal helminthosis in the babirusa (Babyrousa babyrussa) and response to albendazole. Veterinary Record 126: 16.Google Scholar

Nijman, V. & Nekaris, K. A. I. (2014). Trade in Babirusa skulls on Bali in 2013. Suiform Soundings 12(2): 34–36.Google Scholar

Oliver, W. L. R. (1995). Taxonomy and conservation status of the suiformes: an overview. IBEX J. M. E. 3: 3–5.Google Scholar

Patry, M., Leus, K. & Macdonald, A. A. (1995). Group structure and behavior of babirusa (Babyrousa babyrussa) in Northern Sulawesi. Australian Journal of Zoology 43: 643–655.Google Scholar

Rappole, J.H. (2007). Wildlife of the Mid-Atlantic: a complete reference manual. Philadelphia, PA: University of Pennsylvania Press.Google Scholar

Sheherazade, & Tsang, S. M. (2015). Quantifying the bat bushmeat in North Sulawesi, Indonesia, with suggestions for conservation action. Global Ecology and Conservation 3: 324–330.Google Scholar

Stelbrink, B., Albrecht, C., Hall, R. & von Rintelen, T. (2012). The biogeography of Sulawesi revisited: is there evidence for a vicariant origin of taxa on Wallace's ‘anomalous island’? Evolution 66: 2252–2271.Google Scholar

Tulung, B., Umboh, J. F. & Pendong, A. F. (2013). A study on babirusa (Babyrousa babyrussa celebensis) in tropical forest of northern part of Sulawesi. Scientific Papers, Series D, Animal Science 56: 107–112.Google Scholar

van Wees, S., Nujboer, J., Everts, H. & Beynen, A. C. (2000). Apparent digestibility of macronutrients in captive Babirusa (Babyrousa babyrussa). Journal of Zoo and Wildlife Medicine 31: 508–511.Google Scholar PubMed

References

Akbar, S., Indrawan, M., Yasin, M. P., Burton, J. & Ivan, J. (2007). Status and conservation of Babyrousa babyrussa in the Togean Islands, based on direct observations and questionnaire surveys (intermittently, 1990–2001). Suiform Soundings 7(1): 16–25.Google Scholar

Balik, I. W., Ito, M., Nakata, H. & Jaga, I. M. (2005). Nest building of Celebes babirusa (Babyrousa babyrussa celebensis). In Sugiri, N., Mustari, A. H., Suwelo, I. S. & Djuwita, I. (eds.), Kumpulan makalah seminar sehari peduli Anoa dan Babirusa Indonesia. Bogor, Indonesia: Institute Pertanian Bogor, pp. 84–89.Google Scholar

Cannon, J. & Surjadi, P. (2004). Informing natural resources policy making using participatory rapid economic valuation (PREV): the case of the Togean Islands, Indonesia. Agriculture, Ecosystems and Environment 104: 99–111.Google Scholar

Froehlich, J. W. & Supriatna, J. (1996). Secondary intergradation between Macaca maurus and M. tonkeana in South Sulawesi, and the species status of M. togeanus. In Fa, J. E., & Lindburg, D. G. (eds.), Evolution and Ecology of Macaque Societies. Cambridge: Cambridge University Press, pp. 43–70.Google Scholar

Groves, C. (1980). Notes on the systematics of Babyrousa (Artiodactyla, Suidae). Zoologische Mededelingen 55: 29–46.Google Scholar

Groves, C. P. (2001). Mammals in Sulawesi: where did they come from and when, and what happened to them when they got there? In Metcalfe, I., Smith, J. M. B., Morwood, M. & Davidson, I. (eds.), Faunal and floral migrations and evolution in SE Asia–Australasia. Lisse, The Netherlands: A. A. Balkema, pp. 333–342.Google Scholar

Indrawan, M., Somadikarta, S., Supriatna, J., et al. (2006). The birds of the Togian islands, Central Sulawesi, Indonesia. Forktail 22: 7–22.Google Scholar

Ito, M. (2003). Preliminary report on Togian babirusa (Babyrousa babyrussa togeanensis) on Malenge Island, Central Sulawesi. Unpublished report to LIPI. Jakarta, Indonesia. July 2003.Google Scholar

Ito, M. (2008). Field status surveys and educational programs of Togian babirusa (Babyrousa togeanensis) on Malenge Island, Central Sulawesi. Unpublished report to LIPI. Jakarta, Indonesia. January 2008.Google Scholar

Ito, M. (2009). The development and growth of the canine teeth in the Celebes Babirusa (Babyrousa celebensis). Unpublished report to RISTEK. Jakarta, Indonesia. January 2009.Google Scholar

Ito, M. (2010). Educational programmes on conservation of the babirusa (Babyrousa spp.) and their natural habitats in Central Sulawesi. Unpublished report to RISTEK. Jakarta, Indonesia. March 2010.Google Scholar

Ito, M. & Balik, I. W. (2010). X-ray anatomical observation of deciduous teeth in the Celebes Babirusa (Babyrousa celebensis). ATBC 2010 Abstracts, The 2010 International Meeting of Association for Tropical Biology and Conservation, p. 302. Bali, Indonesia.Google Scholar

Ito, M., Nakata, H., Jaga, I. M. & Balik, I. W. (2005). Status of Togian babirusa (Babyrousa babyrussa togianensis) on Malenge Island, Central Sulawesi. In Sugiri, N., Mustari, A. H., Suwelo, I. S. & Djuwita, I. (eds.), Kumpulan makalah seminar sehari peduli Anoa dan Babirusa Indonesia. Bogor, Indonesia: Institute Pertanian Bogor, pp. 71–77.Google Scholar

Ito, M., Balik, I. W. & Setiawan, L. (2008). Needs of educational activity for conservation of Togean babirusa in Togean Archipelago, Central Sulawesi. In Proceedings Joint meeting of the 3rd International Meeting on Asian Zoo/Wildlife Medicine and Conservation & 10th National Veterinary Scientific Conference of Indonesian Veterinary Medical Association, pp. 234–236. Bogor, Indonesia.Google Scholar

Jepson, P. & Whittaker, R. J. (2002). Histories of protected areas: internationalisation of conservationist values and their adoption in the Netherlands Indies (Indonesia). Environment and History 8: 129–172.Google Scholar

Leus, K. & Macdonald, A. A. (1997). From babirusa (Babyrousa babyrussa) to domestic pig: the nutrition of swine. Proceeding of the Nutrition Society 56: 1001–1012.Google Scholar

Macdonald, A. A., Burton, J. & Leus, K. (2008). Babyrousa togeanensis. In IUCN 2015: IUCN Red List of Threatened Species. Version 2015.3. www.iucnredlist.org, accessed 1 October 2015.Google Scholar

Macdonald, A., Leus, K., Masaki, I. & Burton, J. (2016). Babyrousa togeanensis. The IUCN Red List of Threatened Species 2016: e.T136472A44143172.Google Scholar

Meijaard, E. & Groves, C. (2002a). Proposal for taxonomic changes within the genus Babyrousa. Asian Wild Pig News 2(1): 9–10.Google Scholar

Meijaard, E. & Groves, C. (2002b). Upgrading three subspecies of Babirusa (Babyrousa sp.) to full species level. Asian Wild Pig News 2(2): 33–39.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. R. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world. Volume 2: Hoofed mammals. Barcelona: Lynx Edicions, pp. 248–291.Google Scholar

Melisch, R. (1994). Observation of swimming Babirusa Babyrousa babyrussa in Lake Poso, Central Sulawesi, Indonesia. Malayan Nature Journal 47: 431–432.Google Scholar

Menteri Kehutanan Republik Indonesia. (2013). Peraturan Menteri Kehutanan Republik, Indonesia, Nomor: P.55/Menhut-II/2013 tentang strategi dan rencanaaksi konservasi babirusa (Babyrousa babyrussa) tahun 2013–2022.Google Scholar

Ministry of Forestry (2013). Forestry statistics of Indonesia 2012. Jakarta, September 2013.Google Scholar

Selmier, V. J. (1983). Bestandsgröße und Verhalten des Hirschebers (Babyrousa babyrussa) auf den Togian Inseln. BONGO 7: 51–64.Google Scholar

Setyodirwiryo, K. (1959). Nature protection in Indonesia. Proceedings of the Ninth Pacific Science Congress of the Pacific Science Association 7: 18–20.Google Scholar

Sody, H. J. V. (1949). Notes on some primates, carnivora, and the babirusa from the Indo-Malayan and Indo-Australian regions. Treubia 20: 121–190.Google Scholar

Surjadi, P. & Supriatna, J. (1998). Bridging community needs and government planning in the Togean Islands, Central Sulawesi, Indonesia. In Dight, I., Kenchington, R. & Baldwin, J. (eds.), Proceedings, International Tropical Marine Ecosystems Management Symposium (ITMEMS), November 22–26, pp. 280–286. Townsville, Australia.Google Scholar

USDA National Nutrient Database for Standard Reference Release 27. (2015). Full Report (All Nutrients): 12104, Nuts, coconut meat, raw. http://ndb.nal.usda.gov/ndb/search, accessed 1 October 2015.Google Scholar

References

Anderson, N. E., Mubanga, J., Fevre, E. M., et al. (2011). Characterisation of the wildlife reservoir community for human and animal trypanosomiasis in the Luangwa Valley, Zambia. PLoS Neglected Tropical Diseases 5(6): e1211. doi:10.1371/journal.pntd.0001211Google Scholar

Ansell, W. F. H. (1972). Order Artiodactyla. In Meester, J. & Setzer, H. W. (eds.), The mammals of Africa: an identification manual. Part 15. Washington, DC: Smithsonian Institution Press, pp. 1–84.Google Scholar

Bigourdan, J. (1948). Le phacochère et les suides dans l'Ouest Africain. Bulletin de l'Institut Fondamental d'Afrique Noire 10: 285–360.Google Scholar

Bolyse, D. G. & Dehority, B. A. (2012). Gastrointestinal protozoa and digestive tract parameters of wild South African warthogs (Phacochoerus aethiopicus). African Zoology 47: 169–177.Google Scholar

Boomker, J., Horak, I. G., Booyse, D. G. & Meyer, S. (1991). Parasites of South African wildlife. VIII. Helminth and arthropod parasites of warthogs, Phacochoerus aethiopicus, in the eastern Transvaal. Onderstepoort Journal of Veterinary Research 58: 195–202.Google Scholar

Boshe, J. I. (1981). Reproductive ecology of the warthog Phacochoerus aethiopicus and its significance for management in the eastern Selous Game Reserve, Tanzania. Biological Conservation 20: 37–44.Google Scholar

Boshoff, A., Landman, M. & Kerley, G. I. H. (2015). Filling the gaps on the maps: historical distribution patterns of some larger mammals in part of southern Africa. Transactions of the Royal Society of South Africa 71: 23–87.Google Scholar

Bosma, A. A. (1978). The chromosomal G-banding pattern in the wart hog, Phacochoerus aethiopicus (Suidae, Mammalia) and its implications for the systematic position of the species. Genetica 49: 15–19.Google Scholar

Bradley, R. M. (1968). Some aspects of the ecology of the warthog (Phacochoerus aethiopicus Pallas) in Nairobi National Park. MSc thesis, University of Nairobi.Google Scholar

Bradley, R. M. (1972). Warthog (Phacochoerus aethiopicus Pallas) burrows in Nairobi National Park. East African Wildlife Journal 9: 149–152.Google Scholar

Butynski, T. M. & De Jong, Y. A. (2010). Warthogs: an alert to zoos, museums, trophy hunters, and conservationists. Suiform Soundings 9(2): 10–13. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

Chardonnet, P. (2001). Southwestern Mali. Antelope Survey Update Number 8. Gland: IUCN/SSC Antelope Specialist Group, pp. 31–38.Google Scholar

Child, G., Sowls, L. & Mitchell, B. L. (1965). Variations in the dentition, ageing criteria and growth patterns in warthog. Arnoldia (Rhodesia) 1(38): 1–23.Google Scholar

Child, G., Roth, H. H. & Kerr, M. (1968). Reproduction and recruitment patterns in warthog (Phacochoerus aethiopicus) populations. Mammalia 32: 6–29.Google Scholar

Clauss, M., Nijboer, J., Loermans, J. H. M., et al. (2008). Comparative digestion studies in wild suids at Rotterdam Zoo. Zoo Biology 27: 305–319.Google Scholar

Clough, G. (1969). Some preliminary observations on reproduction in the warthog, Phacochoerus aethiopicus Pallas. Journal of Reproduction and Fertility (Suppl.) 6: 323–337.Google Scholar

Clough, G. & Hassam, A. G. (1970). A quantitative study of the daily activity of the warthog in the Queen Elizabeth National Park, Uganda. East African Wildlife Journal 8: 19–24.Google Scholar

Coetzee, H. C. (2010). Observations of southern ground-hornbill Bucorvus leadbeateri grooming common warthog Phacochoerus africanus. African Journal of Ecology 48: 1131–1133.Google Scholar

Cooke, H. B. S. & Wilkinson, A. F. (1978). Suidae and Tayassuidae. In Maglio, B. J. & Cooke, H. B. S. (eds.), Evolution of African mammals. Cambridge, MA: Harvard University Press, pp. 435–482.Google Scholar

Cumming, D. H. M. (1975). A field study of the ecology and behaviour of warthog. Museum Memoir No. 7. Salisbury: National Museums & Monuments of Rhodesia.Google Scholar

Cumming, D. H. M. (2013). Phacochoerus africanus common warthog. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury, pp. 54–60.Google Scholar

Cunningham, P. (2016). Encounters with common warthogs along the B1 Highway in north-central Namibia. Suiform Soundings 14(2): 32–37. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

De Garine-Wichatitsky, M., Caron, A., Kock, R., et al. (2013). A review of bovine tuberculosis at the wildlife–livestock–human interface in sub-Saharan Africa. Epidemiology and Infection 141: 1342–1356.Google Scholar

De Jong, Y. A. & Butynski, T. M. (2012). Photos: Biodiversity of northern Kenya's Huri Hills and Mount Forole. National Geographic Explorers Journal. http://voices.nationalgeographic.com/2014/01/03/photos-biodiversity-of-northern-kenyas-huri-hills-and-mount-forole/Google Scholar

De Jong, Y. A. & Butynski, T. M. (2014). Distribution, abundance, ecology, and conservation status of the desert warthog (Phacochoerus aethiopicus) in northern Kenya. Unpublished report to the National Geographic Society, Washington, DC. www.wildsolutions.nl Google Scholar

De Jong, Y. A. & Butynski, T. M. (2016). Photographic map of the common warthog and the desert warthog in eastern Africa. www.wildsolutions.nl/photomaps/phacochoerus/Google Scholar

De Jong, Y. A., Butynski, T. M. & d'Huart, J. P. (2016a). Phacochoerus aethiopicus. The IUCN Red List of Threatened Species 2016: e.T41767A99376685. Gland: IUCN/SSC. www.iucnredlist.org/details/41767/0 Google Scholar

De Jong, Y. A., Cumming, D. H. M., d'Huart, J. P. & Butynski, T. M. (2016b). Phacochoerus africanus. The IUCN Red List of Threatened Species 2016: e.T41768A109669842. Gland: IUCN/SSC. www.iucnredlist.org/details/41767/0 Google Scholar

De Jong, Y. A., d'Huart, J. P. & Butynski, T. M. (In preparation). Biogeography of the desert warthog Phacochoerus aethiopicus (Pallas, 1766) and common warthog Phacochoerus africanus (Gmelin, 1788) in the Horn of Africa.Google Scholar

De Leeuw, J., Waweru, M. N., Okello, O. O., et al. (2001). Distribution and diversity of wildlife in northern Kenya in relation to livestock and permanent water points. Biological Conservation 100: 297–306.Google Scholar

Deribe, E., Bekele, A. & Balakrishnan, M. (2008). Population status and diurnal activity patterns of the common warthog (Phacochoerus africanus) in the Bale Mountains National Park, Ethiopia. International Journal of Ecology and Environmental Sciences 34: 91–97.Google Scholar

d'Huart, J. P. & Grubb, P. (2001). Distribution of the common warthog (Phacochoerus africanus) and the desert warthog (Phacochoerus aethiopicus) in the Horn of Africa. African Journal of Ecology 39: 156–169.CrossRef Google Scholar

d'Huart, J. P. & Grubb, P. (2005). A photographic guide to the differences between the common warthog (Phacochoerus africanus) and the desert warthog (Ph. aethiopicus). Suiform Soundings 5(2): 4–8. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

d'Huart, J. P., Nowak-Kemp, M. & Butynski, T. M. (2013). A seventeenth century warthog skull in Oxford, England. Archives of Natural History 40: 294–301.Google Scholar

Domenech, J., Lubroth, J. & Sumption, K. (2010). Immune protection in animals: the examples of rinderpest and foot-and-mouth disease. Journal of Comparative Pathology 142: 120–124.Google Scholar

Estes, R. D., Cumming, D. H. M. & Hearn, G. W. (1982). New facial glands in domestic pig and warthog. Journal of Mammalogy 63: 618–624.Google Scholar

Ewer, R. F. (1958). Adaptive features in the skulls of African Suidae. Proceedings of the Zoological Society of London 131: 135–155.Google Scholar

Field, C. R. (1970). Observations on the food habits of tame warthog and antelope in Uganda. East African Wildlife Journal 8: 1–17.Google Scholar

Field, C. R. (1972). The food habits of wild ungulates in Uganda by analyses of stomach contents. East African Wildlife Journal 10: 17–42.Google Scholar

Frädrich, H. (1965). Zur biologie und ethologie des warzenschweines (Phacochoerus aethiopicus Pallas) unter berücksightigung des verhaltens anderer suiden. Zietschrift fur Tierpsychologie 22: 328–393.Google Scholar

Geigy, R. (1955). Observations sur les phacochères du Tanganyika. Revue suisse de Zoologie 62: 139–163.Google Scholar

Grobler, J. H. (1980). Host selection and species preference of the red-billed oxpecker Buphagus erythrorhynchus in the Kruger National Park. Koedoe 23: 89–97.Google Scholar

Grobler, J. H. & Charsley, G. W. (1978). Host preference of the yellow-billed oxpecker Buphagus africanus in the Rhodes Matopos National Park, Rhodesia. South African Journal of Wildlife Research 8: 169–170.Google Scholar

Groves, C. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Grubb, P. (1993). The Afrotropical suids Phacochoerus, Hylochoerus and Potamochoerus. 4.1 Taxonomy and description. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group and IUCN/SSC Hippo Specialist Group, pp. 66–75.Google Scholar

Grubb, P. (2005). Order Artiodactyla. In Wilson, D. E. & Reeder, D. M. (eds.), Mammal species of the world: a taxonomic and geographic reference. 3rd ed. Baltimore, MD: The Johns Hopkins University Press, Vol. 1, pp. 637–722.Google Scholar

Grubb, P. (2013). Phacochoerus warthogs. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury, p. 50.Google Scholar

Grubb, P. & d'Huart, J. P. (2010). Rediscovery of the Cape warthog Phacochoerus aethiopicus: a review. Journal of East African Natural History 99: 77–102.Google Scholar

Grubb, P. & d'Huart, J. P. (2013). Phacochoerus aethiopicus desert warthog. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury, pp. 51–53.Google Scholar

Grubb, P., Jones, T. S., Davies, A. G., et al. (1998). Mammals of Ghana, Sierra Leone and The Gambia. Cornwall: The Trendrine Press.Google Scholar

Guiraud, M. (1948). Contribution a l'etude du Phacochoerus aethiopicus (Pallas). Mammalia 12: 54–66.Google Scholar

Haltenorth, T. (1963). Klassifikation der säugetiere: Artiodactyla 1(18). Handbuch der Zoologie 8(32): 1–167.Google Scholar

Hayward, M. W. & Hayward, M. D. (2012). Waterhole use by African fauna. South African Journal of Wildlife Research 42: 117–127.Google Scholar

Hollister, N. (1924). East African mammals in the United States National Museum. Part III. Primates, Artiodactyla, Perissodactyla, Proboscidea and Hyracoidea. Bulletin of the Smithsonian Institution, United States National Museum 99: 1–164.Google Scholar

Horak, I. G., Boomker, J., De Vos, V. & Potgieter, F. T. (1988). Parasites of domestic and wild animals in South Africa. XXIII. Helminths and arthropods of warthogs, Phacochoerus aethiopicus, in the eastern Transvaal Lowveld. Onderstepoort Journal of Veterinary Research 55: 145–152.Google Scholar

Jori, F. & Bastos, A. D. S. (2009). Role of wild suids in the epidemiology of African swine fever. EcoHealth 6: 296–310.Google Scholar

Kingdon, J. (1979). East African mammals: an atlas of evolution in Africa. Vol. 3, Pt B: Large Mammals. London: Academic Press.Google Scholar

Kumssa, T. & Bekele, A. (2013). Population status and activity pattern of desert warthog (Phacochoerus aethiopicus) in Abijata-Shalla Lakes National Park, Ethiopia. Academia Journal of Environmental Sciences 1: 9–17.Google Scholar

Künzel, T., Rayaleh, H. A. & Heckel, J-O. (2004). Warthogs of Djibouti. Suiform Soundings 4(2): 55–57. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

Lamprey, H. F. (1963). Ecological separation of large mammal species in the Tarangire Game Reserve, Tanganyika. East African Wildlife Journal 1: 63–93.CrossRef Google Scholar

Lönnberg, E. (1909). Remarks on some warthog skulls in the British Museum. Proceedings of the Zoological Society of London 1908: 936–940.Google Scholar

Mason, D. R. (1982). Studies on the biology and ecology of the warthog Phacochoerus aethiopicus sundevalli Lönnberg, 1908 in Zululand. DSc thesis, University of Pretoria.Google Scholar

Mason, D. R. (1984). Dentition and age determination of the warthog Phacochoerus aethiopicus in Zululand, South Africa. Koedoe 27: 79–119.Google Scholar

Mason, D. R. (1985). Postnatal growth and physical condition of warthogs Phacochoerus aethiopicus in Zululand. South African Journal of Wildlife Research 15: 89–97.Google Scholar

Mason, D. R. (1986). Reproduction in the male warthog Phacochoerus aethiopicus from Zululand, South Africa. South African Journal of Zoology 21: 39–47.Google Scholar

Mason, D. R. (1990). Juvenile survival and population structure of blue wildebeest and warthogs in the Central Region of the Kruger National Park during the mid-summer drought of 1988/89. Koedoe 33: 29–45.Google Scholar

Matthee, S., Swanepoel, M., van der Mescht, L., Leslie, A. J. & Hoffman, L. C. (2013). Ectoparasites of a non-indigenous warthog population, Phacochoerus africanus, in the Free State Province, South Africa. African Zoology 48: 259–265.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. R. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of mammals of the world. Barcelona: Lynx Edicions, pp. 248–291.Google Scholar

Musilova, P., Kubickova, S., Hornak, M., et al. (2010). Different fusion configurations of evolutionary conserved segments in karyotypes of Potamochoerus porcus and Phacochoerus africanus. Cytogenetic and Genome Research 129: 305–309.Google Scholar

Muwanika, V. B., Nyakaana, S., Siegismund, H. R. & Arctander, P. (2003). Phylogeography and population structure of the common warthog (Phacochoerus africanus) inferred from variation in mitochondrial DNA sequences and microsatellite loci. Heredity 91: 361–372.Google Scholar

Naish, D. (2015). 5 neat things about warthog skeletons. Scientific American Blogs. https://scifeeds.com/blog/5-neat-things-about-warthog-skeletons/Google Scholar

Nyafu, K. (2009). Warthog as an introduced species in the Eastern Cape. MSc thesis, Nelson Mandela Metropolitan University.Google Scholar

Ogutu, J. O., Piepho, H. P. & Dublin, H. T. (2014). Reproductive seasonality in African ungulates in relation to rainfall. Wildlife Research 41: 323–342.Google Scholar

Ogutu, J. O., Owen-Smith, N., Piepho, H. P. & Dublin, H. T. (2015). How rainfall variation influences reproductive patterns of African savanna ungulates in an equatorial region where photoperiod variation is absent. PLoS ONE 10(8): e0133744.Google Scholar

Owen, J. (2015). Turtles groom warthog in never-before-seen behavior. National Geographic Weird and Wild. http://news.nationalgeographic.com/2015/10/151008-turtles-warthogs-africa-animals-science/.Google Scholar

Penrith, M-L. (2009). African swine fever: transboundary diseases. Onderstepoort Journal of Veterinary Research 76: 91–95.Google Scholar

Pienaar, U. de V. (1969). Predator–prey relationships amongst the larger mammals of the Kruger National Park. Koedoe 12: 108–187.Google Scholar

Plesner Jensen, S., Siefert, L., Okori, J. J. L. & Clutton-Brock, T. H. (1999). Age-related participation in allosuckling by nursing warthogs Phacochoerus africanus. Journal of Zoology 248: 443–449.Google Scholar

Plumptre, A. J. (2016). Banded mongooses grooming warthogs. Suiform Soundings 14(2): 31. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

Radke, R. (1991). Monographie des warzenschweines (Phacochoerus aethiopicus). Bongo, Berlin 18: 119–134.Google Scholar

Radke, R. & Niemitz, C. (1989). Zu funktionen des duftdrüsenmarkierens beim warzenschwein (Phacochoerus aethiopicus). Zietschrift für Säugetierkunde 54: 111–122.Google Scholar

Renwick, A. R., White, P. C. L. & Bengis, R. G. (2007). Bovine tuberculosis in southern African wildlife: a multi-species host–pathogen system. Epidemiology and Infection 135: 529–540.Google Scholar

Rodgers, W. A. (1984). Warthog ecology in south east Tanzania. Mammalia 48: 327–350.Google Scholar

Rosenmeier, T. (2013). iNaturalist photograph and comments: Pelomedusa galeata grooming Phacochoerus africanus. Website: www.inaturalist.org/observations/500014 Google Scholar

Roth, H. H. (1965). Observations on growth and ageing of warthog Phacochoerus aethiopicus (Pallas, 1766). Zietschrift für Säugetierkunde 30: 367–380.Google Scholar

Sazima, I. (2010). What do coatis and mongooses have in common? Biota Neotropica 10: 457–461.Google Scholar

Schaller, G. (1972). The Serengeti lion. A study of predator–prey relations. Chicago, IL: University of Chicago Press.Google Scholar

Shortridge, G. C. (1934). The mammals of South West Africa. Vols. 1 & 2. London: William Heinemann.Google Scholar

Skinner, J. D. & Chimimba, C. T. (2005). The mammals of the Southern African Subregion. 3rd ed. Cape Town: Cambridge University Press.Google Scholar

Smith, L. (2011). Common warthog Phacochoerus africanus. North American Regional Studbook. Sioux Falls, SD: Great Plains Zoo.Google Scholar

Smithers, R. H. N. (1971). The mammals of Botswana. Museum Memoir No. 4. Salisbury: National Museums and Monument of Rhodesia.Google Scholar

Somers, M. J. (1997). Activity patterns and activity budgets of warthogs (Phacochoerus aethiopicus) in the Eastern Cape Province, South Africa. African Journal of Ecology 35: 73–79.Google Scholar

Somers, M. J. & Penzhorn, B. L. (1992). Reproduction in a reintroduced warthog population in the Eastern Cape Province. South African Journal of Wildlife Research 22: 57–60.Google Scholar

Somers, M. J., Penzhorn, B. L. & Rasa, O. A. E. (1994). Home range size, range use and dispersal of warthogs in the Eastern Cape, South Africa. Journal of African Zoology 108: 361–373.Google Scholar

Somers, M. J., Rasa, O. A. E. & Penzhorn, B. L. (1995). Group structure and social behaviour of warthogs Phacochoerus aethiopicus. Acta Theriologica 40: 257–281.Google Scholar

Souron, A. (2015). Are we ready for meta-analyses of mammalian faunas based on faunal lists? A case-study using the Plio–Pleistocene African Suidae. Suiform Soundings 14(1): 35–43. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

Souron, A. (2016). On specimens of extant warthogs (Phacochoerus) from the Horn of Africa with unusual basicranial morphology: rare variants of Ph. africanus or hybrids between Ph. africanus and Ph. aethiopicus? Suiform Soundings 15(1): 86–92. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

Sowls, L. K. & Phelps, R. J. (1966). Body temperatures of juvenile warthogs (Phacochoerus aethiopicus) and bushpigs (Potamochoerus porcus). Journal of Mammalogy 47: 134–137.Google Scholar

Spinage, C. A. (1972). African ungulate life tables. Ecology 53: 645–652.Google Scholar

Spinage, C. A. & Jolly, G. M. (1974). Age estimation of warthog. Journal of Wildlife Management 38: 229–233.Google Scholar

Stommel, C., Hofer, M., Grobbel, M. & East, M. L. (2016). Large mammals in Ruaha National Park, Tanzania, dig for water when water stops flowing and bacterial load increases. Mammalian Biology 81: 21–30.Google Scholar

Swanepoel, M., Schulze, E. & Cumming, D. H. M. (2016). A conservation assessment of Phacochoerus africanus. In Child, M. F., Roxburgh, L., Do Linh San, E., Raimondo, D. & Davis-Mostert, H. T. (eds.), The Red List of mammals of South Africa, Swaziland and Lesotho. Pretoria: South African National Biodiversity Institute and Endangered Wildlife Trust, pp. 1–7.Google Scholar

Treydte, A. C., Bernasconi, S. M., Kreuzer, M. & Edwards, P. J. (2006). Diet of the common warthog (Phacochoerus africanus) on former cattle grounds in a Tanzanian savanna. Journal of Mammalogy 87: 889–898.Google Scholar

Uehara, S. (1997). Predation on mammals by the chimpanzee (Pan troglodytes). Primates 38: 193–214.Google Scholar

Vale, G. A. & Cumming, D. H. M. (1976). The effects of selective elimination of hosts on a population of tsetse flies (Glossina morsitans morsitans Westwood (Diptera, Glossinidae)). Bulletin of Entomological Research 66: 713–729.Google Scholar

Vercammen, P. & Mason, D. R. (1993). 402 The warthogs (Phacochoerus africanus and P. aethiopicus). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group and IUCN/SSC Hippo Specialist Group, pp. 75–84.Google Scholar

White, A. M. (2010). A pigheaded compromise: do competition and predation explain variation in warthog group size? Behavioral Ecology 21: 485–492.Google Scholar

White, A. M. & Cameron, E. Z. (2009). Communal nesting is unrelated to burrow availability in the common warthog. Animal Behaviour 77: 87–94.Google Scholar

Yalden, D. W., Largen, M. J., Kock, D. & Hillman, J. C. (1996). Catalogue of the mammals of Ethiopia and Eritrea. 7. Revised checklist, zoogeography and conservation. Tropical Zoology 9: 73–164.Google Scholar

References

Boshoff, A. F. & Kerley, G. I. H. (2013). Historical incidence of the larger mammals in the Free State Province (South Africa) and Lesotho. Port Elizabeth: Centre for African Conservation Ecology, Nelson Mandela Metropolitan University.Google Scholar

Culverwell, J., Feely, J., Bell-Cross, S., De Jong, Y. A. & Butynski, T. M. (2008). A new pig for Tsavo. Swara 31: 50–52. www.wildsolutions.nl/a-new-pig-for-tsavo/Google Scholar

Cumming, D. H. M. (1975). A field study of the ecology and behaviour of warthog. Museum Memoir No. 7. Salisbury: National Museums & Monuments of Rhodesia.Google Scholar

Cuvier, F. (1810). Essais sur les rapports des espèces du genre cochon; et description des dents de ces animaux. Nouveau Bulletin des Sciences par la Société Philomathique 2: 138–139.Google Scholar

Cuvier, F. (1816). Le Règne Animal. Vol. 1, pp. 235. Paris.Google Scholar

Cuvier, F. (1826). Dictionnaire des Sciences Naturelles. 39: 393.Google Scholar

De Jong, Y. A. & Butynski, T. M. (2011). Primate survey on the north coast of Kenya. Unpublished report by the Eastern Africa Primate Diversity and Conservation Program, Nanyuki, Kenya. www.wildsolutions.nl Google Scholar

De Jong, Y. A. & Butynski, T. M. (2014). Distribution, abundance, ecology, and conservation status of the desert warthog (Phacochoerus aethiopicus) in northern Kenya. Unpublished report to the National Geographic Society, Washington, DC. www.wildsolutions.nl Google Scholar

De Jong, Y. A. & Butynski, T. M. (2016). Photographic map of the common warthog and the desert warthog in eastern Africa. www.wildsolutions.nl/photomaps/phacochoerus/Google Scholar

De Jong, Y. A., Culverwell, J. & Butynski, T. M. (2009). Desert warthog Phacochoerus aethiopicus found in Tsavo East National Park and Tsavo West National Park, southern Kenya. Suiform Soundings 8(2): 4–6. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

De Jong, Y. A., Butynski, T. M. & d'Huart, J. P. (2016). Phacochoerus aethiopicus. The IUCN Red List of Threatened Species 2016: e. T41767A99376685. Gland: IUCN/SSC. www.iucnredlist.org/details/41767/0 Google Scholar

De Jong, Y. A., d'Huart, J. P. & Butynski, T. M. (In preparation). Biogeography of the desert warthog Phacochoerus aethiopicus (Pallas, 1766) and common warthog Phacochoerus africanus (Gmelin, 1788) in the Horn of Africa.Google Scholar

d’Huart, J. P. & Grubb, P. (2005). A photographic guide to the differences between the common warthog (Phacochoerus africanus) and the desert warthog (Ph. aethiopicus). Suiform Soundings 5(2): 4–8. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

d'Huart, J. P., Nowak-Kemp, M. & Butynski, T. M. (2013). A seventeenth century warthog skull in Oxford, England. Archives of Natural History 40: 294–301.Google Scholar

Domenech, J., Lubroth, J. & Sumption, K. (2010). Immune protection in animals: the examples of rinderpest and foot-and-mouth disease. Journal of Comparative Pathology 142: 120–124.Google Scholar

Estes, R. D., Cumming, D. H. M. & Hearn, G. W. (1982). New facial glands in domestic pig and warthog. Journal of Mammalogy 63: 618–624.Google Scholar

Ewer, R. F. (1957). A collection of Phacochoerus aethiopicus teeth from the Kalkbank Middle Stone Age site, Central Transvaal. Paleontologia Africana 5: 5–20.Google Scholar

Ewer, R. F. (1958). Adaptive features in the skulls of African Suidae. Proceedings of the Zoologica Society of London 131: 135–155.Google Scholar

Fagotto, F. (1985). Larger animals of Somalia in 1984. Environmental Conservation 12: 260–264.Google Scholar

Funaioli, U. & Simonetta, A. M. (1966). The mammalian fauna of the Somali Republic: status and conservation problems. Monitore Zoologico Italiano 74: 285–347.Google Scholar

Gongora, J., Cuddahee, R. E., Ferreira do Nascimento, F., et al. (2011). Rethinking the evolution of extant sub-saharan African suids (Suidae, Artiodactyla). Zoologica Scripta 40: 327–335.Google Scholar

Groves, C. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: The Johns Hopkins University Press.Google Scholar

Grubb, P. (1993). The Afrotropical suids: Phacochoerus, Hylochoerus and Potamochoerus. 4.1 Taxonomy and description. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group and IUCN/SSC Hippo Specialist Group, pp. 66–75.Google Scholar

Grubb, P. (2005). Order Artiodactyla. In Wilson, D. E. & Reeder, D. M. (eds.), Mammal species of the world: a taxonomic and geographic reference, 3rd ed. Baltimore, MD: The Johns Hopkins University Press, Vol. 1, pp. 637–722.Google Scholar

Grubb, P. & d'Huart, J. P. (2010). Rediscovery of the Cape warthog Phacochoerus aethiopicus: a review. Journal of East African Natural History 99: 77–102.Google Scholar

Grubb, P. & d’Huart, J. P. (2013). Phacochoerus aethiopicus desert warthog. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury, pp. 51–53.Google Scholar

Grubb, P. & Oliver, W. (1991). A forgotten warthog. Species 17: 61.Google Scholar

Haltenorth, T. (1963). Klassifikation der säugetiere: Artiodactyla 1(18). Handbuch der Zoologie 8(32): 1–167.Google Scholar

Happold, D. & Lock, J. M. (2013). The biotic zones of Africa. In Kingdon, J., Happold, D., Hoffmann, M., et al. (eds.), Mammals of Africa. Vol. 1. Introductory chapters and Afrotheria. London: Bloomsbury, pp. 57–75.Google Scholar

Harris, J. M. (2013). Subfamily Suinae pigs, hogs. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury, pp. 25–26.Google Scholar

Heller, E. (1914). Four new subspecies of large mammals for equatorial Africa. Smithsonian Miscellaneous Collection 61 (22): 1–7.Google Scholar

Hoffman, M. T. & Cowling, R. M. (1990). Vegetation change in the semi-arid Karoo over the last 200 years: an expanding Karoo – fact or fiction? South African Journal of Science 86: 286–294.Google Scholar

IUCN (2001). IUCN Red List Categories and Criteria: Version 3.1. Gland: IUCN/SSC. www.iucnredlist.org Google Scholar

Jori, F. & Bastos, A. D. S. (2009). Role of wild suids in the epidemiology of African swine fever. EcoHealth 6: 296–310.Google Scholar

Kerley, G. I. H. & Boshoff, A. F. (2014). The common warthog and its parasites in the Free State Province (South Africa) cannot be used to test the ‘enemy release’ hypothesis for an introduced species: the value of reference point information for testing hypotheses of change. African Zoology 49: 169–171.Google Scholar

Kingdon, J. (1979). East African mammals: an atlas of evolution in Africa. Vol. 3, Pt. B: Large mammals. London: Academic Press.Google Scholar

Kingdon, J. (2015). The Kingdon field guide to African mammals. 2nd ed. London: Bloomsbury.Google Scholar

Lönnberg, E. (1909). Remarks on some wart-hog skulls in the British Museum. Proceedings of the Zoological Society of London 1908: 936–940.Google Scholar

Ludwig, J. A., Tongway, D. J., Freudenberger, D., Noble, J. & Hodgkinson, K. (eds.) (1997). Landscape ecology: function and management: principles from Australia's rangelands. Melbourne: CSIRO Publishing.Google Scholar

Lwande, O. W., Lutomiah, J., Obanda, V., et al. (2013). Isolation of tick and mosquito-borne arboviruses from ticks sampled from livestock and wild animal hosts in Ijara District, Kenya. Vector Borne Zoonotic Diseases 13: 637–642.Google Scholar

Lydekker, R. (1908). The game animals of Africa. London: Rowland Ward.Google Scholar

Lydekker, R. (1911). Supplement to the game animals of Africa. London: Rowland Ward.Google Scholar

Lydekker, R. (1915). Catalogue of the ungulate mammals in the British Museum (Natural History). Vol. 4. London: Trustees of the British Museum.Google Scholar

Mendoza, M. & Palmqvist, P. (2008). Hypsodonty in ungulates: an adaptation for grass consumption or for foraging in open habitat? Journal of Zoology 274: 134–142.Google Scholar

Morrison-Scott, T. C. S. (1953). Proposed use of the plenary powers to validate the generic name ‘Phacochoerus' as from Cuvier (F.), 1826, as the generic name for the wart hog. Bulletin of Zoological Nomenclature 11: 191–195. http://direct.biostor.org/reference/146391.text Google Scholar

Muwanika, V. B., Kock, R., Masembe, C. & Siegismund, H. R. (2012). Genetic diversity in the desert warthog (Phacochoerus aethiopicus delamerei) population of eastern Africa. South African Journal of Wildlife Research 42: 54–59.Google Scholar

Naish, D. (2015). 5 neat things about warthog skeletons. Scientific American Blogs. https://scifeeds.com/blog/5-neat-things-about-warthog-skeletons/Google Scholar

Njoroge, P., Yeggo, R., Muchane, M., et al. (2009). A survey of the large and medium sized mammals of Arawale National Reserve, Kenya. Journal of East African Natural History 98: 119–128.Google Scholar

Nyafu, K. (2009). Warthog as an introduced species in the Eastern Cape. MSc thesis, Nelson Mandela Metropolitan University.Google Scholar

Pallas, P. S. (1766). Miscellanea zoologica quibus novae imprimis atque obscurae animalium species describuntur et observationibus iconibusque illustrantur. Hagae Comitum: P. van Cleef.Google Scholar

Randi, E., d'Huart, J. P., Lucchini, V. & Aman, R. (2002). Evidence of two genetically deeply divergent species of warthog Phacochoerus africanus and P. aethiopicus (Artiodactyla: Suiformes) in East Africa. Mammalian Biology 67: 91–96.Google Scholar

Rookmaaker, L. C. (1989). The zoological exploration of Southern Africa 1650–1790. Rotterdam: Balkema.Google Scholar

Roosevelt, T. & Heller, E. (1915). Life histories of African game animals. London: John Murray.Google Scholar

Schmidt, C. R. (1990). Pigs. In Grzimek, B. (ed.), Grzimek's encyclopedia of mammals. New York, NY: McGraw-Hill, Vol. 3, pp. 20–47.Google Scholar

Sclater, P. L. (1869). Notices of additions to the Society's menagerie. Exhibition of drawings illustrative of wart-hogs. Proceedings of the Zoological Society of London 1869: 276–277.Google Scholar

Skead, C. J. (2011). Historical incidence of the larger land mammals in the broader western and northern Cape. 2nd ed. Port Elizabeth: Centre for African Conservation Ecology, Nelson Mandela Metropolitan University.Google Scholar

Skinner, J. D. & Chimimba, C. T. (2005). The mammals of the Southern African Subregion. 3rd ed. Cape Town: Cambridge University Press.Google Scholar

Sparrman, A. (1789). A Voyage to the Cape of Good Hope, towards the Antarctic Polar Circle, and round the world: but chiefly into the country of the Hottentots and Caffres, from the year 1772 to 1776. Vol. 2. Perth: Morison & Son.Google Scholar

Vercammen, P. & Mason, D. R. (1993). The warthogs (Phacochoerus africanus and P. aethiopicus). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group and IUCN/SSC Hippo Specialist Group, pp. 75–84.Google Scholar

Vosmaer, A. (1766). Natuurlyke historie van het Africaansche breedsnuitig varken, of Bosch-Zwyn. Amsterdam: Pieter Meijer.Google Scholar

White, F. (1983). The vegetation of Africa: a descriptive memoir to accompany the UNESCO/AETFAT/UNSC vegetation map of Africa. Paris: UNESCO.Google Scholar

Wilhelmi, F., Kaariye, X. Y. & Heckel, J.-O. (2004). The desert warthog in the Ogaden, Ethiopia. Suiform Soundings 4(2): 52–54. https://sites.google.com/site/wildpigspecialistgroup/iucnssc-wild-pig-specialist-group/suiform-soundings-2 Google Scholar

References

Cerling, T. E. & Viehl, K. (2004). Seasonal diet changes of the giant forest hog (Hylochoerus meinertzhageni Thomas) based on the carbon isotopic composition of hair. African Journal of Ecology 42: 88–92.Google Scholar

Chapman, C. A., Chapman, L. J., Jacob, A. L., et al. (2010). Tropical tree community shifts: implications for wildlife conservation. Biological Conservation 143: 366–374.Google Scholar

d'Huart, J. P. (1978). Écologie de l'hylochère (Hylochoerus meinertzhageni Thomas) au Parc National des Virunga. Exploration PNV, Deuxième Série, Fasc. 25. Bruxelles: Fondation pour Favoriser les Recherches Scientifiques en Afrique.Google Scholar

d’Huart, J. P. (1993). The Forest Hog (Hylochoerus meinertzhageni). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 84–93.Google Scholar

d'Huart, J. P. & Kingdon, J. (2013). Hylochoerus meinertzhageni Forest Hog. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa: Vol. 6. Pigs, hippopotamuses, chevrotain, giraffes, deer and bovids. London: Bloomsbury Publishing, pp. 42–49.Google Scholar

d'Huart, J. P. & Klingel, H. (2008). Hylochoerus meinertzhageni. In IUCN Red List of Threatened Species. Version 2010.1. www.iucnredlist.org. Downloaded 12 December 2015.Google Scholar

d'Huart, J. & Reyna, R. (2016). Hylochoerus meinertzhageni. The IUCN Red List of Threatened Species 2016.Google Scholar

d'Huart, J. P. & Siege, L.. (2012). More on the giant forest hog in Jibat, Ethiopia: Dr Jean-Pierre d'Huart and Dr Ludwig Siege continue the conversation. Suiform Sounding 12: 4–5.Google Scholar

d'Huart, J. P. & Yohannes, E. (1995). Assessment of the present distribution of the forest hog (Hylochoerus meinertzhageni) in Ethiopia. Ibex 3: 46–48.Google Scholar

Ewer, R. F. (1970). The head of the Forest Hog, Hylochoerus meinertzhageni. East African Wildlife Journal 8: 43–52.Google Scholar

Fimpel, S. (2002). Zur Ökologie und Ethologie des Afrikanischen Riesenwaldschweines (Hylochoerus meinertzhageni Thomas). 133 pp. Diplomarbeit Freie Universität Berlin.Google Scholar

Grimshaw, J. M. (1998). The Giant Forest Hog Hylochoerus meinertzhageni in Tanzania – records rejected. Mammalia 62: 123–125.Google Scholar

Groves, C. P. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Grubb, P. (1993). The Afrotropical Suids Phacochoerus, Hylochoerus, and Potamochoerus. In: Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 66–75.Google Scholar

Hart, J. A. (2001). Diversity and abundance in an African forest ungulate community and implications for conservation. Part III: The forest ecosystem. In Weber, W., White, L. J. T., Vedder, A. & Naughton-Treves, L. (eds.), African rain forest ecology and conservation: an interdisciplinary perspective. New Haven, CT: Yale University Press, pp. 183–206.Google Scholar

Kingdon, J. (1979). East African mammals. an atlas of evolution in Africa. Volume III Part B (large mammals). London: Academic Press.Google Scholar

Klingel, H. & Klingel, U. (1999). The African Giant Forest Hog Hylochoerus meinertzhageni. International Ethological Conference in Bangalore. Advances in Ethology 34: 152.Google Scholar

Klingel, H. & Klingel, U. (2004). Giant forest hog Hylochoerus meinertzhageni in Queen Elizabeth National Park, Uganda. Suiform Soundings 4: 24–25.Google Scholar

Klingel, H., Klingel, U., Dorges, B. & Heucke, J. (2001). Infanticide in ungulates. International Ethological Conference in Tubingen. Advances in Ethology 36: 111.Google Scholar

Kock, D. & Howell, K. M. (1999). The enigma of the giant forest hog, Hylochoerus meinertzhageni (Mammalia: Suidae), in Tanzania reviewed. Journal of East African Natural History 88: 25–34.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermier, R. A. (eds.), Handbook of the mammals of the world, volume 2, hoofed mammals. Barcelona: Lynx Editions, pp. 248–291.Google Scholar

Rahm, U. & Christiaensen, A. (1963). Les mammifères de la région occidentale du Lac Kivu. Annales du Musée Royal de l'Afrique Centrale – Sciences Zoologiques 118: 54–56.Google Scholar

Reyna-Hurtado, R. (2015). The giant forest hog (Hylochoerus meinertzhageni) and other terrestrial mammals of Kibale National Park, Uganda. Final report to National Geographic Committee of Research and Exploration.Google Scholar

Reyna-Hurtado, R., Tumukunde, A., Chapman, C. A., et al. (2014). On the track of the Giant Forest Hog in Kibale, National Park, Uganda: a preliminary report on studying the species. Suiform Soundings 12: 38–41.Google Scholar

Schneider, S. & Viehl, K. (2000). The Giant Forest Hog: neither bold nor beautiful. Africa Environment and Wildlife 8: 72–76.Google Scholar

Siege, L. (2011). Infanticide in giant forest hog (Hylochoerus meinertzhageni). Suiform Soundings 11(1): 3–5.Google Scholar

Tumukunde, A., Reyna-Hurtado, R., Chapman, C. A., et al. (Submitted). Gastro-intestinal parasites of wild suids in Kibale National Park, Uganda and domestic suids a the park boundary: the potential for parasites transmission. Journal of Parasitology.Google Scholar

Turkalo, A. (In preparation). Visitation frequency and group size of giant forest hog (Hylochoerus meinertzhageni) and red river hog (Potamochoerus porcus), Dzanga Ndoki National Park, Central African Republic.Google Scholar

Viehl, K. (2003). Untersuchungen zur Nahrungsökologie des Afrikanischen Riesenwaldschweins (Hylochoerus meinertzhageni Thomas) im Queen Elizabeth National Park, Uganda. Osnabrück: Der Andere Verlag.Google Scholar

References

Attwell, C. A. M. & Bearder, S. (1976). The bushpigs of Narina. African Wildlife 30 (2): 12–13.Google Scholar

Beuerle, W. (1975). Freilanduntersuchungen zum Kampf- und Sexualverhalten des europäischen Wildschweines (Sus scrofa L). Zeitschrift für Tierpsychologie 39: 211–258.Google Scholar

Boomker, J. (2007). Helminth infections: wildlife. Pretoria: University of Pretoria.Google Scholar

Breytenbach, G. J. (1977). An ecological study of the bushpig (Potamochoerus porcus – 1758) of the eastern shores of Lake St Lucia, with particular reference to feeding. BSc Hons (Zoology) thesis, Department of Zoology, University of Pretoria.Google Scholar

Breytenbach, G. J. (1979). The enigmatic bushpig. African Wildlife 33 (5): 48–49.Google Scholar

Breytenbach, G. J. & Skinner, J. D. (1982). Diet, feeding and habitat utilization by bushpigs Potamochoerus porcus Linnaeus. South African Journal of Wildlife Research 12: 1–7.Google Scholar

Cooke, H. B. S. & Wilkinson, A. F. (1978). Suidae and Tayassuidae. In Maglio, V. J. & Cooke, H. B. S. (eds.), Evolution of African mammals. Cambridge, MA: Harvard University Press.Google Scholar

Cowling, R. M. (1982). Vegetation studies in the Humansdorp region of the Fynbos Biome. PhD thesis, Department of Botany, University of Cape Town.Google Scholar

d'Huart, J. P. (1978). Ecologie de l'Hylochère (Hylochoerus meinertzhageni Thomas) au Parc National des Virunga. Exploration du Parc National des Virunga. Deuxième Série, Fascicule 25, Bruxelles, Belgium.Google Scholar

Frädrich, H. (1967). Das Verhalten der Schweine (Suidae, Tayassuidae) und Flusspferde (Hippopotamidae). Handbuch der Zoologie 8 (10): 1–44.Google Scholar

Frädrich, H. (1974). A comparison of behaviour in the Suidae. IUCN Publications (New Series), No. 24, Vol. 1: Paper No. 6: 133–143.Google Scholar

Gaidet, N., Hervé, F. & Nyahuma, C. (2003). A participatory counting method to monitor populations of large mammals in non-protected areas: a case study of bicycle counts in the Zambezi Valley, Zimbabwe. Biodiversity and Conservation 12: 1571–1585.Google Scholar

Geist, V. (1978). On weapons, combat and ecology. In Kranes, L., Pliner, P. & Alloway, T. (eds.), Aggression, dominance and individual spacing (advances in the study of communication and affect). New York, NY: Plenum, Vol. 4, pp. 1–30.Google Scholar

Ghiglieri, M. P., Butynski, T. M., Struhsaker, T. T., et al. (1982). Bushpig (Potamochoerus porcus) polychromatism and ecology in Kibale Forest, Uganda. African Journal of Ecology 20: 231–236.Google Scholar

Gray, J. (1868). Synopsis of the species of pigs (Suidae) in the British Museum. Proceedings of the Zoological Society, No. II.Google Scholar

Groves, C. & Grubb, P. (2011). Ungulate taxonomy. 5. Suidae. Baltimore, MD: The John Hopkins University Press.Google Scholar

Grubb, P. (1993). The Afrotropical Suids Phacochoerus, Hylochoerus and Potamochoerus: the bushpigs (Potamochoerus porcus and Potamochoerus larvatus). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group; IUCN/SSC Hippo Specialist Group, IUCN, pp. 66–75.Google Scholar

Gundlach, H. (1968). Brutfürsorge, Brutpflege, Verhaltensontogonese und Tagesperiodik beim Europäischen Wildschwein (Sus scrofa L.). Zeitschrift für Tierpsychologie 25: 955–995.Google Scholar

Haltenorth, T. (1963). Die Klassifikation der Säugetiere 18. Ordnung Paarhufer, Artiodactyla. Handbuch der Zoologie 8 (1): 1–167.Google Scholar

Horak, I. G., Boomker, J. & Flamand, J. R. B. (1991). Ixodid ticks and lice infesting red duikers and bushpig in northeastern Natal. Onderstepoort Journal of Veterinary Research 58: 281–284.Google Scholar

Jarvis, M. J. F., Currie, M. H. & Palmer, N. G. (1980). Food of crowned eagles in the Cape Province, South Africa. Ostrich 51: 215–218.Google Scholar

Jobaert, A. J. (1958). Le Potamochère. Zooleo 6 (44): 145–154.Google Scholar

Jones, M. A. (1978). A scent marking gland in the bushpig Potamochoerus porcus (Linn., 1758). Arnoldia Rhodesia 8(30): 1–4.Google Scholar

Jones, M. A. (1984). Seasonal changes in the diet of bushpig, Potamochoerus porcus Linn., in the Matopos National Park. South African Journal of Wildlife Research 14: 97–100.Google Scholar

Jori, F. & Bastos, A. D. S. (2009). The role of suids in the epidemiology of African swine fever. Review. EcoHealth 6 (2): 296–310.Google Scholar

Kingdon, J. (1979). East African mammals. Vol. IIIB. London: Academic Press.Google Scholar

Lönnberg, E. (1910). Contributions to the knowledge of the genus Potamochoerus. Arkiv för Zoologi 7 (6): 1–40.Google Scholar

Mason, D. R. (1982). Studies on the biology and ecology of the warthog Phacochoerus aethiopicus sundevalli Lönnberg, 1908 in Zululand. DSc thesis (Wildlife Management), University of Pretoria.Google Scholar

McNab, B. K. (1986). The influence of food habits on the energetics of eutherian mammals. Ecological Monographs 56 (1): 1–19.Google Scholar

Melton, D. A., Cooper, S. M. & Whittington, A. E. (1989). The diet of bushpigs in a sugar-cane agroecosystem. South African Journal of Wildlife Research 19 (1): 48–51.Google Scholar

Mentis, M. T. (1970). Estimates of natural biomasses of large herbivores in the Umfolozi Game Reserve Area. Mammalia 34(3): 363–393.Google Scholar

Oliver, W. L. R. (1995). Taxonomy and conservation status of the Suiformes – an overview. Ibex Journal of Mountain Ecology 3: 3–5.Google Scholar

Seydack, A. H. W. (1983). Age assessment in the bushpig Potamochoerus porcus Linn. 1758 in the Southern Cape. MSc thesis, University of Stellenbosch.Google Scholar

Seydack, A. H. W. (1990). Ecology of the bushpig Potamochoerus porcus Linn. 1758 in the Cape Province, South Africa. PhD dissertation, University of Stellenbosch.Google Scholar

Seydack, A. H. W. (1991). Monographie des Buschschweines. Bongo 18: 85–102.Google Scholar

Seydack, A. H. W. (2013). Bushpig Potamochoerus larvatus. In Kingdon, J. & Hoffmann, M. (eds.), Mammals of Africa. London: Bloomsbury, Vol. 6, pp. 32–36.Google Scholar

Seydack, A. H. W. (2016). Potamochoerus larvatus. The IUCN Red List of Threatened Species, Version 2016: e.T41770A44140926. http://dx.doi.org/10.2305/IUCN.UK.2016-1.RLTS.T41770A44140926.en5.Google Scholar

Seydack, A. H. W. & Bigalke, R. C. (1992). Nutritional ecology and life history tactics in the bushpig (Potamochoerus porcus): development of an interactive model. Oecologia 90: 102–112.Google Scholar

Skead, C. J. (1986). Historical mammal incidence in the Cape Province. Vol. 2. Cape Town: The Department of Nature and Environmental Conservation of the Provincial Administration of the Cape of Good Hope.Google Scholar

Skinner, J. D., Breytenbach, G. J. & Maberly, C. T. A. (1976). Observations on the ecology and biology of the bushpig Potamochoerus porcus Linn. in the Northern Transvaal. South African Journal of Wildlife Research 6 (2): 123–128.Google Scholar

Smithers, R. H. N. & Wilson, V. J. (1979). Check list and atlas of the mammals of Zimbabwe Rhodesia. Museum Memoirs of the National Museum and Monuments of Rhodesia 9.Google Scholar

Sowls, L. K. & Phelps, R. J. (1968). Observations on the African bushpig Potamochoerus porcus Linn. in Rhodesia. Zoologica N.Y. 53 (3): 75–84.Google Scholar

Thomas, A. D. & Kolbe, F. F. (1942). The wild pigs of South Africa: their distribution and habits, and their significance as agricultural pests and carriers of disease. Journal of South African Veterinary Medical Association 13 (1): 1–11.Google Scholar

Tinley, K. L. (1977). Framework of the Gorongoza Ecosystem. PhD thesis, University of Pretoria.Google Scholar

Van Daalen, J. C. (1984). Distinguishing features of forest species on nutrient-poor soils in the Southern Cape. Bothalia 15 (1&2): 229–239.Google Scholar

Vercammen, P., Seydack, A. H. W. & Oliver, W. L. R. (1993). The Afrotropical Suids Phacochoerus, Hylochoerus, Potamochoerus: the bushpigs (Potamochoerus porcus and Potamochoerus larvatus). In Oliver, W.L.R. (ed.), Pigs, peccaries and hippos. Gland and Cambridge: IUCN/SSC Pigs and Peccaries Specialist Group; IUCN/SSC Hippo Specialist Group, IUCN, pp. 93–100.Google Scholar

Von Boetticher, H. (1933). Die geographische Verbreitung der afrikanischen Wildschweine und ihre ökologischen Grundlagen. Jenaische Zeitschrift für Naturwissenschaft 68 (2): 463–498.Google Scholar

Wilson, V. J. (1968). Weights of some mammals from eastern Zambia. Arnoldia Rhodesia 3 (32): 1–20.Google Scholar

References

Aba'a, R. (2006). Abondance relative des grands mammiferes et des activités humaines au parc National des Monts de Cristal et sa peripherie. Libreville, Gabon: Wildlife Conservation Society, p. 40.Google Scholar

Aba'a, R. & Bezangoye, A. (2007). Wildlife and human impact monitoring, Birougou National Park, Gabon. Final report. Libreville, Gabon: Wildlife Conservation Society.Google Scholar

Aba'a, R., Maisels, F., Starkey, M. & Memiaghe, H. R. (2011). Inventaire des grands mammifères et l'impact humaine dans le Mayombe. Activité 3.1b part 1: Rapport Final. Libreville, Gabon: Wildlife Conservation Society, p. 27.Google Scholar

Abernethy, K. A. & White, L. J. T. (1999). Like living vacuum cleaners, red river hogs give the forest floor a clean sweep. Wildlife Conservation 102: 50–55.Google Scholar

Abernethy, K. A., Coad, L., Taylor, G., Lee, M. E. & Maisels, F. (2013). Extent and ecological consequences of hunting in Central African rainforests in the twenty-first century. Philosophical Transactions of the Royal Society B: Biological Sciences 368: 20120303.Google Scholar

Abitsi, G. (2006). Inventaires de reconnaissance des grands mammiferes et de l'impact des activités anthropiques. Parc National de Waka, Gabon. Décembre 2005–Juillet 2006. Libreville, Gabon: Wildlife Conservation Society, p. 38.Google Scholar

Aebischer, T., Hickisch, R., Mararv, E. & Simpson, D. (2013). The Chinko Project: Sustainable Nature Management in the Chinko/Mbari Drainage Basin, Central African Republic. Online at http://chinkoproject.com Google Scholar

Allam, A., N'Goran, K. P., Mahoungou, S. & Ikoa, B. (2016a). Rapport d'inventaire des grands et moyens mammiferes dans la forêt de Djoua-Ivindo. Sembe, République du Congo: WWF GCPO–MEFDD, p. 57.Google Scholar

Allam, A., Beukou, G. B. & N'Goran, K. P. (2016b). Rapport d'inventaire des grands et moyens mammifères dans la forêt de Messok-Dja. Sembe, République du Congo: WWF GCPO–MEFDD, p. 58.Google Scholar

Anderson, E. C., Hutchings, G. H., Mukarati, N. & Wilkinson, P. J. (1998). African swine fever virus infection of the bushpig (Potamochoerus porcus) and its significance in the epidemiology of the disease. Veterinary Microbiology 62: 1–15.Google Scholar

Angelici, F. M., Luiselli, L., Politano, E. & Akani, G. C. (1999). Bushmen and mammal-fauna: a survey of the mammals traded in bush-meat markets of local people in the rainforests of southeastern Nigeria. Anthropologica 30: 51–58.Google Scholar

ANPN, WCS, WWF (2013). Wildlife and poaching assessment in northeast Gabon. Final report. Libreville, Gabon: ANPN, WCS, WWF, USFWS, p. 23.Google Scholar

Beaune, D., Bollache, L., Fruth, B. & Bretagnolle, F. (2012). Bush pig (Potamochoerus porcus) seed predation of bush mango (Irvingia gabonensis) and other plant species in Democratic Republic of Congo. African Journal of Ecology 50: 509–512.Google Scholar

Beudels-Jamar, R., Bankanza, M., Fumutoto, R., et al. (2014). Inventaires faunistiques et botaniques dans la Réserve Naturelle du Triangle de la Ngiri. (du 29/09 au 10/11/2013). Institut Royal des Sciences Naturelles de Belgique/WWF/ICCN, p. 46.Google Scholar

Beudels-Jamar, R., Lafontaine, R.-M., Robert, H., et al. (2015). Inventaires faunistiques dans la Réserve Naturelle de Tumba-Lediima et dans la zone de Mbanzi/Nsélé (17/03 au 25/04/2014 et 19/08 au 20/09/2014). Institut Royal des Sciences Naturelles de Belgique/WWF/ICCN, p. 69.Google Scholar

Bezangoye, A. & Maisels, F. (2010). Great ape and human impact monitoring in the Lopé-Waka Exceptional Priority Area, Gabon. Part 1 : Lope National park. GACF Agreement: 98210-8-G529. Final performance report to USFWS. Libreville, Gabon: Wildlife Conservation Society, p. 62.Google Scholar

Blake, S. (2005). Long term system for monitoring the illegal killing of elephants (MIKE): Central African Forests – final report on population surveys (2003–2004). Washington, DC: CITES-MIKE, p. 122.Google Scholar

Blake, S. & Fay, J. M. (1997). Seed production by Gilbertiodendron dewevrei in the Nouabale-Ndoki National Park, Congo, and its implications for large mammals. Journal of Tropical Ecology 13: 886–891.Google Scholar

Bout, N. (2006). Suivi écologique des grands mammifères et de la pression humaine. Parc National des Plateaux Batéké. Rapport finale. Libreville, Gabon: Wildlife Conservation Society Gabon /JAF, p. 108.Google Scholar

Breuer, T., Breuer-Ndoundou Hockemba, M. & Mavinga, F. (2010). Dung decay and its implication for population estimates of duikers (Cephalophus and Philantoba spp.) and red river hogs (Potamochoerus porcus) in the Nouabalé-Ndoki National Park, Republic of Congo. African Jounal of Ecology 48: 551–554.Google Scholar

Burvenich, P. (2014). Red River Hog (Potamochoerus porcus) AZA Regional Studbook., Silver Spring, MD: Association of Zoos and Aquariums.Google Scholar

Castley, J., Bruton, J. S., Kerley, G. & Mclachlan, A. (2001). The importance of seed dispersal in the Alexandria Coastal Dunefield, South Africa. Journal of Coastal Conservation 7: 57–70.Google Scholar

Dasgupta, S. (2015). ‘Forgotten forests' of South Sudan: Camera traps capture first-ever pictures of forest elephants, giant pangolins in the country. Available at: http://news.mongabay.com/2015/12/forgotten-forests-of-south-sudan-camera-traps-capture-first-ever-pictures-of-forest-elephants-giant-pangolins-in-the-country/. Red river hogs: www.bucknell.edu/x107202.xml.Google Scholar

Devos, C., Ikembelo Beka, B. & Tshimanga, G. (2011). Inventaires de faune dans le sud du paysage Tumba, RDC : Bloc forestier de Bopaka (novembre 2011). Unpublished report. Projet PICBOU, Composante du Programme Lac Tumba, WWF, Kinshasa, DRC.Google Scholar

Ekinde, A. E. & Khumbah, P. (2006). Cross River gorilla surveys in south-east UFA 11-002 and search for genetic samples in the Besali–Bechati–Fossimondi forests. Limbe, Cameroon: Wildlife Conservation Society, and ERuDeF, p. 27.Google Scholar

Ekinde, A. E., Ashu, M. & Sunderland-Groves, J. (2005). Preliminary ape surveys around the Fungom Forest Reserve and Furu-Awa subdivision, North-West Province, Cameroon. Limbe, Cameroon: Wildlife Conservation Society, p. 45.Google Scholar

Ekobo, A. (2006). Evaluation des potentialites fauniques du Sanctuaire des gorilles a Mengame. Yaounde, Cameroon: WWF, p. 51.Google Scholar

Ekobo, A. (2007). Surveys of large mammals in the Mount Cameroon forest. Yaounde, Cameroon: WWF Cameroon Coastal Forests Programme, p. 41.Google Scholar

Ekobo, A. (2009). Etude Sur les Potentialités Fauniques des UFAs 11-003 et 11-004 Province du Sud-ouest, Cameroun. Yaounde, Cameroon: WWF, p. 26.Google Scholar

Fa, J. E. & Purvis, A. (1997). Body size, diet and population density in afrotropical forest mammals: a comparison with neotropical species. Journal of Animal Ecology 66: 98–112.Google Scholar

Foerster, S., Wilkie, D.S., Morelli, G.A., et al. (2012). Correlates of bushmeat hunting among remote rural households in Gabon, Central Africa. Conservation Biology 26: 335–344.Google Scholar

Foguekem, D. & Nzooh Dongmo, Z. L. (2012). Abundance, distribution of large mammals, and human activities in the Ngoyla-Mintom forest block, Cameroon: implication for land-use planning, management and biodiversity conservation. Yaounde, Cameroon: WWF Cameroon Country Programme Office, p. 66.Google Scholar

Fotso, R., Eno Nku, M. & Groves, J. (2002). Distribution and conservation status of gorilla population in the forests around Belabo, Eastern Province, Cameroon. Report to Cameroon Oil Transportation Company (COTCO), p. 59.Google Scholar

Gessner, J. (2008). Survey of mammals at Ikwa bai - Nki National Park, south-east Cameroon in terms of conservation and ethology with a focus on the African forest buffalo (Syncerus caffer nanus). Oldenburg: Carl von Ossietsky University, p. 123.Google Scholar

Ghiglieri, M. P., Butynski, T. M., Struhsaker, T. T., et al. (1982). Bush pig (Potamochoerus porcus) polychromatism and ecology in Kibale Forest, Uganda. African Journal of Ecology 20: 231–236.Google Scholar

Greengrass, E. J. & Maisels, F. (2007). Conservation of the Nigerian–Cameroon chimpanzee P. t. vellerosus (and other mammals) in and around the Banyang-Mbo Wildlife Sanctuary, South-west Province, Cameroon. Limbe, Cameroon: Wildlife Conservation Society, p. 74.Google Scholar

Grubb, P. (1993). The Afrotropical suids Phacochoeros, Hylochoeros, and Potamochoerus. In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN (World Conservation Union), pp. 66–75.Google Scholar

Grubb, P., Jones, T. S., Davies, A. G., et al. (1998). Mammals of Ghana, Sierra Leone and The Gambia. Zennor, St Ives: Trendrine Press.Google Scholar

Hart, J. A. (2001). Diversity and abundance in an African forest ungulate community and implications for conservation. In Weber, B., White, L., Vedder, A. & Naughton-Trees, L. (eds.), African rainforest ecology and conservation. New Haven, CT: Yale University Press.Google Scholar

Hart, T. B., Hart, J A., Dechamps, R., Ataholo, M. & Fournier, M. (2009). A New Conservation Landscape for Bonobo: Discovery and Conservation of the Tshuapa–Lomami–Lualaba Landscape, in the Democratic Republic of Congo. Final Report on USFWS Assistance Award Agreement # 98210-7-G285 Lukuru Wildlife Research Foundation/Tshuapa-Lomami-Lualaba Project, Kinshasa, DRC.Google Scholar

Henschel, P., Abernethy, K. A. & White, L. J. T. (2005). Leopard food habits in the Lopé National Park, Gabon, Central Africa. African Journal of Ecology 43: 21–28.Google Scholar

Hicks, T. C. (2014). Faunal Diversity and Human Impact in Two Protected Areas of Northern DR Congo: Bili-Uéré and Rubi-Tele January 2014. Unpublished report. Lukuru Wildlife Research Foundation, Kinshasa, DRC.Google Scholar

Ikfuingei, R. & Kuchambi, E. (2013). The Takamanda National Park – large mammal survey, May–July 2013. Limbe, Cameroon: Wildlife Conservation Society, p. 34.Google Scholar

Inkamba-Nkulu, C., Telfer, P. & Maisels, F. (2012). Conservation of forest elephants in the Ogooué-Leketi National Park, Republic of Congo (Batéké Plateaux, Congo) Phase III. Interim report. Grant #. 96200-0-G2S7 African Elephant Fund. Reporting period: 25 August 2010–30 September 2012. Brazzaville, Congo: Wildlife Conservation Society, p. 26.Google Scholar

IUCN/MINFOF. (2015). Caractérisation d'une population de grands et moyens mammifères dans la Reserve de Faune du Dja: Potentiel et menaces. p. 31, Yaoundé, Cameroun.Google Scholar

Iyenguet, F. C., Malanda, G. F., Madzoke, B. & Twagirashyaka, F. (2008). Recensement et Distribution des Grands Mammifères et Activités Humaines dans la Zone Impfondo. Brazzaville, Congo: Wildlife Conservation Society, p. 55.Google Scholar

Iyenguet, F. C., Madzoke, B., Twagirashyaka, F., et al. (2012). Inventaire des Grands Mammifères et Activités Humaines dans la Batanga, Périphérie est de la Réserve Communautaire du Lac Télé, République du Congo. Brazzaville, Congo: Wildlife Conservation Society, p. 53.Google Scholar

Kerley, G. I. H., Mclachlan, A. & Castley, J. G. (1996). Diversity and dynamics of bushpockets in the Alexandria coastal Dunefield, South Africa. Landscape and Urban Planning 34: 255–266.Google Scholar

Kingdon, J. S. & Hoffmann, M. (eds.). (2013). The mammals of Africa. Amsterdam: Academic Press.Google Scholar

Kujirakwinja, D., Plumptre, A. J., Moyer, D. & Mushenzi, N. (2006). Recensement aérien des grands mammifères du Parc National des Virunga. Kinshasa, DRC: ICCN, WCS, USFWS.Google Scholar

Kujirakwinja, D., Kirkby, A., Spira, C., et al. (2015). Inventaire de la Biodiversité dans le Parc National de Kahuzi Biega, République Démocratique du Congo. Secteur de Nzovu-Ouest (basse altitude). In Spira, C., Mitamba, G. M., Kirkby, A., et al. (eds.), Inventaire de la Biodiversité dans le Parc National de Kahuzi Biega, République Démocratique du Congo. Secteurs de Nzovu-Est (basse altitude) et de Tshivanga (haute altitude). Kinshasa, DRC: ICCN/Wildlife Conservation Society, p. 58.Google Scholar

Lahm, S. A. (1994). Diversity, abundance and distribution of game in relation to human predation in northeastern Gabon. New York, NY: Wildlife Conservation Society.Google Scholar

Lameed, G. A., Omifolaji, J. K., Abere, A. S. & Ilori, S. O. (2015). Hunting intensity on wildlife population in Oban Sector of Cross River National Park. Natural Resources 6: 325–330.Google Scholar

Latour, S. (2005). Inventaire de faune autour des lacs du delta de l'Ogooué. Libreville, Gabon: Wildlife Conservation Society, p. 30.Google Scholar

Latour, S. (2006). Recensement des elephants et de grands singes dans le region du parc national de Pongara (Gabon). Libreville, Gabon: WCS/Especes Phares, p. 54.Google Scholar

Laurance, W. F., Croes, B. M., Tchignoumba, L., et al. (2006). Impacts of roads and hunting on Central African rainforest mammals. Conservation Biology 20: 1251–1261.Google Scholar

Laws, R. M., Parker, I. S. C. & Johnstone, R. C. B. (1975). Elephants and their habitats: the ecology of elephants in north Bunyoro. Uganda: Oxford University Press.Google Scholar

Leduc Yeno, S. (2006). Suivi des grands mammifères dans le secteur Sud Parc National de Loango, 12 avril au 08 Septembre 2006. Gamba, Gabon: WWF, p. 39.Google Scholar

Le-Duc Yeno, S. & N'Goran, K. P. (2016). Rapport de l'inventaire des grands et moyens mammifères dans la forêt de Djoua-Zadié. Libreville, Gabon: WWF GCPO, p. 44.Google Scholar

Leus, K. & Vercammen, P. (2013). Potamochoerus porcus. In Kingdon, J. S. & Hoffmann, M. (eds.), The mammals of Africa. Amsterdam: Academic Press.Google Scholar

Liengola, I., Vosper, A., Maisels, F., Bonyenge, A. & Nkumu, P. (2009). Conserving bonobos in the last unexplored forest of the Democratic Republic of Congo the Tshuapa–Lomami–Lualaba Landscape. Kinshasa, DRC: Wildlife Conservation Society.Google Scholar

Liengola, I., Maisels, F., Nkumu, P. & Bonyenge, A. (2010). Conserving bonobos in the Lokofa Block of the Salonga National Park, Democratic Republic of Congo. Report to the Beneficia Foundation. Kinshasa, DRC: Wildlife Conservation Society.Google Scholar

Likondo Lokonga, C. (2006). Abundance and distribution of large mammals and human activities throughout the proposed 4,000 km² Djolou Wamba multiple use zone (Maringa Lopori landscape). Unpublished report. AWF, Kinshasa, DRC.Google Scholar

Lushimba, A. (2012). Recensements des grands mammifères et d'impacts humains dans la Réserve de Faune de Lomako–Yokokala. Kinshasa, DRC: AWF.Google Scholar

Luther, N. J., Majiyagbe, K. A., Shamaki, D., et al. (2007). Detection of African swine fever virus genomic DNA in a Nigerian red river hog (Potamochoerus porcus). Veterinary Record 160: 58–59. doi:10.1136/vr.160.2.58.Google Scholar

Macdonald, A. A. (2000). Comparative anatomy, physiology and ecology of pregnancy and lactation in wild pigs: a review. In Nijboer, J., Hatt, J. M., Kaumanns, W., Beijnen, A. & Gansloßer, U. (eds.), Zoo animal nutrition. Fürth: Filander Verlag, pp. 213–236.Google Scholar

Maisels, F. & Ella Akou, M. (2013b). Mwagna National Park: Report on WWF survey 2012. Libreville, Gabon: ANPN/WCS/WWF, p. 14.Google Scholar

Maisels, F., Abitsi, G. & Bezangoye, A. (2008). Great ape and human impact monitoring in the Lopé-Waka Exceptional Priority Area, Gabon. Part 2: The Lopé-Waka Corridor. GACF Agreement: 98210-7-G289. Final performance report to USFWS. Libreville, Gabon: Wildlife Conservation Society, p. 30.Google Scholar

Maisels, F., Nkumu, P. & Bonyenge, A. (2009a). Salonga National Park, Democratic Republic of Congo: Terrestrial wildlife and human impact monitoring programme. Survey Report – Salonga Corridor. Kinshasa, DRC: Wildlife Conservation Society.Google Scholar

Maisels, F., Ambahe, E., Ambassa, R., Nvemgah Yara, C. & Fosso, B. (2009b). Great ape and human impact monitoring in the Mbam et Djerem National Park, Cameroon. Final report to USFWS–GACF Agreement 98210-7-G290. Unpublished report. Wildlife Conservation Society, Yaounde, Cameroon.Google Scholar

Maisels, F., Motsaba, P. & Aba'a, R. (2010a). Final report, second cycle of monitoring in Ivindo National Park and southern buffer zone. Final Report to USFWS–GACF Agreement: 98210-7-G297. Libreville, Gabon: Wildlife Conservation Society, p. 71.Google Scholar

Maisels, F., Ambahe, R., Fosso, B., Puomegne, J.-B. & Fotso, R. (2010b). Wildlife and human impact surveys of the Deng Deng National Park and UFA 10065. Yaounde, Cameroon: Wildlife Conservation Society.Google Scholar

Maisels, F., Nishihara, T., Strindberg, S., et al. (2012). Great ape and human impact monitoring training, surveys, and protection in the Ndoki-Likouala Landscape, Republic of Congo. GACF Agreement 96200-9-G247. Final Report. Brazzaville, Congo: Wildlife Conservation Society.Google Scholar

Maisels, F., Strindberg, S., Kiminou, F., et al. (2013a). Wildlife and Human Impact Survey 2012, and monitoring 2005-2008-2012. Odzala-Kokoua National Park, Republic of Congo. Brazzaville, Congo: Fondation Odzala-Kokoua/Wildlife Conservation Society, p. 48.Google Scholar

Maisels, F., Strindberg, S., Ambahe, R., et al. (2013b). Deng Deng National Park and UFA 10-065, Republic of Cameroon. Wildlife and Human Impact Survey 2012. Yaoundé, Cameroon: Wildlife Conservation Society, p. 37.Google Scholar

Maisels, F., Strindberg, S., Rayden, T., et al. (2014a). Wildlife and human impact survey of the Ngombé Ntokou-Pikounda forest landscape, Republic of Congo. Feb–Oct 2014. Republic of Congo: WCS, p. 71.Google Scholar

Maisels, F., Strindberg, S., Bechem, M., et al. (2014b). Boumba Bek National Park, Republic of Cameroon: Wildlife and Human Impact Survey 2012. Nairobi, Kenya: CITES Monitoring of Illegal Killing of Elephants, p. 64.Google Scholar

Makana, J. R., Madidi, J., Masselink, J., Vyahavwa, C. & Mukinzi, J. (2010). Rapport des explorations biologiques dans le Sud de la Zone CBNRM Bakwanza (Bloc Samboko). Brazzaville, Congo: WCS.Google Scholar

Makana, J. R., Madidi, J., Vyahavwa, C., et al. (2012). Preliminary Surveys of Chimpanzees in Eastern Ituri Forest, DRC. Final Report: USFWS Agreement no. 98210-8-G642. Unpublished report. Wildlife Conservation Society, Kinshasa, DRC.Google Scholar

Makaya, Q.P. (2010). Monitoring écologique des grands mammifères terrestres et l'impact anthropique dans le Parc National de Mayumba, Gabon – rapport final. Mayumba, Gabon: Wildlife Conservation Survey.Google Scholar

Malanda, G., Iyenguet, F. & Madzoke, B. (2010). Inventaire et Distribution des Grands Mammifères et Activités Humaines dans la Zone Tanga. Brazzaville, Congo: Wildlife Conservation Society, p. 79.Google Scholar

Melletti, M., Mirabile, M., Penteriani, V. & Boitani, L. (2009). Habitat use by forest mammals in Dzanga-Ndoki National Park, Central Africa Republic. African Journal of Ecology 47: 797–800.Google Scholar

Morgan, B. J. (2007). Group size, density and biomass of large mammals in the Reserve de Faune du Petit Loango, Gabon. African Journal of Ecology 45: 508–518.Google Scholar

Motsaba, P. & Aba'a, R. (2012). Inventaire préliminaire de grands mammifères et des activités anthropiques à la Réserve Présidentielle de Wonga-Wongué. Libreville, Gabon: Wildlife Conservation Society/Projet GEF PARCS – Composante 2, p. 24.Google Scholar

Nakashima, Y. (2015). Inventorying medium- and large-sized mammals in the African lowland rainforest using camera trapping. Tropics 23, 151–164.Google Scholar

N'Goran, K. P., Ndomba, D. L. & Beukou, G. B. (2016). Rapport de l'inventaire des grands et moyens mammifères dans le segment RCA du paysage Tri-national de la Sangha. Bayanga, République Centrafricaine: WWF RCA–APDS, p. 113.Google Scholar

Nixon, S., Mufabule, K., Eliba, A. & Manubo Patule, I. (2007). A Prospection Survey of the Usala Forest and Proposed Usala (Community) Gorilla Reserve, Democratic Republic of Congo, March–April 2007. Distribution and Conservation Status of Large Mammals with an emphasis on Grauer's Eastern Gorilla, Gorilla beringei graueri. Unpublished report. The Dian Fossey Gorilla Fund International, UGADEC (Union des Associations de Conservation des Gorilles pour le Développement Communautaire à l'Est de RDC), Tayna Centre for Conservation Biology, North Kivu, DRC, Usala Gorilla Reserve, North Kivu DRC, Kinshasa, DRC.Google Scholar

Nku, E. (2003a). Rapid large mammal assessment of Ejagham Forest Reserve, South West Province, Cameroon. Limbe, Cameroon: WCS Cameroon.Google Scholar

Nku, E. M. (2003b). Rapid large mammal assessment of Nkwende Hills Forest Concession (UFA 11-001) & Upper Banyang Forest Concession (UFA 11-002), South West Province – Cameroon. Limbe, Cameroon: WCS Cameroon, p. 28.Google Scholar

Nzooh Dongmo, Z. L., N'Goran, K. P., Fondja Hendji, C. & Nkono, J. (2015). Evaluation de la dynamique des populations de grands et moyens mammifères dans le domaine forestier permanent de l'unite technique operationelle Campo Ma'an. Yaoundé, Cameroun: WWF CCPO-MINFOF, p. 103.Google Scholar

Nzooh Dongmo, Z. L., N'Goran, K. P., Ekodeck, H., et al. (2016a). Les populations de grand et moyen mammiferes dans le segment Lobéké du paysage Tri National de la Sangha. Yaounde, Cameroun: MINFOF-WWF CCPO, p. 103.Google Scholar

Nzooh Dongmo, Z. L., N'Goran, K. P., Etoga, G., et al. (2016b). Les populations de grands et moyens mammifères dans le segment Cameroun du Paysage TRIDOM: Forêt de Ngoyla-Mintom, PN Boumba Bek et PN Nki et leurs zones périphériques. Yaounde, Cameroon: WWF CCPO-MINFOF, p. 101.Google Scholar

Oduro, W. (1989). Ecology of the red river hog in southern Nigeria. Unpublished PhD thesis, University of Ibadan, Nigeria.Google Scholar

Okon, D. & Atanga, E. (2007). Monitoring large mammals and human activities in Korup National Park. Yaounde, Cameroon: WWF Cameroon.Google Scholar

Payne, A. (2002). Gestion de la ressource en viande de brousse au Gabon : exemple du potamochère (Potamochoerus porcus) dans la région de Makokou. France: Ecole Nationale Vétérinaire d'Alfort, p. 154.Google Scholar

Pintea, L., Atencia, R. & Cox, D. (2012). The status of gorillas in the Dimonika Biosphere Reserve. Gorilla Journal 46: 16–19.Google Scholar

Plumptre, A. J., Kujirakwinja, D., Matunguru, J., et al. (2008). Biodiversity surveys in the Misotshi-Kabogo and Marungu regions of Eastern Democratic Republic of Congo with a focus on chimpanzees. Kampala, Uganda: Wildlife Conservation Society.Google Scholar

Plumptre, A. J., Amsini, F., Kujirakwinja, D., et al. (2009). Itombwe Massif Conservation Project: delimitation and zoning of the Itombwe Natural Reserve for protection of great apes. Final Report for USFWS Project 98210 – 7– G293. Unpublished report. Wildlife Conservation Society, Kampala, Uganda.Google Scholar

Princee, F. P. G. (2013). Biomonitoring Survey 2011–2012 in Dzanga-Sangha Protected Areas. Unpublished report. World Wide Fund for Nature, Bayanga, Central African Republic.Google Scholar

Reiter, J. (2013). European Endangered Species Programme (EEP) studbook for the red river hog (Potamochoerus porcus pictus) Edition 2012. Amsterdam: European Association of Zoos and Aquariums.Google Scholar

Reyna, R., Jori, F., Querouil, S. & Leus, K. (2016). Potamochoerus porcus. The IUCN Red List of Threatened Species 2016: e.T41771A44141118.Google Scholar

Ruffler, H., Murai, M. & Kuhl, H. (2012). A Conservation survey of great apes and elephants, Rio Muni, Equatorial Guinea. Final report submitted to US Fish and Wildlife Service, p. 55. Conservation International, Arlington, USA.Google Scholar

Seufert, V., Linden, B. & Fischer, F. (2010). Revealing secondary seed removers: results from camera trapping. African Journal of Ecology 48: 914–922.Google Scholar

Seydack, A. H. W. (1990). Ecology of the bushpig (Potamochoerus porcus Linn. 1758) in the Cape Province, South Africa. Unpublished PhD thesis, University of Stellenbosch, South Africa.Google Scholar

Seydack, A. H. W. (1991). Monographie des buschschweines (Potamochoerus porcus). Bongo 18: 85–102.Google Scholar

Starkey, M. (2004). Commerce and subsistence: the hunting, sale and consumption of bushmeat in Gabon. Cambridge: University of Cambridge.Google Scholar

Stokes, E. J., Strindberg, S., Bakabana, P. C., et al. (2010). Monitoring great ape and elephant abundance at large spatial scales: measuring effectiveness of a conservation landscape. PLoS ONE 5: e10294.Google Scholar

Stuart, S. N. & Adams, R. J. (1990). Biodiversity in Sub-Saharan Africa and its Islands. IUCN/SSC Occasional Papers, No. 6. Gland: IUCN.Google Scholar

Tutin, C. E. G., White, L. J. T. & Mackanga-Missandzou, A. (1997). The use of rain forest mammals of natural forest fragments in an equatorial African savanna. Conservation Biology 11(5): 1190–1203.Google Scholar

Vanleeuwe, H. (2014). Ecological Surveys 2005, 2008, 2010 and 2013: Ecological Surveys At Conkouati-Douli National Park, Republic Of Congo. Brazzaville, Congo: Wildlife Conservation Society Congo, p. 15.Google Scholar

Vercammen, P., Seydack, A. H. W. & Oliver, W. L. R. (1993). The bush pigs (Potamochoerus larvatus and P. porcus). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist Group–IUCN/SSC Hippo Specialist Group, pp. 93–101.Google Scholar

Vosper, A., Masselink, J. & Maisels, F. (2012). WCS RFO Program: Great ape and human impact monitoring in Okapi Faunal Reserve, Democratic Republic of Congo. Final report to USFWS–GACF Agreement 96200-0-G100. Unpublished report. Wildlife Conservation Society, Kinshasa, DRC.Google Scholar

Warren, Y. & Bila, S. E. (2008). Mbulu Survey. Unpublished report. Wildlife Conservation Society Limbé, Cameroon.Google Scholar

Warren, Y. & Ekinde, A. (2007). Large mammal recce survey of the Mone Forest Reserve. Limbé, Cameroon: Wildlife Conservation Society, p. 69.Google Scholar

Westcott, D. A., Bentrupperbaumer, J., Bradford, M. G. & Mckeown, A. (2005). Incorporating patterns of disperser behaviour into models of seed dispersal and its effects on estimated dispersal curves. Oecologia 146: 57–67.Google Scholar

White, L. & Abernethy, K. (1997). A guide to the vegetation of the Lope Reserve Gabon. New York, NY: Wildlife Conservation Society.Google Scholar

White, L. J. T. (1994). Biomass of rain forest mammals in Lopè Reserve, Gabon. Journal of Animal Ecology 63: 499–512.Google Scholar

Wilkie, D. S. & Carpenter, J. F. (1999). Bushmeat hunting in the Congo Basin. An assessment of impact and options for mitigation. Biodiversity Conservation 8: 927–945.Google Scholar

Williamson, E. A., Bayogo, R., Guimiyessi, G., et al. (2004). Survey of elephants, Bangassou, Central African Republic: conservation status and human impacts May–June 2004. Unpublished report. WCS/CITES/MIKE, New York.Google Scholar

Woodhouse, C. W. (1911). Some East African pigs. Journal of The East Africa and Uganda Natural History Society 2: 40–46.Google Scholar

Ziegler, S., Fa, J. E., Wohlfart, C., et al. (2016). Mapping bushmeat hunting pressure in Central Africa. Biotropica 48: 405–412.Google Scholar

References

AZA. (2015). VISAYAN WARTY PIG Studbook. San Diego Zoo.Google Scholar

CITES (Convention on the International Trade in Endangered Species of Wild Flora and Fauna). (2009). Appendices I, II and III, as adopted by the Conference of the Parties, valid from 22 May 2009.Google Scholar

Cummings, M. J. (2003). An assessment of the Visayan Warty Pig (Sus cebifrons) in the Imbang-Caliban Watershed of the North Negros Forest Reserve, Philippines: ecological and social perspectives. MSc thesis. London: University College London.Google Scholar

De Leon, M. P., Gonzalez, J. C. T. & Hedreyda, C. T. (2008). Complete DNA sequence analysis of the mitochondrial 16s rRNA and cytochrome b genes of the Visayan warty pig (Sus cebifrons). Asia Life Sciences 17: 295–308.Google Scholar

EAZA. (2015). Visayan Warty Pig Studbook. Wrocław Zoo.Google Scholar

Groves, C. P. (1997). Taxonomy of wild pigs (Sus) of the Philippines. Zoological Journal of the Linnean Society 120: 163–191.Google Scholar

Groves, C. P. & Grubb, P. (1993). The Eurasian suids Sus and Babyrousa. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and action plan. Gland: IUCN, pp. 107–111.Google Scholar

Hamann, A. & Curio, E. (1999). Interactions among frugivores and fleshy fruit trees in a Philippine submontane rainforest. Conservation Biology 13: 766–773.Google Scholar

Huffman, B. (2010). Sus cebifrons. Visayan Warty Pig. www.ultimateungulate.com/Artiodactyla/Sus_cebifronsReferences.html (accessed 2 April 2016).Google Scholar

ISIS (2005). Specimen Records.Google Scholar

Kubbinga, B. (2005). First Visayan piglets in Rotterdam Zoo. Suiform Soundings 5: 24–25.Google Scholar

Lastica, E. A. (2003). Visayan Warty Pig (Sus cebifrons) – Species husbandry guidelines. Philippines Biodiversity Conservation Programmes.Google Scholar

Lastimoza, L. (2006). The latest information on conservation breeding projects on Panay island. ZGAP Mitteilungen 22: 15–16.Google Scholar

Liu, F., Tang, H-X., Liu, Y. G., Bai, M-J., & Tang, Y-X. (2015). The complete genome of Sus cebifrons (Sus, Suidae). Mitochondrial DNA 26: 483–484.Google Scholar

Nuijten, R. J. M., Bosse, M., Crooijmans, R. P. M. A., et al. (2016). The use of genomics in conservation management of the endangered Visayan warty pig (Sus cebifrons). International Journal of Genomics. http://dx.doi.org/10.1155/2016/5613862 Google Scholar

Oliver, W. (2008). Sus cebifrons. The IUCN Red List of Threatened Species 2008: e.T21175A9244915. http://dx.doi.org/10.2305/IUCN.UK.2008.RLTS.T21175A9244915.en. Downloaded on 20 May 2016.Google Scholar

Oliver, W. L. R. (1995). The taxonomy, distribution and status of Philippine wild pigs. Ibex 3: 26–32.Google Scholar

Oliver, W. L. R. (2004). First (and last?) breeding loan export of Visayan (Negros) warty pigs. Suiform Soundings 4: 25–27.Google Scholar

Oliver, W. L. R. (2009). Reintroduction programme for threatened endemic species of the Philippines – the planned sicogon reintroduction project in West Visaya. ZGAP Mitteilungen 25: 8.Google Scholar

Oliver, W. L. R., Cox, C. R. & Groves, C. P. (1993). The Philippine warty pigs (Sus philippensis and S. cebifrons). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and action plan. Gland: IUCN, pp. 145–155.Google Scholar

Pedregosa, D. G. M. d. (2005). Visayan warty pig, Sus cebifrons. Suiform Soundings 5: 18–19.Google Scholar

Rabor, D. S. (1977). Philippine birds and mammals. Quezon City, Philippines: University of Philippines Press.Google Scholar

References

Brashares, J. S., Arcese, P., Sam, M. K., et al. (2004). Bushmeat hunting, wildlife declines, and fish supply in west Africa. Science 306: 1180–1183.Google Scholar

Cruzana, B. C., De Ocampo, G. D., Sasaki, M., Kitamura, N. & Yamada, J. (2005). Cytochrome P450 aromatase and estrogen receptors (ER). Philippine Journal of Veterinary Medicine 42: 102–104.Google Scholar

de Chabannes, P. (2015). Zoos around Manila. International Zoo News 62: 164–177.Google Scholar

Duya, M. R. M., Alviola, P. A., Duya, M. V., Balete, D. S. & Heaney, L. R. (2007). Report on a survey of mammals of the Sierra Madre Range, Luzon Island, Philippines. Banwa 4: 41–68.Google Scholar

Griffin, P. B. & Griffin, M. B. (2000). Agta hunting and sustainability of resource use in northeastern Luzon, Philippines. In Robinson, J. G. & Bennett, E. L. (eds.), Hunting for sustainability in tropical forests. New York, NY: Columbia University Press, pp. 325–335.Google Scholar

Groves, C. P. (1997). Taxonomy of wild pigs (Sus) of the Philippines. Zoological Journal of the Linnean Society 120: 163–191.Google Scholar

Groves, C. P. (2001). Taxonomy of wild pigs of Southeast Asia. Asian Wild Pig News 1: 2–3.Google Scholar

Heaney, L. R., Balete, D. S., Dolar, M. L., et al. (1998). A synopsis of the mammalian fauna of the Philippine Islands. Fieldiana: Zoology 88: 1–61.Google Scholar

Heaney, L. R., Balete, D. S., Gee, G.V., et al. (2005). Preliminary report on the mammals of Balbasang, Kaling Province, Luzon. Sylvatrop. The Philippine Forest Research Journal 13: 51–62.Google Scholar

Heaney, L. R., Tabaranza, B. R. Jr., Rickart, E.A., Balete, D. S. & Ingle, N. R. (2006). The mammals of Mt. Kitanglad Nature Park, Mindanao, Philippines. Fieldiana Zoology 112: 1–63.Google Scholar

Heaney, L. R., Balete, D. S. & Rickart, E. A. (2016). The mammals of Luzon Island: biogeography and natural history of a Philippine fauna. Baltimore, MD: John Hopkins University Press.Google Scholar

Hoogstraal, H. & Wassef, H. Y. (1983). Haemaphysalis (Garnhamphysalis) rusae (Ixodoidea: Ixodidae): identity, deer and pig hosts, and distribution in Luzon and Mindanao. The Journal of Parasitology 69: 215–220.Google Scholar

Hoogstraal, H., Kohls, G. M. & Parrish, D. W. (1967). Studies on Southeast Asian Haemaphysalis ticks (Ixodoidea, Ixodidae). H. (Kaiseriana) psalistos sp. n., a parasite of deer and boars in Luzon, Philippines. The Journal of Parasitology 53: 1096–1102.Google Scholar

Hoogstraal, H., Kohls, G. M. & Parrish, D. W. (1968). Studies on Southeast Asian Haemaphysalis ticks (Ixodoidea, Ixodidae). H. (Kaiseriana) susphilippensis sp. n., a parasite of Luzon and Mindanao boars. The Journal of Parasitology 54: 616–621.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. R. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world, volume 2, hoofed mammals. Barcelona: Lynx Edicions, pp. 248–291.Google Scholar

Mudar, K. M. (1985). Bearded pigs and beardless men: predator–prey relationships between pigs and Agta in northeastern Luzon, Philippines. In Griffin, P. B. & Estioko, A. E. (eds.), The Agta of Northeastern Luzon: recent studies. Cebu, Philippines: San Carlos Publications, pp. 69–84.Google Scholar

Mudar, K. M. (1997). Patterns of animal utilization in the holocene of the Philippines: a comparison of faunal samples from four archaeological sites. Asian Perspectives 36: 67–105.Google Scholar

Nelson, S. M. (1998). Ancestors for the pigs. Pigs in prehistory. Philadelphia, PA: Museum Applied Science Center for Archaeology.Google Scholar

Oliver, W. L. R. (1992). The taxonomy, distribution, and status of Philippine wild pigs. Silliman Journal 36: 55–64.Google Scholar

Oliver, W. L. R. (1995). The taxonomy, distribution and status of Philippine wild pigs. Ibex 3: 26–32.Google Scholar

Oliver, W. L. R., Cox, C.R. & Groves, C. P. (1993). The Philippine warty pigs (Sus philippensis and S. cebifrons). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos. Gland: IUCN, pp. 145–155.Google Scholar

Oliver, W. & Heaney, L. (2008). Sus Philippensis. The IUCN Red List of Threatened Species 2008. e.T21176A9245407.Google Scholar

Rabor, D. S. (1977). Philippine birds and mammals. Quezon City, Philippines: University of Philippine Press.Google Scholar

Scheffers, B. R., Corlett, R. T., Diesmos, A. & Laurance, W. F. (2012). Local demand drives a bushmeat industry in a Philippine forest preserve. Tropical Conservation Science 5(2): 133–141. Available online: www.tropicalconservationscience.org Google Scholar

Stibig, H.-J., Stolle, F., Dennis, R. & Feldkötter, C. (2007). Forest cover change in Southeast Asia. The regional pattern. JRC Scientific and Technical Reports: EUR 22896 EN – 2007. Ispra, Italy: Joint Research Center.Google Scholar

Wu, G. S., Pang, J. F. & Zhang, Y. P. (2006). Molecular phylogeny and phylogeography of Suidae. Zoological Research 27: 197–201.Google Scholar

References

Balete, D. S., Heaney, L. R. & Sarmiento, J. B. (2013a). Final Report on the Survey of Mammals of Mt. Calavite, Oriental Mindoro province, Mindoro Island. Submitted 29 November 2013 in compliance with Wildlife Gratuitous Permit No. 220.Google Scholar

Balete, D. S., Heaney, L. R. & Sarmiento, J. B. (2013b). Final Report on the Survey of Mammals of Mt. Halcon, Oriental Mindoro province, Mindoro Island. Submitted 29 November 2013 in compliance with Wildlife Gratuitous Permit No. 220.Google Scholar

Balete, D. S., Heaney, L. R. & Sarmiento, J. B. (2015). Final Report on the Survey of Mammals of Mt. Wood, Mts. Iglit-Baco National Park, Occidental Mindoro province, Mindoro Island. Submitted 3 June 2015 in compliance with Wildlife Gratuitous Permit No. 238.Google Scholar

Gonzalez, J. C. T., Dans, A. T. L. & Afuang, L. E. (1999). Rapid island-wide survey of terrestrial fauna and flora on Mindoro Island, Philippines. Report to Pilipinas Shell Foundation, and FFI-Philippines Programme.Google Scholar

Groves, C. P. (1997). Taxonomy of wild pigs (Sus) of the Philippines. Zoological Journal of the Linnean Society 120: 163–191.Google Scholar

Groves, C. P. (2001). Taxonomy of wild pigs of Southeast Asia. IUCN/SSC Pigs, Peccaries, and Hippos Specialist Group (PPHSG) Newsletter 1(1): 3–4.Google Scholar

Grubb, P. (2005). Artiodactyla. In Wilson, D. E. & Reeder, D. M. (eds.), Mammal species of the world. A taxonomic and geographic reference. 3rd ed. Baltimore, MD: Johns Hopkins University Press, pp. 637–722.Google Scholar

Heaney, L. R., Balete, D. S., Dolar, M. L., et al. (1998). A synopsis of the mammalian fauna of the Philippine Islands. Fieldiana: Zoology 88: 1–61.Google Scholar

Heaney, L. R., Dolar, M. L., Balete, D. S., et al. (2010). Synopsis of Philippine mammals. www.fieldmuseum.org/philippine_mammals.Google Scholar

Lit, Jr., Yap, I. L., Alviola, S.A., et al. (2011). Naujan Lake National Park Site Assessment and Profile Updating. Muntinlupa City: Mindoro Biodiversity Conservation Foundation Inc.Google Scholar

Lucchini, V., Meijaard, E., Diong, C. H., Groves, C. P. & Randi, E. (2005). New phylogenetic perspectives among species of South-east Asian wild pig (Sus sp.) based on mtDNA sequences and morphometric data. Journal of Zoology 266: 25–25.Google Scholar

Meijaard, E., d'huart, J. P. & Oliver, W. L. R. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world, volume 2, hoofed mammals. Barcelona: Lynx Edicions, pp. 248–291.Google Scholar

Mindoro Biodiversity Conservation Foundation Inc. (2014). Mt. Calavite Wildlife Sanctuary Resource and Socio-Economic Assessment (RSEA) Final Report. Muntinlupa City: Mindoro Biodiversity Conservation Foundation Inc.Google Scholar

Oliver, W. L. R. (1992). The taxonomy, distribution, and status of Philippine wild pigs. Silliman Journal 36: 55–64.Google Scholar

Oliver, W. L. R. (1993). Threatened endemic artiodactyls of the Philippines: status and future priorities. International Zoo Yearbook 32: 131–144.Google Scholar

Oliver, W. L. R., Cox, C. R. & Groves, C. P.. (1993). The Philippine warty pigs (Sus philippensis and Sus cebifrons). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: International Union for the Conservation of Nature.Google Scholar

Oliver, W. (2008). Sus oliveri. In IUCN 2014: IUCN Red List of Threatened Species. Version 2014.3. www.iucnredlist.org.Google Scholar

Schütz, E. (2014). Tamaraw Program – Conservation and enhancement of the Natural Heritage of Mts Iglit-Baco National Park. Mission Report, Noé Conservation (unpublished).Google Scholar

Schütz, E. (2015a). Records of Mindoro warty pig (Sus oliveri) in the interior of Mindoro Island – Philippines. Suiform Soundings – newsletter of the IUCN/SSC Wild Pig, Peccary, and Hippo Specialist Groups 13(2): 13–15.Google Scholar

Schütz, E. (2015b). Tamaraw population survey and current status. Field Mission Report. Noé Conservation (unpublished).Google Scholar

Schütz, E. (2016). Sus Oliveri. The IUCN Red List of Threatened Species 2016.Google Scholar

Tabaranza, D. G. E., Bueno, M. C., Cielo, K. L. S. & Panopio, J. K. (2013). Mt.Siburan IBA Rapid Survey of Biological Diversity – Technical Report. Haribon Foundation and Mindoro Biodiversity Conservation Foundation, Inc. (unpublished).Google Scholar

References

Cruz, R.M., Villafuerte-van den Beukel, D., Widmann, I. D., Schoppe, S., & Widmannn, P. (2009). Wildlife trade in southern Palawan, Philippines. In Widmann, I. D., Widmann, P., Schoppe, S., van den Beukel, D. & Espeso, M. (eds.), Conservation studies on Palawan biodiversity. Puerto Princesa City, Philippines: Katala Foundation, Inc., pp. 171–178.Google Scholar

Esselstyn, J. A., Widmann, P. & Heaney, L. R. (2004). The mammals of Palawan Island, Philippines. Proceedings of the Biological Society of Washington 117: 271–302.Google Scholar

Hoogstraal, H. (1951). Philippine Zoological Expedition 1946–1947 – narrative and itinerary. Fieldiana Zoology 33: 1–91.Google Scholar

IUCN (2016). IUCN Red List of Threatened Species. Version 2016.1. (www.iucnredlist.org).Google Scholar

Lacerna, I. D. D. & Widmann, P. (1999). Biodiversity utilization in a Tagbanua community, southern Palawan, Philippines. In Goeltenboth, F., Milan, P. P. & Asio, V. B. (eds.), International conference on applied tropical ecology. Baybay, Leyte, Philippines: ViSCA-GTZ Applied Tropical Ecology Programme, pp. 52–64.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. (2011). Family Suidae (pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world Vol. 2: hoofed mammals. Barcelona: Lynx Edicions, pp. 248–291.Google Scholar

Oliver, W. L. R. (1995). The taxonomy, distribution and status of Philippine wild pigs. IBEX 3: 26–32.Google Scholar

Oliver, W. (2008). Sus ahoenobarbus. The IUCN Red List of Threatened Species 2008.Google Scholar

Piper, P. J., Ochoa, J., Robles, E. C., Lewis, H. & Paz, V. (2011). Palaeozoology of Palawan Island, Philippines. Quaternary International 233: 142–158.Google Scholar

Reis, K. R. & Garong, A.M. (2001). Late Quaternary terrestrial vertebrates from Palawan Island, Philippines. Palaeogeography, Palaeoclimatology, Palaeoecology 171: 409–421.Google Scholar

Sanborn, C. C. (1952). Philippine Zoological Expedition 1946–1947: mammals. Fieldiana Zoology 33: 158.Google Scholar

Widmann, P., Dumalag, R. M., Widmann, I. D. L., et al. (2008). Observations of the mammals of lowland forests in the Pagdanan Range and Dumaran Island, Palawan, Philippines. In Widmann, I. D. L., Widmann, P., Schoppe, S. & van den Beukel, D. (eds.), Conservation studies on Palawan biodiversity. Puerto Princesa City, Palawan, Philippines: Katala Foundation, Inc., pp. 2–14.Google Scholar

References

Balen, J. V. (1914). De Dierenwereld van Insulinde in woord en beeld (vol. 1). Zoogdieren.Google Scholar

Banks, E. (1931). A popular account of the mammals of Borneo. Journal of the Malayan Branch of the Royal Asiatic Society 9: part II.Google Scholar

Banks, E. (1949). Bornean mammals. Kuching: Kuching Press.Google Scholar

Bastoni, B. (2008). PKHS/STTCP Senepis. Annual Report of PKHS/STTCP 0: 45–54.Google Scholar

Beccari, O. (1904). Wanderings in the great forests of Borneo. Oxford: Oxford University Press.Google Scholar

Bennett, E. L. & Gumal, M. T. (2001). The inter-relationships of commercial logging, hunting and wildlife in Sarawak, and recommendations for forest management. In Fimbel, R. A., Grajal, A. & Robinson, J. G. (eds.), The cutting edge: conserving wildlife in logged tropical forest. New York, NY: Columbia University Press.Google Scholar

Bennett, E. L., Nyaoi, A. J. & Sompud, J. (1999). Saving Borneo's bacon: the sustainability of hunting in Sarawak and Sabah. In Robinson, J. G. & Bennett, E. L. (eds.), Hunting for sustainability in tropical forests. New York, NY: Columbia University Press.Google Scholar

Blouch, R. A. (1984). Current status of the Sumatran rhino and other large mammals in Southern Sumatra. Bogor: WWF Report.Google Scholar

Briedermann, L. (1965). Die altersbestjmznung erlegten schwarzwi. Deutsche Akademie de Landwirtschaftswissenschaften zu Berlin. Arbeitsgemejnschaft für Jagd-urid Wildforschung. Merkblatt 22: 10–20.Google Scholar

Caldecott, J. (1988). Hunting and wildlife management in Sarawak. Gland: IUCN, pp. 176–182.Google Scholar

Caldecott, J. (1991). Eruptions and migrations of bearded pig populations. Bongo 18: 233–243.Google Scholar

Caldecott, J. & Caldecott, S. (1985). A horde of pork. New Scientist 1469: 32–35.Google Scholar

Caldecott, J. O., Blouch, R. A. & MacDonald, A. A. (1993). The bearded pig (Sus barbatus). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos. Status survey and conservation action plan. Gland: IUCN/SSC Pigs and Peccaries Specialist group and IUCN/SSC Hippos Specialist Group.Google Scholar

Chin, C. (2001). Pig in the pot: comments on Sus barbatus in the hunting lifestyle of the Penan in Sarawak (Borneo). Asian Wild Pig News 1: 10–12.Google Scholar

Chua, K. B. (2003). Nipah virus outbreak in Malaysia. Journal of Clinical Virology 26: 265–275.Google Scholar

Clayton, L., Keeling, M. & Milner-Gulland, E. J. (1997). Bringing home the bacon: a spatial model of wild pig hunting in Sulawesi, Indonesia. Ecological Applications 7: 642–652.Google Scholar

Corlett, R. T. (2007). The impact of hunting on the mammalian fauna of tropical Asian forests. Biotropica 39: 292–303.Google Scholar

Curran, L. M. & Leighton, M. (2000). Vertebrate responses to spatiotemporal variation in seed production of mast-fruiting Dipterocarpaceae. Ecological Monographs 70: 121–150.Google Scholar

Curran, L. M. & Webb, C. O. (2000). Experimental tests of the spatiotemporal scale of seed predation in mast-fruiting Dipterocarpaceae. Ecological Monographs 70: 151–170.Google Scholar

Dove, M. R. (1993). The response of dayak and bearded pig to mast-fruiting in Kalimantan: an analysis of nature-culture analogies. In Hladik, C. M., Hladik, A., Linares, O. F., et al. (eds.), Tropical forest people and food: biocultural interactions and applications to development. London: UNESCO Parthenon Publishing Group.Google Scholar

Endert, U. (1925). Cited in Nederlandsch Indische Vereeniging tot Natuurbescherming (NIVN), 1939. Netherlands.Google Scholar

Francis, C. M. & Barrett, P. (2008). A guide to the mammals of Southeast Asia. Princeton, NJ: Princeton University Press, p. 392.Google Scholar

Fryxell, J. M., Sinclair, A. R. & Caughley, G. (2014). Wildlife ecology, conservation, and management. New York, NY: John Wiley & Sons.Google Scholar

Groves, C. (1981). Ancestors for the pigs: taxonomy and phylogeny of the genus Sus. Technical Bulletin of Department of Prehistory, Research School of Pacific Studies 3. Canberra: Australian National University.Google Scholar

Groves, C. P. (2001). Taxonomy of wild pigs of Southeast Asia. Asian Wild Pig News 1: 2–3.Google Scholar

Hanebuth, T., Stattegger, K. & Grootes, P. M. (2000). Rapid flooding of the Sunda Shelf: a late-glacial sea-level record. Science 288: 1033–1035.Google Scholar

Harrison, R. D. (2011). Emptying the forest: hunting and the extirpation of wildlife from tropical nature reserves. BioScience 61: 919–924.Google Scholar

Harrison, R. D., Tan, S., Plotkin, J. B., et al. (2013). Consequences of defaunation for a tropical tree community. Ecology Letters 16: 687–694.Google Scholar

Harrison, T. (1998). Vertebrate faunal remains from the Madai Caves, Sabah, East Malaysia. Bulletin of the Indo-Pacific Prehistory Association 17: 85–92.Google Scholar

Hislop, J. A. (1949). Some field notes on the bearded pig. Malay Naturalist Journal 4: 62–65.Google Scholar

Hislop, J. A. (1955). Notes on the migration of bearded pig. In Sieveking, G. (ed.), Excavations at Gua Cha, Kelantan, 1954. Appendix E. Federations Museum Journal 2: 134–137.Google Scholar

Hose, C. (1926). Natural man: a record from Borneo. London: Macmillan, London; Singapore: Oxford University Press (reprint).Google Scholar

Ickes, K., Dewalt, S. J. & Thomas, S. C. (2003). Resprouting of woody saplings following stem snap by wild pigs in a Malaysian rain forest. Journal of Ecology 91: 222–233.Google Scholar

ISIS. (2011). International Species Information System: Sus barbatus. Version 12, accessed on 15 January, 2011.Google Scholar

Janzen, D. H. (1974). Tropical blackwater rivers, animals, and mast fruiting by the Dipterocarpaceae. Biotropica 12: 69–103.Google Scholar

Kawanishi, K. & Sunquist, M. E. (2004). Conservation status of tigers in a primary rainforest of Peninsular Malaysia. Biological Conservation 120: 329–344.Google Scholar

Kawanishi, K., Richardson, D. & Lazarus, K. (2006). Contraction of bearded pig Sus barbatus distribution in Peninsular Malaysia. Suiform Soundings 6: 13–16.Google Scholar

Kawanishi, K., Clements, G. R., Gumal, M., et al. (2013). Using BAD for good: how best available data facilitated a precautionary policy change to improve protection of the prey of the tiger Panthera tigris in Malaysia. Oryx 47: 420–426.Google Scholar

Ke, A. and Luskin, M. S. (2017). Integrating disparate occurence reports to map data-poor species ranges and occupancy: a case study of the vulnerable bearded pig Sus barbatus. Oryx 1–11.Google Scholar

Leighton, M. & Leighton, D. R. (1983). Vertebrate response to fruiting seasonality within a Bornean rain forest. In Sutton, S. L., Whitmore, T. C. & Chadwick, A. C. (eds.), Tropical rainforest ecology and management. Oxford: Blackwell Scientific Publications.Google Scholar

Linkie, M. & Sadikin, L. (2003). The bearded pig in Kerinci Seblat National Park, Sumatra. Asian Wild Pig News 3: 3–9.Google Scholar

Linkie, M., Guillera-Arroita, G., Smith, J., et al. (2013). Cryptic mammals caught on camera: assessing the utility of range wide camera trap data for conserving the endangered Asian tapir. Biological Conservation 162: 107–115.Google Scholar

Lohe, R. (2015). Bearded pigs on the Malayan Peninsular – a travel report. Suiform Soundings 21: 21–23.Google Scholar

Luskin, M. S. & Potts, M. D. (2011). Microclimate and habitat heterogeneity through the oil palm lifecycle. Basic and Applied Ecology 12: 540–551.Google Scholar

Luskin, M. S., Christina, E. D., Kelley, L. C. & Potts, M. D. (2014). Modern hunting practices and wild meat trade in the oil palm plantation-dominated landscapes of Sumatra, Indonesia. Human Ecology 42: 35–45.Google Scholar

Lyon, M. W. (1908). Mammals collected in Eastern Sumatra by W. L. Abbott during 1903, 1906, and 1907, with descriptions of new species and sub-species. Proceedings of the U S National Museum 34: 619–679.Google Scholar

Lyon, M. W. (1911). Mammals collected by Dr. W.L. Abbott on Borneo and some of the small adjacent islands. Proceedings of the U S National Museum 40: 53.Google Scholar

MacKinnon, K., Hatta, G., Halim, H. & Mangalik, A. (1996). The ecology of Kalimantan. Singapore: Periplus Editions.Google Scholar

Margono, B. A., Turubanova, S., Zhuravleva, I., et al. (2012). Mapping and monitoring deforestation and forest degradation in Sumatra (Indonesia) using Landsat time series data sets from 1990 to 2010. Environmental Research Letters 7: 034010.Google Scholar

Medway, L. (1964). Post-Pleistocene changes in the mammalian fauna of Borneo: archaeological evidence from the Niah caves. Studies in Speleology 1: 33–37.Google Scholar

Medway, L. (1977). Mammals of Borneo. Kuala Lumpur, Malaysia.Google Scholar

Meijaard, E. (2000). Bearded pigs (Sus barbatus): ecology, conservation status, and research methodology. WWF-Indonesia, CIFOR, and Ecosense Consultants.Google Scholar

Meijaard, E. (2002). Wild pig meat on Sumatran and Bornean markets. Asian Wild Pig News 2: 8–10.Google Scholar

Meijaard, E. & Sheil, D. (2008). The persistence and conservation of Borneo's mammals in lowland rain forests managed for timber: observations, overviews and opportunities. Ecological Research 23: 21–34.Google Scholar

Miettinen, J., Shi, C. & Liew, S. C. (2011). Deforestation rates in insular Southeast Asia between 2000 and 2010. Global Change Biology 17: 2261–2270.Google Scholar

Miller, G. S. (1905). Notes on Malayan pigs. Proceedings of the U S National Museum 30: 737–758.Google Scholar

NIVN. (1939). Nederland Indische Vereniging tot Natuurbescherming. 3 jaren Indisch Natuurleven. Netherlands.Google Scholar

Pfeffer, P. (1959). Biologie et migrations du sanglier de Borneo (Sus barbatus Müller 1869). Mammalia 23: 277–303.Google Scholar

Pfeffer, P. & Caldecott, J. T. (1986). The bearded pig in East Kalimantan and Sarawak. Journal of the Malayan Branch of the Royal Asiatic Society 59: 81–100.Google Scholar

Puri, R. (1992). Mammals and hunting on the Lurah River: recommendations for management of faunal resources in the Cagar-Alam Kayan-Mentarang. Samarinda, East Kalimantan: WWF, p. 48.Google Scholar

Robinson, J. G. & Bennett, E. L. (2013). Hunting for sustainability in tropical forests. New York, NY: Columbia University Press.Google Scholar

Ross, J., Hearn, A. J., Johnson, P. J. & Macdonald, D. W. (2013). Activity patterns and temporal avoidance by prey in response to Sunda clouded leopard predation risk. Journal of Zoology 290: 96–106.Google Scholar

Schaik, C. P. V. (1986). Phenological changes in a Sumatran rainforest. Journal of Tropical Ecology 2: 327–347.Google Scholar

Schaik, C. P. V. & Noordwijk, M. A. V. (1985). Interannual variability in fruit abundance and reproductive seasonality in Sumatran long-tailed macaques (Macaca fascicularis). Journal of Zoology 206: 533–549.Google Scholar

Te Wong, S., Servheen, C., Ambu, L. & Norhayati, A. (2005). Impacts of fruit production cycles on Malayan sun bears and bearded pigs in lowland tropical forest of Sabah, Malaysian Borneo. Journal of Tropical Ecology 21: 627–639.Google Scholar

Wallace, A. R. (1869). The Malay Archipelago: the land of the orangutan and the bird of paradise; a narrative of travel, with studies of man and nature. London: Courier Corporation Press.Google Scholar

Wich, S. A. & Schaik, C. P. V. (2000). The impact of El Nino on mast fruiting in Sumatra and elsewhere in Malesia. Journal of Tropical Ecology 16: 563–577.Google Scholar

References

Appelman, F. J. (1955). Über Sus celebensis Müller & Schlegel. Zoologischer Garten 21: 152–156.Google Scholar

Avalard, M. S. (2000). The potential for sustainable harvests by traditional Wana hunters in Morowali Nature Reserve, Central Sulawesi, Indonesia. Human Organization 59(4): 428–440.Google Scholar

Bell, J. (1987). Nutrition and reproduction of Indonesian wild pigs. Unpublished report, Edinburgh University. 6 pp.Google Scholar

Blouch, R. A. (1990). Report from the field: Indonesia. Smithsonian Institute Conservation and Research Centre Newsletter 1: 6–8.Google Scholar

Bosma, A. A., de Haan, N. A., Blouch, R. A. & Macdonald, A. A. (1991). Comparative cytogenetic studies in Sus verrucosus, Sus celebensis and Sus scrofa vittatus (Suidae, Mammalia). Genetica 83: 189–194.Google Scholar

Budiarso Wilar, A. F., Tulung, B., Kaligis, D. & Kaligis, W. A. A. (1991). The importance of Sulawesi wild pig (Sus celebensis) as a source of meat in North Sulawesi. Unpublished report, Universitas Sam Ratulangi and World Wide Fund for Nature Indonesia Programme. 19 pp.Google Scholar

Burton, J. & Macdonald, A. A. (2006). The Sulawesi Warty Pig (Sus celebensis), a status review. Suiform Soundings 6(2): 5–13.Google Scholar

Burton, J. & Macdonald, A. A. (2008). Sus Celebensis. The IUCN Red List of Threatened Species 2008.Google Scholar

Burton, J. A. & Macdonald, A. A. (2009). Variation in distribution and abundance of large mammals in Lore Lindu National Park, Central Sulawesi, Indonesia. Malay Nature Journal 61(4): 295–305.Google Scholar

Catibog-Sinha, C. (1985). Depredation of wild pigs (Sus celebensis Sanborn) on shifting cultivation. Sylvatrop, Philippine Forest Research Journal 10: 283–292.Google Scholar

Clayton, L. & Milner-Gulland, E. J. (2000). The trade in wildlife in north Sulawesi, Indonesia. In Robinson, J. G. & Bennett, E. L. (eds.), Hunting for sustainability in tropical rainforests. New York, NY: Columbia University Press, pp. 473–496.Google Scholar

Clayton, L. M., Keeling, M. J. & Milner-Gulland, E. J. (1997). Bringing home the bacon: a spatial model of the wild pig hunting in Sulawesi, Indonesia. Ecological Applications 7(2): 642–652.Google Scholar

Cucchi, T., Fujita, M. & Dobney, K. (2009). New insights into pig taxonomy, domestication and human dispersal in Island South East Asia: molar shape analysis of Sus remains from Niah Caves, Sarawak. International Journal of Osteoarchaeology 19(4): 508–530.Google Scholar

Dobney, K., Cucchi, T. & Larson, G. (2008). The pigs of Island Southeast Asia and the Pacific: new evidence for taxonomic status and human-mediated dispersal. Asian Perspectives 47 (1): 59–74.Google Scholar

Evans, B. J., Morales, J. C., Supriatna, J. & Melnick, D. J. (1999). Origin of the Sulawesi macaques (Cercopithecidae: Macaca) as suggested by mitochondrial DNA phylogeny. Biological Journal of the Linnean Society 66(4): 539–560.Google Scholar

Fooden, J. (1969). Taxonomy and evolution of the monkeys of Celebes (Primates: Cercopithecidae). Basel: S. Karger (Bibliotheca Primatologica, No. 10).Google Scholar

Frantz, A. F., Schraiber, J. G., Madsen, O., et al. (2013). Genome sequencing reveals fine scale diversification and reticulation history during speciation in Sus. Genome Biology 14: 107.Google Scholar

Gongora, J., Cuddahee, R., do Nascimento, F., et al. (2011). Rethinking the evolution of extant sub-Saharan African suids (Suidae, Artiodactyla). Zoologica Scripta 40(4): 327–335.Google Scholar

Groves, C. (1981). Ancestors for the pigs: taxonomy and phylogeny of the genus Sus. Tech. Bull. No. 3. Canberra: Australian National University Press. 96 pp.Google Scholar

Groves, C. (1983). Pigs east of the Wallace Line. Journal de la Société des océanistes 39: 105–119.Google Scholar

Groves, C. (1997). Taxonomy of wild pigs (Sus) of the Philippines. Zoological Journal of the Linnaean Society 120(2): 163–191.Google Scholar

Groves, C. P. & Grubb, P. (1993). The suborder Suiformes. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 1–4.Google Scholar

Groves, C. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: John Hopkins University Press.Google Scholar

Grubb, P. (2005). Order Artiodactyla. In Wilson, D. E. & Reeder, D. M. (eds.), Mammal species of the world: a taxonomic and geographic reference. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Hardjasasmita, H. S. (1987). Taxonomy and phylogeny of the Suidae (Mammalia) in Indonesia. Scripta Geologica 85: 1–68.Google Scholar

Hooijer, D. A. (1950). Man and other mammals from Toalian sites in S. W. Celebes. Verhandelingen der Koninklijke Nederlandische Akademie van Wetenschappen (Natuurkunde) 46 (2): 1–162.Google Scholar

Hooijer, D. A. (1969). Pleistocene vertebrates from Celebes, 8 Sus celebensis Muller & Schlegel, 1845. Beaufortia 16: 215–218.Google Scholar

Jamaludin, M., Mustari, A. H., Burton, J. A. & Hernowo, J. B. (2008). Demographic parameters and behaviours of Sulawesi warty pig (Sus celebensis Muller and Schlegel 1843) in Tanjung Peropa Wildlife Reserve, southeast Sulawesi. Media Konservasi 13 (2): 90–93.Google Scholar

Larson, G., Dobney, K., Albarella, U., et al. (2005). Worldwide phylogeography of wild boar reveals multiple centers of pig domestication. Science 307: 1618–1621.Google Scholar

Larson, G., Cucchi, T., Fujita, M., et al. (2007). Phylogeny and ancient DNA of Sus provides insights into neolithic expansion in Island Southeast Asia and Oceania. Proceedings of the National Academy of Sciences 104: 4834–4839.Google Scholar

Lee, R. J. (2000). Impact of subsistence hunting in North Sulawesi, Indonesia, and conservation options. In Robinson, G. & Bennet, E. L. (eds.), Hunting for sustainability in tropical forest. New York, NY: Columbia University Press, pp. 455–472.Google Scholar

Macdonald, A. A. (1991). Monographe des Celebes-schweines (Sus celebensis). Bongo 18: 39–45.Google Scholar

Macdonald, A. A. & Leus, K. (2005). The naming of animals by the people of Wallacea. Unpublished.Google Scholar

Macdonald, A. A., Kneepkens, A. F. L. M. & Bosma, A. A. (1984). Anatomical studies on the female and male reproductive tracts of wild pigs. In Spitz, F. & Pepin, D. (eds.), Proc. Symp. Int. sur le Sanglier. Paris: INRA (Les Colloques de l'INRA No. 22), pp. 93–104.Google Scholar

Macdonald, A.A., Leus, K., Florence, A., Clare, J. & Patry, M. (1996). Notes on the behaviour of Sulawesi Warty pigs (Sus celebensis) in North Sulawesi, Indonesia. Malaysian Nature Journal 50: 47–53.Google Scholar

MacKinnon, J. (1981). The distribution and status of wild pigs in Indonesia. Unpublished report. IUCN/SSC Pigs and Peccaries Specialist Group. 9 pp.Google Scholar

Mustari, A. H. (2005). Ecology and conservation of lowland anoa Bubalus depressicornis in Sulawesi Indonesia. PhD thesis, University of New England, Australia.Google Scholar

Mustari, A. H. (2009). Population density of Sulawesi's forest ungulates in Tanjung Peropa and Tanjung Amoalengo Wildlife Reserves, southeast Sulawesi. Media Konservasi 14(2): 89–94.Google Scholar

Mustari, A. H., Siswanto, N., Burton, J. A. & Kartono, A. P. (2009). Study on food plants and feeding behaviour of Sulawesi warty pig (Sus celebensis Muller & Schlegel, 1843) in Tanjung Peropa Wildlife Reserve, South East Sulawesi. Unpublished report.Google Scholar

National Research Council. (1983). Little-known Asian animals with a promising economic future. Washington: National Academy Press, pp. 75–79.Google Scholar

O'Brien, T. G. & Kinnaird, M. F. (1996). Changing population of birds and mammals in north Sulawesi. Oryx 30: 150–156.Google Scholar

Oliver, W. L. R., Brisbin, I. L. J. & Takahashi, S. (1993). The Eurasian wild pig, Sus scrofa. In Oliver, W. L. R. (ed.), Status survey and conservation action plan: pigs, peccaries and hippos specialist group. Gland: IUCN.Google Scholar

Riley, J. (2002). Current Wildlife Conservation Society research and conservation of Sulawesi's suids. Asian Wild Pig News 2(2): 26–29.Google Scholar

Ruedi, M., Auberson, M. & Savolainen, V. (1998). Biogeography of Sulawesian shrews: testing for their origin with a parametric bootstrap on molecular data. Molecular Biological Evolution 9: 567–571.Google Scholar

Sanborn, C. C. (1952). Philippine Zoological Expedition 1946–47. Fieldiana: Zoology 33: 89–158.Google Scholar

Setyodiwiryo, K. (1959). Nature protection in Indonesia. Proc. 9th Pacific Science Congress 7: 18–20.Google Scholar

Sinha, C. C. S. (1982). The quality and quantity of wild food plants and the depredation of wild pigs in the Philippines. Dissertation Abstracts International (B) 42(a): 3513.Google Scholar

Smiet, F. (1982). Threats to the Spice Islands. Oryx 14: 323–328.CrossRef Google Scholar

Sody, H. J. V. (1941). Tweede bijdrage over de voortplantings tijden der Indische zoogdieren. De Nederlandsch-Indische Jager 11: 198–201 and 256–265.Google Scholar

van der Made, J. & Moya-Sola, S. (1989). European Suinae (Artiodactyla) from the late Miocene onwards. Bolletina della Societa Palaentologica Italiana 28: 239–339.Google Scholar

Wiles, P. R., Burton, J. A., Macdonald, A. A. & Mustari, A. H. (2002). Records of Babirusa and warty pigs in SE Sulawesi. Asian Wild Pig News 2(2): 31–32.Google Scholar

References

Blouch, R. A. (1988). Ecology and conservation of the Javan warty pig Sus verrucosus Müller, 1840. Biological Conservation 43: 295–307.Google Scholar

Blouch, R. A., Laban, B. Y., Susilo, H. D. & Atmo-Soedirdjo, S. (1983). The Javan warty pig: distribution, status, and prospects for the future. Bogor: World Wildlife Fund.Google Scholar

Dewi, K. & Nugraha, R. T. P. (2007). Endoparasit pada feses babi kutil (Sus verrucosus) di Kebun Binatang Surabaya [Endoparasites of warty pig (Sus verrucosus) faeces in Surabaya Zoo]. Zoo Indonesia 16: 13–20.Google Scholar

Farnesi, R. M., Vagnetti, D., Santarella, B. & Tei, S. (1999). Morphological and ultrastructural study of carpal organ in adult female wild swine. Anatomica, Histologia, Embryologia 28: 31–38.Google Scholar

Frantz, L. A. F., Schraiber, J. G., Madsen, O., et al. (2013). Genome sequencing reveals fine scale diversification and reticulation history during speciation in Sus. Genome Biology 14: R107.Google Scholar

Groves, C. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: John Hopkins University Press.Google Scholar

Groves, C. P. (1981). Ancestors for the pigs. Canberra: Australian National University Press.Google Scholar

Hardjasamita, H. S. (1987). Taxonomy and phylogeny of the Suidae (Mammalia) in Indonesia. Scripta Geologica 85: 1–68.Google Scholar

Heise-Pavlov, S., Heise-Pavlov, P. & Bradley, A. (2005). Carpal glands in feral pigs (Sus domesticus) in tropical lowland rainforest in north-east Queensland, Australia. Journal of Zoology, London 266: 73–80.Google Scholar

Hoogerwerf, A. (1967). Notes on the island of Bawean (Java Sea) with special reference to the birds (II). The Natural History Bulletin of the Siam Society 22: 15–103.Google Scholar

IUCN/SSC (2013). Guidelines for reintroductions and other conservation translocations. Version 1.0. Gland: IUCN Species Survival Commission.Google Scholar

MacKinnon, J. R. (1997). Protected areas systems review of the Indo-Malayan realm. Asian Bureau for Conservation.Google Scholar

Meijaard, E. (2006). Differentiating between Sus scrofa and Sus verrucosus. Suiform Soundings 6: 22–24.Google Scholar

Meijaard, E. (2014). A literature review of ecological separation between Sus verrucosus and S. scrofa. Suiform Soundings 12: 18–25.Google Scholar

Meijaard, E., d'Huart, J. P. & Oliver, W. L. R. (2011). Family Suidae (Pigs). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world. Volume 2. Barcelona: Lynx Editions, pp. 248–291.Google Scholar

Meijaard, E., Leus, K. & Burton, J. (2014). Think pig. Results from our first Wild Pig Specialist Group Meeting for South-East and South Asia. Suiform Soundings 12: 4–8.Google Scholar

Nascimento, F., Gongora, J. & Moran, C. (2007). Detection of porcine endogenous retrovirus DNA sequences among species of the family Suidae. Proceedings of the Faculty of Veterinary Science 2007 Postgraduate Conference. The University of Sydney, pp. 56–57.Google Scholar

National Research Council (1983). Little-known Asian animals with a promising economic future. Washington, DC: National Academic Press.Google Scholar

Nijman, V. (2004). Survey on birds of prey and owls (Falconiformes and Strigiformes) on Bawean, Java Sea, with records of three species new to the island. The Raffles Bulletin of Zoology 52: 647–651.Google Scholar

Nijman, V. (2006). The endemic Bawean Serpent-eagle Spilornis baweanus: habitat use, abundance and conservation. Bird Conservation International 16: 131–143.Google Scholar

Olivier, J. (1925). De wilde zwijnen van Java. Soorten of rassen? – of nog wat anders? De Tropische Natuur 14: 145–154.Google Scholar

Olivier, J. (1933). Allemaal zwijnerij (doch niet, gelijk men 't gewoonlijk verstaat). De Tropische Natuur 22: 184–188.Google Scholar

Oliver, W. L. R. (1993). Status survey and conservation action plan. Pigs, peccaries and hippos. Gland: IUCN.Google Scholar

Postolache, A. N., Ciobanu, M. M. & Boisteanu, P. C. (2015). Selected biometric characteristics of wild boar (Sus scrofa ferus) in North-East Rumania. Bulletin UASVM Food Science and Technology 72: 136–138.Google Scholar

Rademaker, M. (2015). Warty Watch, putting the spotlight on Indonesia's most distinct pig. Suiform Soundings 14: 14–21.Google Scholar

Rademaker, M. & Rode-Margono, J. (2015). DD – Bawean Warty Pig. [Online]. In Wild Pigs of the World. IUCN/SSC Wild Pig Specialist group. Accessed 9 January 2016. https://sites.google.com/site/wildpigspecialistgroup/home/ne---bawean-warty-pig Google Scholar

Rademaker, M., Rode-Margono, J. & Tritto, A. (2015). Behaviour of wild caught and captiveborn Javan warty pigs (Sus verrucosus) and implications for reintroduction. Suiform Soundings 14: 5–13.Google Scholar

Rademaker, M., Meijaard, E., Semiadi, G., et al. (2016). First ecological study of the Bawean warty pig (Sus blouchi), one of the rarest pigs on earth. PLoS ONE 11(4): e0151732.Google Scholar

Rademaker, M. (2016). Sus verrucosus ssp. blouchi. [online] IUCN Red List of Threatened Species. e.T84697083A88214700. Accessed 11 July 2017. http://dx.doi.org/10.2305/IUCN.UK.2016-1.RLTS.T84697083A88214700.en.Google Scholar

Randi, E., Lucchini, V., Hoong Diong, C. (1996). Evolutionary genetics of the suiformes as reconstructed using mtDNA sequencing. Journal of Mammalian Evolution 3: 163–194.Google Scholar

Rode-Margono, E. J., Diana, P., Zahra, S., et al. (2016). Behaviour and group patterns of wild Bawean warty pigs (Sus blouchi) on Bawean island, Indonesia. Suiform Soundings 14(2): 15–20.Google Scholar

Rode-Margono, E. J., Blokland, S., Zahra, S., Rademaker, M., & Semiadi, G. (in press). Crop raiding and local people's attitudes on Bawean island, Indonesia, with a focus on the Endangered Bawean warty pigs (Sus blouchi). Asian Journal of Conservation Biology.Google Scholar

Semiadi, G. & Meijaard, E. (2004). Survey of the Javan warty pig (Sus verrucosus) on Java and Bawean Island, with English summary and detailed survey results in Indonesian. Final Report. Bogor, Indonesia: LIPI.Google Scholar

Semiadi, G. & Meijaard, E. (2006). Declining populations of the Javan warty pig Sus verrucosus. Oryx 40: 50–56.Google Scholar

Semiadi, G. & Nugraha, R. T. P. (2009). Some notes on biological aspects of captive Javan warty pig (Sus verrucosus). Biodiversitas 10: 124–128.Google Scholar

Semiadi, G. & Sözer, R. (2007). The establishment of a conservation breeding program for Javan Warty Pig (Sus verrucosus). Proposal. Cibinong & Sukabumi, Indonesia: Research Center for Biology LIPI & Cikananga Species Conservation Center.Google Scholar

Semiadi, G., Rademaker, M. & Meijer, E. (2016). Sus verrucosus. The IUCN Red List of Threatened Species. Accessed 11 July 2017.Google Scholar

Van den Bergh, G. D., de Vos, J. & Sondaar, P. Y. (2001). The Late Quaternary palaeogeography of mammal evolution in the Indonesian Archipelago. Palaeogeography, Palaeoclimatology, Palaeoecology 171: 385–408.Google Scholar

References

Abáigar, T. (1993). Régimen alimentario del jabalí (Sus scrofa, L. 1758) en el sureste Ibérico. Doñana. Acta Vertebrata 20: 35–48.Google Scholar

Abaigar, T., Del Barrio, G. & Vericad, J. R. (1994). Habitat preference of wild boar (Sus scrofa L., 1758) in a Mediterranean environment. Indirect evaluation by signs. Mammalia 58: 201–210.Google Scholar

Acevedo, P., Escudero, M. A., Munoz, R. & Gortázar, C. (2006). Factors affecting wild boar abundance across an environmental gradient in Spain. Acta Theriologica 51: 327–336.Google Scholar

Ahlers, H. (2013). Untersuchungen zum Eintritt in die Geschlechtsreife beim männlichen europäischen Wildschwein (Sus scrofa L.). Göttingen: Georg-August-Universität zu Göttingen.Google Scholar

Alexandri, P., Triantafyllidis, A., Papakostas, S., et al. (2012). The Balkans and the colonization of Europe: the post-glacial range expansion of the wild boar, Sus scrofa. Journal of Biogeography 39: 713–723.Google Scholar

Andrzejewski, R. & Jezierski, W. (1978). Management of a wild boar population and its effects on commercial land. Acta Theriologica 23: 309–339.Google Scholar

Apollonio, M., Andersen, R. & Putman, R. (2010). European ungulates and their management in the 21st century. Cambridge: Cambridge University Press.Google Scholar

Appelius, M. (1995). Einflüsse auf die Populationsdynamik von weiblichen Schwarzwild-Frischlingen aus dem nördlichen Regierungsbezirk Braunschweig und dem Forstamt Saupark. Dissertation. Hannover: Tierärztliche Hochschule Hannover.Google Scholar

Aravena, P., Skewes, O. & Gouin, N. (2015). Mitochondrial DNA diversity of feral pigs from Karukinka Natural Park, Tierra del Fuego Island, Chile. Genetics and Molecular Research 14(2): 4245–4257.Google Scholar

Asahi, M. (1995). Stomach contents of Japanese wild boar in winter. Ibex Journal of Mountain Ecolology 3: 184–185.Google Scholar

AZA (2008). Wild Pig, Peccary and Hippo TAG Regional Collection Plan.Google Scholar

Baber, D. W. & Coblentz, B. E. (1986). Density, home range, habitat use, and reproduction in feral pigs on Santa Catalina Island. Journal of Mammalogy 67: 512–525.Google Scholar

Ballari, S. & Barrios-García, M. (2014). A review of wild boar Sus scrofa diet and factors affecting food selection in native and introduced ranges. Mammal Review 44(2): 124–134.Google Scholar

Ballari, S., Cuevas, M. S., Cirignoli, S. & Valenzuela, A. E. J. (2015). Invasive wild boar in Argentina: using protected areas as a research platform to determine distribution, impacts and management. Biological Invasions 17: 1595–1602.Google Scholar

Barrett, R. H. & Birmingham, G. H. (2005). Wild pigs. USA: Internet Center for Wildlife Damage Management.Google Scholar

Barrette, C. (1986). Fighting behavior of wild Sus scrofa. Journal of Mammalogy 67: 177–179.Google Scholar

Barrios-Garcia, M. & Ballari, S. (2012). Impact of wild boar Sus scrofa in its introduced and native range: a review. Biological Invasions 14: 2283–2300.Google Scholar

Baskin, L. & Danell, K. (2003). Wild ungulates. A handbook of species in eastern Europe and northern and central Asia. Berlin, Heidelberg: Springer-Verlag.Google Scholar

Baubet, E., Brandt, S. & Touzeau, C. (1998). Effet de la chasse sur les stratégies d'occupation de l'espace des sangliers (Sus scrofa). Analyses préliminaires. Gibier Faune Sauvage Game and Wildlilfe 15: 655–658.Google Scholar

Baubet, E., Ropert-Coudert, Y. & Brandt, S. (2003). Seasonal and annual variations in earthworm consumption by wild boar (Sus scrofa scrofa L.). Wildlife Research 30(2): 179–186.Google Scholar

Baubet, E., Bonenfant, C., & Brandt, S. (2004). Diet of the wild boar in the French Alps. Galemys 16: 99–111.Google Scholar

BCMFLNRO (British Columbian Ministry of Forests, Lands and Natural Resource Operations). (2014). Province takes aim at feral pigs. Information Bulletin. www2.news.gov.bc.ca/news_releases_2013-2017/2014FLNR0021-000322.htm. Accessed 20 March 2014.Google Scholar

Beyer, W. N., Connor, E. E. & Gerould, S. (1994). Estimates of soil ingestion by wildlife. Journal of Wildlife Management 58(2): 375–382.Google Scholar

Bieber, C. & Ruf, T. (2005). Population dynamics in wild boar Sus scrofa: ecology, elasticity of growth rate and implications for the management of pulsed resource consumers. Journal of Applied Ecology 42: 1203–1213.Google Scholar

Blom, A., Alers, M. P. T. & Barnes, R. F. W. (1990). Part 3 West and Central Africa. In East, R. (Compiler), Global Survey and Regional Action Plans. Gland: IUCN, 22: 113–120.Google Scholar

Boadella, M., Gortázar, C., Vicente, J. & Ruiz-Fons, F. (2012). Wild boar: an increasing concern for Aujeszky's disease control in pigs? BMC Veterinary Research 8(12).Google Scholar

Bobek, B., Merta, D. & Furtek, J. (2016). Winter food and cover refuges of large ungulates in lowland forests of south-western Poland. Forest Ecology and Management 359: 247–255.Google Scholar

Boitani, L., Mattei, L., Morini, P. & Zagarese, B. (1992). Experimental release of captivity reared wild boar (Sus scrofa). In Spitz, F., Janeau, G., Gonzales, G. & Aulagnier, S. (eds.), ‘Ongulés/Ungulates 91’. Proc. Intern. Symp. Toulouse. Paris: S.F.E.P.M.-I.R.G.M., pp. 413–417.Google Scholar

Boitani, L., Mattei, L., Nonis, D. & Corsi, F. (1994). Spatial and activity patterns of wild boars in Tuscany, Italy. Journal of Mammalogy 75: 600–612.Google Scholar

Boitani, L., Trapanese, P. & Mattei, L. (1995a). Demographic patterns of a wild boar (Sus scrofa L.) population in Tuscany, Italy. IBEX Journal of Mountain Ecology 3: 197–201.Google Scholar

Boitani, L., Trapanese, P., Mattei, L. & Nonis, D. (1995b). Demography of a wild boar (Sus scrofa, L.) population in Tuscany, Italy. Gibier Faune Sauvage 12: 109–132.Google Scholar

Boitani, L., Lovari, S. & Vigna Taglianti, A. (2003). Fauna d'Italia, Mammalia III: Carnivora–Artiodactyla. Bologna: Calderini.Google Scholar

Bosch, J., De La Torre, A., Alexandrov, T., et al. (2014). Can habitat suitability predict the presence of wild boar? Suitable land uses vs. georeferenced data in Bulgaria. Folia Zoologica 63: 194–205.Google Scholar

Bostelaar, R. (2014). Shoot to kill: wild boars are back in eastern Ontario. Ottawa Citizen. http://ottawacitizen.com/news/local-news/shoot-to-kill-the-wild-boars-are-back-in-eastern-ontario. Accessed 30 March 2015.Google Scholar

Bracke, M. B. M. (2011). Review of wallowing in pigs: description of the behaviour and its motivational basis. Applied Animal Behaviour Science 132: 1–13.Google Scholar

Brandt, S., Vassant, J. & Jullien, J. M. (1998). Domaine vital diurne des sangliers en forêt de Châteauvillain-Arc-en-Barrois. Bulletin Mensuel Office National Chasse 234: 4–11.Google Scholar

Briedermann, L. (1970). Zum Körper- und Organwachstum des Wildschweines in der Deutschen Demokratischen Republik. Archiv für Forstwesen 19: 401–420.Google Scholar

Briedermann, L. (1971a). Ermittlungen zur Aktivitätsperiodik des Mitteleuropäischen Wildschweines (Sus scrofa L.). Zoologischer Garten 40: 302–327.Google Scholar

Briedermann, L. (1971b). Zur Reproduktion des Schwarzwildes in der Deutschen Demokratischen Republik. Tag.-Ber. dt. Akad. Landwirtsch.-Wiss. Berlin 113: 169–186.Google Scholar

Briedermann, L. (1986). Schwarzwild. Berlin: VEB Deutscher Landwirtschaftsverlag.Google Scholar

Briedermann, L. (2009). Schwarzwild, 2nd ed. Stuttgart: Franckh-Kosmos Verlags-GmbH & Co. KG.Google Scholar

Brook, R. K. & van Beest, F. M. (2014). Feral wild boar distribution and perceptions of risk on the central Canadian prairies. Wildlife Society Bulletin 38: 486–494.Google Scholar

Brooks, P. H. & Cole, D. J. (1970). The effect of the presence of a boar on the attainment of puberty in gilts. Journal of Reproduction and Fertility 23: 435–440.Google Scholar

Bueno, C. G., Alados, C. L., Gómez-García, D., Barrio, I. C. & García-Gonzáles, R. (2009). Understanding the main factors in the extent and distribution of wild boar rooting on alpine grasslands. Journal of Zoology 279: 195–202.Google Scholar

Bueno, C. G., Barrio, I. C., García-González, R., Alados, C. L. & Gómez, D. (2011). Assessment of wild boar rooting on ecological and pastoral values of alpine pyrenean 12 grasslands. Pirineos 166: 51–67.Google Scholar

Bywater, K. A., Apollonio, M., Cappai, N. & Stephens, P. A. (2010). Litter size and latitude in a large mammal: the wild boar Sus scrofa. Mammal Review 40: 212–220.Google Scholar

Cahill, S., Llimona, F. & Gràcia, J. (2003). Spacing and nocturnal activity of wild boar Sus scrofa in a Mediterranean metropolitan park. Wildlife Biology 9(Suppl.): 3–13.Google Scholar

Cahill, S., Llimona, F., Cabaneros, L. & Calomardo, F. (2012). Characteristics of wild boar (Sus scrofa) habituation to urban areas in the Collserola Natural Park (Barcelona) and comparison with other locations. Animal Biodiversity and Conservation 35: 221–233.Google Scholar

Calenge, C., Maillard, D., Vassant, J. & Brandt, S. (2002). Summer and hunting season home ranges of wild boar (Sus scrofa) in two habitats in France. Game and Wildlife Science 19: 281–301.Google Scholar

Caley, P. (1997). Movement, activity patterns and habitat use of feral pigs (Sus scrofa) in a tropical habitat. Wildlife Research 24: 77–87.Google Scholar

Cano-Manuel, F. J., López-Olvera, J., Fandos, P., et al. (2014). Long-term monitoring of 10 selected pathogens in wild boar (Sus scrofa) in Sierra Nevada National Park, southern Spain. Veterinary Microbiology 174: 148–154.CrossRef Google Scholar PubMed

Canu, A., Scandura, M., Merli, E., et al. (2015). Reproductive phenology and conception synchrony in a natural wild boar population. Hystrix, the Italian Journal of Mammalogy 26(2): online first, doi:10.4404/hystrix-26.2-11324.Google Scholar

Cargnelutti, B., Janeau, G., Spitz, F. & Cousse, S. (1995). GIS as a means to identify the environmental conditions of wild boar diurnal resting places. IBEX Journal of Mountain Ecology 3: 156–159.Google Scholar

Carpio, A. J., Guerrero-Casado, J., Ruiz-Aizpurua, L., Vicente, J. & Tortosa, F. S. (2014). The high abundance of wild ungulates in a Mediterranean region: is this compatible with the European rabbit? Wildlife Biology 20: 161–166.Google Scholar

Carter, S. P. & Bright, P. W. (2002). Habitat refuges as alternatives to predator control for the conservation of endangered Mauritian birds. InVeitch, C. R. & Clout, M. N. (eds.), Turning the tide: the eradication of invasive species. Gland: IUCN SSC Invasive Species Specialist Group, pp. 71–78.Google Scholar

Cellina, S. (2008). Effects of supplemental feeding on the body condition and reproductive state of wild boar Sus scrofa in Luxembourg. PhD thesis, University of Sussex, UK. 141 pp.Google Scholar

Choi, J. W., Chung, W. H., Lee, K. T., et al. (2015). Whole-genome resequencing analyses of five pig breeds, including Korean wild and native, and three European origin breeds. DNA Research: An International Journal for Rapid Publication of Reports on Genes and Genomes 22: 259–267.Google Scholar

Choi, S. K., Lee, J. E., Kim, Y. J., et al. (2014). Genetic structure of wild boar (Sus scrofa) populations from East Asia based on microsatellite loci analyses. BMC Genetics 15: 85.Google Scholar

Claus, R. & Weiler, U. (1985). Influence of light and photoperiodicity on pig prolificacy. Journal of Reproduction and Fertility Supplement 33: 185–197.Google Scholar

Copado, F., de Aluja, A. S., Mayagoitia, L. & Galindo, F. (2004). The behavior of free ranging pigs in the Mexican tropics and its relationships with human feces consumption. Applied Animal Behavior Sciences 88: 243–252.Google Scholar

Cousse, S. & Janeau, G. (1992). Time budget and polyphasic activity in wild boar (Sus scrofa L.). Paris-Toulouse: S.F.E.P.M.-I.R.G.M., pp. 391–394.Google Scholar

Cutini, A., Chianucci, F., Chirichella, R., et al. (2013). Mast seeding in deciduous forests of the northern Apennines (Italy) and its influence on wild boar population dynamics. Annals of Forest Science 70: 493–502.Google Scholar

D'Andrea, L., Durio, P., Perrone, A. & Pirone, S. (1995). Preliminary data of the wild boar (Sus scrofa) space use in mountain environment. IBEX Journal of Mountain Ecology 3: 117–121.Google Scholar

Daim, A. (2015). Kartierung von Wildschäden verursacht durch Schwarzwild (Sus scrofa) an Grünlandflächen. MSc master thesis, Stiftung Tierärztliche Hochschule Hannover und Universität für Bodenkultur Wien.Google Scholar

Daim, A., Hauke, L. & Keuling, O. (2013). Field mapping of economic damage in agricultural drops caused by wild boar (Sus scrofa) with kite aerial photography (KAP) and GIS support. Mammalian Biology – Zeitschrift für Säugetierkunde 78: 8.Google Scholar

Danilkin, A. A. (2002). Swinie (Suidae). Moscow: GEOS. 309 pp.Google Scholar

Dardaillon, M. (1987). Seasonal feeding habits of wild boar in a Mediterranean wetland, the Camargue (Southern France). Acta Theriologica 32: 389–401.Google Scholar

Dardaillon, M. (1988). Wild boar social groupings and their seasonal changes in the Camargue, southern France. Zeitschrift fur Säugetierkunde 53: 22–30.Google Scholar

Delcroix, I., Mauget, R. & Signoret, J. P. (1990). Existence of synchronization of reproduction at the level of the social group of the European wild boar (Sus scrofa). Journal of Reproduction and Fertility 89: 613–617.Google Scholar

Delgado, R., Fernández-Llario, P., Azevedo, M., Beja-Pereira, A. & Santos, P. (2008). Paternity assessment in free-ranging wild boar (Sus scrofa) – are littermates full-sibs? Mammalian Biology 73: 169–176.Google Scholar

Delgado-Acevedo, J., Zamorano, A., DeYoung, R. W., et al. (2010). Promiscuous mating in feral pigs (Sus scrofa) from Texas, USA. Wildlife Research 37: 539–546.Google Scholar

Dewey, T. & Hruby, J. (2002). Sus scrofa. Michigan: University of Michigan Museum of Zoology.Google Scholar

Dexter, N. (1998). The influence of pasture distribution and temperature on habitat selection by feral pigs in a semi-arid environment. Wildlife Research 25: 547–559.Google Scholar

Dinter, U. (1991). Das Raum-Zeitverhalten von Schwarzwild im Grunewald in den Sommermonaten unter besonderer Berücksichtigung menschlicher Störungen. Dissertation, Ludwig-Maximilian-Universität.Google Scholar

Dokken, B. (1999). Manitoba declares war on wild boar. Grand Forks Herald 8: 1A and 5A.Google Scholar

Durio, P., Fogliato, D., Perrone, A. & Tessarin, N. (1995). The autumn diet of the wild boar (Sus scrofa) in an alpine valley. Preliminary results. IBEX Journal of Mountain Ecology 3: 180–183.Google Scholar

East, M. L. & Dehnhard, M. (2013). Chemical signals in vertebrates. New York, NY: Springer, 12, pp. 381–390.Google Scholar

Engeman, R. M., Massei, G., Sage, M. & Gentle, M. (2013). Monitoring wild pig populations: a review of methods. Environmental Science and Pollution Research 20: 8077–8091.Google Scholar

Erkinaro, E., Heikura, K., Lindgren, E., Pulliainen, E. & Sulkava, S. (1982). Occurrence and spread of the wild boar (Sus scrofa) in eastern Fennoscandia. Memoranda Societatis pro Fauna et Flora Fennica 58: 39–47.Google Scholar

Fernández-Llario, P. (2004). Environmental correlates of nest site selection by wild boar Sus scrofa. Acta Theriologica 49: 383–392.Google Scholar

Fernández-Llario, P. (2005). The sexual function of wallowing in male wild boar (Sus scrofa). Journal of Ethology. Doi:10.1007/s10164-004-0121-7, 11.Google Scholar

Fernández-Llarrio, P. & Carranza, J. (2000). Reproductive performance of the wild boar in a Mediterranean ecosystem under drought conditions. Ethology, Ecology & Evolution 12: 335–343.Google Scholar

Fernández-Llario, P. & Mateos-Quesada, P. (2005). Influence of rainfall on the breeding biology of wild boar (Sus scrofa) in a Mediterranean ecosystem. Folia Zoologica 54: 240–248.Google Scholar

Fernández-Llario, P., Carranza, J. & Mateos-Quesada, P. (1999). Sex allocation in a polygynous mammal with large litter size: the wild boar. Animal Behavior 58: 1079–1084.Google Scholar

Fernández-Llario, P., Mateos-Quesada, P., Silverio, S. & Santos, P. (2003). Habitat effects and shooting techniques on two wild boar (Sus scrofa) populations in Spain and Portugal. Zeitschrift für Jagdwissenschaft 49: 120–129.Google Scholar

Ferreira, E., Souto, L., Soares, A. M. V. M. & Fonseca, C. (2006). Genetic structure of the wild boar (Sus scrofa L.) population in Portugal. Wildlife Biology in Practice 2: 17–25.Google Scholar

Ferreira, E. Souto, L. Soares, A. M. V. M. & Fonseca, C. (2009). Genetic structure of the wild boar population in Portugal: evidence of a recent bottleneck. Mammalian Biology 74: 274–285.Google Scholar

Focardi, S., Gaillard, J. M., Ronchi, F. & Rossi, S. (2008). Survival of wild boars in a variable environment: unexpected life-history variation in an unusual ungulate. Journal of Mammalogy 89: 1113–1123.Google Scholar

Fonseca, C., Sousa, J., Vingada, J., Cancela, J. & Soares, A. M. V. M. (2001). Monthly birth distribution of the wild boar (Sus scrofa L.) in central Portugal. Galemys 13: 199–204.Google Scholar

Fonseca, C., Santos, P., Monzón, A., et al. (2004). Reproduction in the wild boar (Sus scrofa Linnaeus, 1758) populations of Portugal. In Fonseca, C., Herrero, J., Luis, A. & Soares A. M. V. M. (eds.), Wild Boar Research 2002. A selection and edited papers from the ‘4th International Wild Boar Symposium’, Lousa, Portugal, 19–22 September 2002. Galemys 16(Special Issue): 53–66.Google Scholar

Fonseca, C., da Silva, A. A., Alves, J., Vingada, J. & Soares, A. M. V. M. (2011). Reproductive performance of wild boar females in Portugal. European Journal of Wildlife Research 57: 363–371.Google Scholar

Fournier-Chambrillon, C., Maillard, D. & Fournier, P. (1995). The diet of wild boar (Sus scrofa L.) inhabiting the Montpellier garrigue. Ibex Journal of Mountain Ecology 3: 174–179.Google Scholar

Frank, B., Monaco, A. & Bath, A. J. (2015). Beyond standard wildlife management: a pathway to encompass human dimension findings in wild boar management. European Journal of Wildlife Research 61: 723.Google Scholar

Frantz, A. C., Massei, G. & Burke, T. (2012). Genetic evidence for past hybridisation between domestic pigs and English wild boars. Conservation Genetics 13(5): 1355–1364. http://springerlink.metapress.com/link.asp?id=105709.Google Scholar

Franzmann, A. W. (1988). A review of wildlife translocations. In Nielsen, L. & Brown, R. D. (eds.), Translocation of wild animals. Wisconsin: Wisconsin Humane Society and C. Kleberg Wildlife Research Institute, pp. 210–229.Google Scholar

Frauendorf, M., Gethöffer, F., Siebert, U. & Keuling, O. (2016). The influence of environmental and physiological factors on the litter size of wild boar (Sus scrofa) in an agriculture dominated area in Germany. Science of The Total Environment 541: 877–882.Google Scholar

Fruzinski, B. (1995). Situation of wild boar populations in western Poland. Ibex Journal of Mountain Ecology 3: 186–187.Google Scholar

Gabor, T. M., Hellengren, E. C., Van Den Bussche, R. A. & Silvy, N. J. (1999). Demography, socio-spatial behavior and genetics of feral pigs (Sus scrofa) in a semi-arid environment. Journal of Zoology 247: 311–322.Google Scholar

Gaillard, J. M., Pontier, D., Allaine, D., et al. (1989). An analysis of demographic tactics in birds and mammals. Oikos 56: 59–76.Google Scholar

Gaillard, J.-M., Brandt, S. & Jullien, J.-M. (1993). Body weight effect on reproduction of young wild boar females: a comparative analysis. Folia Zoologica 42: 204–212.Google Scholar

Gallo Orsi, U., Sicuro, B., Durio, P., et al. (1995). Where and when: the ecological parameters affecting wild boars choice while rooting in grasslands in an Alpine, valley. IBEX Journal of Mountain Ecology 3: 160–164.Google Scholar

García, G., Vergara, J. & Lombardi, R. (2011). Genetic characterization and phylogeography of the wild boar Sus scrofa introduced into Uruguay. Genetics and Molecular Biology 34(2): 329–337.Google Scholar

Garcia, M., Gingras, B., Bowling, D. L., et al. (2016). Structural classification of wild boar (Sus scrofa) vocalizations. Ethology 122: 329–342.Google Scholar

Gaston, W. D. (2008). Feral pig (Sus scrofa) survival, home range, and habitat use at Lowndes County Wildlife Management Area, Alabama. Masters thesis, Auburn University.Google Scholar

Gederaas, L., Moen, T.L., Skjelseth, S., & Larsen, L.K. (2012). Alien Species in Norway-with the Norwegian Black List 2012. Norwegian Biodiversity Information Centre, Norway.Google Scholar

Geisser, H. & Reyer, H.-U. (2005a). The influence of food and temperature on population density of wild boar Sus scrofa in the Thurgau (Switzerland). Journal of Zoology (London) 267: 89–96.Google Scholar

Genov, P. (1981a). The food composition of wild boar in northeastern and western Poland. Acta Theriologica 26: 185–205.Google Scholar

Genov, P. V. (1981b). Significance of natural biocenoses and agrocenoses as the source of food for wild boar (Sus scrofa L.). Ekologia Polska 29: 117–136.Google Scholar

Genov, P. V. (1999). A review of the cranial characteristics of the wild boar (Sus scrofa Linnaeus, 1758), with systematic conclusions. Mammal Review 29: 205–238.Google Scholar

Genov, P. V. (2004). Craniometric characteristics of the subgenus Sus Linnaeus, 1758 a systematic conclusion. Galemys 16: 9–23.Google Scholar

Genov, P., Nikolov, H., Massei, G. & Gerasimov, S. (1991). Craniometrical analysis of Bulgarian wild boar (Sus scrofa) populations. Journal of Zoology 225: 309–325.Google Scholar

Gethöffer, F., Sodeikat, G. & Pohlmeyer, K. (2007). Reproductive parameters of wild boar (Sus scrofa) in three different parts of Germany. European Journal of Wildlife Research 53: 287–297.Google Scholar

Gimenez-Anaya, A., Herrero, J., Rosell, C., Couto, S. & Garcia-Serrano, A. (2008). Food habits of wild boars (Sus scrofa) in a Mediterranean coastal wetland. Wetlands 28: 197–203.Google Scholar

Gipson, P. S., Lee, C. D., Wilson, S., Thiele, J. R. & Hobbick, D. (2006). The status of feral pigs in Kansas and Nebraska. In Springer, J. T. & Springer, E. C. (eds.), Prairie invaders: proceedings of the 20th North American prairie conference. Kearney, NB: University of Nebraska at Kearney, pp. 19–24.Google Scholar

Giuffra, E., Kijas, J. M., Amarger, V., et al. (2000). The origin of the domestic pig: independent domestication and subsequent introgression. Genetics 154: 1785–1791.Google Scholar

Glikman, J. A. & Frank, B. (2011). Human dimensions of wildlife in Europe the Italian way. Human Dimensions in Wildlife 16(5): 368–377.Google Scholar

Goedbloed, D.J., van Hooft, P., Megens, H-J., et al. (2013). Reintroductions and genetic introgression from domestic pigs have shaped the genetic population structure of Northwest European wild boar. BMC Genetics 14: 43.Google Scholar

Goulding, M. (2003). Wild boar in Britain. Suffolk: Whittet Books Ltd.Google Scholar

Goulding, M. (2012). British wild boar. www.britishwildboar.org.uk/Google Scholar

Graves, H. (1984). Behavior and ecology of wild and feral swine (Sus scrofa). Journal of Animal Science 58: 482–492.Google Scholar

Grodziński, W. & Sawicka-Kapusta, K. (1970). Energy values of tree-seeds eaten by small mammals. Oikos 21: 52–58.Google Scholar

Groot Bruinderink, G. W. T. A., Hazebroek, E. & van der Voot, H. (1994). Diet and condition of wild boar, Sus scrofa scrofa, without supplementary feeding. Journal of Zoology 233: 631–648.Google Scholar

Groves, C. P. (1981). Ancestors for the pigs: taxonomy and phylogeny of the genus Sus. Department of Prehistory, Research School of Pacific Studies, Australian Natural University, Technical Bulletin 3: 1–96.Google Scholar

Groves, C. P. (2007). Current view on the taxonomy and zoogeography of the genus Sus. In Albarella, U., Dobney, K., Ervynck, A. & Rowley-Conwy, P. (eds.), Pigs and humans: 10,000 years of interaction. Oxford: Oxford University Press.Google Scholar

Groves, C. P. & Grubb, P. (1993). The Eurasian suids Sus and Babyrousa. In Oliver, W. R. L. (ed.), Pigs, peccaries and hippos. Status, survey and conservation action plan. Gland: IUCN.Google Scholar

Groves, C. P. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Gunczak, N. S. (1980). The nutrition of wild pigs (Sus scrofa) in the Ukrainian Carpathians. Vestnik Zoologii 5: 73–78. [In Russian with English summary.]Google Scholar

Haber, A. (1969). Wild boar. Ecology and management. Warsaw: PWRiL. [In Polish.]Google Scholar

Hadjisterkotis, E. & Heise-Pavlov, P. (2006). The failure of the introduction of wild boar Sus scrofa in the island of Cyprus: a case study. European Journal of Wildlife Research 52: 213–215.Google Scholar

Henry, V. G. (1968). Length of estrous cycle and gestation in European wild hogs. Journal of Wildlife Management 32: 406–408.Google Scholar

Herbst, C. & Keuling, O. (2014). Habitat use of wild boar (Sus scrofa) in an agricultural area – a problem? Mammalian Biology 79: 12.Google Scholar

Herrero, J. & Fernández de Luco, D. (2003). Wild boars (Sus scrofa L.) in Uruguay: scavengers or predators? Mammalia 67: 485–491.Google Scholar

Herrero, J., Irizar, I., Laskurain, N. A., García Serrano, A. & García González, R. (2005). Fruits and roots: wild boar foods during the cold season in the southwestern Pyrenees. Italian Journal of Zoology 72(1): 49–52.Google Scholar

Herrero, J., Garcia-Serrano, A., Couto, S., Ortuno, V. M. & Garcia-Gimenez, R. (2006). Diet of wild boar Sus strofa L. and crop damage in an intensive agroecosystem. European Journal of Wildlife Research 52: 245–250.Google Scholar

Herrero, J., Garcia-Serrano, A. & Garcia-Gonzalez, R. (2008). Reproductive and demographic parameters in two Iberian wild boar Sus scrofa populations. Acta Theriologica 53(4): 355–364.Google Scholar

Herrero-Medrano, J. M., Megens, H-J., Groenen, M. A., et al. (2013). Conservation genomic analysis of domestic and wild pig populations from the Iberian Peninsula. BMC Genetics 14: 106.Google Scholar

Hirotani, A. & Nakatani, J. (1987). Grouping patterns and inter-group relationships of Japanese wild boars (Sus scrofa leucomystax) in the Rokko Mountain Area. Ecological Research 2: 77–84.Google Scholar

Hodgkinson, S. M., Schmidt, M. & Ulloo, N. (2008). Comparison of digestible energy content of maize, oats and alfalfa between the European wild boar (Sus scrofa L.) and Landracex white pig (Sus scrofa domesticus). Animal Feeding Science and Technology 144: 167–173.Google Scholar

Huynh, T. T. T., Aarnink, A. A., Gerrits, W. J. J., et al. (2005). Thermal behaviour of growing pigs in response to high temperature and humidity. Applied Animal Behaviour Science 91: 1–16.Google Scholar

Iacolina, L., Scandura, M., Bongi, P. & Apollonio, M. (2009). Non-kin associations in wild boar social units. Journal of Mammalogy 90: 666–674.Google Scholar

Ickes, K. (2001). Hyper-abundance of native wild pigs (Sus scrofa) in a lowland dipterocarp rain forest of Peninsular Malaysia. Biotropica 33: 682–690.Google Scholar

Ickes, K., Paciorek, C. J. & Thomas, S. C. (2005). Impacts of nest construction by native pigs (Sus scrofa) on lowland Malaysian rain forest saplings. Ecology 86(6): 1540–1547.Google Scholar

Jaksic, F. M., Agustín Iriarte, J., Jiménez, J. E. & Martínez, D. R., (2002). Invaders without frontiers: cross-border invasions of exotic mammals. Biological Invasions 4: 157–173.Google Scholar

Janeau, G. & Spitz, F. (1984). L'espace chez le sanglier (Sus scrofa L.) occupation et mode d'utilisation. Gibier Faune Sauvage Game and Wildlilfe 1: 73–89.Google Scholar

Janeau, G., Cargnelutti, B., Cousse, S., Hewison, M. & Spitz, F. (1995). Daily movement pattern variations in wild boar (Sus scrofa L.). IBEX Journal of Mountain Ecology 3: 98–101.Google Scholar

Jędrzejewska, B., Jędrzejewski, W., Bunevich, A. N., Miłkowski, L. & Krasiński, A. (1997). Factors shaping population densities and increase rates of ungulates in Białowieża Primeval Forest (Poland and Belarus) in the 19th and 20th centuries. Acta Theriologica 42: 399–451.Google Scholar

Jerina, K., Pokorny, B. & Stergar, M. (2014). First evidence of long-distance dispersal of adult female wild boar (Sus scrofa) with piglets. European Journal of Wildlife Research 60: 367–370.Google Scholar

Ježek, M., Kušta, T., Holá, M. & Červený, J. (2013). Effect of supplemental feeding on spatial activity of wild boar during winter season. Mammalian Biology - Zeitschrift für Säugetierkunde 78: 14.Google Scholar

Ježek, M., Holá, M. & Kušta, T. (2014). Is the Central European wild boar still ‘wild’ or has it already become domesticated? In 10th International Symposium on Wild Boar and Other Suids. Velenje: ERICo, p. 66.Google Scholar

Jordt, A. M., Lange, M., Kramer-Schadt, S., et al. (2016). Spatio-temporal modeling of the invasive potential of wild boar – a conflict-prone species – using multi-source citizen science data. Preventive Veterinary Medicine 124: 34–44.Google Scholar

Kairo, M., Ali, B., Cheesman, O., Haysom, K. & Murphy, S. (2003). Invasive species threats in the Caribbean region. Report to the Nature Conservancy. Curepe, Trinidad and Tobago: CAB International.Google Scholar

Kaminski, G., Brandt, S., Baubet, E. & Baudoin, C. (2005). Life-history patterns in female wild boars (Sus scrofa): mother–daughter postweaning associations. Canadian Journal of Zoology 83: 474–480.Google Scholar

Keuling, O. (2007). Sauen als Beutegreifer – Welchen direkten Einfluss kann Schwarzwild auf andere Tierarten ausüben? In Raumberg-Gumpenstein, H. (ed.), 13. Österreichische Jägertagung 2007, Irdning, 2007. Olli-Tagungen, pp. 45–50.Google Scholar

Keuling, O. & Stier, N. (2009). Schwarzwild – Untersuchungen zu Raum- und Habitatnutzung des Schwarzwildes (Sus scrofa L. 1758) in Südwest-Mecklenburg unter besonderer Berücksichtigung des Bejagungseinflusses und der Rolle älterer Stücke in den Rotten. Professur für Forstzoologie der TU Dresden, Tharandt (ed. U.u.V.M.-V.u.S.W.u.W.i.M.-V. Oberste Jagdbehörde im Ministerium für Landwirtschaft).Google Scholar

Keuling, O., Stier, N. & Roth, M. (2008a). Annual and seasonal space use of different age classes of female wild boar Sus scrofa L. European Journal of Wildlife Research 54: 403–412.Google Scholar

Keuling, O., Stier, N. & Roth, M. (2008b). How does hunting influence activity and space use in wild boar Sus scrofa L.? European Journal of Wildlife Research 54: 729–737.Google Scholar

Keuling, O., Stier, N. & Roth, M. (2009). Commuting, shifting or remaining? Different spatial usage patterns of wild boar Sus scrofa L. in forest and field crops during summer. Mammalian Biology 74: 145–152.Google Scholar

Keuling, O., Lauterbach, K., Stier, N. & Roth, M. (2010). Hunter feedback of individually marked wild boar Sus scrofa L.: dispersal and efficiency of hunting in northeastern Germany. European Journal of Wildlife Research 56: 159–167.Google Scholar

Keuling, O., Baubet, E., Duscher, A., et al. (2013). Mortality rates of wild boar Sus scrofa L. in central Europe. European Journal of Wildlife Research 59: 805–814.Google Scholar

Keuling, O., Strauß, E. & Siebert, U. (2016). Regulating wild boar populations is ‘somebody else's problem’! Human dimension in wild boar management. Science of the Total Environment 554–555: 311–319.Google Scholar

Kingdon, J. (1997). The Kingdon field guide to African mammals. London: Academic Press.Google Scholar

Kirkwood, R. N., Hughes, P. E., & Booth, W. D. (1983). The influence of boar-related odors on puberty attainment in gilts. Animal Production 36: 131–136.Google Scholar

Kittawornrat, A. & Zimmerman, J. J. (2011). Toward a better understanding of pig behavior and pig welfare. Animal Health Research Reviews 12: 25–32.Google Scholar

Kodera, Y., Kanzaki, N., Ishikawa, N. & Minagawa, A. (2013). Food habits of wild boar (Sus strofa) inhabiting Iwami District, Shimane Prefecture, western Japan. The Mammal Society of Japan 53(2): 279–287.Google Scholar

Kozdrowski, R. & Dubiel, A. (2004). The effect of season on the properties of wild boar (Sus scrofa L.) semen. Animal Reproduction Science 80: 281–289.Google Scholar

Kuijper, D. P. J., Verwijmeren, M., Churski, M., et al. (2014). What cues do ungulates use to assess predation risk in dense temperate forest? PLoS ONE 9: e84607.Google Scholar

Kurz, J. C. & Marchiton, R. L. (1972). Radiotelemetry studies of feral hogs in South Carolina. Journal of Wildlife Management 36: 1240–1248.Google Scholar

Kusza, S., Podgórski, T., Scandura, M., et al. (2014). Contemporary genetic structure, phylogeography and past demographic processes of wild boar Sus scrofa population in Central and Eastern Europe. PLoS ONE 9: e91401.Google Scholar

Larson, G., Dobney, K., Albarella, U., et al. (2005). Worldwide phylogeography of wild boar reveals multiple centers of pig domestication. Science 307: 1618–1621.Google Scholar

Larson, G., Liu, R. R., Zhao, X.B., et al. (2010). Patterns of East Asian pig domestication, migration, and turnover revealed by modern and ancient DNA. Proceedings of the National Academy of Sciences of the United States of America 107: 7686–7691.Google Scholar

Lemel, J., Truvé, J. & Söderberg, B. (2000). Ranging and activity behaviour of the wild boar, Sus scrofa L., in Sweden. In Lemel, J. (ed.), 3rd International Wild Boar Symposium, Abstracts. Jägareförbundet 1830. Uppsala: Swedish Association for Hunting and Wildlife Management – Research Unit.Google Scholar

Lemel, J., Truvé, J. & Söderberg, B. (2003). Variation in ranging and activity behaviour of European wild boar Sus scrofa in Sweden. Wildlife Biology 9(Suppl): 29–36.Google Scholar

Lever, C. (1994). Naturalized animals: the ecology of successfully introduced species. London: T. & A. D. Poyser.Google Scholar

Liberg, O., Bergstrom, R., Kindberg, J. & Von Essen, H. (2010). Ungulates and their management in Sweden. In Apollonio, M., Andersen, R. & Putman, R. (eds.), European ungulates and their management in the 21st century. Cambridge: Cambridge University Press, pp. 37–70.Google Scholar

Licoppe, A., Prévot, C., Heymans, M., et al. (2013). Wild boar/feral pig in (peri-)urban areas. International Survey Report as an Introduction to the Workshop: ‘Managing Wild Boar in Human-Dominated Landscapes’. Presented at the International Union of Game Biologists – Congress IUGB 2013 – Brussels, Belgium, 28 August 2013.Google Scholar

Lombardini, M., Vidus Rosin, A., Murru, M., Cinerari, C. E. & Meriggi, A. (2014). Reproductive and demographic parameters in Sardinian wild boar, Sus scrofa meridionalis. Folia Zoologica 63: 301–307.Google Scholar

Long, J. L. (2003). Introduced mammals of the world. Melbourne: CABI/CSIRO Publishing.Google Scholar

Lustig, J., Frauendorf, M., Gethöffer, F. & Keuling, O. (2015). Influence of body weight on puberty and pregnancy of female piglets (Sus scrofa L.) in Germany. Mammalian Biology – Zeitschrift für Säugetierkunde 80: 16.Google Scholar

Maillard, D. (1996). Occupation et utilisation de la garrigue et du vignoble mediterraneens par le sanglier (Sus scrofa L.). Thése de doctorat, Université d'Aix-Marseille III.Google Scholar

Maillard, D. & Fournier, P. (1995). Effect of shooting with hounds on home range size of Wild Boar (Sus scrofa L.) groups in Mediterranean habitat. IBEX Journal of Mountain Ecology 3: 102–107.Google Scholar

Maillard, D., Gaillard, J. M., Hewison, M., et al. (2010). Ungulates and their management in France. In Apollonio, M., Andersen, R. & Putman, R. (eds.), European ungulates and their management in the 21st century. Cambridge: Cambridge University Press, pp. 441–474.Google Scholar

Massei, G. & Genov, P. V. (2004). The environmental impact of wild boar. Galemys 16: 135–145.Google Scholar

Massei, G., Genov, P. V. & Staines, B. W. (1996). Diet, food availability and reproduction of Wild Boar in a Mediterranean coastal area. Acta Theriology 41(3): 307–320.Google Scholar

Massei, G., Genov, P.V., Staines, B. & Gorman, M. L. (1997a). Factors influencing home range and activity of wild boar (Sus scrofa) in a Mediterranean coastal area. Journal of Zoology London 242: 411–423.Google Scholar

Massei, G., Genov, P.V., Staines, B. & Gorman, M. L. (1997b). Mortality of wild boar, Sus scrofa, in a Meditteranean area in relation to age and sex. Journal of Zoology London 242: 394–400.Google Scholar

Massei, G., Kindberg, J., Licoppe, A., et al. (2015). Wild boar populations up, numbers of hunters down? A review of trends and implications for Europe. Pest Management Science 71: 492–500.Google Scholar

Mauget, R. (1980). Home range concept and activity patterns of European wild boar (Sus scrofa L.) as determined by radio tracking. In Amlaner, C. J. & McDonald, D. W. (eds.), A handbook of biotelemetry and radiotracking. Oxford: Pergamon Press, pp. 725–728.Google Scholar

Mauget, R. (1982). Seasonality of reproduction in the wild boar. In Cole, D. J. A. & Foxcroft, G. R. (eds.), Control of pig reproduction. London: Butterworth Scientific, pp. 509–526.Google Scholar

Mauget, R. & Boissin, J. (1987). Seasonal changes in testis weight and testosterone concentration in the European wild boar (Sus scrofa L.). Animal Reproduction Science 13: 67–74.Google Scholar

Mayer, J. J. (2013). Wild pig attacks on humans. In Armstrong, J. B. & Gallagher, G. R. (eds.), Proceedings of the 15th Wildlife Damage Management Conference, pp. 17–35.Google Scholar

Mayer, J. J. (2014). Estimation of the number of wild pigs found in the United States. SRNS–STI–2014–00292. Aiken, SC: Savannah River Nuclear Solutions.Google Scholar

Mayer, J. J. & Brisbin, I. L. Jr. (2008). Wild pigs in the United States: their history, comparative morphology, and current status. Athens, GA: The University of Georgia Press.Google Scholar

Mayer, J. J. & Brisbin, I. L. Jr. (2009). Wild pigs: biology, damage, control techniques and management. SRNL-RP-2009-00869. Aiken, SC: Savannah River National Laboratory.Google Scholar

McCann, B., Davie, D. K. & Feldhamer, G. A. (2003). Distribution, habitat use, and morphotypes of feral hogs (Sus scrofa) in Illinois. Transactions of the Illinois State Academy of Science 96(4): 301–311.Google Scholar

McDevitt, A. D., Carden, R. F., Coscia, I. & Frantz, A. C. (2013). Are wild boars roaming Ireland once more? European Journal of Wildlife Research 59(5): 761–764.Google Scholar

McIlroy, J. C. (1989). Aspects of the ecology of feral pigs (Sus scrofa) in the Murchison area, New Zealand. New Zealand Journal of Ecology 12: 11–22.Google Scholar

Meier, R., Ruiz-Fons, F. & Ryser-Degiorgis, M.-P. (2015). A picture of trends in Aujeszky's disease virus exposure in wild boar in the Swiss and European contexts. BMC Veterinary Research 11: 277.Google Scholar

Meng, X. J., Lindsay, D. S. & Sriranganathan, N. (2009). Wild boars as sources for infectious diseases in livestock and humans. Philosophical Transactions of the Royal Society B: Biological Sciences 364: 2697–2707.Google Scholar

Merta, D., Bobek, B., Furtek, J. & Kolecki, M. (2009). Distribution and number of black grouse (Tetrao tetrix) in southwestern Poland and potential impact of predators upon nesting success of the species. Folia Zoologica 58(2): 159–167.Google Scholar

Merta, D., Mocała, P., Pomylacz, M. & Frąckowiak, W. (2014). Autumn–winter diet and fat reserves of wild boars (Sus scrofa) inhabiting forest and forest–farmland environment in south-western Poland. Folia Zoologica 63(2): 95–102.Google Scholar

Meynhardt, H. (1980). Untersuchungen zur akustischen, olfaktorischen und visuellen Kommunikation des Europäischen Wildschweins (Sus scrofa L.). Beiträge für die Forstwirtschaft, Berlin 14: 72–82.Google Scholar

Meynhardt, H. (1989). Schwarzwild-Bibliothek 1: Biologie und Verhalten. Melsungen: Neumann-Neudamm.Google Scholar

Miśkiewicz, M. (2013). Dieta dzika Sus scrofa na terenie Puszczy Niepołomickiej (The diet of wild boar Sus scrofa in Niepołomicka Forest). MSc thesis, Pedagogical University in Cracow, Poland.Google Scholar

Monaco, A., Franzetti, B., Pedrotti, L. & Toso, S. (2003). Linee guida per la gestione del Cinghiale. Ministero per le Politiche Agricole e Forestali, Istituto Nazionale per la Fauna Selvatica, 116 pp. [In Italian.]Google Scholar

Morelle, K., Lehaire, F. & Lejeune, P. (2013). Spatio-temporal patterns of wildlife–vehicle collisions in a region with a high-density road network. Nature Conservation 5: 53–73.Google Scholar

Morelle, K., Podgórski, T., Prévot, C., et al. (2015). Towards understanding wild boar Sus scrofa movement: a synthetic movement ecology approach. Mammal Review 45: 15–29.Google Scholar

Moretti, M. (1995). Birth distribution, structure and dynamics of a hunted mountain population of wild boars (Sus scrofa L.), Ticino, Switzerland. IBEX Journal of Mountain Ecology 3: 192–196.Google Scholar

Morini, P., Boitani, L., Mattei, L. & Zagarese, B. (1995). Space use by pen-raised wild boars (Sus scrofa) released in Tuscany (Central Italy) –II: home range. IBEX Journal of Mountain Ecology 3: 112–116.Google Scholar

Müller, B., Keuling, O., Glensk, C. & Brün, J. (2015). Mother's baby, father's maybe: occurrence and frequency of multiple paternities in the European wild boar. Mammalian Biology – Zeitschrift für Säugetierkunde 80: 18.Google Scholar

Nakatani, J. & Ono, Y. (1995). Grouping pattern of Japanese wild boar. IBEX Journal of Mountain Ecology 3: 128–129.Google Scholar

Nahlik, A. & Sandor, G. (2003). Birth rate and offspring survival in a free-ranging wild boar Sus scrofa population. Wildlife Biology 9: 37–42.Google Scholar

NatureServe. (2013). NatureServe Explorer: An online encyclopedia of life. Arlington, VA: NatureServe.Google Scholar

Navas, J. R. (1987). Los vertebrados exoticos introducidos en la Argentina. Revista del Museo Argentina de Ciencias Naturales “Bernardino Rivadavia” 14(2): 7–38.Google Scholar

NFSMS (National Feral Swine Mapping System). (2015). National Feral Swine Mapping System. http://swine.vet.uga.edu/nfsms/.Google Scholar

Nicolaysen, A. (2015). Record wild boar tusk from Turkey. Suiform Soundings 13(2): 21–22.Google Scholar

Nikolov, I. S., Gum, B., Markov, G. & Kuehn, R. (2009). Population genetic structure of wild boar Sus scrofa in Bulgaria as revealed by microsatellite analysis. Acta Theriologica 54: 193–205.Google Scholar

Novillo, A. & Ojeda, R. A. (2008). The exotic mammals of Argentina. Biological Invasions 10(8): 1333–1344.Google Scholar

Obara, H. (1982). The present status of the Iriomote dwarf hog. Unpublished. 2 pp.Google Scholar

Ohashi, H., Saito, M., Horie, R., et al. (2013). Differences in the activity pattern of the wild boar Sus scrofa related to human disturbance. European Journal of Wildlife Research 59: 167–177.Google Scholar

Oja, R., Zilmer, K. & Valdmann, H. (2015). Spatiotemporal effects of supplementary feeding of Wild Boar (Sus scrofa) on artificial ground nest depredation. PLoS ONE 10(8): e0135254. doi:10.1371/journal.pone.0135254.Google Scholar

Oliver, W. & Leus, K. (2008). Sus scrofa. The IUCN Red List of Threatened Species 2008: e.T41775A10559847. http://dx.doi.org/10.2305/IUCN.UK.2008.RLTS.T41775A10559847.en. Downloaded 15 February 2016.Google Scholar

Oliver, W. L. R. (1984). In Feral Mammals – Problems and Potential. Workshop on Feral Mammals, Caprinae Specialist Group, 3rd. Int. Theriol. Conf., Helsinki, 1982. Morges: IUCN, pp. 87–126.Google Scholar

Oliver, W. L. R., Brisbin, I. L. & Takahashi, S. (1993). The Eurasian wild pig (Sus scrofa). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan Gland: IUCN, pp. 112–121.Google Scholar

Organisation of Eastern Caribbean States. (2012). Management Plan for the Millet Nature Trail, St. Lucia. The OECS Protecting the Eastern Caribbean Region's Biodiversity Project Inception Report. Unpublished draft. Castries, Saint Lucia: OECS.Google Scholar

Övergaard, R., Gemmel, P. & Karlsson, M. (2007). Effects of weather conditions on mast year frequency in beech (Fagus sylvatica L.) in Sweden. Forestry 80: 555–565.Google Scholar

Parkes, J. P., Macdonald, N. & Leaman, G. (2002). An attempt to eradicate feral goats from Lord Howe Island. In Veitch, C. R. & Clout, M. N. (eds.), Turning the tide: the eradication of invasive species. Gland: IUCN SSC Invasive Species Specialist Group, pp. 233–239. Occasional Paper of the IUCN Species Survival Commission no. 27.Google Scholar

Pascal, M., Lorvelec, O. & Vigne, J. D. (2006). Invasions biologiques et extinctions. 11,000 ans d'histoire des vertébrés en France. Paris: Quae-Belin Editions.Google Scholar

Podgórski, T., Baś, G., Jędrzejewska, B., et al. (2013). Spatiotemporal behavioral plasticity of wild boar (Sus scrofa) under contrasting conditions of human pressure: primeval forest and metropolitan area. Journal of Mammalogy 94: 109–119.Google Scholar

Podgórski, T., Scandura, M. & Jędrzejewska, B. (2014a). Next of kin next door – philopatry and socio-genetic population structure in wild boar. Journal of Zoology 294: 190–197.Google Scholar

Podgórski, T., Lusseau, D., Scandura, M., Sönnichsen, L. & Jędrzejewska, B. (2014b). Long-lasting, kin-directed female interactions in a spatially structured wild boar social network. PLoS ONE 9(6): e99875.Google Scholar

Poteaux, C., Baubet, E., Kaminski, E., et al. (2009). Socio-genetic structure and mating system of a wild boar population. Journal of Zoology 278: 116–125.Google Scholar

Prévot, C. (2010). Influence of artificial feeding on spatial utilisation patterns of the wild boar (Sus scrofa L.). In 8th Symposium on Wild Boar and other suids. York: FERA, p. 21.Google Scholar

Prévot, C. & Licoppe, A. (2013). Comparing red deer (Cervus elaphus L.) and wild boar (Sus scrofa L.) dispersal patterns in southern Belgium. European Journal of Wildlife Research 59: 795–803.Google Scholar

Quy, R. J., Massei, G., Lambert, M. S., et al. (2014). Effects of a GnRH vaccine on the movement and activity of free-living wild boar (Sus scrofa). Wildlife Research 41: 185–193.Google Scholar

Rose, C. J. & Williams, W. T. (1983). Ingestion of earthworms, Pontoscolex corethrurus, by village pigs, Sus scrofa papuensis, in the Highlands of Papua New Guinea. Applied Animal Ethology 11: 131–139.Google Scholar

Rosell, C., Navas, F., Romero, S. & Dalmases, de I. (2004). Activity patterns and social organization of wild boar (Sus scrofa L.) in a wetland environment: preliminary data on the effects of shooting individuals. In Fonseca, C., Herrero, J., Luis, A. & Soares, A. M. V. M. (eds.), Wild boar research 2002. A selection and edited papers from the 4th International Wild Boar Symposium. Galemys 16 (Special Issue). Malaga: SECEM, pp. 157–166.Google Scholar

Rosell, C., Navas, F. & Romero, S. (2012). Reproduction of wild boar in a cropland and coastal wetland area: implications for management. Animal Biodiversity and Conservation 35: 209–217.Google Scholar

Rosvold, J. & Andersen, R. (2008). Wild boar in Norway – is climate a limiting factor? NTNU Vitenskapsmuseet Rapp. Zool. Ser. 2008, 1: 1–23.Google Scholar

Ruiz-Fons, F. (2017). A review of the current status of relevant zoonotic pathogens in wild swine (Sus scrofa) populations: changes modulating the risk of transmission to humans. Transboundary and Emerging Diseases 64: 68–88.Google Scholar

Russo, L., Massei, G. & Genov, P.V. (1997). Daily home range and activity of wild boar in a Mediterranean area free from hunting. Ethology, Ecology & Evolution 9: 287–294.Google Scholar

Rusz, P. J. (2007). In pursuit of Boss Hog. The Wildlife Volunteer, March–April. http://miwildlife.org/n-boss%20hog.asp Google Scholar

Saebel, J. (2007). Verhaltensbeobachtungen am Schwarzwild (Sus scrofa L.) durch Videoüberwachung und Radiotelemetrie. Diplomarbeit, Technische Universität.Google Scholar

Saez-Royuela, C. & Telleria, J. L. (1986). The increased population of wild boar (Sus scrofa L.) in Europe. Mammal Review 16: 97–101.Google Scholar

Saïd, S., Tolon, V., Brandt, S. & Baubet, E. (2012). Sex effect on habitat selection in response to hunting disturbance: the study of wild boar. European Journal of Wildlife Research 58: 107–115.Google Scholar

Saito, M., Koike, F., Momose, H., et al. (2012). Forecasting the range expansion of a recolonising wild boar Sus scrofa population. Wildlife Biology 18: 383–392.Google Scholar

Salvador, C. & Fernandez, F. A. S. (2013). Using the Eurasian wild boar phenotype as a basis to document a new process of invasion by Sus scrofa L. in a neotropical biodiversity hotspot. Wildlife Biology in Practise 10: 22–29.Google Scholar

Salvador de Oliveira, C. H. (2012). Ecologia e manejo de javali (Sus scrofa L.) na América do Sul. PhD thesis, Universidade Federal do Rio de Janeiro.Google Scholar

Sanchez-Vizcaino, J. M., Mur, L. & Martinez-Lopez, B. (2013). African swine fever (ASF): five years around Europe. Veterinary Microbiology 165: 45–50.Google Scholar

Santos, P., Mexia-de-Almeida, L. & Petrucci-Fonseca, F. (2004). Habitat selection by wild boar Sus scrofa, L. in Alentejo, Portugal. In Fonseca, C., Herrero, J., Luis, A. & Soares, A. M. V. M. (eds.), Wild Boar Research 2002. A selection and edited papers from the 4th International Wild Boar Symposium. Lousa, Portugal, pp. 167–184.Google Scholar

Sarà, M. (1998). I mammiferi delle isole del Mediterraneo. Palermo: L'Epos.Google Scholar

Saunders, G. & Kay, B. (1991). Movements of feral pigs (Sus scrofa) at Sunny Corner, New South Wales. Wildlife Research 18: 49–61.Google Scholar

Scandura, M., Iacolina, L., Crestanello, B., et al. (2008). Ancient vs. recent processes as factors shaping the genetic variation of the European wild boar: are the effects of the last glaciation still detectable? Molecular Ecology 17: 1745–1762.Google Scholar

Scandura, M., Iacolina, L. & Apollonio, M. (2011a). Genetic diversity in the European wild boar Sus scrofa: phylogeography, population structure and wild x domestic hybridization. Mammalian Review 41: 125–137.Google Scholar

Scandura, M., Iacolina, L., Cossu, A. & Apollonio, M. (2011b). Effects of human perturbation on the genetic make-up of an island population: the case of the Sardinian wild boar. Heredity 106: 1012–1020.Google Scholar

Schauss, M. E., Coletto, H. J. & Kutilek, M. J. (1990). Population characteristics of wild pigs, Sus scrofa, in eastern Santa Clara County, California. Californian Fish and Game 76(2): 68–77.Google Scholar

Schiaffini, M. I. & Vila, A. R. (2012). Habitat use of the wild boar, Sus scrofa Linnaeus 1758, in Los Alerces National Park, Argentina. Studies on Neotropical Fauna and Environment 47: 11–17.Google Scholar

Schley, L. & Roper, T. J. (2003). Diet of wild boar Sus scrofa in Western Europe, with particular reference to consumption of agricultural crops. Mammal Review 33(1): 43–56.Google Scholar

Schley, L., Dufrêne, M., Krier, A. & Frantz, A. C. (2008). Patterns of crop damage by wild boar (Sus scrofa) in Luxembourg over a 10-year period. European Journal of Wildlife Research 54: 589–599.Google Scholar

Schopper, D., Gaus, J., Claus, R. & Bader, H. (1984). Seasonal changes of steroid concentrations in seminal plasma of European wild boar. Acta Endocrinologica 107: 425–427.Google Scholar

Scillitani, L., Monaco, A. & Toso, S. (2010). Do intensive drive hunts affect wild boar (Sus scrofa) spatial behaviour in Italy? Some evidences and management implications. European Journal of Wildlife Research 56: 307–318.Google Scholar

Segura, A., Acevedo, P., Rodríguez, O., Naves, J. & Obeso, J. (2014). Biotic and abiotic factors modulating wild boar relative abundance in Atlantic Spain. European Journal of Wildlife Research 60: 469–476.Google Scholar

Servanty, S., Gaillard, J.-M., Allaine, D., Brandt, S. & Baubet, E. (2007). Litter size and fetal sex ratio adjustment in a highly polytocous species: the wild boar. Behavioural Ecology 18: 427–432.Google Scholar

Servanty, S., Gaillard, J.M., Toïgo, C., Brandt, S. & Baubet, E. (2009). Pulsed resources and climate-induced variation in the reproductive traits of wild boar under high hunting pressure. Journal of Animal Ecology 78: 1278–1290.Google Scholar

Singer, F. J., Otto, D. K., Tipton, A. R. & Hable, C. P. (1981). Home ranges, movements and habitat use of European wild boar in Tennessee. Journal of Wildlife Management 45: 343–353.Google Scholar

Skewes, O. & Jaksic, F. M. (2015). History of the introduction and present distribution of the European wild boar (Sus scrofa) in Chile. Mastozoología Neotropical 22(1): 113–124.Google Scholar

Śliwiński, B., Furgał-Dzierzuk, I., Koreleski, J., Brzóska, F. & Kański, J. (2010). Tabele składu chemicznego wartości pokarmowej pasz. Krakow: Instytut Zootechniki w Balicach. [In Polish.]Google Scholar

Smithers, R. H. N. (1983). The mammals of the southern African subregion. University of Pretoria.Google Scholar

Sodeikat, G. & Pohlmeyer, K. (2003). Escape movements of family groups of wild boar Sus scrofa influenced by drive hunts in Lower Saxony, Germany. Wildlife Biology 9(Suppl): 43–49.Google Scholar

Spencer, P. B. S., Lapidge, S. J., Hampton, J. O. & Pluske, J. R. (2005). The sociogenetic structure of a controlled feral pig population. Wildlife Research 32: 297–304.Google Scholar

Špinka, M. (2009). Behaviour of pigs. In Jensen, P. (ed.), The ethology of domestic animals: an introductory text. Wallingford: CABI Publishing, pp. 177–191.Google Scholar

Spitz, F. (1992). General model of the spatial and social organisation of wild boars (Sus scrofa L.). In Spitz, F., Janeau, G., Gonzales, G. & Aulagnier, S. (eds.), Ongulés/Ungulates 91. Proc. Intern. Symp. Toulouse. Paris-Toulouse: S.F.E.P.M.-I.R.G.M.Google Scholar

Spitz, F. & Janeau, G. (1990). Spatial strategies: an attempt to classify daily movements of wild boar. Acta Theriologica 35: 129–149.Google Scholar

Spitz, F. & Janeau, G. (1995). Daily selection of habitat in wild boar (Sus scrofa). Journal of Zoology London 237: 423–434.Google Scholar

Šprem, N., Škavić, P., Dežđek, D. & Keros, T. (2014). The wild boar attack – a case report of a wild boar inflicted injury and treatment. Collegium Antropologicum. 38(4): 1211–1212.Google Scholar

SPREP (South Pacific Regional Environment Programme). (2000). Invasive species in the Pacific: a technical review and draft technical strategy. Sherley, G. (ed.). Samoa: South Pacific Regional Environment Programme.Google Scholar

Storch, I. (1994). Habitat and survival of capercaillie Tetrao urogallus nests and broods in the Bavarian Alps. Biological Conservation 70(3): 237–243.Google Scholar

Stubbe, W. & Stubbe, M. (1977). Vergleichende Beiträge zur Reproduktions- und Geburtsbiologie von Wild- und Hausschwein – Sus scrofa L., 1758. Beitr. Jagd- u. Wildforschung 10: 153–179.Google Scholar

Suselbeek, L., Adamczyk, V. M. A. P., Bongers, F., et al. (2014). Scatter hoarding and cache pilferage by superior competitors: an experiment with wild boar, Sus scrofa. Animal Behaviour 96: 107–115.Google Scholar

Sweitzer, R., Van Vuren, D., Gardner, I. A., Boyce, V. M. & Waithman, J. D. (2000). Estimating sizes of wild pig populations in the north and central coast regions of California. Journal of Wildlife Management 64(2): 531–543.Google Scholar

Thurfjell, H., Ball, J. P., Åhlén, P.-A., et al. (2009). Habitat use and spatial patterns of wild boar Sus scrofa (L.): agricultural fields and edges. European Journal of Wildlife Research 55: 517–523.Google Scholar

Thurfjell, H., Spong, G. & Ericsson, G. (2013). Effects of hunting on wild boar (Sus scrofa, L.) behaviour. Wildlife Biology 19: 87–93.Google Scholar

Tolon, V., Dray, S., Loison, A., et al. (2009). Responding to spatial and temporal variations in predation risk: space use of a game species in a changing landscape of fear. Canadian Journal of Zoology 87: 1129–1137.Google Scholar

Tolon, V., Martin, J., Dray, S., et al. (2012). Predator–prey spatial game as a tool to understand the effects of protected areas on harvester–wildlife interactions. Ecological Applications 22: 648–657.Google Scholar

Truvé, J. (2004). Pigs in space: movement, dispersal and geographic expansion of wild boar (Sus scrofa) in Sweden. Dissertation, University of Göteborg.Google Scholar

Truvé, J. & Lemel, J. (2003). Timing and distance of natal dispersal for wild boar Sus scrofa in Sweden. Wildlife Biology 9(Suppl): 51–57.Google Scholar

Truvé, J., Lemel, J. & Söderberg, B. (2004). Dispersal in relation to population density in wild boar (Sus scrofa). In Fonseca, C., Herrero, J., Luis, A. & Soares, A. M. V. M. (eds.), Wild Boar Research 2002. A selection and edited papers from the ‘4th International Wild Boar Symposium’. Lousa, Portugal, pp. 75–82.Google Scholar

Tsachalidis, E. P. & Hadjisterkotis, E. (2009). Current distribution and population status of wild boar (Sus scrofa L.) in Greece. Acta Silvatica & Lignaria Hungarica 5: 153–157.Google Scholar

Tschalidis, E. P., Paralikidis, N., Parageorgiu, N. & Hadjisterkotis, E. (2004). Food habit of wild boar (Sus scrofa L.) in Northeastern Greece. Proceedings of the Vth International Wild Boar and Suidae Symposium. Jagiellonian University, 1–6 September 2004. Krakow, Poland.Google Scholar

van Wieren, S. E. (2000). Digestibility and voluntary intake of roughage by wild boar and Meishan pigs. Animal Science 71: 149–156.Google Scholar

Varnham, K. (2006). Non-native species in UK Overseas Territories: a review. JNCC Report No. 372.Google Scholar

Veličković, N., Djan, M., Obreht, D. & Vapa, L. (2012). Population genetic structure of wild boars in the West Balkan region. Russian Journal of Genetics 48: 859–863.Google Scholar

Veličković, N., Djan, M., Ferreira, E., et al. (2015). From north to south and back: the role of the Balkans and other southern peninsulas in the recolonization of Europe by wild boar. Journal of Biogeography 42(4): 716–728.Google Scholar

Veličković, N., Ferreira, E., Djan, M., et al. (2016). Demographic history, current expansion and future management challenges of wild boar populations in the Balkans and Europe. Heredity 117: 348–357.Google Scholar

Vernesi, C., Crestanello, B., Pecchioli, E., et al. (2003). The genetic impact of demographic decline and reintroduction in the wild boar (Sus scrofa): a microsatellite analysis. Molecular Ecology 12: 585–595.Google Scholar

Vetter, S. G., Ruf, T., Bieber, C. & Arnold, W. (2015). What is a mild winter? Regional differences in within-species responses to climate change. PLOS One 10: e0132178.Google Scholar

Vilaça, S. T., Biosa, D., Zachos, F., et al. (2014). Mitochondrial phylogeography of the European wild boar: the effect of climate on genetic diversity and spatial lineage sorting across Europe. Journal of Biogeography 41(5): 987–998. doi:10.1111/jbi.12268.Google Scholar

Villarreal González, J. G., de los Santos, G. S., Moreno Chacón, P. V., et al. (2010). Presencia, distribución y problemática del jabalí europeo y marrano alzado Sus scrofa en los ecositemas de Matorral Espinoso Tamaulipeco del Norte y Cnetro de Nuevo León, México. Cuenca Palo Blanco 6: 12–19.Google Scholar

Weary, D. M. & Fraser, D. (1995). Calling by domestic piglets: reliable signals of need? Animal Behaviour 50: 1047–1055.Google Scholar

West, P. (2008). Assessing invasive animals in Australia 2008. Canberra: National Land & Water Resources Audit and Invasive Animals Cooperative Research Centre.Google Scholar

Wilson, D. E. & Mittermeier, R. A. (2011). Handbook of the mammals of the world. Vol. 2. Hoofed mammals. Barcelona: Lynx Edicions.Google Scholar

Wlazełko, M., Łabudzki, L., Górecki, G. & Skubis, J. (2009). The seasonal pattern of wild boars diet in western Poland – research carried out at the Zielonka Game Research Centre. Acta Scientiarum Polonorum Silvarum Colendarum Ratio et Industria Lignaria 8: 55–70.Google Scholar

Wood, G. W. & Brenneman, R. E. (1980). Feral hog movements and habitat use in South Carolina. Journal of Wildlife Management 44: 420–427.Google Scholar

Wu, N., Abril, C., Hinicacute, V., et al. (2011). Free-ranging wild boar: a disease threat to domestic pigs in Switzerland? Journal of Wildlife Diseases 47: 868–879.Google Scholar

References

Barman, N. N., Bora, D. P., Tiwari, A. K., et al. (2012). Classical Swine Fever in the pygmy hog. Revue scientifique et technique (International Office of Epizootics) 31: 919–930.Google Scholar

Chakraborty, A., Rahman, H., Deka, P. J. & Narayan, G. (1999). Outbreak of mixed infection of Salmonella eneteritidis and Mucormycosis in pigmy hogs (Sus salvanius). Compendium of the National Symposium on Topics of Current Interest in Pathology of Animal and Poultry Diseases – the Millennium Approach & XVI Annual Conference of Indian Association of Veterinary Pathologists, 25–27 November 1999, Bangalore, India, p. 137.Google Scholar

Corbet, G. B. & Hill, J. E. (1980). A world list of mammalian species. London: British Museum (Natural History).Google Scholar

Funk, S. M., Verma, S. K., Larson, G., et al. (2007). The pygmy hog is a unique genus: 19th century taxonomists got it right first time round. Molecular Phylogenetics and Evolution 45: 427–436.Google Scholar

Garson, J. G. (1883). Notes on the anatomy of the Sus salvanius (Porcula salvania Hodgson). Part 1, external characters and visceral anatomy. Proceedings of the Zoological Society of London XXVIII: 413–418.Google Scholar

Gee, E. P. (1964). Wildlife of India. London: Collins Ltd.Google Scholar

Griffith, L. D. (1978). The search for the pigmy hog in Nepal. Nature Ann., Nepal Nature Conservation Society 11: 41–45.Google Scholar

Groves, C. P. (1981). Ancestors for the pigs: Taxonomy and phylogeny of the genus Sus. Technical Bulletin 3, Department of Prehistory, Research School for Pacific Studies, Australian National University VII: pp. 1–96.Google Scholar

Groves, C. P. & Grubb, P. (1993). The Eurasian suids Sus and Babyrousa. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 107–111.Google Scholar

Hodgson, B. H. (1847). On the new form of hog kind or Suideae. Journal of the Asiatic Society of Bengal XVI: 423–428.Google Scholar

Kakati, P., Sarmah, P. C., Bhattacharjee, K., et al. (2015). Gastrointestinal nematodiasis in a captive bred critically endangered pygmy hog (Porcula salvania). International Journal of Recent Scientific Research 6(5): 4231–4234.Google Scholar

Macdonald, A. A., Ossent, P., Rubela, A. B., Isenbugel, E. & Schmidt, C. R. (1990). Desiminated pathogenic lesion associated with pathogenic Actinomycetes in a pygmy hog (Sus salvanius). Journal of Comparative Pathology 102: 385–391.Google Scholar

Mallinson, J. J. C. (1971). The pigmy hog, Sus salvanius (Hodgson) in northern Assam. Journal of the Bombay Natural History Society 68: 424–433.Google Scholar

Mallinson, J. J. C. (1977). Breeding of the pigmy hog, Sus salvanius (Hodgson) in northern Assam. Journal of the Bombay Natural History Society 74: 288–298.Google Scholar

Mishra, A. C. & Singh, K. N. (1978). Description of Haematopinous oliveri sp. nov. (Anapoplura: Haematopinidae) parasitising Sus salvanius. Bulletin of the Zoological Survey of India 1(2): 167–169.Google Scholar

Narayan, G. & Deka, P. J. (2015). Radio tracking pygmy hogs (Porcula salvania) – trials of transmitter attachment methods. Solitaire 26: 19–26.Google Scholar

Narayan, G. & Oliver, W. L. R. (2015). Pygmy hog Porcula salvania. In Johnsingh, A. J. T. & Manjrekar, N. (eds.), Mammals of South Asia. Hyderabad: Universities Press, Vol. 2, pp. 129–145.Google Scholar

Narayan, G., Oliver, W. L. R. & Deka, P. J. (1999a). The status and conservation program for the pygmy hog (Sus salvanius). In Roth, T. L., Swanson, W. F. & Blattman, L. K. (eds.), Seventh World Conference on Breeding Endangered Species: linking zoo and field research to advance conservation. Cincinnati: Cincinnati Zoo and Botanical Garden, pp. 109–127.Google Scholar

Narayan, G., Deka, P. J., Chakraborty, A. & Oliver, W. L. R. (1999b). Increase in captive population of pygmy hogs Sus salvanius: health problems and husbandry. Dodo, Journal of Jersey Wildlife Preservation Trust 35: 70–86.Google Scholar

Narayan, G., Deka, P.J. & Oliver, W. (2008). First captive bred pygmy hogs (Porcula salvania) reintroduced to Sonai Rupai Wildlife Sanctuary, Assam, India. Suiform Soundings 8(1): 16–26.Google Scholar

Narayan, G., Deka, P. J., Oliver, W. L. R. & Fa, J. E. (2010). Conservation breeding and re-introduction of the pygmy hog in NW Assam, India. In Soorae, P. S. (ed.), Global re-introduction perspectives: additional case-studies from around the globe. Abu Dhabi: IUCN/SSC Re-introduction Specialist Group.Google Scholar

Oliver, W. L. R. (1979). Observations of the biology of the pigmy hog (with a footnote on the hispid hare): pigmy hog survey report, part II. Journal Bombay of Natural History Society 76: 115–42.Google Scholar

Oliver, W. L. R. (1980). The biology and conservation of the pigmy hog Sus (Porcula) salvanius and the hispid hare Caprolagus hispidus. Special Scientific Report No. 1, Jersey Wildlife Preservation Trust.Google Scholar

Oliver, W. L. R. (1984). The distribution and status of the hispid hare Caprolagus hispidus: the summarised findings of the 1984 pigmy hog/hispid hare field survey in northern Bangladesh, southern Nepal and northern India. Dodo, Journal of Jersey Wildlife Preservation Trust 21: 6–32.Google Scholar

Oliver, W. L. R. & Deb Roy, S. (1993). The pygmy hog (Sus salvanius). In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 121–129.Google Scholar

Oliver, W. L. R., Narayan, G. & Raj, M. (1997). The Pygmy Hog Conservation Programme: background description and report on progress to end December 1996. Dodo, Journal of Jersey Wildlife Preservation Trust 33: 45–71.Google Scholar

Rahman, H., Chakraborty, A., Deka, P. J., Narayan, G. & Prager, R. (2001). An outbreak of Salmonella enteritides infection in pygmy hogs (Sus salvanius). Tropical Animal Health and Production 33: 95–102.Google Scholar

Rahman, H., Deka, P. J., Chakraborty, A. & Narayan, G. (2003). An outbreak of Salmonella choleraesuis infection in pygmy hogs (Sus salvanius). Indian Journal of Animal Sciences 73(3): 257–258.Google Scholar

Rands, M., Brown, P. & Newton, P. (1979). University of East Anglia Nepal Expedition, 1978–79 (unpublished report), 70 pp.Google Scholar

Ranjitsinh, M. K. (1972). A note on the future conservation plan for the pigmy hog (Sus salvanius) and hispid hare (Caprolagus hispidus Pearson, 1839). D.O. No. 682/DSF 1023/72, Govt. of India. (Unpublished.)Google Scholar

Tessier-Yandell, J. (1971). The pigmy hog, Sus salvanius. Cheetal 14(3): 23–28.Google Scholar

References

Altrichter, M. (2005). The sustainability of subsistence hunting of peccaries in the Argentine Chaco. Biological Conservation 126: 351–362.Google Scholar

Altrichter, M. (2006). Wildlife in the life of local people in the Argentine Chaco. Biodiversity and Conservation 15: 2719–2736.Google Scholar

Altrichter, M. & Boaglio, G. (2004). Distribution and abundance of peccaries in the Argentinean Chaco: its associations with human factors. Biological Conservation 116: 217–225.Google Scholar

Altrichter, M., Taber, A., Noss, A. & Maffei, L. (2008). Catagonus wagneri. IUCN Red List of Threatened Species. Version 2012.2. www.iucnredlist.org. Downloaded 20 October 2015.Google Scholar

Altrichter, M., Desbiez, A., Camino, M. & Decarre, J. (eds.) (2016). Pecarí del Chaco o Taguá Catagonus wagneri. Una estrategia para su conservación. Revisión de situación, análisis de viabilidad poblacional y aptitud del hábitat. Asunción, Paraguay: UICN Grupo Especialista en Pecaríes, SSC, Guyra Paraguay, CCCI Paraguay.Google Scholar

Benirschke, K. & Heuschele, W. P. (1993). Proyecto Taguá: the giant Chaco peccary Catagonus wagneri conservation project. International Zoo Yearbook 32: 28–31.Google Scholar

Benirschke, K. & Kumamoto, A. T. (1989). Further studies on the chromosomes of three species of peccary. Advances in Neotropical Mammalogy 1: 309–316.Google Scholar

Brooks, D. M. (1992). Reproductive behaviour and development of the young of the Chacoan peccary (Catagonus wagneri Rusconi, 1930) in the Paraguayan Chaco. Zeitschrift für Säugetierkunde 57: 316–317.Google Scholar

Brooks, D. M. (1996). Herd interactions of chacoan peccaries (Catagonus wagneri). Costs and benefits. Anim. K. Forum 23: 123–134.Google Scholar

Bucher, E. H. (1983). Chaco and caatinga: South American arid savannas, woodlands and thickets. In Huntley, B. & Walker, B. (eds.), Ecology of tropical savannas, ecological studies. New York, NY: Springer, pp. 48–79.Google Scholar

Caballero, J., Palacios, F., Arevalos, F., Rodas, O. & Yanosky, A. (2014). Cambio de Uso De La Tierra en el Gran Chaco Americano en el año 2013. Paraquaria Natural 2: 21–28.Google Scholar

Caldas, M. M., Goodin, D., Sherwood, S., Campos Krauer, J. M. & Wisely, S. M. (2013). Land-cover change in the Paraguayan Chaco: 2000–2011. Journal of Land Use Science 10: 1–18.Google Scholar

Day, G. I. (1985). Javelina; research and management in Arizona. Phoenix, AZ: Arizona Game and Fish Department.Google Scholar

Ferraz, K., Angeleri, C., Altrichter, M., et al. (2016). Predicting the current distribution of the Chacoan peccary (Catagonus wagneri) in the Gran Chaio. Suiform Soundings 5(1): 53–63.Google Scholar

Fowler, M. E. (1996). Husbandry and diseases of captive wild swine and peccaries. Revue scientifique et technique 15: 141–154.Google Scholar

Guyra Paraguay. (2012). INFORME TÉCNICO. Resultados del Monitoreo Mensual de los Cambios de Uso de la Tierra, Incendios e Inundaciones en el Gran Chaco Americano.Google Scholar

Handen, C. F. & Benirschke, K. (1991). The giant chacoan peccary: feeding and social behavior of a captive group in natural habitat. Zoo Biology 10: 209–217.Google Scholar

Handen, E. C. (1994). Current status of the tagua (Catagonus wagneri) in Paraguay. Der Zoologishe Garten 6: 329–337.Google Scholar

Huang, C., Kim, S., Song, K., et al. (2009). Assessment of Paraguay's forest cover change using Landsat observations. Global and Planetary Change 67: 1–12.Google Scholar

Maffei, L., Cuéllar, R. L. & Banegas, J. (2008). Distribución del solitario (Catagonus wagneri) en Bolivia. Ecologia en Bolivia 43: 141–145.Google Scholar

Mayer, J. J. & Brandt, P. N. (1982). Identity, distribution, and natural history of the peccaries, Tayassuidae. Special Publication Pymatuning Laboratory of Ecology 6: 433–455.Google Scholar

Mayer, J. J. & Wetzel, R. M. (1986). Catagonus wagneri. Mammalian Species 259: 1–5.Google Scholar

Morello, J. & Adamoli, J. (1968). Las Grandes Unidades de Vegetacióny Ambiente del Chaco Argentino. Primera parte: Objetivos y Metodología. Serie Fitogeografica, 10. Buenos Aires: Instituto Nacional de Tecnología Agropecuaria.Google Scholar

Neris, N., Colman, F., Ovelar, E., Sukigara, N. & Ishii, N. (2002). Guia de Mamiferos Medianos y Grandes del Paraguay. Distribucion, Tendencia Poblacional y Utilización. Asunción, Paraguay: Secretaria del Ambiente, Agencia de Cooperación Internacional del Japón.Google Scholar

Noss, A. (1999). La sostenibilidad de la cacería de subsistencia Izoceña. In Cabrera, E., Mercolli, C. & Resquin, R. (eds.), Manejo de fauna silvestre en Amazonía y Latinoamérica. Asunción, Paraguay: CITES Paraguay, Fundación Moises Bertoni, University of Florida, pp. 535–543.Google Scholar

Noss, A., Cuellar, J. E. & Cuellar, R. L. (2003). Hunter self-monitoring as a basis for biological research: data from the Bolivian Chaco. Mastozoologıa Neotropical 10: 49–67.Google Scholar

Parisi, R., Casali, D. M., Missagia, R. V., et al. (2016). Phylogenetic systematics of peccaries (Tayassuidae: Artiodactyla) and a classification of South American tayassuids. Journal of Mammalian Evolution doi:10.1007/s10914-016-9347-8.Google Scholar

Pearce, F. (2011). Forgotten Eden. New Scientist 211: 43–47.Google Scholar

Redford, K. H. & Eisenberg, J. F. (1992). Mammals of the Neotropics: the Southern Cone. Chicago, IL: University of Chicago Press.Google Scholar

Sowls, L. K. (1984). The peccaries. Tucson, AZ: The University of Arizona Press.Google Scholar

Sowls, L. K. (1997). Javelina and other peccaries, 2nd ed. College Station, TX: Texas A & M University Press.Google Scholar

Taber, A. B. (1989). Pig from green hell. Animal Kingdom 92: 20–27.Google Scholar

Taber, A. B. (1990). Monographie des Chaco-Pekaris (Catagonus wagneri). Bongo 18: 135–150.Google Scholar

Taber, A. B. (1991). The status and conservation of the Chacoan peccary in Paraguay. Oryx 25: 147–155.Google Scholar

Taber, A. B. (1993). The Chacoan peccary (Catagonus wagneri). In Oliver, W. L. R. (ed.). Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN, pp. 22–28.Google Scholar

Taber, A. B., Doncaster, C. P., Neris, N. N. & Colman, F. H. (1993). Ranging behavior and population dynamics of the Chacoan peccary, Catagonus wagneri. Journal of Mammalogy 74: 443–454.Google Scholar

Taber, A. B., Doncaster, C. P., Neris, N. N. & Colman, F. (1994). Ranging behaviour and activity patterns of two sympatric species, Catagonus wagneri and Tayassu tajacu in the Paraguayan Chaco. Mammalia 58: 61–71.Google Scholar

Todd, N. B. (1985). Significance of a diploid number of 20 in the peccary Catagonus wagneri. Journal of Heredity 76: 310.Google Scholar

Torres, R. & Jayat, P. (2010). Modelos predictivos de distribución para cuatro especies de mamíferos (Cingulata, Artiodactyla y Rodentia) típicas del chaco en Argentina. Mastozoología Neotropical 17: 335–352.Google Scholar

Torres, R., Tamburini, D., Lescano, J. & Rossi, E. (2016). New records of the Endangered Chacoan peccary Catagonus wagneri suggest a broader distribution than formerly known. Oryx 1: 1–4.Google Scholar

Vallejos, M., Volante, J. N., Mosciaro, M. J., et al. (2015). Transformation dynamics of the natural cover in the Dry Chaco ecoregion: a plot level geo-database from 1976 to 2012. Journal of Arid Environments 123: 3–11.Google Scholar

Wetzel, R. M. (1977a). The Chacoan peccary, Catagonus wagneri (Rusconi). Bulletin of the Carnegie Museum of Natural History 3: 1–36.Google Scholar

Wetzel, R. M. (1977b). The extinction of peccaries and a new case of survival. Annals of the New York Academy of Science 288: 538–544.Google Scholar

Wetzel, R. M. (1981). The hidden Chacoan peccary. Carnegie Magazine 55: 24–32.Google Scholar

Wetzel, R. M., Dubos, R. E., Martin, R. L. & Myers, P. (1975). Catagonus an ‘extinct’ peccary, alive in Paraguay. Science 189: 379–381.Google Scholar

Wright, D. B. (1998). Tayassuidae. In Janis, C. M., Scott, K. M. & Jacobs, L. L. (eds.), Evolution of tertiary mammals of North America. London: Cambridge University Press, pp. 389–401.Google Scholar

Yahnke, C. J., Unger, J., Lohr, B., Meritt, D. A. & Heuschele, W. (1997). Age-specific fecundity, litter size, and sex ratio in the Chacoan peccary (Catogonus wagneri). Zoo Biology 16: 301–307.Google Scholar

Zervanos, S.M. (1985). Relative renal medullary thickness of two species of peccary. In Ockenfels, R. A., Day, G. I. & Supplee, V. C. (eds.), Proceedings of the Peccary Workshop. Phoenix, AZ: Arizona Game and Fish Department, p. 48.Google Scholar

References

Albert, S., Ramotnik, C. A., & Schmitt, C. G. (2004). Collared peccary range expansion in northwestern New Mexico. The Southwestern Naturalist 49: 524–528.Google Scholar

Altrichter, M. (2005). The sustainability of subsistence hunting of peccaries in the Argentine Chaco. Biological Conservation 126: 351–362.Google Scholar

Beck, H. (2005). Seed predation and dispersal by peccaries throughout the Neotropics and its consequences: a review and synthesis. In Forget, P-M., Lambert, J. E., Hulme, P. E. & Vander Wall, S. B. (eds.), Seed fate: predation, dispersal and seedling establishment. Wallingford: CABI Publishing, pp. 77–115.Google Scholar

Beck, H. (2006). A review of peccary–palm interactions and their ecological ramifications across the Neotropics. Journal of Mammalogy 87: 519–530.Google Scholar

Beck, H., Thebpanya, P. & Filiaggi, M. (2010). Do Neotropical peccary species (Tayassuidae) function as ecosystem engineers for anurans? Journal of Tropical Ecology 26: 407–414.Google Scholar

Bissonette, J. A. (1982). Ecology and social behavior of the collared peccary in Big Bend National Park. Scientific Monograph Series No 16. Washington, DC: US National Park Service.Google Scholar

Bodmer, R. E. (1989). Frugivory in Amazonian Artiodactyla: evidence for the evolution of the ruminant stomach. Journal of Zoology 219: 457–467.Google Scholar

Bodmer, R. E. & Sowls, L. K. (1993). The collared peccary (Tayassu tajacu). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN.Google Scholar

Bodmer, R.E., Fang, T.G., Puertas, P.E., et al. (2014). Cambio climático y fauna Silvestre en la Amazonia peruana. Iquitos, Peru: Wust Editions.Google Scholar

Briceño-Mendes, M., Naranjo, E., Altrichter, M. & Reyna-Hurtado, R. (2016). Responses of two sympatric species of peccaries (Tayassu pecari and Pecari tajacu) to hunting in Calakmul, Mexico. Tropical Conservation Science 9: 1–11.Google Scholar

Builes, D. F. P., Loaiza, I. D. D., Lopez, J. B. O., Marquez, E. M. & Bock, B. C. (2004). Citogenetica basica del pecari de Collar Tayassu tajacu. Diferencias cromosomicas gruesas entre sus poblaciones. Universidad Nacional de Colombia, Medellin. Available from: www.reuna.edu.co/temporales/memorias/especies/EspeciesAnimales.htm.Google Scholar

Byers, J. A. (1980). Social behavior and its development in the collared peccary (Tayassu tajacu). PhD dissertation, University of Colorado, Boulder, CO.Google Scholar

Castellanos, H. G. (1983). Aspectos de la organización social del baquiro de collar Tayassu tajacu en el estado Guarico, Venezuela. Acta Zoológica Venezolana 11: 127–143.Google Scholar

Castellanos, H. G. (1985). Home range size and habitat selection of the collared peccary in the state of Guarico, Venezuela. In Ockenfels, R. A., Day, G. I. & Suppleee, V. C. (eds.), Peccary workshop proceedings. Phoenix, AZ: Arizona Game and Fish Department.Google Scholar

Cooper, J. D., Waser, P. M., Hellgren, E. C., Garbor, T. M. & De Wood, J. A. (2011). Is sexual monomorphism a predictor of polygynandry? Evidence from a social mammal, the collared peccary. Behavioral Ecology and Sociobiology 6: 775–785.Google Scholar

Cullen, L. Jr., (1997). Hunting and biodiversity in Atlantic forest fragments, São Paulo, Brazil. MS thesis. Gainesville, FL: University of Florida.Google Scholar

Cullen, L. Jr., Bodmer, R. E. & Valladares-Padua, C. (2001). Ecological consequences of hunting in Atlantic forest patches, Sao Paulo, Brazil. Oryx 35: 137–144.Google Scholar

Day, G. I. (1985). Javelina research and management in Arizona. Phoenix, AZ: Arizona Game and Fish Department.Google Scholar

de Freitas, T. T., Keuroghlian, A., Eaton, D., et al. (2010). Prevalence of Leptospira interrogans antibodies in free-ranging Tayassu pecari of the Southern Pantanal, Brazil, an ecosystem where wildlife and cattle interact. Tropical Animal Health and Production 42: 1695–1703.Google Scholar

Desbiez, A. L. J., Santos, S. A., Keuroghlian, A. & Bodmer, R. E. (2009). Niche partitioning between sympatric populations of native white-lipped peccary (Tayassu pecari), collared peccary (Tayassu tajacu), and introduced feral pigs (Sus scrofa). Journal of Mammalogy 90(1): 119–128.Google Scholar

Eisenberg, J. F. (1980). The density and biomass of tropical mammals. In Soulé, M. & Wilcox, B. A. (eds.), Conservation biology: an evolutionary–ecological perspective. Sunderland, MA: Sinauer Associates, pp. 35–55.Google Scholar

Eisenberg, J. F., O'Connell, M. A. & August, P. V. (1979). Density, productivity, and distribution of mammals in two Venezuelan habitats. In Vertebrate ecology in the northern Neotropics. Washington, DC: Smithsonian Institution Press, pp. 187–207.Google Scholar

Ellisor, J. E. & Harwell, F. (1969). Mobility and home range of collared peccary in southern Texas. Journal of Wildlife Management 33: 425–427.Google Scholar

Emmons, L. H. & Feer, F. (1990). Neotropical rainforest mammals. A field guide. Chicago, IL: The University of Chicago Press.Google Scholar

Fang, T. G., Bodmer, R. E., Puertas, P.E., et al. (2008). Certificación de pieles de pecaríes en la Amazonia Peruana. Lima: Wust Editions.Google Scholar

Fragoso, J. M. V. (1999). Perception of scale and resource partitioning by peccaries: behavioral causes and ecological implications. Journal of Mammalogy 80(3): 993–1003.Google Scholar

Galetti, M., Camargo, H., Siqueira, T., et al. (2015). Diet overlap and foraging activity between feral pigs and native peccaries in the Pantanal. PLoS ONE 10(11): e0141459. doi:10.1371/journal.pone.0141459Google Scholar

Glanz, W. E. (1982). The terrestrial mammal fauna of Barro Colorado Island: censuses and long-term changes. In Leigh, E. G., Jr, Rand, A. S. & Windsor, D. M. (eds.), The ecology of a tropical forest. Washington, DC: Smithsonian Institution Press.Google Scholar

Gómez, B. & Montenegro, O. (2012). Abundancia del pecarí de collar (Pecari tajacu) en dos áreas protegidas de la Guayana colombiana. Mastozoología neotropical 19: 163–178.Google Scholar

Gongora, J. & Moran, C. (2005). Nuclear and mitochondrial evolutionary analyses of Collared, White-lipped, and Chacoan peccaries (Tayassuidae). Molecular Phylogenetics and Evolution 34: 181–189.Google Scholar

Gongora, J., Morales, S., Bernal, J. E. & Moran, C. (2006). Phylogenetic divisions among collared peccaries (Pecari tajacu) detected using mitochondrial and nuclear sequences. Molecular Phylogenetics and Evolution 41: 1–11.Google Scholar

Gongora, J., Reyna-Hurtado, R., Beck, H., et al. (2011a). Pecari tajacu. The IUCN Red List of Threatened Species 2011: e.T41777A10562361. http://dx.doi.org/10.2305/IUCN.UK.2011-2.RLTS.T41777A10562361.en. Downloaded 5 November 2015.Google Scholar

Gongora, J., Biondo, C., Cooper, J., et al. (2011b). Revisiting the species status of Pecari maximus van Roosmalen et al., 2007 (Mammalia) from the Brazilian Amazon. Bonn Zoological Bulletin 60(1): 95–101.Google Scholar

Gottdenker, N. L. & Bodmer, R. E. (1998). Reproduction and productivity of white-lipped and collared peccaries in the Peruvian Amazon. Journal of Zoology 245: 423–430.Google Scholar

Green, G. E., Grant, W.E. & Davis, E. (1984). Variability of observed group sizes within collared peccary herds. Journal of Wildlife Management 48: 244–248.Google Scholar

Groves, C. P. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Grubb, P. & Groves, C. P. (1993). The Neotropical Tayassuids Tayassu and Catagonus. In Oliver, W. L. R. (ed.), Pigs, peccaries and hippos: status survey and conservation action plan. Gland: IUCN, pp. 5–7.Google Scholar

Hall, E. R. (1981). The mammals of North America. New York, NY: John Wiley and Sons.Google Scholar

Ilse, L. M. & Hellgren, E. C. (1995). Resource partitioning in sympatric populations of collared peccaries and feral hogs in southern Texas. Journal of Mammalogy 76: 784–799.Google Scholar

Jones, J. K. & Manning, R. W. (1992). Illustrated key to skulls of genera of North American land mammals. Lubbock, TX: Texas Tech University Press.Google Scholar

Judas, J. & Henry, O. (1999). Seasonal variation of home range of collared peccary in tropical rain forests of French Guiana. Journal of Wildlife Management 63: 546–555.Google Scholar

Karesh, W. B., Uhart, M., Painter, L., et al. (1998). Health evaluation of white lipped peccary populations in Bolivia. Omaha, NB: American Association of Wildlife Veterinarians, pp. 445–449.Google Scholar

Keuroghlian, A. & Desbiez, A. L. J. (2010). Biometric and age estimation of live peccaries in the Southern Pantanal, Brazil. Suiform Soundings 9: 24–35.Google Scholar

Keuroghlian, A., Eaton, D. P. & Longland, W. S. (2004). Area use by white-lipped and collared peccaries (Tayassu pecari and Tayassu tajacu) in a tropical forest fragment. Biological Conservation 120: 411–425.Google Scholar

Keuroghlian, A., Donald, P. & Eaton, D. P. (2008). Fruit availability and peccary frugivory in an isolated Atlantic forest fragment: effects on peccary ranging behavior and habitat use. Biotropica 40: 62–70.Google Scholar

Kiltie, R. A. (1981). Stomach contents of rain forest peccaries (Tayassu tajacu and T. pecari). Biotropica 13: 234–236.Google Scholar

Kiltie, R. A. & Terborgh, J. (1983). Observations on the behavior of rain forest peccaries in Peru. Why do white-lipped peccaries form herds? Zeitschrift für Tierpsychologie 62: 214–255.Google Scholar

Knipe, T. (1957). Javelinas in Arizona. Wildlife Bulletin No 2. Phoenix, AZ: Arizona Game and Fish Department.Google Scholar

Lochmiller, R. L., Hellgren, E. C. & Grant, W. E. (1984). Selected aspects of collared peccary (Dicotyles tajacu) reproductive biology in a captive Texas herd. Zoo Biology 3: 145–149.Google Scholar

Low, W. A. (1970). The influence of aridity on reproduction of the collared peccary (Dicotyles tajacu; Linn.) in Texas. PhD dissertation. Vancouver: University of British Columbia.Google Scholar

Mandujano, S. (1999). Variation in herd size of collared peccaries in a Mexican tropical forest. The Southwestern Naturalist 44: 199–204.Google Scholar

Mayor, P., Guimaraes, D.A., Lopez-Gatius, F. & Lopez-Bejar, M. (2006a). First postpartum estrus and pregnancy in the female collared peccary (Tayassu tajacu) from the Amazon. Theriogenology 66: 2001–2007.Google Scholar

Mayor, P., Fenech, M., Bodmer, R. E. & Lopez-Bejar, M. (2006b). Ovarian features of the wild collared peccary (Tayassu tajacu) from Peruvian Northeastern Amazon. General and Comparative Endocrinology 147: 268–275.Google Scholar

McCoy, M. B., Vaughan, C. S. & Rodrigues, M. A. (1990). Seasonal movement, home range, activity and diet of collared peccaries (Tayassu tajacu) in Costa Rican dry forest. Vida Silvestre Neotropical 2: 6–20.Google Scholar

Merriam, C. H. (1901). Six new mammals from Cozumel Island, Yucatán. Proceedings of the Biological Society of Washington XIV: 99–104.Google Scholar

Naranjo, E. J. (2002). Population ecology and conservation of ungulates in the Lacandon forest, México. PhD dissertation, The University of Florida, Gainesville, Florida.Google Scholar

Nava, A. & Cullen, L. (2003). Peccaries as sentinel species: conservation, health and training in Atlantic Forest Fragments, Brazil. Suiform Soundings 3(2).Google Scholar

Oldenburg, P. W., Ettestad, P.J., Grant, W.E. & Davis, E. (1985). Size, overlap and temporal shifts of collared peccary herd territories in South Texas. Journal of Mammalogy 66: 378–380.Google Scholar

Peres, C. A. (1996). Population status of white-lipped Tayassu pecari and collared peccaries T. tajacu in hunted and unhunted Amazonian forest. Biological Conservation 77: 115–123.Google Scholar

Peres, C. A. & Palacios, E. (2007). Basin-wide effects of game harvest on vertebrate population densities in Amazonian forests: implications for animal-mediated seed dispersal. Biotropica 39: 304–315.Google Scholar

Pérez-Cortéz, S. & Reyna-Hurtado, R. (2008). La dieta de los pecaríes (Pecari tajacu y Tayassu pecari) en la región de Calakmul, Campeche, México. Revista Mexicana de Mastozoología 12: 17–42.Google Scholar

Reider, K. E., Carson, W. P. & Donnelly, M. A. (2013). Effects of collared peccary (Pecari tajacu) exclusion on leaf litter amphibians and reptiles in a Neotropical wet forest, Costa Rica. Biological Conservation 163: 90–98.Google Scholar

Reyna-Hurtado, R. & Tanner, G. W. (2007). Ungulate relative abundance in hunted and non-hunted sites in Calakmul Forest (Southern Mexico). Biodiversity and Conservation 16: 743–757.Google Scholar

Robinson, J. G. & Eisenberg, J. F. (1985). Group size and foraging habits of the collared peccary (Tayassu tajacu). Journal of Mammalogy 66: 153–155.Google Scholar

Robinson, J. G. & Redford, K. (1986). Body size, diet and population density of Neotropical forest mammals. American Naturalist 128: 665–680.Google Scholar

Romero, A., O'Neill, B. J., Timm, R. M., Gerow, K. G. & McClearn, D. (2013). Group dynamics, behavior, and current and historical abundance of peccaries in Costa Rica's Caribbean lowlands. Journal of Mammalogy 94: 771–791.Google Scholar

Ruvinsky, A., Rothschild, M., Larson, G. & Gongora, J. (2011). Systematics and evolution of the pig. In Rothschild, M. F. & Ruvinsky, A. (eds.), The genetics of the pig. 2nd ed. Wallingford: CABI Publishing, pp. 1–13.Google Scholar

Sabogal, R. & Sandra, P. (2011). Filogeografía y conservación genética del pecarí de collar, Pecari tajacu en cuatro departamentos de Colombia[Phylogeography and conservation genetics of collared peccari, Pecari tajacu in four Colombian departments]. Maestría thesis, Universidad Nacional de Colombia. www.bdigital.unal.edu.co/4000/#sthash.i2Bzt85s.dpuf Google Scholar

Schaller, G. B. (1983). Mammals and their biomass on a Brazilian ranch. Arquivos de Zoologia (Sao Paulo) 31: 1–36.Google Scholar

Schweinsburg, R. E. (1971). The home ranges and herd integrity of the collared peccary. Journal of Wildlife Management 35: 455–460.Google Scholar

Schweinsburg, R. E. & Sowls, L. K. (1972). Aggressive behavior and related phenomena in the collared peccary. Tierpsychol 30: 132–145.Google Scholar

Sowls, K. (1997). Javelines and other peccaries. Their biology management and use. 2nd ed. Tucson, AZ: Texas A & M University Press, p. 325.Google Scholar

Stangl, F. B. & Dalquest, W. W. (1990). Status of the javelina Tayassu tajacu in north-central Texas and Southern Oklahoma. Texas Journal of Science 42: 305–306.Google Scholar

Supple, V. C. (1983). The dynamics of collared peccary dispersion into available range. Federal Aid in Wildlife Restoration Project W-78-Arizona Game and Fish Department, Phoenix, AZ. 31 pp.Google Scholar

Taber, A. B., Doncaster, C. P., Neris, N. N. & Coleman, F. H. (1994). Ranging behavior and activity patterns of two sympatric peccaries, Catagonus wagneri and Tayassu tajacu in the Paraguayan Chaco. Mammalia 58: 61–71.Google Scholar

Taber, A., Altrichter, M., Harald, B. & Gongora, J. (2011). Family Tayassuidae (peccaries). In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world - volume 2: hoofed mammals. Barcelona: Lynx Editions, pp. 292–307.Google Scholar

Weber, M. (2000). Effects of hunting on tropical deer populations in Southeastern México. MSc thesis, London: Royal Veterinary College, University of London.Google Scholar

References

Almeida-Jácomo, A. T. (2004). Ecologia manejo e conservação do queixada Tayassu pecari no Parque Nacional das Emas e em propiedades rurais de seu entorno. PhD dissertation. Brasília: Universidade de Brasília.Google Scholar

Altrichter, M. (2005). The sustainability of subsistence hunting of peccaries in the Argentine Chaco. Biological Conservation 126: 351–362.Google Scholar

Altrichter, M. (2006). Wildlife in the life of local people in the Argentine Chaco. Biodiversity and Conservation 15: 2719–2736.Google Scholar

Altrichter, M. & Almeida, R. (2002). Exploitation of white-lipped peccaries (Tayassu pecari) on the Osa Peninsula, Costa Rica. Oryx 36: 126–131.Google Scholar

Altrichter, M. & Almeida, R. (2009). White-lipped peccaries have personal guards in the Osa Peninsula, Costa Rica. Suiform Soundings 9: 8.Google Scholar

Altrichter, M. & Boaglio, G. (2004). Distribution and abundance of peccaries in the Argentinean Chaco: its associations with human factors. Biological Conservation 116: 217–225.Google Scholar

Altrichter, M., Sáenz, J. C., Carrillo, E. & Fuller, T. K. (2000). Dieta estacional del Tayassu peccari (Artiodactyla: Tayassuidae) en el Parque Nacional Corcovado, Costa Rica. Revista de Biología Tropical 48: 689–702.Google Scholar

Altrichter, M., Drews, C., Sáenz, J. & Carrillo, E. (2001a). Sex ratio and breeding of white-lipped peccary (Tayassu pecari) in a Costa Rican rain forest. Biología Tropical 49: 383–389.Google Scholar

Altrichter, M., Carrillo, E., Sáenz, J. & Fuller, T. (2001b). White-lipped peccary (Tayassu pecari, Artiodactyla: Tayassuidae) diet and fruit availability in a Costa Rican rain forest. Biología Tropical 49: 1183–1192.Google Scholar

Altrichter, M., Taber, A., Beck, H., et al. (2012). Range-wide declines for a key Neotropical ecosystem architect, the near threatened white-lipped peccary Tayassu pecari. Oryx 46: 87–98.Google Scholar

Andrade-Figueira, M. L., Orlandelli-Carrer, C. & Bezerra, P. (2003). Ganho de peso e evolução do rebanho de queixadas selvagens (Tayassu pecari) em sistemas de criação semi-extensivo e extensivo em Reserva do Cerrado. Revista Brasileira de Zootecnia 32: 191–199.Google Scholar

Beck, H. (2006). A review of peccary–palm interactions and their ecological ramifications across the Neotropics. Journal of Mammalogy 87: 519–530.Google Scholar

Beck, H. (2007). Synergistic impacts of ungulates and falling palm fronds on saplings in the Amazon. Journal of Tropical Ecology 23: 599–602.Google Scholar

Beck, H., Thebpanya, P. & Filiaggi, M. (2010). Do Neotropical peccary species (Tayassuidae) function as ecosystem engineers for anurans? Journal of Tropical Ecology 26: 407–414.Google Scholar

Beck, H., Snodgrass, J. & Thebpanya, P. (2013). Long-term exclosure of large terrestrial vertebrates: implications of defaunation for seedling demographics in the Amazon rainforest. Biological Conservation 163: 115–121.Google Scholar

Benirschke, K. & Kumamoto, A. T. (1989). Further studies on the chromosomes of three species of peccary. In Redford, K. H. & Eisenberg, J. F. (eds.), Advances in neotropical mammalogy. Gainesville, FL: Sandhill Crane Press, pp. 309–316.Google Scholar

Biondo, C., Keuroghlian, K., Gongora, J. & Miyaki, C. Y. (2011). Population genetic structure and dispersal in the white-lipped peccaries (Tayassu pecari) from the Brazilian Pantanal. Journal of Mammalogy 92: 267–274.Google Scholar

Bodmer, R. E. (1989). Frugivory in Amazonian artiodactyla: evidence for the evolution of ruminant stomach. Journal of Zoology 219: 457–467.Google Scholar

Bodmer, R. E. (1991a). Strategies of seed dispersal and seed predation in Amazonian ungulates. Biotropica 23: 255–261.Google Scholar

Bodmer, R. E. (1991b). Influence of digestive morphology on resource partitioning in Amazonian ungulates. Oecologia 85: 361–365.Google Scholar

Carrillo, E., Saenz, J. C. & Fuller, T. K. (2002). Movements and activities of white-lipped peccaries in Corcovado National Park, Costa Rica. Biological Conservation 108: 317–324.Google Scholar

Crandall, L. S. (1964). The management of wild mammals in captivity. Chicago, IL: University of Chicago Press.Google Scholar

Cullen, L. (1997). Hunting and biodiversity in Atlantic forest fragments, Sao Paulo, Brazil. Msc thesis. Gainesville, FL: University of Florida.Google Scholar

Cullen, L. Jr., Bodmer, R. E. & Valladares-Pádua, C. (2001). Ecological consequences of hunting in Atlantic forest patches, Sao Paulo, Brazil. Oryx 35: 137–144.Google Scholar

Dalila, A. L., Rufo, A. D., Keuroghlian, A., Miyaki, Y. C. & Biondo, C. (2013). Análise do sistema de acasalamento de um mamífero sem dimorfismo sexual: a queixada (Tayassu pecari) [Mating system of a mammal without sexual dimorfism: white-lipped peccary (Tayassu pecari)]. XXXI Encontro Anual de Etologia IV Simposio Latino Americano de Etologia, 10–13 de Novembro 2013 Sao Paulo, S.P.Google Scholar

Desbiez, A., Donatti, C. I., Marquez, R. M., et al. (2004). Uso de Habitat e Densidades Populacionais de Queixadas, Catetos e Porcos-Monteiros em duas Áreas do Pantanal Brasileiro. In Libro de Resumenes VI Congresso Internacional sobre Manejo de Fauna Silvestre en la Amazonia y Latinoamerica. Iquitos, Peru. www.bio-nica.info/biblioteca/Unap2004ResumenesVICongresoFauna.pdf Google Scholar

Desbiez, A. L. J., Bodmer, R. E. & Tomas, W. M. (2010). Mammalian densities in a neotropical wetland subject to extreme climatic events. Biotropica 42: 372–378.Google Scholar

Dirzo, R., Young, H. S., Galetti, M., et al. (2014). Defaunation in the Anthropocene. Science 345: 401–406.Google Scholar

Ditt, E. H. (2002). Fragmentos florestais no pontal do paranapanema. Sao Paulo: Annablume Editora, Ipe, IIEB.Google Scholar

Estes, J. A., Terborgh, J., Brashares, J. S., et al. (2011). Trophic downgrading of planet Earth. Science 333: 301–306.Google Scholar

Estrada, N. (2005). Selección de hábitat y actividad diaria del chancho cariblanco Tayassu pecari en el Parque Nacional Corcovado: uso de trampas-cámara. MSc thesis. Heredia, Costa Rica: Universidad Nacional de Costa Rica.Google Scholar

Fairchild, G. B., Kohls, G. M. & Tipton, V. J. (1966). The ticks of Panama (Acarina: Ixodoidea). In Wenzel, R. L. & Tipton, V. J. (eds.), Ectoparacites of Panama. Chicago, IL: Chicago Field Museum, pp. 167–219.Google Scholar

Fang, T. G., Bodmer, R. E., Puertas, P. E., et al. (2008). Certificación de pieles pecaries en la Amazonia Peruana: Una estrategia para la conservación y manejo de fauna silvestre en la Amazonia Peruana. Lima: Wust Ediciones.Google Scholar

Fragoso, J. M. (1998). Home range and movement patterns of white-lipped peccary (Tayassu pecari) herds in the Northern Brazilian Amazon. Biotropica 30: 458–469.Google Scholar

Fragoso, J. M. (2004). A long-term study of white-lipped peccary (Tayassu pecari) population fluctuation in Northern Amazonia. In Silvius, K., Bodmer, R. E. & Fragoso, J. M. V. (eds.), People in nature, wildlife conservation in South and Central America. New York, NY: Columbia University Press, pp. 286–296.Google Scholar

Freitas, T. P. T., Keuroghlian, A., Eaton, D. P., et al. (2010). Prevalence of Leptospira interrogans antibodies in free-ranging Tayassu pecari of the Southern Pantanal, Brazil, an ecosystem where wildlife and cattle interact. Trop Anim Health Prod. DOI 10.1007/s11250-010-9622-2Google Scholar

Galetti, M., Camargo, H., Siqueira, T., et al. (2015a). Diet overlap and foraging activity between feral pigs and native peccaries in the Pantanal. PLoS ONE 10(11): e0141459. doi:10.1371/journal.pone.0141459.Google Scholar

Galetti, M., Guevara, R., Neves, C. L., et al. (2015b). Defaunation affect populations and diet of rodents in Neotropical rainforests. Biological Conservation 190: 2–7.Google Scholar

Gentry, A. H. (1988). Changes in plant community diversity and floristic composition on geographical and environmental gradients. Annals of the Missouri Botanical Garden 75: 1–34.Google Scholar

Giannoni, M. A., Ferrari, I. & Giannoni, M. L. (1981). Chromosome polymorphism among Brazilian populations of Tayassu albirostris (Peccary). Revista Brasileira de Genetica 4: 117–134.Google Scholar

Gongora, J. & Moran, C. (2005). Nuclear and mitochondrial evolutionary analyses of collared, white-lipped, and chacoan peccaries (Tayassuidae). Molecular Phylogenetics and Evolution 34: 181–189.Google Scholar

Gottdenker, N. L. & Bodmer, R. E. (1998). Reproduction and productivity of white-lipped and collared peccaries in the Peruvian Amazon. Journal of Zoology 245: 423–430.Google Scholar

Greenwood, P. J. (1980). Mating systems, philopatry and dispersal in birds and mammals. Animal Behaviour 28: 1140–1162.Google Scholar

Groves, C. P. & Grubb, P. (1993). The suborder Suiformes. In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN, pp. 1–4.Google Scholar

Groves, C. P. & Grubb, P. (2011). Ungulate taxonomy. Baltimore, MD: Johns Hopkins University Press.Google Scholar

Grubb, P. & Groves, C. P. (1993). The Neotropical tayassuids Tayassu and Catagonus. In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN, pp. 5–6.Google Scholar

Henderson, A. (1995). The palms of the Amazon. New York, NY: Oxford University Press.Google Scholar

Henderson, A. (2002). Evolution and ecology of palms. New York, NY: The New York Botanical Garden Press.Google Scholar

Hernandez, O. E., Barreto, G. R. & Ojasti, J. (1995). Observations of behavioural patterns of white-lipped peccaries in the wild. Mammalia 59: 146–148.Google Scholar

Herrera, H. M., Norek, A., Freitas, T. P. T., et al. (2005). Domestic and wild mammals infection by Trypanosoma evansi in a pristine area of the Brazilian Pantanal region. Parasitology Research 96: 121–126.Google Scholar

Herrera, H. M., Abreu, U. G. P., Keuroghlian, A., Freitas, T. P. & Jansen, A. (2008). The role played by sympatric collared peccary (Tayassu tajacu), white-lipped peccary (Tayassu pecari), and feral pig (Sus scrofa) as maintenance hosts for Trypanosoma evansi and Trypanosoma cruzi in a sylvatic area of Brazil. Parasitology Research 103: 619–624.Google Scholar

Herring, S. W. (1972). The role of canine morphology in the evolutionary divergence of pigs and peccaries. Journal of Mammalogy 53: 500–512.Google Scholar

Iidiaques, A. G. (1978). Mamíferos de mi tierra. Tegucigala, Honduras: Lopez and Compania.Google Scholar

Izawa, K. & Kobayashi, M. (1997). Seed dispersal of the monocarpic herbaceous bamboo Pharus virescens (Poaceae: Bambusoideae) found in the Neotropical rain forest of La Macarena and Tinigua National Parks of Colombia. Tropics 7: 153–159.Google Scholar

Jacamo, A. T. A., Furtado, M. M. & Kashivakura, C. K. (2013). White-lipped peccary home-range size in a protected area and farmland in the central Brazilian grasslands. Journal of Mammalogy 94: 137–145.Google Scholar

Jones, C. G., Lawton, J. H. & Shachakm, M. (1994). Organisms as ecosystem engineers. Oikos 69: 373–386.Google Scholar

Kahn, F. (1991). Palms as key swamp forest resources in Amazonia. Forest Ecology and Management 38: 133–142.Google Scholar

Keuroghlian, A. & Desbiez, A. L. J. (2010). Biometric and age estimation of live peccaries in the Southern Pantanal, Brazil. Suiform Soundings 9: 24–35.Google Scholar

Keuroghlian, A. & Eaton, D. P. (2008a). Importance of rare habitats and riparian zones in a tropical forest fragment: preferential use by Tayassu pecari, a wide-ranging frugivore. Journal of Zoology 275: 283–293.Google Scholar

Keuroghlian, A. & Eaton, D. P. (2008b). Fruit availability and peccary frugivory in an isolated Atlantic forest fragment: effects on peccary ranging behavior and habitat use. Biotropica 40: 62–70.Google Scholar

Keuroghlian, A. & Eaton, D. P. (2009). Removal of palm fruits and ecosystem engineering in palm stands by white-lipped peccaries (Tayassu pecari) and other frugivores in an isolated Atlantic Forest fragment. Biodiversity and Conservation 18: 1733–1750.Google Scholar

Keuroghlian, A., Eaton, D. P. & Desbiez, A. L. J. (2009). The response of a landscape species, white-lipped peccaries, to seasonal resource fluctuations in a tropical wetland, the Brazilian Pantanal. International Journal of Biodiversity and Conservation 1: 87–97.Google Scholar

Keuroghlian, A., Desbiez, A. L. J., Beisiegel, B. M., et al. (2012). Avaliação do Risco de Extinção do queixada, Tayassu pecari (Link, 1795) no Brasil. Biodiversidade Brasileira 3: 84–102.Google Scholar

Keuroghlian, A., Desbiez, A., Reyna-Hurtado, R., et al. (2013). Tayassu pecari. The IUCN Red List of Threatened Species 2013.Google Scholar

Keuroghlian, A., Santos, M. C. A. & Eaton, D. P. (2015). The effects of deforestation on white-lipped peccary (Tayassu pecari) home range in the southern Pantanal. Mammalia 70: 491–497.Google Scholar

Kiltie, R. A. (1981a). Stomach contents of rain forest peccaries (Tayassu tajacu and T. pecari). Biotropica 13: 234–236.Google Scholar

Kiltie, R. A. (1981b). Distribution of palm fruits on a rain forest floor: why white-lipped peccaries forage near objects. Biotropica 13: 141–145.Google Scholar

Kiltie, R. A. (1981c). The function of interlocking canines in rain forest peccaries (Tayassuidae). Journal of Mammalogy 62: 459–469.Google Scholar

Kiltie, R. A. (1982). Bite force as a basis for niche differentiation between rain forest peccaries (Tayassu tajacu and T. pecari). Biotropica 14: 188–195.Google Scholar

Kiltie, R. A. & Terborgh, J. (1983). Observation on the behavior of rain forest peccaries in Peru: why do white-lipped peccaries form herds? Zeitschrift fuer Tierpsychologie 62: 241–255.Google Scholar

Leopold, A. S. (1959). Wildlife of Mexico, the game birds and mammals. Berkeley, CA: University of California Press.Google Scholar

Lopez, M. T., Altrichter, M., Eduarte, E. & Sáenz, J. (2006). Nutritional aspects of the diet of the white-lipped peccary Tayassu pecari in Corcovado National Park, Costa Rica. Biología Tropical 54: 687–700.Google Scholar

Maffei, L. F. (2003). Age structure of two hunted peccary species in the Bolivian Chaco (Tayassu tajacu and T. pecari). Mammalia 67: 575–578.Google Scholar

March, M.I. J. (1993). The white-lipped peccary (Tayassu pecari). In Oliver, W. L. R. (ed.), Pigs, peccaries, and hippos: status survey and conservation action plan. Gland: IUCN, World Conservation Union, pp. 7–13.Google Scholar

Mayer, J. J. & Wetzel, R. M. (1987). Tayassu peccary. Mammalian Species 293: 1–7.Google Scholar

Mayor, P., Bodmer, R. E. & López-Béjar, M. (2009). Reproductive performance of the white-lipped peccary (Tayassu pecari) female in the Peruvian Amazon. European Journal of Wildlife Research 55: 631–634.Google Scholar

Mayor, P., Bodmer, R. E. & Lopez-Bejar, M. (2010). Reproductive performance of the wild white-lipped peccary (Tayassu pecari) female in the Peruvian Amazon. European Journal of Wildlife Research 56: 681–684.Google Scholar

Mendez, E. (1970). Los principals mamíferos silvestres de Panama. Panama: Zoología Laboratorio Conmemorativo Gorgas.Google Scholar

Moreira-Ramírez, J. (2009). Patrones diarios de actividad, composición, tamaño y abundancia relativa de manadas de jabalí Tayassu pecari (Link, 1795), en el Parque Nacional Mirador-Río Azul, Petén, Guatemala. Tesis de Licenciatura. Ciudad de Guatemala, Guatemala: Universidad de San Carlos de Guatemala.Google Scholar

Naranjo, E. J. (2002). Population ecology and conservation of ungulates in the Lacandon forest, Mexico. PhD dissertation. Gainesville, FL: The University of Florida.Google Scholar

Nogueira, S. S. C., Macêdo, J. F., Sant'Anna, A. C., et al. (2015). Assessment of temperament traits of white-lipped (Tayassu pecari) and collared peccaries (Pecari tajacu) during handling in a farmed environment. Animal Welfare 24: 291–298.Google Scholar

Nowak, R. M. (1991). Walker's mammals of the World: III. Baltimore, MD: Johns Hopkins Press.Google Scholar

Painter, L. R. E. (1998). Gardeners of the forest: plant–animal interactions in a Neotropical forest ungulate community. PhD dissertation. Liverpool: University of Liverpool.Google Scholar

Peres, C. A. (1994). Composition, density, and fruiting phenology of arborescent palms in an Amazonian Terra Firme Forest. Biotropica 26: 285–294.Google Scholar

Peres, C. A. (1996). Population status of white-lipped (Tayassu pecari) and collared peccaries (T. tajacu) in hunted and unhunted Amazonian forest. Biological Conservation 77: 115–123.Google Scholar

Pitman, N. C. A., Terborgh, J., Silman, M. R., et al. (2001). Dominance and diversity of tree species in upper Amazonian terra firme forests. Ecology 82: 2101–2117.Google Scholar

Reyna-Hurtado, R. (2007). Social ecology of the white-lipped peccary (Tayassu pecari) in Calakmul Forest, Campeche, Mexico. Gainesville, FL: University of Florida.Google Scholar

Reyna-Hurtado, R. & Tanner, G. W. (2007). Ungulate relative abundance in hunted and non-hunted sites in Calakmul Forest (Southern Mexico). Biodiversity and Conservation 16: 743–756.Google Scholar

Reyna-Hurtado, R., Rojas-Flores, E. & Tanner, G. W. (2009). Home range and habitat preferences of white-lipped peccaries (Tayassu pecari) in Calakmul, Campeche, Mexico. Journal of Mammalogy 90: 1199–1209.Google Scholar

Reyna-Hurtado, R., Naranjo, E., Chapman, C. A. & Tanner, G. W. (2010). Hunting patterns, population density, group size, and conservation of the white-lipped peccary (Tayassu pecari) in the Calakmul region of Mexico. Oryx 44: 88–96.Google Scholar

Reyna-Hurtado, R., Chapman, C. A., Calme, S. & Pedersen, E. (2012). Searching in heterogeneous environments: foraging strategies in the white-lipped peccary (Tayassu pecari). Journal of Mammalogy 93: 124–133.Google Scholar

Reyna-Hurtado, R., Beck, H., Altrichter, M., et al. (2015). What ecological and anthropogenic factors affect group size in white-lipped peccaries (Tayassu pecari)? Biotropica 48: 246–254.Google Scholar

Richard-Hansen, C., Surugue, N., Khazraie, K., Le Noc, M. & Grenand, P. (2014). Long-term fluctuations of white-lipped peccary populations in French Guiana. Mammalia 78: 291–301.Google Scholar

Ripple, W. J., Estes, J. A., Beschta, R. L., et al. (2014). Status and ecological effects of the world's largest carnivores. Science 343: 1241484.Google Scholar

Rivera, C. J. (2014). Facing the 2013 gold rush: a population viability analysis for the endangered white-lipped peccary (Tayassu pecari) in Corcovado National Park, Costa Rica. Natural Resources 5: 1007–1019.Google Scholar

Roots, C. G. (1966). Notes on the breeding of white-lipped peccaries Tayassu albirostis at Dudley Zoo. International Zoo Yearbook.Google Scholar

Ruiz-García, M., Pinedo-Castro, M., Luengas-Villamil, K., et al. (2015). Molecular phylogenetics of the white-lipped peccary (Tayassu pecari) did not confirm morphological subspecies in northwestern South America. Genetics and Molecular Research 2: 5355–5378.Google Scholar

Saenz, J. C. & Carrillo, E. (1999). Ecologia y conservacion del chanchos de monte (Tayassu pecari) en el parque Nacional Corcovado, Costa Rica. In Aquino, A. L., Bodmer, R. E. & Yanosky, A. (Eds.), Libro de resumenes del IV Congresso Internacional sobre Manejo de Fauna Silvestre en la Amazonia y Latino America, Asuncion-Paraguay, p. 90.Google Scholar

Sánchez, P., Montenegro, O. & Gómez, B. (2009). Geographic size variation of peccaries (Tayassu pecari and Pecari tajacu) in Colombia. 10th International Mammalogical Congress Abstracts: Mendoza, Argentina, 9–14 August 2009. Abstract, p. 245.Google Scholar

Schmidt, C. R. (1990). Monographie des Halsband-pekaris (Tayassu tajacu). Bongo, Frädrich-Jubiläumsband 18: 171–190.Google Scholar

Secretaría de Medio Ambiente, Recursos Naturales (SEMARNAT). (2010). Norma Oficial Mexicana NOM-059-ECOL-2010. Protección ambiental, especies de flora y fauna silvestres de México, categorías de riesgo y especificaciones para su inclusión, exclusión o cambio, y lista de especies en riesgo. Diario Oficial de la Federación, Jueves 30 de diciembre de 2010. 1: 1–77.Google Scholar

Silman, M. R., Terborgh, J. W. & Kiltie, R. A. (2003). Population regulation of a dominant rain forest tree by a major seed predator. Ecology 84: 431–438.Google Scholar

Sowls, L. K. (1984). The peccaries. Tucson, AZ: University of Arizona Press.Google Scholar

Sowls, L. K. (1997). Javelinas and other peccaries. College Station, TX: Texas A & M University Press.Google Scholar

Taber, A., Altrichter, M., Beck, H. & Gongora, J. (2011). The Tayassuidae. In Wilson, D. E. & Mittermeier, R. A. (eds.), Handbook of the mammals of the world: Volume 2: hoofed mammals. Barcelona: Lynx Edicions, pp. 292–307.Google Scholar

Terborgh, J., Foster, R. B. & Nuòez, P. V. (1996). Tropical tree communities: a test of the nonequilibrium hypothesis. Ecology 77: 561–567.Google Scholar

Terborgh, J., Nuñez-Iturri, G., Pitman, N. C. A., et al. (2008). Tree recruitment in an empty forest. Ecology 89: 1757–1768.Google Scholar

Vickers, W. T. (1991). Hunting yields and game composition over ten years in an Amazon Indian territory. In Robinson, J. G. & Redford, K. (eds.), Neotropical wildlife use and conservation. Chicago, IL: The University of Chicago Press.Google Scholar

Book contents

Part II - Species Accounts

Summary

Access options

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive