Book contents
- The Living Planet
- The Living Planet
- Copyright page
- Contents
- Contributors
- Preface
- Acknowledgements
- One Introduction and the Evolution of Life on Earth
- Two Flowering Plants
- Three Bryophytes and Pteridophytes: Spore-Bearing Land Plants
- Four Terrestrial Mammals
- Five Marine Mammals: Exploited for Millennia, But Still Holding On
- Six How Birds Reveal the Scale of the Biodiversity Crisis
- Seven Reptiles
- Eight Amphibians
- Nine Freshwater Fishes: Threatened Species and Threatened Waters on a Global Scale
- Ten The Amazing Yet Threatened World of Marine Fishes
- Eleven Insects
- Twelve Marine Invertebrates
- Thirteen Non-Insect Terrestrial Arthropods
- Fourteen Terrestrial Invertebrates Other Than Arthropods and Molluscs
- Fifteen Non-Marine Molluscs
- Sixteen An Account of the Diversity and Conservation of Fungi and Their Close Relatives
- Seventeen Simple Life Forms
- Eighteen Assessing Species Conservation Status: The IUCN Red List and Green Status of Species
- Nineteen Problems with the World’s Ecosystems: The Future and Attempts to Mitigate Decline
- Twenty Conservation Methods and Successes
- Twenty One What Does the Future Hold for Our Planet and its Wildlife?
- Species Index
- Subject Index
- References
Three - Bryophytes and Pteridophytes: Spore-Bearing Land Plants
Published online by Cambridge University Press: 13 April 2023
By
Edited by
Book contents
- The Living Planet
- The Living Planet
- Copyright page
- Contents
- Contributors
- Preface
- Acknowledgements
- One Introduction and the Evolution of Life on Earth
- Two Flowering Plants
- Three Bryophytes and Pteridophytes: Spore-Bearing Land Plants
- Four Terrestrial Mammals
- Five Marine Mammals: Exploited for Millennia, But Still Holding On
- Six How Birds Reveal the Scale of the Biodiversity Crisis
- Seven Reptiles
- Eight Amphibians
- Nine Freshwater Fishes: Threatened Species and Threatened Waters on a Global Scale
- Ten The Amazing Yet Threatened World of Marine Fishes
- Eleven Insects
- Twelve Marine Invertebrates
- Thirteen Non-Insect Terrestrial Arthropods
- Fourteen Terrestrial Invertebrates Other Than Arthropods and Molluscs
- Fifteen Non-Marine Molluscs
- Sixteen An Account of the Diversity and Conservation of Fungi and Their Close Relatives
- Seventeen Simple Life Forms
- Eighteen Assessing Species Conservation Status: The IUCN Red List and Green Status of Species
- Nineteen Problems with the World’s Ecosystems: The Future and Attempts to Mitigate Decline
- Twenty Conservation Methods and Successes
- Twenty One What Does the Future Hold for Our Planet and its Wildlife?
- Species Index
- Subject Index
- References
Summary
Spore-bearing land plants are much fewer in number than flowering plants, with around 20,000 bryophytes and 12,000 pteridophytes, but they have a much longer history, with the first recognisable land plant fossil dating from the Silurian. Bryophytes and pteridophytes are not a significant food source for man, nor do they provide essential commodities like timber or cloth, but they have a significant role in maintaining healthy ecosystems and storing carbon, and bryophytes deliver key ecological functions in arctic, boreal and peatland ecosystems. The major threats to bryophytes and pteridophytes are habitat loss and climate change, followed by overexploitation. Global conservation assessments are available for just 1.5 percent of bryophyte species and 5.7 percent of pteridophytes. However, progress towards an accessible worldwide flora is growing through international collaboration and coordination, and molecular studies are increasing understanding of relationships between species, genera and families.
- Type
- Chapter
- Information
- The Living PlanetThe State of the World's Wildlife, pp. 37 - 64Publisher: Cambridge University PressPrint publication year: 2023
References
Alatalo, J.M., Jägerbrand, A.K., Erfanian, M.B., et al. (2020) Bryophyte cover and richness decline after 18 years of experimental warming in alpine Sweden. AoB Plants 12(6): plaa061.Google Scholar
Alexander, P.D., Bragg, N.C., Meade, R., Padelopoulos, G. and Watts, O. (2008) Peat in horticulture and conservation: the UK response to a changing world. Mires and Peat 3: 08.Google Scholar
Antonovics, J. (2020) Pathogenic fungi in ferns and angiosperms: a comparative study. Amer Fern J 110: 79–94.Google Scholar
Aros-Mualin, D., Noben, S., Karger, D.N., et al. (2021) Functional diversity in ferns is driven by species richness rather than by environmental constraints. Front Plant Sci 11: 615723.Google Scholar
Ayres, P.G. (2015) Isaac Bayley Balfour, Sphagnum moss, and the Great War (1914–1918). Arch Nat Hist 42(1): 1–9.Google Scholar
Bachman, S., Nic Lughadha, E.M. and Rivers, M.C. (2018) Quantifying progress toward a conservation assessment for all plants. Conserv Biol 32(3): 516–524.Google Scholar
Bain, C.G., Bonn, A., Stoneman, R., et al. (2011) IUCN UK Commission of Inquiry on Peatlands. IUCN UK Peatland Programme. Edinburgh: IUCN.Google Scholar
Barthlott, W., Hostert, A., Kier, G., et al. (2007) Geographic patterns of vascular plant diversity at continental to global scales. Erdkunde 61(4): 305–315.Google Scholar
Biersma, E.M., Jackson, J.A., Hyvönen, J., et al. (2017) Global biogeographic patterns in bipolar moss species. Royal Soc Open Sci 4: 170147.Google Scholar
Bowd, E.J., Lindenmayer, D.B., Banks, S.C. and Blair, D.P. (2018) Logging and fire regimes alter plant communities. Ecol Appl 28(3): 826–841.Google Scholar
Brummitt, N. Aletrari, E., Syfert, M.M. and Mulligan, M. (2016) Where are threatened ferns found? Global conservation priorities for pteridophytes. J Syst Evol 54(6): 604–616.Google Scholar
CAFF (Conservation of Arctic Fauna and Flora) (2013) Chapter 9: Plants. In: Arctic Biodiversity Assessment 2013. Akureyri, Iceland: CAFF.Google Scholar
CAFF (Conservation of Arctic Fauna and Flora) (2021) State of the Arctic Terrestrial Biodiversity: Key Findings and Advice for Monitoring. Akureyri, Iceland: CAFF.Google Scholar
Cámara-Leret, R., Frodin, D.G., Adema, F., et al. (2020) New Guinea has the world’s richest island flora. Nature 584 : 579–583.Google Scholar
Carter, B. (2012) Species delimitation and cryptic diversity in the moss genus Scleropodium (Brachytheciaceae). Mol Phylogenet Evol 63(3): 891–903.CrossRefGoogle ScholarPubMed
Cooper-Driver, G. (1985) Anti-predation strategies in pteridophytes: a biochemical approach. Proc Roy Soc Edinburgh 86B: 397–402.Google Scholar
Crump, J. (Ed.) (2017) Smoke on Water: Countering Global Threats From Peatland Loss and Degradation. A UNEP Rapid Response Assessment. Nairobi, Kenya and Arendal, Norway: United Nations Environment Programme and GRID-Arendal.Google Scholar
Cruz de Carvalho, R., Maurício, A., Pereira, M.F., Marques da Silva, J. and Branquinho, C. (2019) All for one: the role of colony morphology in bryophyte desiccation tolerance. Front Plant Sci 10: 1360.CrossRefGoogle ScholarPubMed
Da Silva, A.A., Pereira, A.F. de N. and Barros, I.C.L. (2014) Fragmentation and loss of habitat: consequences for the fern communities in Atlantic forest remnants in Alagoas, north-eastern Brazil. Plant Ecol Divers 7(4): 509–517.Google Scholar
Dauphin, B. Farrar, D.R., Maccagni, A. and Grant, J.R. (2017) A worldwide molecular phylogeny provides new insight on cryptic diversity within the moonworts (Botrychium s. s., Ophioglossaceae). Syst Bot 42(4): 620–639.Google Scholar
Davey, M.L. and Currah, R.S. (2006) Interactions between mosses (Bryophyta) and fungi. Canada J Bot 84: 1509–1519.CrossRefGoogle Scholar
Edwards, D., Feehan, J. and Smith, D.G. (1983) A late Wenlock flora from Co. Tipperary, Ireland. Bot J Linn Soc 86(1–2): 19–36.CrossRefGoogle Scholar
FAO and UNEP. (2020) The State of the World’s Forests 2020: Forests, biodiversity and people. Rome: FAO and UNEP.Google Scholar
Farrar, D.R. (1974) Gemmiferous fern gametophytes: Vittariaceae. Am J Bot 61: 146–155.Google Scholar
Feldberg, K, Schneider, H., Stadler, T., et al. (2014) Epiphytic leafy liverworts diversified in angiosperm-dominated forests. Sci Rep 4: 5974.Google Scholar
Fenton, N.J. and Bergeron, Y. (2008) Does time or habitat make old-growth forests species rich? Bryophyte richness in boreal Picea mariana forests. Biol Conserv 141: 1389–1399.Google Scholar
Flagmeier, M., Squirrell, J., Woodhead, M., et al. (2020) Globally rare oceanic-montane liverworts with disjunct distributions: evidence for long-distance dispersal. Biodivers Conserv 29: 3245–3264.CrossRefGoogle Scholar
Frahm, J.-P. (2008) Diversity, dispersal and biogeography of bryophytes (mosses). Biodivers Conserv 17: 277–284.Google Scholar
Frahm, J.-P. and Ohlemüller, R. (2001) Ecology of bryophytes along altitudinal and latitudinal gradients in New Zealand: Studies in austral temperate rain forest bryophytes 15. Trop Bryol 20: 117–137.Google Scholar
García Criado, M., Väre, H., Nieto, A., et al. (2017) European Red List of Lycopods and Ferns. Brussels, Belgium: IUCN.Google Scholar
Geffert, J.L., Frahm, J.P., Barthlott, W. and Mutke, J. (2013) Global moss diversity: spatial and taxonomic patterns of species richness. J Bryol 35: 1–11.Google Scholar
Geiger, J.M.O., Ranker, T.A., Ramp Neale, J.M. and Klimas, S.T. (2007) Molecular biogeography and origins of the Hawaiian fern flora. Brittonia 59: 142–158.Google Scholar
Glime, J.M. (2017) Light: reflectance and fluorescence. In: Glime, J.M. (Ed.), Bryophyte Ecology, Volume 1: Physiological Ecology. Ebook available at http://digitalcommons.mtu.edu/bryophyte-ecology/ (accessed September 2022).Google Scholar
Goffinet, B. and Shaw, A.J. (Eds.) (2008) Bryophyte Biology, Second Edn. Cambridge, UK: Cambridge University Press.Google Scholar
Harmens, H., Norris, D.A., Steinnes, E., et al. (2010) Mosses as biomonitors of atmospheric heavy metal deposition: spatial patterns and temporal trends in Europe. Environ Pollut 158(10): 3144–3156.Google Scholar
Hawkins, J. (2019) Tasmanian tree ferns…an indicator of corruption? Tasmanian Times, 5 February. www.tasmaniantimes.com/2019/02/tasmanian-tree-ferns-an-indicator-of-corruption/ (accessed September 2022).Google Scholar
Heim, R.J., Bucharova, A., Brodt, L., et al. (2021) Post-fire vegetation succession in the Siberian subarctic tundra over 45 years. Sci Total Environ 760(2021): 143425.Google Scholar
Hillebrand, H. (2004) On the generality of the latitudinal diversity gradient. Am Nat 163(2): 192–211.Google Scholar
Hodgetts, N., Cálix, M., Engleeld, E., et al. (2019) A Miniature World in Decline: European Red List of Mosses, Liverworts and Hornworts. Brussels, Belgium: IUCN.Google Scholar
Hollingsworth, P.M., Li, D., VanderBank, M. and Twyford, A.D. (2016) Telling plant species apart with DNA: from barcodes to genomes. Philos Trans R Soc B 371: 20150338.Google Scholar
Hugelius, G., Loisel, J., Chadburn, S., et al. (2020) Large stocks of peatland carbon and nitrogen are vulnerable to permafrost thaw. PNAS 117(34): 20438–20446.Google Scholar
Ingimundardóttir, G.V., Weibull, H. and Cronberg, N. (2014) Bryophyte colonization history of the virgin volcanic island Surtsey, Iceland. Biogeosciences 11: 4415–4427.Google Scholar
IPCC. (2019) Summary for Policymakers. In: Shukla, P.R., Skea, J., Calvo Buendia, E., et al. (Eds.), Climate Change and Land: An IPCC Special Report on Climate Change, Desertification, Land Degradation, Sustainable Land Management, Food Security, and Greenhouse Gas Fluxes in Terrestrial Ecosystems. Geneva, Switzerland: IPCC.Google Scholar
Johnson, G.N., Rumsey, F.J., Headley, A.D. and Sheffield, E. (2000) Adaptations to extreme low light in the fern Trichomanes speciosum. New Phytol 148: 423–431.Google Scholar
Kauserud, H., Mathiesen, C. and Ohlson, M. (2008) High diversity of fungi associated with living parts of boreal forest bryophytes. Botany 86:1326–1333.Google Scholar
Kenrick, P. and Crane, P.R. (1997) The Origin and Early Diversification of Land Plants: A Cladistics Study. Washington, DC: Smithsonian Institution Press.Google Scholar
Kreft, H., Jetz, W., Mutke, J. and Barthlott, W. (2010) Contrasting environmental and regional effects on global pteridophyte and seed plant diversity. Ecography 33: 408e419.Google Scholar
Laenen, B., Shaw, B., Schneider, H., et al. (2014) Extant diversity of bryophytes emerged from successive post-Mesozoic diversification bursts. Nat Commun 5: 5134.Google Scholar
Lee, W.G. (2001) Negative effects of introduced plants, II.B. Salvinia molesta (Salviniaceae). In: Encyclopedia of Biodiversity. Cambridge, MA: Academic Press.Google Scholar
Lehtonen, S., Silvestro, D., Karger, D.N., et al. (2017) Environmentally driven extinction and opportunistic origination explain fern diversification patterns. Sci Rep 7(1): 4831.Google Scholar
Lindo, Z., Nilsson, M.-C. and Gundale, M.J. (2013) Bryophyte-cyanobacteria associations as regulators of the northern latitude carbon balance in response to global change. Glob Change Biol 19: 2022–2035.Google Scholar
Liu, Y., Johnson, M.G., Cox, C. J., et al. (2019) Resolution of the ordinal phylogeny of mosses using targeted exons from organellar and nuclear genomes. Nat Commun 10(1): 1485.CrossRefGoogle ScholarPubMed
Longton, R.E. (1992) Bryophyte vegetation in polar regions. In: Smith, A.J.E. (Ed.), Bryophyte Ecology. London, UK: Chapman & Hall.Google Scholar
MacArthur, R.H. and Wilson, E.O. 1967. The Theory of Island Biogeography. Princeton, NJ: Princeton University Press.Google Scholar
Mägdefrau, K. (1982) Life-forms of bryophytes. In: Smith, A.J.E. (Ed.), Bryophyte Ecology. London, UK: Chapman & Hall.Google Scholar
Mandl, N., Lehnert, M., Kessler, M. and Gradstein, S.R. (2010) A comparison of alpha and beta diversity patterns of ferns, bryophytes and macrolichens in tropical montane forests of southern Ecuador. Biodivers Conserv 19: 2359–2369.Google Scholar
Mateo, R.G., Broennimann, O., Normand, S., et al. (2016) The mossy north: an inverse latitudinal diversity gradient in European bryophytes. Sci Rep 6: 25546.Google Scholar
McHaffie, H. (2006) Alpine lady ferns: are they suffering with climate change? Pteridologist 4(5): 162–164.Google Scholar
Mehltreter, K., Walker, L. and Sharpe, J. (Eds). (2010) Fern Ecology. Cambridge, UK: Cambridge University Press.Google Scholar
Merced, A. and Renzaglia, K.S. (2017) Structure, function and evolution of stomata from a bryological perspective. Bryophyt Divers Evol 39: 7–20.Google Scholar
Minayeva, T., Bragg, O. and Sirin, A. (2016) Peatland biodiversity and its restoration. In: Bonn, A., Allott, T., Evans, M., Joosten, H. and Stoneman, R. (Eds.), Peatland Restoration and Ecosystem Services: Science, Policy and Practice (Ecological Reviews). Cambridge, UK: Cambridge University Press.Google Scholar
Morris, J.L., Puttick, M.N., Clark, J.W., et al. (2018) The timescale of early land plant evolution. Proc Natl Acad Sci USA 115(10): E2274–E2283.Google Scholar
Mounce, R., Rivers, M., Sharrock, S., Smith, P. and Brockington, S. (2018) Comparing and contrasting threat assessments of plant species at the global and sub‐global level. Biodivers Conserv 27: 907–930.Google Scholar
Muir, P.S., Norman, K.N. and Sikes, K.G. (2006) Quantity and value of commercial moss harvest from forests of the Pacific Northwestern and Appalachian regions of the US. The Bryologist 109(2): 197–214.Google Scholar
Myers, N., Mittermeier, R. A., Mittermeier, C. G., Da Fonseca, G. A. and Kent, J. (2000) Biodiversity hotspots for conservation priorities. Nature 403(6772): 853–858.Google Scholar
Navarrete, H. and Pitman, N. (2003) Cyathea. In: IUCN 2010 Red List of Threatened Species. Gland, Switzerland: IUCN.Google Scholar
Nelson, K., Thompson, D., Hopkinson, C., Petrone, R. and Chasmer, L. (2021) Peatland-fire interactions: a review of wildland fire feedbacks and interactions in Canadian boreal peatlands. Sci Total Environ 769: 145212.Google Scholar
O’Neill, K.P. (2001) Role of bryophyte-dominated ecosystems in the global carbon budget. In: Shaw, A.J. and Goffinet, B. (Eds.), Bryophyte Biology. Cambridge, UK: Cambridge University Press.Google Scholar
Pampurova, S. and Van Dijck, P. (2014) The desiccation tolerant secrets of Selaginella lepidophylla: What we have learned so far? Plant Physiol Biochem 80: 285–290.Google Scholar
Patiño, J., Solymos, P., Carine, M. A., et al. (2015) Island floras are not necessarily more species poor than continental ones. J Biogeogr 42: 8–10.Google Scholar
Patiño, J., Mateo, R.G., Zanatta, F., et al. (2016) Climate threat on the Macaronesian endemic bryophyte flora. Sci Rep 6: 29156.Google Scholar
Patiño, J. and Vanderpoorten, A. (2018) Bryophyte biogeography, Crit Rev Plant Sci 37(2–3): 175–209.Google Scholar
Peck, J.L.E. and Frelich, L.E. 2008. Moss harvest truncates the successional development of epiphytic bryophytes in the Pacific northwest. Ecol Appl 18(1): 146–158.Google Scholar
Pisa, S., Biersma, E.M., Convey, P., et al. (2014) The cosmopolitan moss Bryum argenteum in Antarctica: recent colonisation or in situ survival? Polar Biol 37(10): 1469–1477.Google Scholar
PPG 1 (2016) A community-derived classification for extant lycophytes and ferns. J Syst Evol 54(6): 563–603.Google Scholar
Roth, S. (2002) Just a frond memory? The Guardian, 6 March. www.theguardian.com/society/2002/mar/06/highereducation.biologicalscience (accessed September 2022).Google Scholar
Rumsey, F.J., Vogel, J.C., Russell, S.J., Barrett, J.A. and Gibby, M. (1999) Population structure and conservation biology of the endangered fern Trichomanes speciosum Willd. (Hymenophyllaceae) at its northern distributional limit. Biol J Linn Soc 66: 333–344.Google Scholar
Schneider, H., Schuettpelz, E., Pryer, K.M., et al. (2004) Ferns diversified in the shadow of angiosperms. Nature 428(6982): 553–557.Google Scholar
Shaw, A.J., Cox, C. and Goffinet, B. (2005) Global patterns of moss diversity: taxonomic and molecular inferences. Taxon 4(2): 337–352.Google Scholar
Sheffield, E., Wolf, P.G. and Haufler, C.H. (1989) How big is a bracken plant? Weed Res 29: 455–460.Google Scholar
Smith, R.L. (2014) A fern cultured from Antarctic glacier detritus. Antarct Sci 26(4): 341–344.Google Scholar
Söderström, L., Hagborg, A., von Konrat, M., et al. (2016) World checklist of hornworts and liverworts. PhytoKeys 59: 1–821.Google Scholar
Suissa, J.S., Sundue, M.A. and Testo, W.L. (2021) Mountains, climate and niche heterogeneity explain global patterns of fern diversity. J Biogeogr 48(6): 1296–1308.Google Scholar
Travis, J.M.J. (2003) Climate change and habitat destruction: a deadly anthropogenic cocktail. Proc Royal Soc. B 270(1514): 467–473.Google Scholar
Tristan da Cunha Government & RSPB. (2012) Biodiversity Action Plan for the Tristan da Cunha Islands (2012–2016). Edinburgh of the Seven Seas, Tristan da Cunha, South Atlantic: Tristan Conservation Department.Google Scholar
Troudet, J., Grandcolas, P., Blin, A., Vignes-Lebbe, R. and Legendre, F. (2017) Taxonomic bias in biodiversity data and societal preferences. Sci Rep 7: 9132.Google Scholar
UNEP-WCMC. (2019) EU Wildlife Trade 2017: Analysis of the European Union’s Annual Reports to CITES 2017. Cambridge, UK: European Commission.Google Scholar
van Rooy, J., Bergamini, A. and Bisang, I. (2019) Fifty shades of red: lost or threatened bryophytes in Africa, Bothalia 49(1): a2341.Google Scholar
Villarreal, J.C., Cargill, D.C., Hagborg, A. Söderström, L. and Renzaglia, K.S. (2010) A synthesis of hornwort diversity: patterns, causes and future work. Phytotaxa 9: 150–166.Google Scholar
Villarreal, A.J.C., Crandall‐Stotler, B.J., Hart, M.L., Long, D.G. and Forrest, L.L. (2016) Divergence times and the evolution of morphological complexity in an early land plant lineage (Marchantiopsida) with a slow molecular rate. New Phytol 209: 1734–1746.Google Scholar
Vitt, D.H., Li, Y. and Belland, R.J. (1995) Patterns of bryophyte diversity in peatlands of continental western Canada. Bryologist 98: 218–227.Google Scholar
von Konrat, M., Söderström, L., Renner, M.A.M., Hagborg, A. and Briscoe, L. (2010) Early Land Plants Today (ELPT): how many liverwort species are there? Phytotaxa 9: 22–40.Google Scholar
Wagner, W.L., Herbst, D.R. and Lorence, D.H. (2005) Flora of the Hawaiian Islands. https://naturalhistory2.si.edu/botany/hawaiianflora/ (accessed September 2022).Google Scholar
Walker, D.A., Raynolds, M.K., Daniëls, F.J., et al.; CAVM Team. (2005) The Circumpolar Arctic vegetation map. J Veg Sci 16: 267–282.Google Scholar
Whiteley, J.A. and Gonzalez, A. (2016) Biotic nitrogen fixation in the bryosphere is inhibited more by drought than warming. Oecologia 181: 1243–1258.Google Scholar
Witze, A. (2020) The Arctic is burning like never before – and that’s bad news for climate change. Nature, 10 September. www.nature.com/articles/d41586-020-02568-y (accessed September 2022).Google Scholar
Wong, J.L.G., Dickinson, B.G. and Thorogood, A. (2016) Assessing the scale of Sphagnum moss collection from Wales. NRW Evidence Reports. Report No 185. Bangor, Wales: Natural Resources Wales.Google Scholar
Zuquim, G., Tuomisto, H., Jones, M.M., et al. (2014) Predicting environmental gradients with fern species composition in Brazilian Amazonia. J Veg Sci 25(5): 1195–1207.Google Scholar