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Critical role of air and soil temperature in the development of primary and secondary physical dormancy in Albizia julibrissin (Fabaceae)

Published online by Cambridge University Press:  18 January 2021

Ganesh K. Jaganathan Open the ORCID record for Ganesh K. Jaganathan [Opens in a new window]  and
Matthew Biddick Open the ORCID record for Matthew Biddick [Opens in a new window]
Ganesh K. Jaganathan*
Affiliation:
Institute of Biothermal Science and Technology, University of Shanghai for Science and Technology, China
Matthew Biddick
Affiliation:
School of Biological Sciences, Victoria University of Wellington, Wellington, New Zealand
*
Author for correspondence:*Ganesh K. Jaganathan, Email: jganeshcbe@gmail.com
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Abstract

Physical dormancy (PY) is typically induced by seed coat impermeability that develops once the moisture content of seeds drops below a species-specific threshold. Considering this, we utilized Albizia julibrissin (Fabaceae) to ask (i) whether seeds that mature on the outer branches of trees (directly exposed to sunlight) are more likely to be impermeable than seeds matured under canopy cover; (ii) whether this difference might be explained by the maternal environment in which the seeds mature; and (iii) which conditions impose secondary dormancy following dispersal? Temperature was tracked in both shaded and sun-exposed seed pods throughout the growing season using data-loggers. Temperatures remained lower in pods under canopy cover than those exposed to direct sunlight. Consequently, the moisture content of seeds collected from sun-exposed branches were significantly lower than seeds matured under canopy cover, thereby producing a higher percentage of impermeable seeds. A dispersal-mimicking experiment revealed that seeds matured in sun-exposed branches and subsequently dispersed to an open site for 4 months were more likely to develop impermeability (i.e. secondary dormancy). The opposite was found to be true for seeds matured in shaded branches and subsequently dispersed to a canopy-covered site. We conclude that the microclimate of both the maternal environment in which seeds mature, and the site to which they disperse, determines the development of primary and secondary dormancy, respectively.

Keywords

dryingimpermeable seed coatsmaternal environmentmicro-climatemoisture content
Type
Research Article
Information
Journal of Tropical Ecology , Volume 36 , Issue 6 , November 2020 , pp. 251 - 257
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Copyright
© The Author(s) 2021. Published by Cambridge University Press.

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References

Literature cited

Argel, P. and Humphreys, L. (1983) Environmental effects on seed development and hardseededness in Stylosanthes hamata cv. Verano. I. Temperature. Crop and Pasture Science 34, 261270.CrossRefGoogle Scholar
Barrett-Lennard, R. and Gladstones, J. (1964) Dormancy and hard-seededness in Western Australian serradella (Ornithopus compressus L.). Crop and Pasture Science 15, 895904.CrossRefGoogle Scholar
Baskin, C.C. and Baskin, J.M. (2014) Seeds: Ecology, Biogeography and Evolution of Dormancy and Germination. Second edition. San Diego, CA: Elsevier.Google Scholar
Baskin, J.M. and Baskin, C.C. (2004) A classification system for seed dormancy. Seed Science Research 14, 116.CrossRefGoogle Scholar
Burrows, G.E., Alden, R. and Robinson, W.A. (2018) The lens in focus – lens structure in seeds of 51 Australian Acacia species and its implications for imbibition and germination. Australian Journal of Botany 66, 398413.CrossRefGoogle Scholar
Busse, W. (1930) Effect of low temperatures on germination of impermeable seeds. Botanical Gazette 89, 169179.CrossRefGoogle Scholar
Chang, S.-M., Gonzales, E., Pardini, E. and Hamrick, J. (2011) Encounters of old foes on a new battle ground for an invasive tree, Albizia julibrissin Durazz (Fabaceae). Biological Invasions 13, 10431053.CrossRefGoogle Scholar
Corner, E. (1951) The leguminous seed. Phytomorphology 1, 117150.Google Scholar
D’hondt, B., Brys, R. and Hoffmann, M. (2010) The incidence, field performance and heritability of non-dormant seeds in white clover (Trifolium repens L.). Seed Science Research 20, 169177.CrossRefGoogle Scholar
Fenner, M. and Thompson, K. (2005) The Ecology of Seeds. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Gama-Arachchige, N., Baskin, J., Geneve, R. and Baskin, C. (2011) Acquisition of physical dormancy and ontogeny of the micropyle–water-gap complex in developing seeds of Geranium carolinianum (Geraniaceae). Annals of Botany 108, 5164.CrossRefGoogle Scholar
Geneve, R.L. (2009) Physical seed dormancy in selected Caesalpinioid legumes from eastern North America. Propagation of Ornamental Plants 9, 129134.Google Scholar
Geneve, R.L., Baskin, C.C., Baskin, J.M., Jayasuriya, K.G. and Gama-Arachchige, N.S. (2018) Functional morpho-anatomy of water-gap complexes in physically dormant seed. Seed Science Research 28, 186191.CrossRefGoogle Scholar
Gladstones, J.S. (1958) The influence of temperature and humidity in storage on seed viability and hard-seededness in the west Australian, blue lupin, Lupinus digitatus Forsk. Australian Journal of Agricultural Research 9, 171181.CrossRefGoogle Scholar
Gogue, G. and Emino, E. (1979) Seed coat scarification of Albizia julbrissin Durazz by natural mechanisms. Journal of the American Society for Horticultural Science 104, 421423.Google Scholar
Gutterman, Y. (ed.) (2000) Maternal Effects on Seeds During Development. Wallingford: CABI.CrossRefGoogle Scholar
Hay, F.R., Smith, R.D., Ellis, R.H. and Butler, L.H. (2010) Developmental changes in the germinability, desiccation tolerance, hardseededness, and longevity of individual seeds of Trifolium ambiguum . Annals of Botany 105, 10351052.CrossRefGoogle ScholarPubMed
Hopkins, E.F., Silva, J.R., Pagan, V. and Villafane, A.G. (1947) Investigations on the storage and preservation of seed in Puerto Rico. Bulletin – Agricultural Experiment Station, Rio Piedras, Puerto Rico 72, 47.Google Scholar
Hyde, E.O.C. (1954) The function of the hilum in some Papilionaceae in relation to the ripening of the seed and the permeability of the testa. Annals of Botany 18, 241256.CrossRefGoogle Scholar
ISTA (2015) Determination of moisture content. International Rules for Seed Testing: International Seed Testing Association 2015, 912.Google Scholar
Jaganathan, G.K. (2016) Influence of maternal environment in developing different levels of physical dormancy and its ecological significance. Plant Ecology 217, 7179.CrossRefGoogle Scholar
Jaganathan, G.K. (2018) Physical dormancy alleviation and soil seed bank establishment in Cassia roxburghii is determined by soil microsite characteristics. Flora 244, 1923.CrossRefGoogle Scholar
Jaganathan, G.K. and Liu, B. (2014a) Role of seed sowing time and microclimate on germination and seedling establishment of Dodonaea viscosa (Sapindaceae) in a seasonal dry tropical environment – a special insight to restoration efforts. Botany 93, 2329.CrossRefGoogle Scholar
Jaganathan, G.K. and Liu, B. (2014b) Seasonal influence on dormancy alleviation in Dodonaea viscosa (Sapindaceae) seeds. Seed Science Research 24, 229237.CrossRefGoogle Scholar
Jaganathan, G.K., Song, D., Liu, W., Han, Y. and Liu, B. (2017a) Relationship between seed moisture content and acquisition of impermeability in Nelumbo nucifera (Nelumbonaceae). Acta Botanica Brasilica 31, 639644.CrossRefGoogle Scholar
Jaganathan, G.K., Wu, G.R., Han, Y.Y. and Liu, B. (2017b) Role of the lens in controlling physical dormancy break and germination of Delonix regia (Fabaceae: Caesalpinioideae). Plant Biology 19, 5360.CrossRefGoogle Scholar
Jaganathan, G.K., Yule, K.J. and Biddick, M. (2018) Determination of the water gap and the germination ecology of Adenanthera pavonina (Fabaceae, Mimosoideae); the adaptive role of physical dormancy in mimetic seeds. AoB Plants 10, ply048.CrossRefGoogle ScholarPubMed
Lute, A.M. (1928) Impermeable Seed of Alfalfa. Fort Collins, CO: Colorado Experiment Station, Agricultural Section.Google Scholar
Mai-Hong, T., Hong, T.D., Hien, N.T. and Ellis, R.H. (2003) Onset of germinability, desiccation tolerance and hardseededness in developing seeds of Peltophorum pterocarpum (DC) K. Heyne (Caesalpinioideae). Seed Science Research 13, 323327.CrossRefGoogle Scholar
Martinez-Fernandez, V., Martinez-Garcia, F. and Garcia, F.P. (2014) Census, reproductive biology, and germination of Astragalus gines-lopezii (Fabaceae), a narrow and endangered endemic species of SW Spain. Turkish Journal of Botany 38, 686695.CrossRefGoogle Scholar
Merou, T., Takos, I., Konstantinidou, E., Galatsidas, S. and Varsamis, G. (2011) Effect of different pretreatment methods on germination of Albizia julibrissin seeds. Seed Science and technology 39, 248252.CrossRefGoogle Scholar
Michael, P.J., Steadman, K.J. and Plummer, J.A. (2006) Climatic regulation of seed dormancy and emergence of diverse Malva parviflora populations from a Mediterranean-type environment. Seed Science Research 16, 273281.CrossRefGoogle Scholar
Norman, H.C., Cocks, P.S. and Galwey, N.W. (2002) Hardseededness in annual clovers: variation between populations from wet and dry environments. Australian Journal of Agricultural Research 53, 821829.CrossRefGoogle Scholar
Ooi, M.K., Denham, A.J., Santana, V.M. and Auld, T.D. (2014) Temperature thresholds of physically dormant seeds and plant functional response to fire: variation among species and relative impact of climate change. Ecology and Evolution 4, 656671.CrossRefGoogle ScholarPubMed
Pérez-García, F. (1997) Germination of Cistus ladanifer seeds in relation to parent material. Plant Ecology 133, 5762.CrossRefGoogle Scholar
Quinlivan, B. (1961) The effect of constant and fluctuating temperatures on the permeability of the hard seeds of some legume species. Crop and Pasture Science 12, 10091022.CrossRefGoogle Scholar
Quinlivan, B. (1965) The influence of the growing season and the following dry season on the hardseeedness of subterranean clover in different environments. Australian Journal of Agricultural Research 16, 277291.CrossRefGoogle Scholar
Quinlivan, B.J. (1967) Environmental variation in the long term pattern of germination from hard seeds of Lupinus varius . Australian Journal of Experimental Agriculture and Animal Husbandry 7, 263265.CrossRefGoogle Scholar
Quinlivan, B. (1968) Seed coat impermeability in the common annual legume pasture species of Western Australia. Animal Production Science 8, 695701.CrossRefGoogle Scholar
Quinlivan, B. and Millington, A. (1962) The effect of a Mediterranean summer environment on the permeability of hard seeds of subterranean clover. Crop and Pasture Science 13, 377387.CrossRefGoogle Scholar
Rodrigues-Junior, A.G., Mello, A.C.M., Baskin, C.C., Baskin, J.M., Oliveira, D.M. and Garcia, Q.S. (2018) A function for the pleurogram in physically dormant seeds. Annals of Botany 123, 867876.CrossRefGoogle Scholar
Rolston, M.P. (1978) Water impermeable seed dormancy. The Botanical Review 44, 365396.CrossRefGoogle Scholar
Smýkal, P., Vernoud, V., Blair, M.W., Soukup, A. and Thompson, R.D. (2014) The role of the testa during development and in establishment of dormancy of the legume seed. Frontiers in Plant Science 5, 351.Google ScholarPubMed
Suzaki, T., Kume, A. and Ino, Y. (2005) Effects of slope and canopy trees on light conditions and biomass of dwarf bamboo under a coppice canopy. Journal of Forest Research 10, 151156.CrossRefGoogle Scholar
Taylor, G.B. (1996) Effect of the environment in which seeds are grown and softened on the incidence of autumn seed softening in two species of annual medics. Australian Journal of Agicultural Research 47, 141159.CrossRefGoogle Scholar
Taylor, G.B. and Palmer, M.J. (1979) The effect of some environmental conditions on seed development and hard-seededness in subterranean clover (Trifolium subterraneum L.). Australian Journal of Agicultural Research 30, 6576.CrossRefGoogle Scholar
Temim, E., Leto, A., Hadziabulic, S., Hadziabulic, A. and Dorbic, B. (2016) The effect of different dormancy breaking treatments on germination of Albizia julibrissin seeds. Radovi Poljoprivrednog Fakulteta Univerziteta u Sarajevu (Works of the Faculty of Agriculture University of Sarajevo) 61, 368370.Google Scholar
Tozer, M.G. and Ooi, M.K. (2014) Humidity-regulated dormancy onset in the Fabaceae: a conceptual model and its ecological implications for the Australian wattle Acacia saligna . Annals of Botany 114, 579590.CrossRefGoogle ScholarPubMed
Van Assche, J.A., Debucquoy, K.L. and Rommens, W.A. (2003) Seasonal cycles in the germination capacity of buried seeds of some Leguminosae (Fabaceae). New Phytologist 158, 315323.CrossRefGoogle Scholar
Willis, C.G., Baskin, C.C., Baskin, J.M., Auld, J.R., Venable, D.L., Cavender-Bares, J., Donohue, K. and Rubio de Casas, R. (2014) The evolution of seed dormancy: environmental cues, evolutionary hubs, and diversification of the seed plants. New Phytologist 203, 300309.CrossRefGoogle ScholarPubMed
Xu, B. and Gu, Z. (1985) Effect of sulphuric acid treatment in breaking dormancy in hard seeds. Plant Physiology Communications (Zhiwu Shenglixue Tongxun) 2, 2225.Google Scholar