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A comparative study of seed dormancy and germination in an annual and a perennial species of Senna (Fabaceae)

Published online by Cambridge University Press:  19 September 2008

Jerry M. Baskin ,
Xiaoying Nan  and
Carol C. Baskin
Jerry M. Baskin*
Affiliation:
School of Biological Sciences, University of Kentucky, Lexington, KY 40506–0225, USA
Xiaoying Nan
Affiliation:
School of Biological Sciences, University of Kentucky, Lexington, KY 40506–0225, USA
Carol C. Baskin
Affiliation:
School of Biological Sciences, University of Kentucky, Lexington, KY 40506–0225, USA
*
* E-mail: JMBASK0@UKCC.UKY.EDU
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Abstract

Seed dormancy and germination of Senna marilandica and S. obtusifolia were compared in greenhouse and laboratory studies. About 90% of the S. obtusifolia seeds were green and had hard seed coat dormancy, whereas the other 10% were brown and nondormant. Seed-colour morphs did not occur in S. marilandica, and nearly 100% of the seeds had hard seed coat dormancy. Seeds of S. obtusifolia were significantly heavier than those of S. marilandica. Mechanical scarification was very effective in overcoming dormancy in seeds of both species. However, concentrated sulfuric acid, absolute ethanol and boiling water were less effective in breaking dormancy in seeds of S. marilandica than in those of S. obtusifolia. Further, incubating seeds at 30/15 to 40/25°C and dry-heat treatments at 80–100°C were ineffective in breaking dormancy in S. marilandica, but significantly increased germination percentages in S. obtusifolia. In neither species were simulated daily/seasonal temperature shifts effective in breaking dormancy. Scarified seeds of both species germinated over a wide range of temperatures in both light and darkness. Under near-natural temperature conditions, seeds of S. marilandica germinated in spring only, whereas those of S. obtusifolia emerged in late spring and throughout summer. Both species can form a long-lived seed bank. Dormancy break by high field temperatures in seeds of S. obtusifolia allows this species to germinate throughout the warm growing season and thus contributes to its success as a weed in arable crops.

Keywords

hard seed coat dormancylegumesphysical dormancyseed banksseed germinationSenna
Type
Ecology
Information
Seed Science Research , Volume 8 , Issue 4 , December 1998 , pp. 501 - 512
Copyright
Copyright © Cambridge University Press 1998

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References

Ballard, L.A.T. (1973) Physical barriers to germination. Seed Science and Technology 1, 285303.Google Scholar
Ballard, L.A.T., Nelson, S.O., Buchwald, T. and Stetson, L.E. (1976) Effects of radiofrequency electric fields on permeability to water of some legume seeds, with special reference to the strophiolar conditions. Seed Science and Technology 4, 257274.Google Scholar
Barker, W.T. (1969) The flora of the Kansas Flint Hills. University of Kansas Science Bulletin 48, 525584.Google Scholar
Barton, L.V. (1947) Species studies on seed coat impermeability. Contributions of the Boyce Thompson Institute 14, 355362.Google Scholar
Baskin, C.C. and Baskin, J.M. (1998) Seeds: Ecology, biogeography, and evolution of dormancy and germination. San Diego, Academic Press.Google Scholar
Baskin, J.M. and Baskin, C.C. (1977) Predation of Cassia marilandica seeds by Sennius abbreviatus (Coleoptera: Bruchidae). Bulletin of the Torrey Botanical Club 104, 6164.Google Scholar
Baskin, J.M. and Baskin, C.C. (1997) Methods of breaking dormancy in the endangered species Iliamna corei (Sherff) Sherff (Malvaceae), with special attention to heating. Natural Areas Journal 17, 313323.Google Scholar
Baskin, J.M., Quarterman, E. and Caudle, C. (1968) Preliminary check-list of the herbaceous vascular plants of cedar glades. Journal of the Tennessee Academy of Science 43, 6571.Google Scholar
Bell, D.T., Plummer, J.A. and Taylor, S.K. (1993) Seed germination ecology of southwestern Western Australia. The Botanical Review 59, 2473.CrossRefGoogle Scholar
Brant, R.E., McKee, G.W. and Cleveland, R.W. (1971) Effect of chemical and physical treatment on hard seed of penngift crownvetch. Crop Science 11, 16.Google Scholar
Brenan, J.P.M. (1958) New and noteworthy cassias from tropical Africa. Kew Bulletin 13, 231252.Google Scholar
Bridges, D.C. and Walker, R.H. (1985) Influence of weed management and cropping systems on sicklepod (Cassia obtusifolia) seed in the soil. Weed Science 33, 800804.Google Scholar
Brown, N.A.C. and de V. Booysen, P. (1969) Seed coat impermeability in several Acacia species. Agroplantae 1, 5160.Google Scholar
Cavanagh, A.K. (1980) A review of some aspects of the germination of Acacias. Proceedings of the Royal Society of Victoria 91, 161180.Google Scholar
Cranfill, R. (1991) Flora of Hardin County, Kentucky. Castanea 56, 228267.Google Scholar
Creel, J.M. Jr., Hoveland, C.S. and Buchanan, G.A. (1968) Germination, growth and ecology of sicklepod. Weed Science 16, 396400.Google Scholar
Crocker, W. (1948) Growth of plants. Twenty years of research at Boyce Thompson Institute. New York, Reinhold Publishing Company.Google Scholar
Crocker, W. and Barton, L.V. (1957) Physiology of seeds. Waltham, Massachusetts, Chronica Botanica Company.Google Scholar
Dell, B. (1980) Structure and function of the strophiolar plug in seeds of Albizia lophantha. American Journal of Botany 67, 556563.Google Scholar
Egley, G.H. (1979) Seed coat impermeability and germination of showy crotalaria (Crotalaria spectabilis Roth) seeds. Weed Science 27, 355361.CrossRefGoogle Scholar
Egley, G.H. and Chandler, J.M. (1978) Germination and viability of weed seeds after 2.5 years in a 50-year buried-seed study. Weed Science 26, 230239.CrossRefGoogle Scholar
Egley, G.H. and Chandler, J.M. (1983) Longevity of weed seeds after 5.5 years in the Stoneville 50-year buried-seed study. Weed Science 31, 264270.CrossRefGoogle Scholar
Fernald, M.L. (1950) Gray's manual of botany. 8th edition. New York, American Book Company.Google Scholar
Fribourg, H.A., Brown, R.H., Prine, G.M. and Taylor, T.H. (1967) Aspects of the microclimate at five locations in the southeastern United States. Southern Regional Bulletin Number 124 for Regional Research Project S-47.Google Scholar
Gibson, D. (1961) Life-forms of Kentucky flowering plants. The American Midland Naturalist 66, 160.CrossRefGoogle Scholar
Gleason, H.A. and Cronquist, A. (1991) Manual of vascular plants of northeastern United States and adjacent Canada. 2nd edition. Bronx, New York Botanical Garden.CrossRefGoogle Scholar
Great Plains Flora Association (GPFA) (1986) Flora of the Great Plains. Lawrence, University Press of Kansas.Google Scholar
Grubbs, J.T. and Fuller, M.J. (1991) Vascular flora of Hickman County, Kentucky. Castanea 56, 193214.Google Scholar
Hill, J.D. (1976) Climate of Kentucky. University of Kentucky Agriculture Experiment Station Progress Report No. 221.Google Scholar
Holm, L., Pancho, J.V., Herberger, J.P. and Plucknett, D.L. (1979) A geographical atlas of world weeds. New York, John Wiley and Sons.Google Scholar
Holm, L., Doll, J., Holm, E., Pancho, J. and Herberger, J. (1997) World weeds: Natural histories and distribution. New York, John Wiley and Sons.Google Scholar
Irwin, H.S. and Barneby, R.C. (1982) The American Cassiinae. A synoptical revision of Leguminosae tribe Cassieae subtribe Cassiinae in the New World. Memoirs of the New York Botanical Garden 35 (parts 1 and 2), v + 1918.Google Scholar
Isely, D. (1975) Leguminosae of the United States: II. Subfamily Caesalpinioideae. Memoirs of the New York Botanical Garden 25, 1228.Google Scholar
Isley, D. (1990) Vascular flora of the southeastern United States. Volume 3, part 2. Leguminosae (Fabaceae). Chapel Hill, University of North Carolina Press.Google Scholar
Kelley, K.M. and van Staden, J. (1985) Effect of acid scarification on seed coat structure, germination and seedling vigor of Aspalathus linearis. Journal of Plant Physiology 121, 3745.CrossRefGoogle Scholar
Kumari, A. and Kohli, P.K. (1984) Studies on dormancy and macromolecular drifts during germination of Cassia occidentalis L. seeds. Journal of Tree Science 3, 111125.Google Scholar
Manning, J.C. and van Staden, J. (1987) The role of the lens in seed imbibition and seedling vigor of Sesbania punicea (Cav.) Benth. (Leguminosae: Papilionoideae). Annals of Botany 59, 705713.Google Scholar
Martin, R.E., Miller, R.L. and Cushwa, C.T. (1975) Germination response of legume seeds subjected to moist and dry heat. Ecology 56, 14411445.CrossRefGoogle Scholar
Mitchell, E. (1926) Germination of seeds of plants native to Dutchess County, New York. Botanical Gazette 81, 108112.Google Scholar
Mott, J.J., Cook, S.J. and Williams, R.J. (1982) Influence of short duration, high temperature seed treatment on the germination of some tropical and temperate legumes. Tropical Grasslands 16, 5055.Google Scholar
Nan, X. (1992) Comparison of some aspects of the ecological life history of an annual and a perennial species of Senna (Leguminosae: Section Chamaefistula), with particular reference to seed dormancy. M.S. thesis, University of Kentucky, Lexington.Google Scholar
Nikolaeva, M.G. (1977) Factors controlling the seed dormancy pattern. pp 5174in Khan, A.A. (Ed.) The physiology and biochemistry of seed dormancy and germination. Amsterdam, North-Holland Publishing Company.Google Scholar
Quinlivan, B.J. (1968) The softening of hard seeds of sand-plain lupin (Lupinus varius L.). Australian Journal of Agricultural Research 19, 507515.Google Scholar
Radford, A.E., Ahles, H.E. and Bell, C.R. (1968) Manual of the vascular flora of the Carolinas. Chapel Hill, University of North Carolina Press.Google Scholar
Retzinger, E.J. (1984) Growth and development of sicklepod (Cassia obtusifolia) selections. Weed Science 32, 608611.Google Scholar
Roach, D.A. and Wulff, R.D. (1987) Maternal effects in plants. Annual Review of Ecology and Systematics 18, 209235.CrossRefGoogle Scholar
Rolston, M.P. (1978) Water impermeable seed dormancy. The Botanical Review 44, 365396.CrossRefGoogle Scholar
Singh, J.S. (1968) Comparison of growth performance and germination behaviour of seeds of Cassia tora L. and C. obtusifolia L. Tropical Ecology 9, 6471.Google Scholar
Steyermark, J.A. (1963) Flora of Missouri. Ames, Iowa State University Press.Google Scholar
Tarrega, R., Calvo, L. and Trabaud, L. (1992) Effect of high temperatures on seed germination of two woody Leguminosae. Vegetatio 102, 139147.CrossRefGoogle Scholar
Taylor, G.B. (1981) Effect of constant temperature treatments followed by fluctuating temperatures on the softening of hard seeds of Trifolium subterraneum L. Australian Journal of Plant Physiology 8, 547558.Google Scholar
Teem, D.H., Hoveland, C.S. and Buchanan, G.A. (1980) Sicklepod (Cassia obtusifolia) and coffee senna (Cassia occidentalis): Geographic distribution, germination, and emergence. Weed Science 28, 6870.Google Scholar
Teketay, D. (1996) The effect of different presowing treatments, temperature and light on the germination of five Senna species from Ethiopia. New Forests 11, 155171.CrossRefGoogle Scholar
Thanos, C.A. and Georghiou, K. (1988) Ecophysiology of fire-stimulated seed germination in Cistus anciens ssp. creticus (L.) Heywood and C. salvifolius L. Plant, Cell and Environment 11, 841849.CrossRefGoogle Scholar
Todaria, N.P. and Negi, A.K. (1992) Pretreatment of some Indian Cassia seeds to improve germination. Seed Science and Technology 20, 583588.Google Scholar
Toole, E.H. and Brown, E. (1946) Final results of the Duvel buried seed experiment. Journal of Agricultural Research 72, 201210.Google Scholar
Tran, V.N. (1979) Effects of microwave energy on the strophiole, seed coat and germination of Acacia seeds. Australian Journal of Plant Physiology 6, 277287.Google Scholar
Underwood, J.K. (1965) Tennessee weeds. University of Tennessee Agriculture Experiment Station Bulletin No. 393.Google Scholar
Walker, H.L. and Riley, J.A. (1982) Evaluation of Alternaria cassiae for the biocontrol of sicklepod (Cassia obtusifolia). Weed Science 30, 651654.Google Scholar