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Detecting and overcoming water-impermeable barriers in prickly sida (Sida spinosa L.) seeds

Published online by Cambridge University Press:  19 September 2008

G. H. Egley*
Affiliation:
Southern Weed Science Laboratory, Agricultural Research Service, U.S. Department of Agriculture, Stoneville, MS 38776, USA
R. N. Paul Jr
Affiliation:
Southern Weed Science Laboratory, Agricultural Research Service, U.S. Department of Agriculture, Stoneville, MS 38776, USA
*
* Correspondence

Abstract

Barriers to water permeability in prickly sida seeds were characterized using solvents and water-soluble salts. The seeds imbibed water when barriers in the chalazal area broke down. The major barrier was in the distal region of the palisade layer bordered internally by the light line. Soaking dormant seeds in certain organic solvents overcame the barrier and enabled the seeds to imbibe water. The most active were non-polar solvents with dielectric constants between 3.7 and 18.5, and with a high ability to hydrate and swell cellulosic materials. We concluded that the most active solvents (pyridine, diethylamine) overcame the major barrier, entered the proximal portion of the palisade layer and caused the swelling of cellulosic cell components. The cellular expansion created stresses that broke thin walls of the underlying subpalisade cells in the chalazal area. The breakage resulted in separation of the cell layers and rapid entry of water into the seed. Highly non-polar or highly polar solvents had little or no activity. Some solvents overcame the barrier but did not cause swelling and disruption of the cell layers. We propose that the natural breakdown of impermeability in prickly sida seeds was due to the gradual seepage of water past the barrier in the distal portion of the coat in the chalazal area and into the inner portions where swelling of hygroscopic components triggered the breakage of subpalisade cell walls resulting in cell layer separation.

Type
Research Papers
Copyright
Copyright © Cambridge University Press 1993

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Footnotes

1

Plant Physiologist

2

Biologist

References

Abraham, J.L. and DeNee, P.B. (1974) Biomedical applications of backscattered electron imaging—one year's experience with SEM histochemistry. Scanning Electron Microscopy 1974, 251258.Google Scholar
Ballard, L.A.T. (1973) Physical barriers to germination. Seed Science and Technology 1, 285303.Google Scholar
Burbano, J.L., Pizzolato, T.D., Morey, P.R. and Berlin, J.D. (1976) An application of the prussian blue technique to a light microscope study of water movement in transpiring leaves of cotton (Gossypium hirsutum L.) Journal of Experimental Botany 27, 134144.CrossRefGoogle Scholar
Egley, G.H. (1976) Germination of developing prickly sida seeds. Weed Science 24, 239243.CrossRefGoogle Scholar
Egley, G.H. (1989) Water-impermeable seed coverings as barriers to germination. pp 207223 in Taylorson, R.B. (Ed.) Recent advances in the development and germination of seeds. New York, Plenum Press.CrossRefGoogle Scholar
Egley, G.H. and Paul, R.N. Jr., (1981) Morphological observations on the early imbibition of water by Sida spinosa (Malvaceae) seed. American Journal of Botany 68, 10561065.CrossRefGoogle Scholar
Egley, G.H. and Paul, R.N. Jr., (1982) Development, structure and function of subpalisade cells in water impermeable Sida spinosa seeds. American Journal of Botany 69, 14021409.CrossRefGoogle Scholar
Egley, G.H., Paul, R.N. Jr., and Lax, A.R. (1986) Seed coat imposed dormancy: Histochemistry of the region controlling onset of water entry into Sida spinosa seeds. Physiologia Plantarum 67, 320327.CrossRefGoogle Scholar
Fairbrother, T.E. (1991) Effect of fluctuating temperatures and humidity on the softening rate of hard seed of subterranean clover (Trifolium subteraneum L.). Seed Science and Technology 19, 93105.Google Scholar
Hagon, M.W. and Ballard, L.A.T. (1970) Reversibility of strophiolar permeability to water in seeds of subterranean clover (Trifolium subterraneum L.). Australian Journal of Botanical Science 23, 519528.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
Paul, R.N. and Egley, G.H. (1983) Techniques for preparing seeds with water-impermeable coats for light and electron microscopy. Stain Technology 58, 7377.CrossRefGoogle ScholarPubMed
Quinlivan, B.J. (1961) The effect of constant and fluctuating temperatures on the permeability of the hard seeds of some legume species. Australian Journal of Agricultural Research 12, 10091022.CrossRefGoogle Scholar
Reynolds, E.S. (1963) The use of lead citrate at high pH as an electron opaque stain in electron microscopy. Journal of Cell Biology 17, 208212.CrossRefGoogle ScholarPubMed
Rolston, M.P. (1978) Water impermeable seed dormancy. Botanical Review 44, 365396.CrossRefGoogle Scholar
Spurr, A.R. (1969) A low viscosity epoxy resin embedding medium for electron mocroscopy. Journal of Ultrastructure Research 26, 3143.CrossRefGoogle Scholar
Stamm, A.J. (1964) Wood and Cellulose Science, pp 248263. New York, The Ronald Press Co.Google 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
Werker, E. (1980/1981) Seed dormancy as explained by the anatomy of embryo envelopes. Israel Journal of Botany 29, 2244.Google Scholar