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The development of desiccation-sensitive seeds in Quercus robur L.: Reserve accumulation and plant growth regulators

Published online by Cambridge University Press:  19 September 2008

W. E. Finch-Savage  and
Jill M. Farrant
W. E. Finch-Savage*
Affiliation:
Horticulture Research International, Wellesbourne, Warwick CV35 9EF, UK
Jill M. Farrant
Affiliation:
Department of Botany, University of Cape Town, Private Bag, Rondebosch 7700, South Africa
*
*Correspondence
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Abstract

The fruits of Quercus robur are shed containing seeds at high moisture contents which remain desiccation sensitive and exhibit recalcitrant storage behaviour. Little is known of the control of seed development in these and other recalcitrant seeds. In the present work the changing concentrations of four plant growth regulators during seed reserve accumulation was studied over five years on seeds from the same tree. The pattern of reserve accumulation and changing ABA content in seeds differed between years. Although ABA content in the cotyledons increased in line with increasing dry weight to different contents at shedding, similar concentrations existed in cotyledons in each year. Thus ABA did not appear to be influencing dry weight accumulation. However, unlike orthodox seeds the decline in ABA concentration prior to shedding was limited and consistent with a continuing role for ABA in preventing precocious germination. An earlier peak in ABA concentration was associated with greater desiccation tolerance at shedding across years. The concentrations of zeatin and zeatin riboside in cotyledons were similar in each year and declined during reserve accumulation in a similar fashion to that reported for orthodox seeds. By contrast, IAA concentration increased in both the cotyledons and axes in the latter stages of seed development, opposite to that reported for orthodox seeds. It is possible that the increasing IAA concentration in cotyledons and axes and the stable concentration of zeatin and zeatin riboside throughout the latter stages of development in the axes of Q. robur are linked to the maintenance of active metabolism for the rapid initiation of germination upon shedding observed in seeds of this species.

Keywords

ABAcytokininsdesiccation toleranceIAAQuercus roburrecalcitrant seedsseed development
Type
Development
Information
Seed Science Research , Volume 7 , Issue 1 , March 1997 , pp. 35 - 39
Copyright
Copyright © Cambridge University Press 1997

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References

Berjak, P., Farrant, J.M. and Pammenter, N.W. (1989) The basis of recalcitrant seed behaviour, pp 89108in Taylorson, R.B. (Ed.) Recent advances in the development and germination of seeds. New York, Plenum Press.CrossRefGoogle Scholar
Bewley, J.D. and Black, M. (1994) Seeds: Physiology of development and germination. New York, Plenum Press.Google Scholar
Bialek, K. and Cohen, J.D. (1989) Free and conjugated indole-3-acetic acid in developing bean seeds. Plant Physiology 91, 775779.CrossRefGoogle ScholarPubMed
Bonner, F.T. (1976) Maturation of Shumard and white oak acorns. Forest Science 22, 149154.Google Scholar
Browning, G. (1989) The physiology of fruit set. pp 195217in Wright, C.J. (Ed.) Manipulation of fruiting. London, Butterworths.CrossRefGoogle Scholar
Cohen, J.D. and Bandurski, R.S. (1982) Chemistry and physiology of the bound auxins. Annual Review of Plant Physiology 33, 403430.Google Scholar
Eeuwens, F.T. and Schwabe, W.W. (1975) Seed and pod wall development in Pisum sativum L. in relation to extracted and applied hormones. Journal of Experimental Botany 26, 114.CrossRefGoogle Scholar
Farrant, J.M., Pammenter, N.W., Cutting, J.G.M. and Berjak, P. (1993). The role of plant growth regulators in the development and germination of the desiccation-sensitive (recalcitrant) seeds of Avicennia marina. Seed Science Research 3, 5563.Google Scholar
Finch-Savage, W.E. (1992a) Embryo water status and survival in the recalcitrant species Quercus robur L.: Evidence for a critical moisture content. Journal of Experimental Botany 43, 663669.CrossRefGoogle Scholar
Finch-Savage, W.E. (1992b) Seed development in the recalcitrant species Quercus robur L.: Development of germinability and desiccation tolerance. Seed Science Research 2, 1722.CrossRefGoogle Scholar
Finch-Savage, W.E. and Blake, P.S. (1994) Indeterminate development in desiccation-sensitive seeds of Quercus robur L. Seed Science Research 4, 127133.CrossRefGoogle Scholar
Finch-Savage, W.E. and Clay, H.A. (1994) Evidence that ethylene, light and abscisic acid interact to inhibit germination in the recalcitrant seeds of Quercus robur L. Journal of Experimental Botany 45, 12951299.CrossRefGoogle Scholar
Finch-Savage, W.E., Clay, H.A., Blake, P.S. and Browning, G. (1992) Seed development in the recalcitrant species Quercus robur L.: Water status and endogenous abscisic acid levels. Journal of Experimental Botany 43, 671679.Google Scholar
Finch-Savage, W.E., Grange, R.I., Hendry, G.A.F. and Atherton, N.M. (1993) Embryo water status and loss of viability during desiccation in the recalcitrant species Quercus robur L.. pp. 723730in Côme, D. and Corbineau, F. (Eds) Proceedings of the Fourth International Workshop on Seeds: Basic and Applied Aspects of Seed Biology.Paris,ASFIS.Google Scholar
Finch-Savage, W.E., Pramanik, S.K. and Bewley, J.D. (1994) The expression of dehydrin proteins in desiccation-sensitive (recalcitrant) seeds of temperate trees. Planta 193, 478485.Google Scholar
Gosling, P.G. (1989) The effect of drying Quercus robur acorns to different moisture contents, followed by storage, either with or without imbibition. Forestry 62, 4150.Google Scholar
ISTA (1993) International rules for seed testing. Seed Science and Technology 21 (supplement).Google Scholar
Kermode, A.R. (1990) Regulatory mechanisms involved in the transition from seed development to germination. Critical Reviews in Plant Science 9, 155195.Google Scholar
McWha, J.A. (1975) Changes in abscisic acid levels in developing grains of wheat (Triticum aestivum L.). Journal of Experimental Botany 26, 823827.CrossRefGoogle Scholar
Michalski, L. (1969) Content of plant growth regulators in the developing seeds of oak (Quercus robur L.) II. Auxin-like substances. Acta Societatis Botanicorum Poloniae, 38, 157163.Google Scholar
Pence, V.C. (1991). Abscisic acid in developing zygotic embryos of Theobroma cacao. Plant Physiology 95, 12911293.Google Scholar
Poulsen, K.M. and Eriksen, E.N. (1992) Physiological aspects of recalcitrance in embryonic axes of Quercus robur L. Seed Science Research 2, 215221.Google Scholar
Sandberg, G., Ernstsen, A. and Hamnede, M. (1987) Dynamics of indole-3-acetic acid and indole-3-ethanol during development and germination of Pinus sylvestris seeds. Physiologia Plantarum 71, 411418.CrossRefGoogle Scholar
Valpuesta, V., Quesada, M.A., Sanchez-Roldan, C., Tigier, H.A., Heredia, A. and Bukovac, M.J. (1989) Changes in indole-3-acetic acid, indole-3-acetic acid oxidase and peroxidase isoenzymes in the seeds of developing peach fruits. Journal of Plant Growth Regulation 8, 255261.Google Scholar
van Staden, J., Davey, J.E. and Brown, N.A.C. (1982) Cytokinins in seed development and germination. pp 137156in Khan, A.A. (Ed.) The physiology and biochemistry of seed development, dormancy and germination. Amsterdam, Elsevier Biomedical Press.Google Scholar
Vertucci, C.W. and Farrant, J.M. (1995) Acquisition and loss of desiccation tolerance. pp 237271in Kigel, J. and Galili, G. (Eds) Seed development and germination. New York, Marcel Dekker.Google Scholar
Wolswinkel, P. (1992) Transport of nutrients into developing seeds: a review of physiological mechanisms. Seed Science Research 2, 5973.CrossRefGoogle Scholar