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The longevity of crop seeds stored under ambient conditions

Published online by Cambridge University Press:  19 November 2009

Manuela Nagel  and
Andreas Börner
Manuela Nagel
Affiliation:
Leibniz-Institut für Pflanzengenetik und Kulturpflanzenforschung (IPK), Corensstrasse 3, D-06466Gatersleben, Germany
Andreas Börner*
Affiliation:
Leibniz-Institut für Pflanzengenetik und Kulturpflanzenforschung (IPK), Corensstrasse 3, D-06466Gatersleben, Germany
*
*Correspondence Email: boerner@ipk-gatersleben.de
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Abstract

The ability of crop seeds to retain their viability over extended periods of uncontrolled temperature and/or relative humidity conditions has not been widely investigated, although this is an important issue for genebank management. We report here the response of 18 crop species to storage for up to 26 years at 20.3 ± 2.3°C and 50.5 ± 6.3% relative humidity. Germination rates decreased in a sigmoid fashion, but the curve parameters were species characteristic. Pea, common bean and maize seeds retained their viability over the longest period (23, 21 and 19 years, respectively). In contrast, chive seeds survived for only 5 years and lettuce for 7 years. In addition to this interspecific variability, there were also indices for intraspecific variability, particularly in bean and chive seeds, just as in collard, lupin, poppy, wheat and maize seeds. A significant correlation was obtained between germination performance in the laboratory and seedling emergence following autumn sowing. Seeds in which oil was the major seed storage component were more short lived, whereas carbohydrates or proteins did not show an effect on seed longevity.

Keywords

ambient storageconservationfield establishmentgenebankgenetic diversitylongevityseeds
Type
Research Article
Information
Seed Science Research , Volume 20 , Issue 1 , March 2010 , pp. 1 - 12
Copyright
Copyright © Cambridge University Press 2009

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References

Börner, A. (2006) Preservation of plant genetic resources in the biotechnology era. Biotechnology Journal 1, 13931404.CrossRefGoogle ScholarPubMed
Debeaujon, I., Léon-Kloosterziel, K.M. and Koornneef, M. (2000) Influence of the testa on seed dormancy, germination, and longevity in Arabidopsis. Plant Physiology 122, 403413.CrossRefGoogle ScholarPubMed
Earle, F.R. and Jones, Q. (1962) Analyses of seed samples from 113 plant families. Economic Botany 15, 221250.CrossRefGoogle Scholar
Ellis, R.H. and Roberts, E.H. (1980) Improved equations for the prediction of seed longevity. Annals of Botany 45, 1330.CrossRefGoogle Scholar
FAO (1994) Genebank standards. Rome, Food and Agriculture Organization of the United Nations; Rome, International Plant Genetic Resources Institute.Google Scholar
Gidrol, X., Serghini, H., Noubhani, A., Mocquot, B. and Mazliak, P. (1989) Biochemical changes induced be accelerated aging in sunflower seeds. I. Lipid peroxidation and membrane damage. Physiologia Plantarum 76, 591597.CrossRefGoogle Scholar
Haferkamp, M.E., Smith, L. and Nilan, R.A. (1953) Studies on aged seeds I – relation of age of seed to germination and longevity. Agronomy Journal 45, 434437.CrossRefGoogle Scholar
ISTA (2005) International rules for seed testing. Bassersdorf, International Seed Testing Association.Google Scholar
Jones, Q. and Earle, F.R. (1966) Chemical analyses of seeds II: oil and protein content of 759 species. Economic Botany 20, 127155.CrossRefGoogle Scholar
Linington, S.H. and Pritchard, H.W. (2001) Gene Banks. pp. 165181in Levin, S.A. (Ed.) Encyclopedia of biodiversity. Vol. 3. San Diego, Academic Press.CrossRefGoogle Scholar
Liu, K., Eastwood, R.J., Flynn, S., Turner, R.M. and Stuppy, W.H. (2008) Seed information database (release 7.1, May 2008). Available athttp://www.kew.org/data/sid (accessed 27 October 2009).Google Scholar
Maxted, N., Ford-Lloyd, V.V. and Hawkes, J.G. (1997) Plant genetic conservation. The in situ approach. London, Chapman & Hall.CrossRefGoogle Scholar
Medeiros, A.C.S., Probert, R.J., Sader, R. and Smith, R.D. (1998) The moisture relations of seed longevity in Astronium urundeuva (Fr. All.) Engl. Seed Science and Technology 2, 289298.Google Scholar
Moore, F.D. and Roos, E.E. (1982) Determining differences in viability loss rates during seed storage. Seed Science and Technology 10, 283300.Google Scholar
Nagel, M., Vogel, H., Landjeva, S., Buck-Sorlin, G., Lohwasser, U., Scholz, U. and Börner, A. (2009) Seed conservation in ex situ genebanks – genetic studies on longevity in barley. Euphytica 170, 5114.CrossRefGoogle Scholar
Powell, A.A. (1988) Seed vigour and field establishment. Advances in Research and Technology of Seeds 11, 2961.Google Scholar
Priestley, D.A. (1986) Seed ageing: implications for seed storage and persistence in the soil. New York, Comstock.Google Scholar
Priestley, D.A., Cullinan, V.I. and Wolfe, J. (1985) Differences in seed longevity at the species level. Plant, Cell and Environment 8, 557562.CrossRefGoogle Scholar
Pritchard, H.W. and Dickie, J.B. (2004) Predicting seed longevity: the use and abuse of seed viability equations. pp. 653722in Smith, R.D.; Dickie, J.B.; Linington, S.H.; Pritchard, H.W.; Probert, R.J. (Eds) Seed conservation: turning science into practice. Kew, London, Royal Botanic Gardens Kew.Google Scholar
Roberts, E.H. (1972) Viability of seeds. London, Chapman & Hall.CrossRefGoogle Scholar
Ruckenbauer, P. (1971) Keimfähiger Winterweizen aus dem Jahre 1877 [Germinable winterwheat by the 1877]. Die Bodenkultur 22, 372386.Google Scholar
Sallon, S., Solowey, E., Cohen, Y., Korchinsky, R., Egli, M., Woodhatch, I., Somchoni, O. and Kislev, M. (2008) Germination, genetics, and growth of an ancient date seed. Science 320, 1464.CrossRefGoogle ScholarPubMed
Sinclair, T.R. and DeWit, C.T. (1975) Photosynthate and nitrogen requirements for seed production by various crops. Science 189, 565567.CrossRefGoogle ScholarPubMed
Sinniah, U.R., Ellis, R.H. and John, P. (1998) Irrigation and seed quality development in rapid-cycling brassica: soluble carbohydrates and heat-stable proteins. Annals of Botany 82, 647655.CrossRefGoogle Scholar
Steadman, K.J., Pritchard, H.W. and Dey, P.M. (1996) Tissue-specific soluble sugars in seeds as indicators of storage category. Annals of Botany 77, 667674.CrossRefGoogle Scholar
Steiner, A.S. and Ruckenbauer, P. (1995) Germination of 110-year-old cereal and weed seeds, the Vienna sample of 1877. Verification of effective ultra-dry storage at ambient temperature. Seed Science Research 5, 195199.CrossRefGoogle Scholar
Sun, W.Q. and Leopold, A.C. (1997) Cytoplasmic vitrification and survival of anhydrobiotic organisms. Comparative Biochemistry and Physiology 117, 327333.CrossRefGoogle Scholar
Vertucci, C.W. and Leopold, A.C. (1987) Oxidative processes in soybean and pea seeds. Plant Physiology 84, 10381043.CrossRefGoogle ScholarPubMed
Walters, C., Wheeler, L.M. and Grotenhuis, J.M. (2005) Longevity of seeds stored in a genebank: species characteristics. Seed Science Research 15, 120.CrossRefGoogle Scholar