Abstract
The importance of rich biological diversity in providing greater opportunities for economic development, discoveries in medicine and especially in adaptation responses to challenges such as climate change and natural disasters is receiving tremendous attention globally. One way of conserving biological materials of plants is through storage of seeds in genebanks. Presently there are 1,750 genebanks worldwide storing more than 7.4 million accessions. Mankind has also taken a giant leap in establishing the Svalbard Global Seed Vault the largest seed bank conserving seeds under permafrost conditions with a capacity of four million accessions under one roof. The challenge to date is to ensure that the seed genebanks are coordinated and properly managed in relation to maintenance of viability, characterization with systems that are user friendly and finally is accessible for utilization when necessary. This chapter introduces the importance of having genebanks and how the genebanks are observed as an insurance policy. It explains the biology of seeds and factors which promote seed longevity. The importance of understanding the nature of the seed to be stored is discussed in relation to orthodox, recalcitrant and intermediate seeds. The method suitable for different kind of seeds such as cryogenic storage for recalcitrant and intermediate seeds is mentioned. The role and types of seed banks, national, regional and international as well as a genebank of single crop or multiple crops is discussed. Finally a discussion on issues in seed banks management in general.
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References
Barclay A (2009) Scuba rice: Stemming the tide in flood-prone South Asia. Rice Today 8(2): 26–31
Barona MJ (2011) Mankind takes a giant leap – again. Rice Today 10(3):30–31, International Rice Research Institute
Barton LV, Polunin N (2005) SEEDS: their preservation and longevity. Asiatic Publishing House, Delhi, 216 pp
Benson EE (1999) Cryopreservation. In: Benson EE (ed) Plant conservation biotechnology. Taylor & Francis, London, pp 83–95
Berjak P, Pammenter NW (2004) Recalcitrant seeds. In: Benech-Arnold RL, Sanchez RA (eds) Handbook of seed physiology: applications to agriculture. Haworth Press, New York, pp 305–345
Berjak P, Farant JM, Mycock DJ, Pammenter NW (1990) Recalcitrant (homoiohydrous) seeds: the enigma of their desiccation sensitivity. Seed Sci Technol 18:297–310
Berjak P, Boby Varghese S, Pammenter NW (2011) Cathodic amelioration of the adverse effects of oxidative stress accompanying procedures necessary for cryopreservation of embryonic axes of recalcitrant-seeded species. Seed Sci Res 21:187–203
Bioversity International, IRRI, WARDA (2007) Descriptors for wild and cultivated rice (Oryza spp.). Bioversity International/International Rice Research Institute/WARDA, Africa Rice Center, Rome/Los Banos/Cotonou
Brenchley WE (1918) Buried weed seeds. J Agric Sci 9:1–31
Brown HT, Escombe F (1897–1898) Note on the influence of very low temperatures on the germinative power of seeds. Proc R Soc Lond B 62:160–165
Chin HF (1978) Production and storage of recalcitrant seeds in the tropics. Acta Hortic 83:17–21
Chin HF (1994) Seedbanks: conserving the past for the future. Seed Sci Technol 22:385–400
Chin HF, Aziz M, Ang BB, Hamzah S (1981) The effect of moisture and temperature on the ultrastructure and viability of seeds of Hevea brasiliensis. Seed Sci Technol 9:411–422
Chin HF, Hor YL, Mohd Lassim MB (1984) Identification of recalcitrant seeds. Seed Sci Technol 12:429–436
Cohen BM (1991) Nikolai Ivanovich Vavilov: the explorer and plant collector. Econ Bot 45(1): 38–46
Concellon A, Anon MC, Chaves AR (2007) Effect of low temperature storage on physical and physiological characteristics of eggplant fruit (Solanum melongena L.). LWT- Food Sci Technol 40:389
Consultative Group on International Agricultural Research (1996). Report of the CGIAR Genetic Resources Policy Committee on facing the poverty challenge
Darlington HT (1951) The seventy year period for Dr. Beal’s seed viability experiment. Am J Bot 38:379–381
Dulloo ME, Hunter D, Borelli T (2010) Ex situ and in situ conservation of agricultural biodiversity: major advances and research needs. Not Bot Horti Agrobot Cluj 38(2) special issue:123–135
Ellis RH, Hong TD, Roberts EH (1990) An intermediate category of seed storage behaviour? I. Coffee. J Exp Bot 41:1167–1174
Ellis RH, Hong TD, Roberts EH (1991) Effect of storage temperature and moisture on the germination of papaya seeds. Seed Sci Res 1:69–72
Ellis RH, Hong TD, Astley D, Pinnegar AE, Kraak HL (1996) Survival of dry and ultra-dry seeds of carrot, groundnut, lettuce, oilseed rape, and onion during five years; hermetic storage at two temperatures. Seed Sci Technol 24:347–358
FAO/IPGRI (1994) Genebank standards. FAO and IPGRI, Rome
Guest EA (1933) A package of seeds. http://www.goantiques.com/detail,package-seeds-edgar,765874.html. Accessed on 15 November 2011
Hajari E, Berjak P, Pammenter NW, Paula Watt M (2011) A novel means for cryopreservation of germplasm of the recalcitrant-seeded species, Ekebergia capensis. CryoLetters 32(4):308–316
Hanson J, Williams JT, Freund R (1984) Institutes conserving crop germplasm: the IBPGR global network of genebanks. IBPGR, Rome, 25 pp
IBPGR (1976) Report of IBPGR working group on engineering, design and cost aspects of long-term seed storage facilities. International Board for Plant Genetic Resources, Rome
International Rice Research Institute (2010) Mankind takes a giant leap – again. Rice Today 10(3):30–31
IRRI (2000) Rice genebank operation manual http://www.knowledgebank.irri.org/extension/index.php/grcmanual
Johnson RC, Hodgkin T (1999) Core collections for today and tomorrow. IPGRI, Rome, 81 pp
Kesseler RL, Stuppy W (2006) Seeds time capsule of life. Papadaley, London, 264 pp
Kyu-Won K, Chung H-K, Cho G-T, Ma K-H, Chandrabalan D, Gwag J-G, Kim T-S, Cho E-G, Park Y-J (2007) PowerCore. Bioinformatics, vol 23, issue 16. Oxford University Press, Oxford, pp 2155–2162
Lipman CB (1936) Normal viability of seeds and bacterial spores after exposure to temperatures near absolute zero. Plant Physiol 11:201–205
McDonald MB (1999) Seed deterioration: physiology, repair and assessment. Seed Sci Technol 27:177–237
Narayana Murthy UM, Kumar PP, Sun WQ (2003) Mechanisms of seed ageing under different storage conditions for Vigna radiata (L.) Wilczek: lipid peroxidation, sugar hydrolysis, Maillard reactions and their relationship to glass state transition. J Exp Bot 54(384):1057–1067
Painting KA, Perry MC, Denning RA, Ayad WG (1995) Guidebook for genetic resources documentation. IPGRI, Rome
Paule Ma C, Cuerdo JG, Reyes MA, Rala A, van Etten J, Nelson A, Hijmans RJ (2010) Mapping genebank collections. Rice Today 9(2):30–31
Pérez-García F, González-Benito ME, Gómez-Campo C (2007) High viability recorded in ultra-dry seeds of 37 species of Brassicaceae after almost 40 years of storage. Seed Sci Technol 35:143–153
Pérez-García F, Gómez-Campo C, Ellis RH (2009) Successful long-term ultra dry storage of seed of 15 species of Brassicaceae in a genebank: variation in ability to germinate over 40 years and dormancy. Seed Sci Technol 37(3, 10):640–649
Plucknett DL, Smith NJH, Williams JT, Anishetty NM (1987) Genebanks and the World’s food. Princeton University Press, Princeton
Porsild AE, Pharington CR, Mulligan GA (1967) Lupinus arcticus’ Wats. grown from seeds of pleistocene age. Science 158:113–114
Priestley DA (1986) Seed aging: implications of seed storage and persistence in the soil. Cornell University Press, Ithaca, 304 pp
Pukacka S, Ratajczak E (2005) Production and scavenging of reactive oxygen species in Fagus sylvatica seeds during storage at varied temperature and humidity. J Plant Physiol 162: 873–885
Rao NK, Hanson J, Dulloo ME, Ghosh K, Nowell A, Larinde M (2006) Manual of seed handling in genebanks. Handbooks for genebanks no. 8. Bioversity International, Rome
Roberts EH (1973) Predicting the storage life of seeds. Seed Sci Technol 1:499–514
Roberts EH, Abdalla FH (1968a) The effects of temperature and moisture on the induction of genetic changes in seeds of barley, broad beans, and peas during storage. Ann Bot 33(1): 153–167
Roberts EH, Abdalla FH (1968) The influence of temperature, moisture, and oxygen on the period of seed viability in barley, broad beans, and peas. Ann Bot 32:97–117
Shen-Miller J (2002) Sacred lotus the long-living fruits of China Antique. Seed Sci Res 12:131–143
Shetty P (2005) Tsunami-hit farmers to grow salt-tolerant rice. http://www.scidev.net/en/news/tsunamihit-farmers-to-grow-salttolerant-rice.html. Accessed 2 Feb 2005
Smith MT, Berjak P (1995) Deteriorative changes associated with the loss of viability of stored desiccation-tolerant and desiccation-sensitive seeds. In: Kigel J, Galili G (eds) Seed development and germination. Marcel Dekker, New York, pp 701–746
Stanwood PC, Bass CN (1981) Seed germplasm preservation using liquid nitrogen. Seed Sci Technol 9:423–427
Tatum LA (1971) The southern corn leaf blight epidemic. Science 171(3976):1113–1116
Vavilov NI (1940) The new systematic of cultivated plants. In: Huxley J (ed) The new systematics. Clarendon Press, Oxford, pp 549–566
Vavilov NI (1957) World resources of cereals, leguminous seed crops and flax, and their utilization in plant breeding. Academy of Sciences of the USSR, Moscow
Vidal J (2010) Pavlovsk seed bank faces destruction. guardian.co.uk, Sunday 8 Aug 2010. Article history: http://www.guardian.co.uk/environment/2010/aug/08/pavlovsk-seed-bank-russia
Walters C (1998) Understanding the mechanisms and kinetics of seed aging. Seed Sci Res 8:223–244
Zhang Z (2002) Plant genetic resources data and information management and public awareness. In: Zhang Z, Zhou M, Ramanatha Rao V (eds) Plant genetic resources network in East Asia. Proceedings of the meeting for the regional network for conservation and use of plant genetic resources in East Asia, 13–16 Aug 2001, Ulaanbaatar, Mongolia. IPGRI Office for East Asia, Beijing
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Chin, H.F., Quek, P., Sinniah, U.R. (2013). Seed Banks for Future Generation. In: Normah, M., Chin, H., Reed, B. (eds) Conservation of Tropical Plant Species. Springer, New York, NY. https://doi.org/10.1007/978-1-4614-3776-5_3
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DOI: https://doi.org/10.1007/978-1-4614-3776-5_3
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