Żywotność nasion gryki (Fagopyrum esculentum Moench) przechowywanych długoterminowo w banku genów

• Autorzy: Gryziak G.

Warianty tytułu

EN

Viability of long-term stored buckwheat seeds (Fagopyrum esculentum Moench) in a genebank

• Języki publikacji: PL

Abstrakty

PL

Celem pracy było określenie żywotności nasion gryki zwyczajnej po długoterminowym przechowywaniu w banku genów. W tym celu określono zdolność kiełkowania 25 odmian gryki przed umieszczeniem w banku genów oraz po 6, 11, 21 latach. Po 21 latach przechowywania długoterminowego gryki nie wykazano istotnej zmiany żywotności nasion. Wykazano, że kontrola żywotności dobrej jakości i dosuszanych nasion gryki nie musi być przeprowadzana po raz pierwszy wcześniej niż po 20 latach, jeśli przechowywane są w stabilnym środowisku banku genów.

EN

Genebanks are the facilities used for long-term storage of genetic resources (mainly seeds) precious or rare species and varieties of crop important for food and agriculture. Objects are stored at low temperatures and in airtight containers. According to genebank standards viability monitoring test intervals should be set at one-third of the objects are stored in them to be carried out after, but no longer than 40 years. This time can be determined from the Ellis–Roberts equation, which result is an estimation based on the results of viability tests of seed subjected to accelerated ageing under different conditions. Even slight rounding of the equation input parameters (round-off error equal to 0.01) gives the difference in life expectancy reaching even more than 70 years. Its overestimation and, in consequently, not noticing the falling of seeds’ viability can lead to irretrievable loss of precious germplasm. Thus, the results of multiyear observation of seeds stored under constant conditions in the gene bank are indispensable. The aim of the study is to determine the effect of long-term storage on viability buckwheat expressed as seeds germination capacity. Currently, in the genebank of the National Centre for Plant Genetic Resources IHAR-PIB there are 209 objects of genera Fagopyrum Mill., including 195 objects of buckwheat Fagopyrum esculentum Moench. To compare the viability of buckwheat seeds 25 varieties stored since 1991 in refrigeration (about 1°C) were selected. Before being placed in the genebank buckwheat seeds were subjected to drying to equilibrium, i.e. to 6–8% water content and were closed at vacuum in jars with twist-off lids. In the same year they determined the initial viability in accordance with the ISTA. Subsequent tests were performed in 1997, 2002 and 2012 (i.e. after 6, 11 and 21 years), however in 2012 a simplified method of testing were used: decreased number of seeds to 75 and the medium was changed to cosmetic pads. Other parameters, i.e. temperature and duration of incubation and control days, remained unchanged. Reducing number of seeds resulted from the need to preserve as many objects stored in genebank as possible, in accordance with international genebank standards while changing the medium was dictated by streamlining testing facilities. The percentage of germinated seeds was counted. Buckwheat seeds stored for 21 years in the genebank conditions do not manifest a significant change in viability. Testing of buckwheat seed viability does not need to be performed for the first time earlier than after 20 years (provided that the seeds were of good quality, dried to 6–8% of water and stored in airtight containers at about 1°C).

• Wydawca: -
• Czasopismo: Zeszyty Problemowe Postępów Nauk Rolniczych
• Rocznik: 2016
• Tom: 584
• Opis fizyczny: s.33-38,rys.,tab.,bibliogr.

Twórcy

autor

Gryziak G.

• nstytut Hodowli i Aklimatyzacji Roślin - Państwowy Instytut Badawczy, Krajowe Centrum Roślinnych Zasobów Genowych, 05-870 Radzików

Bibliografia

• Chojnowski M., 2007. Przechowywanie nasion roślin uprawnych w bankach genów – standardy i wymagania. ZPPNR 517, 127–137.
• Conn J.S., Werdin-Pfisterer N.R., 2010. Variation in seed viability and dormancy of 17 weed species after 24.7 years of burial: the concept of buried seed safe sites. Weed Sci. 58, 209–215.
• IHAR-PIB, 2015. EGISET Dystrybucja obiektów. Dostępne na http://egiset.ihar.edu.pl/ (data dostępu: 13.07.2015).
• Ellis R.H., Roberts E.H., 1980. Improved equations for the prediction of seed longevity. Ann. Bot. 45, 13–30.
• FAO, 2013. Genebank standards for plant genetic resources for food and agriculture. Rome.
• Górski M., 2004. Reakcja odmian gryki na długoterminowe przechowywanie w banku genów. Biul. IHAR 233, 157–162.
• FAO/IPGRI, 1994. Genebank standards. Rome.
• Hammer Ø., Harper D.A.T., Ryan P.D., 2001. PAST: Paleontological statistics software package for education and data analysis. Palaeon. Electron. 4 (1), 9.
• Ho-Sun L., Young-Ah J., Young-Yi L., Sok-Young L., Yeon-Gyu K., 2013. Comparison of seed viability among 42 species stored in a genebank. Korean J. Crop Sci. 58(4), 432–438.
• ISTA, 1985. International rules for seed testing. Rules and Annexes 1985. Seed Sci. Technol. 13, 299–513.
• Luthar Z., 2013. Determination of germination and freshness of preserved buckwheat samples in the genebank. W: New challenges in agronomy 2013, Zreče, Slovenia, 24–25 January, 2013. Symposium Proceedings (Red. B. Čeh, P. Dolničar, R. Mihelič) Slovenian Society for Agronomy, Lublana, 315–321.
• MRiRW, 2014. Program Rozwoju Obszarów Wiejskich na lata 2014–2020. Skrócona wersja Programu. Warszawa. Pobrane z http://www.minrol.gov.pl/content/download/50664/278862/ version/3/file/PROW2014-2020.pdf (data dostępu: 24.07.2015).
• Niedzielski M., Walters C., Łuczak W., Hill L.M., Wheeler L.J., Puchalski J., 2009. Assessment of variation in seed longevity within rye, wheat and the intergenetic hybrid triticale. Seed Sci. Res. 19, 213–224.
• Sapra R.L., Narain P., Bhat S.R., Lal S.K., Jain S.K., 2003. Prediction of seed longevity in the genebank: How reliable are the estimates? Curr. Sci. 85, 1612–1616.