Search Results - "ВЫСОКОТЕМПЕРАТУРНЫЙ СТРЕСС"

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Изменчивость признаков мужского гаметофита у перспективных линий томата в зависимости от уровня закладки соцветия на вегетирующем растении

Authors: Macovei, M.D., Makovey, M.D., Macovei, M., Маковей, М.Д.

Source: Buletinul Academiei de Ştiinţe a Moldovei. Ştiinţele vieţii 333 (3) 96-106

Subject Terms: гетерозисная селекция, линии, признаки, соцветия, пыльца, пыльцевые трубки, высокотемпературный стресс, Изменчивость

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Relation: https://ibn.idsi.md/vizualizare_articol/57374; urn:issn:1857064X

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TEMPERATURE STRESS AND THERMO DORMANCY OF VEGETABLE SEEDS OF UMBELLIFERAE CROPS. FEATURES OF INDUCTION, MANIFESTATION AND OVERCOME ; ТЕМПЕРАТУРНЫЙ СТРЕСС И ТЕРМОПОКОЙ СЕМЯН ОВОЩНЫХ ЗОНТИЧНЫХ КУЛЬТУР. ОСОБЕННОСТИ ИНДУКЦИИ, ПРОЯВЛЕНИЯ И ПРЕОДОЛЕНИЯ (ЧАСТЬ I)

Authors: A. F. Buharov, D. N. Baleev, А. Ф. Бухаров, Д. Н. Балеев

Source: Vegetable crops of Russia; № 2 (2013); 36-41 ; Овощи России; № 2 (2013); 36-41 ; 2618-7132 ; 2072-9146

Subject Terms: степень недоразвития зародыша (СНЗ), embryo, seedgermination, Umbelliferae, thermodormancy, hightemperature stress, thermotolerance, thermosensitive, the temperature coefficient (Q10), the degree of under development of theembryo (DUE), зародыш, прорастание семян зонтичные, термопокой, высокотемпературный стресс, термотоустойчивость, чувствительность к высокой температуре

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Relation: https://www.vegetables.su/jour/article/view/134/362; Балеев Д. Н., Бухаров А. Ф. Аллелопатия овощных зонтичных (Umbelliferae). Торможение прорастания и индукция состояния покоя семян. – Saarbrcken: LAP Lambert Academic Publishing GmbH & Co. KG, 2012. 128 с.; Балеев Д. Н., Бухаров А. Ф. Специфика прорастания семян овощных зонтичных культур при различных температурных режимах // Овощи России, 2012. №3 (16). С. 38 – 46.; Доспехов Б. А. Методика полевого опыта. – М.: Агропромиздат, 1985. 351 с.; Кошкин Е. И. Физиология устойчивости сельскохозяйственных культур. – М.: Дрофа, 2010. 638 с.; Леманн Е., Айхеле Ф. Физиология прорастания семян злаков // пер. с нем. В. А. Бриллиант, М. Ф. Лилиенштерн. – М.: Сельхозгиз, 1936. 489 с.; Alonso6Blanco C., Bentsink L., Hanhart C.J., Blankestijnde Vries H., Kornneef M. Analysis of natural variation at seed dormancy loci of Arabidopsis thaliana // Genetics, 2003. Vol. 164. pp. 711 – 729.; Baskin J.M., Baskin C.C. A classification system for seed dormancy // Seed Science Research, 2004. Vol. 14. pp. 1 – 16.; Bentsink L., Hanson J., Hanhart C.J. Natural variation for seed dormancy in Arabidopsis is regulated by additive genetic and molecular pathways // Proceedings of the National Academy of Sciences of the United States of America, 2010. Vol. 107. pp. 4264 – 4269.; Bentsink L., Jowett J., Hanhart C.J., Koornneef M. Cloning of DOG1, a quantitative trait locus controlling seed dormancy in Arabidopsis // Proceedings of the National Academy of Sciences of the United States of America, 2006. Vol. 103. pp. 1742 – 1747.; Berges J. A., Varela D. E., Harrison P. J. Effects of temperature on growth rate, cell composition and nitrogen metabolism in the marine diatom Thalassiosira pseudonana (Bacillariophyceae) // Mar. Ecol. Prog. Ser., 2002. Vol. 225. pp. 139 – 146.; Chiwocha D. S. Karrikins: a new family of plant growth regulators in smoke // Plant Sci., 2009. Vol. 177. pp. 252 – 256.; Endo A., Tatematsu K., Hanada K. Tissue6specific transcriptome analysis reveals cell wall metabolism, flavonol biosynthesis and defense responses are activated in the endosperm of germinating Arabidopsis thaliana seeds // Plant and Cell Physiology, 2012. Vol. 53. pp. 16 – 27.; Finch6Savage W. E., Leubner6Metzger G. Seed dormancy and the control of germination // New Phytologist, 2006. Vol. 171. pp. 501 – 523.; Finkelstein R., Reeves W., Ariizumi T., Steber C. Molecular aspects of seed dormancy // Annual Review of Plant Biology, 2008. Vol. 59. pp. 387 – 415.; Flintham J. E. Different genetic components control coat6imposed and embryo6imposed dormancy in wheat // Seed Sci. Res., 2000. Vol. 10. pp. 43 – 50.; Gu X.Y., Chen Z.X., Foley M.E. Inheritance of seed dormancy in weedy rice // Crop Science, 2003. Vol. 43. pp. 835 – 843.; Gubler F., Millar A. A., Jacobsen J. V. Dormancy release, ABA and pre6harvest sprouting // Curr. Opin. Plant Biol., 2005. Vol. 8. pp. 183 – 187.; Holdsworth M.J., Bentsink L., Soppe W.J.J. Molecular networks regulating Arabidopsis seed maturation, after6ripening, dormancy and germination // New Phytologist, 2008. Vol. 179. pp. 33 – 54.; Kendall S.L., Hellwege A., Marriot P., Whalley C., Graham I.A., Penfield S. Induction of dormancy in Arabidopsis summer annuals requires parallel regulation of DOG1 and hormone metabolism by low temperature and CBF transcription factors // The Plant Cell, 2011. Vol. 23. pp. 2568 – 2580.; Kilian B., Ozkan H., Pozzi C., Salamini F. Domestication of the Triticeae in the fertile crescent. In Genetics and Genomics of the Triticeae // In: Plant Genetics and Genomics: Crops and Models. – New York: Springer Science + Business Media, 2009. pp. 81 – 119.; Li Y.6C., Ren J.6P., Cho M.6J., Zhou S.6M., Kim Y.6B. The level of expression of thioredoxin is linked to fundamental properties and applications of wheat seeds // Mol. Plant, 2009. 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ABA levels and sensitivity in developing wheat embryos of sprouting resistant and susceptible cultivars // Plant Physiol., 1987. Vol. 84. pp. 61 – 66.; Warner R. L., Kudrna D. A., Spaeth S. C., Jones S. S. Dormancy in wheat6grain mutants of Chinese spring wheat (Triticum aestivumL.) // Grain Sci. Res., 2000. Vol. 10. pp. 51 – 60.; Xie X., Yoneyama K., Yoneyama K. The strigolactone story // Annu. Rev. Phytopathol, 2010. Vol. 48. pp. 93 – 117.; https://www.vegetables.su/jour/article/view/134

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https://doi.org/10.18619/2072-9146-2013-2-36-41

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