Azərbaycan respublikasi kənd təSƏRRÜfati naziRLİYİ aqrar elm və İnformasiya məSLƏHƏt məRKƏZİ
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ЛИТЕРАТУРА 1. Карагезов Т.Г., Ибрагимова У.Ф., Мамедова М.Г. Стрессорная реакция листьев и корней различных генотипов пшеницы при внезапном и постепенном засолении.//Известия НАН Азербайджана(биологические науки), 2008, том 63, N5-6, стр.14-21 2. Кузнецов В.В. Индуцибельные системы и их роль при адаптации растений к стрессорным факторам. /(Автореф. докт. дисс. В форме научного доклада). Кишенев, 1992, 74 с. 3. Кузнецов В.В.Физиологические механизмы адаптации и создание стресс-толерантных трансгенных растений. /VII Купревичские чтения «Проблемы экспериментальной ботаники», отв. редактор Н.А.Ламан, НАН Беларуси, Минск «Тэхналогiя». 2009, С. 5-78 4. Кузнецов В.В., Шевякова Н.И. Пролин при стрессе: биологическая роль, метаболизм, регуляция.// Физиол. растений , 1999, 46, 321–336 5. Allakhverdiev S.I., Sakamoto A., Nishiyama Y., Inaba M., Murata N. Ionic and Osmotic Effects of NaCl-Induced Inactivation of Photosystems I and II in Synechococcussp // Plant Physiol. 2000. V. 123. P. 1047-1056 6. Allakhverdiev S.I., Sakamoto A., Nishiyama Y., Murata N. Inactivation of Photosystems I and II in Response to Osmotic Stress in Synechococcus. Contribution of Water Channels // Plant Physiol. 2000. V. 122. P. 1201- 1208 7. Allakhverdiev S.I., Nishiyama Y., Miyairi S., Yamamoto H., Inagaki N., Kanesaki Y., Murata N. Salt Stress Inhibits the Repair of Photodamaged Photosystem II by Suppressing the Transcription and Translation of psbA Genes in Synechocystis // Plant Physiol. 2002. V. 130. P. 1443-1453 8. Allakhverdiev S.I., Murata N. Salt Stress Inhibits Photosystems II and I in Cyanobacteria // Photosynth. Res. 2008. V. 98. P. 529-539 9. Dajic Z.(2006) Salt Stress// Physiology and Molecular Biology of Stress Tolerance in Plants / Eds. (MadhavaRao K.V., Raghavendra A.S., Janardhan R.K.) Dordrecht: Kluwer, P. 41-101 10. Deinlein U., Stephan A.B., Horie T., Luo W., Xu G., and Schroeder J.I. Plant salt-tolerance mechanisms. Trends in Plant Science , 2014, 19 , 371- 379 209 11. Geng Yu., Wu R., Wee C.W., Xie F., Wei X., Chan P.M.Y., Tham C., Duan L., Dinneny J.R.A Spatio-Temporal Understanding of Growth Regulation during the Salt Stress Response in Arabidopsis. //Plant Cell, 2013,25, 2132-2154 12. Kanesaki Y., Suzuki I., Allakhverdiev S.I., Mikami K., Murata N . Salt Stress and Hyperosmotic Stress Regulate the Expression of Different Sets of Genes in Synechocystis sp. PCC 6803 // Biochem. Biophys. Res. Commun. 2002. V. 290. P. 339-348 13. KuznetsovVl.V., Shevyakova N.I. Stress responses of tobacco cells to high temperature and salinity: accumulation and phosphorylation of polypeptides. // PhysiologiaPlantarum , 1997,100, 320-326 14. Los D.A., Zinchenko V.V. Regulatory Role of Membrane Fluidity in Gene Expression // Lipids in Photosynthesis. Essential and Regulatory Functions / Eds Wada H., Murata, N. Dordrecht: Springer Science + Business Media B.V., 2009. P. 329-348 15. Los D.A., Zorina A., Sinetova M., Kryazhov S., Mironov K., ZinchenkoV.V. Stress Sensors and Signal Transducers in Cyanobacteria // Sensors. 2010. V. 10. P. 2386-2415 16. Mittler R., Vanderauwera S., Suzuki N., Miller G., Tognetti V.B., Vandepoele K., Gollery M., Shulaev V. and Breusegem F.V.(2011) ROS signaling: the new wave. // Trends in Plant Science , 16 , 63–68 17. Paithoonrangsarid K., Shoumskaya M.A., Kanesaki Y., Satoh S., TabataS., Los D.A., Zinchenko V.V., Hayashi H., Tanticharoen M., Suzuki I., Murata N. Five Histidine Kinases Perceive Osmotic Stress and Regulate Distinct Sets of Genes in Synechocystis // J. Biol. Chem. 2004. V. 279. P. 53 078-53 086. 18. Shapiguzov A., Lyukevich A.A., Allakhverdiev S.I., Sergeyenko T.V., Suzuki I., Murata N., Los D.A. Osmotic Shrinkage of Cells of Synechocystis sp. PCC 6803 by Water Efflux via Aquaporins Regulates Osmostress-Inducible Gene Expression // Microbiology. 2005. V. 151. P. 447-455 19. Shoumskaya M.A., Paithoonrangsarid K., Kanesaki Y., Los D.A., Zinchenko V.V., Tanticharoen M., Suzuki I., Murata N. Identical Hik-Rre Systems Are Involved in Perception and Transduction of Salt Signals and Hyperosmotic Signals but Regulate the Expression of Individual Genes to Different Extents in Synechocystis // J. Biol. Chem. 2005. V. 280. P. 21 531-21 538 20. Taji, Teruaki. Comparative genomics in salt tolerance between Ara- bidopsis and Arabidopsis-related halophyte salt cress using Arabidopsis microarray / TajiTeruaki, Seki Motoaki, Satou Masakazu, Sakurai Tetsuya, Kobayashi Ma-satomo, IshiyamaKanako, Namsaka Yoshihiro, Nanisaka Mari, Zhu Jian-Kang, Shinozaki Kazuo.// Plant Physiol. - 2004. - 135, № 3. - C. 1697-1709 21. Vandepoele K., Gollery M., Shulaev V. and Breusegem F.V.(2011) 210 ROS signaling: the new wave. // Trends in Plant Science , 16, 63–68. 22. Yan S.H., Zhou H.M.(2006) Role of osmolytes as cheperones during the refolding of aminoacylase. Biochem.// Cell Biol ., 84, 30-38 Yüklə 9,32 Mb. Dostları ilə paylaş:
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