Поделиться Поделиться

Диксон М., Уэбб Э. Ферменты: Пер. с англ. –М.: Мир, 1982.-Т. 3 – 921с

3. Ершова А.Н. Организация метаболических процессов растений в условиях дефицита кислорода и повышенного содержания СО2: дис. …доктора биол. наук / А.Н. Ершова. – Воронеж, 1996. – 426 с.

4. Лакин Г.Ф. Биометрия / Г.Ф. Лакин. - М.: Высш. шк., 1990. - 351с.

5. Особенности метаболической адаптации у растений амаранта в условиях гипобарической гипоксии/ С.А. Войцеховская и др.// Сельскохозяйственная биология.-2010. - №5.-С.106-111.

6. Ракитина В.Г. Нарушение нормального газообмена растений – фактор, препятствующий защитному действию сахаров и глицерина/ В.Г. Ракитина // Физиология растений. – 1978. – Т. 25, № 3. – С. 584-591.

7. Селиванова Н.В. Биохимические методы исследования ферментов глиоксилатного циклаи ЦТК: учеб. пособие / Н.В. Селиванова, Д.Н. Федорин, А.Т. Епринцев. - Воронеж: издаельский дом ВГУ, 2014. -50с.

8. Чиркова Т.В. Физиологические основы устойчивости растений. СПб.: Изд-во СПб. ун-та, 2002. 244 с.

9. Amino acid sequence of porcine heart fumarase / J.C. Sacchettini [et al.] // Biochem Biophys Res Commun. – 1988. – V. 153. – P. 435-440.

10. Arabidopsis has a cytosolic fumarase required for the massive allocation of photosynthate into fumaric acid and for rapid plant growth on high nitrogen / I. Pracharoenwattana [et al.] // Plant J. — 2010. — V. 62. — P. 785-795.

11. Bailey-Serres J. Flooding stress: acclimations and genetic diversity/J. Bailey-Serres, L.A. Voesenek//Annual Review of Plant Biology.-2008.-V.59.-P.313-339.

12. Bown A.W. The influence of carbon dioxide on protein synthesis in ethiolated coleoptiles of Avena sativa / A.W. Bown, W.W. Lampmann // Canad. J. Bot. – 1972. – V. 50.- N.9. – Р. 1937-1942.

13. Chomczynski P. Singlestep-method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction / P. Chomczynski, N. Sacchi // Anal. Biochem. – 1987. – V. 162. – P. 156–159.

14. Comparative analysis between plant species of transcriptional and metabolic responses to hypoxia/R. Narsai [et al.] // New Phytologist.-2011.-V.190.-P.472-487.

15. Decreased Mitochondrial Activities of Malate Dehydrogenase and Fumarase in Tomato Lead to Altered Root Growth and Architecture via Diverse Mechanisms/ M.J. van der Merwe [et al.] //Plant Physiology.-2009.-V.149.-P.653-669

16. Devereux J. A comprehensive set of sequence analysis programs for the VAX / J. Devereux, P. Haeberli, O.A. Smithies // Nucleic Acids Res. – 1981. – V. 12. – P. 7665–7669.

17. Douce R. The uniqueness of plant mitochondria / R. Douce, M. Neuburger // Annu Rev Plant Physiol Plant Mo1 Biol. – 1989. – V. 40. – P. 371-414

18. Expression and properties of the mitochondrial and cytosolic forms of fumarase in germinating maize seeds/A.T. Eprintsev [et al.] // Physiologia Plantarum.-2014.-V.152.-P.231-240.

19. Ferreira de Sousa C. The metabolic response of plants to oxygen deficiency/С. Ferreira de Sousa, L. Sodek//Braz. J. Plant Physiol.-2002.-V.14.-N.2.-P.344-356.

20. Fumaric acid: an overlooked form of fixed carbon in Arabidopsis and other plant species / D.W. Chia [et al.] // Planta. – 2000. – V. 211. – P. 743–751

21. Gupta K.J. Reactive Nitrogen Species in Mitochondria and Their Implications in Plant Energy Status and Hypoxic Stress Tolerance/ K.J.Gupta, A.U. Igamberdiev // Frontiers in Plant Science.-2016.-V.7.-P.369-376.

22. Hypoxia up-regulates mitochondrial genome-encoded transcripts in Arabidopsis roots/ M.W. Hameed //Genes & Genetic Systems.-2016.-V.90.-N.6.-P.325-334.

23. Igamberdiev A.U. Plant mitochondrial function during anaerobiosis/ A.U. Igamberdiev, R.D.Hill // Annals of Botany.-2008.-V.103.-P.259-268

24. Kinoshita T. Epigenetic Memory for Stress Response and Adaptation in Plants/T. Kinoshita, S. Motoaki// Annals of Botany.-2014.-V.55.-P.1859-1863.

25. Low Oxygen Response Mechanisms in Green Organisms/Valeria Banti [et al.]//IJMS.- 2013.-V.14.-P.4734-4761.

26. Molecular cloning, nucleotide sequence and expression of a Sulfolobus solfataricus gene encoding a class I1 fumarase / S. Colombo [et al.] //FEBS Lett. -– 1994. – V. 337. - P. 93-98.

27. Müller E. Influence of NO3- and NH4+ nutrition on fermentation, nitrate reductase activity and adenylate energy charge of roots of Carex pseudocyperus L. and Carex sylvatica Huds. exposed to anaerobic nutrient solutions/E. Müller, B. Albers,P. Janiesch//Plant Soil.-1994.-V.166.-P.221-230

28. Plant inner membrane anion channel (PIMAC) function in plant mitochondria/ M. N. Laus [et al.] //Plant Cell Physiol.-2008.-V.49.-P.1039-1055.

29. Protein import into mitochondria: origins and functions today / R. Lister // Mol Membr Biol. – 2005. – V. 22. – P.87–100.

30. Raghavendra A.S. Interdependence of photosynthesis and respiration in plant cells: interactions between chloroplasts and mitochondria / A.S. Raghavendra, K. Padmasree, K. Saradadevi // Plant Sci. – 1994. – V. 97. – P. 1-14.

31. Taylor A.A. Tissue and subcellular localization of enzymes of arginine metabolism in Pisum sativum. / Taylor A.A., Stewart G.R. // Biochem. Biophys. Res. Commun. 1981. - V. 101. - P. 1281–1289.

32. The exception proves the rule? Dual targeting of nuclear-encoded proteins into endosymbiotic organelles/B. Baudisch [et al.] // New Phytologist.-2014.-V.201.-P.80-90

33. Unifying theory of hypoxia tolerance: molecular/metabolic defense and rescue mechanisms for surviving oxygen lack/ P W Hochachka [et al.] //PNAS.-1996.-V.93.-N.18.-P.9493-9498.

34. Vartapetian B. Plant Adaptations to Anaerobic Stress/B. Vartapetian, M. Jackson // Annals of Botany.-1997.-V.79.-P.3-20

35. Wiedemann N. The protein import machinery of mitochondria / N. Wiedemann, A.E. Frazier, N. Pfanner // J Biol Chem. – 2007. – V. 279. – P. 14473–14476

36. Yogev O. Fumarase: a paradigm of dual targeting and dual localized functions/O. Yogev, A. Naamati// FEBS.-2011.-V.287.-P.4230-4242.

← Предыдущая страница | Следующая страница →