The combined effect of salinity (NaCl) and copper ions on biomass and amino acid content in wheat varieties
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Keywords:
wheat, copper, salinity, growth, aminoacids.Abstract
The article presents results of analysis of the joint and separate effect of salinity (NaCl) and copper ions (CuSO4) on biomass accumulation, and the amino acid content in the wheat varieties. At separate and joint effect of salinity and copper ions are reduced growth and biomass accumulation of wheat varieties. Identified resistant varieties of wheat to the effect of salinity and copper. On the accumulation of biomass by shoots Kazakhstanskaya-3 and Kazakhstanskaya rannaya weree more resistant to the combined effect of copper and salinity, and Shagala and Melturn - the most sensitive. The joint and separate effect of these stressors changes a content of amino acids such as glutamic acid, proline, valine, alanine, and the other aminoacids as a response protective reaction of plants.References
Литература
1 Тасекеев М. Биоремедиация токсичных промышленных отходов // Промышленность Казахстана. – 2004. – № 5 (26). – С. 59-63.
2 http://www.ca-oasis.info/oasis/?jrn=22&id=157.
3 Minocha R., Shortle W.C., Long S., Minocha S. C. A rapid and reliable procedure for extraction of cellular polyamines and inorganic ions from plant tissues // J. Plant Growth Regul. – 1994. – № 13 – Р. 187-193.
4 Kholodova V.P., Volkov K.S., Kuznetsov V.V. Adaptation of the common ice plant to high copper and zinc concentrations and their potential using for phytoremediation // Russ. J. Plant Physiol. - 2005. - Vol. 52. - P. 848–858.
5 Khoshgoftar A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee SEATM., Parker D.R. Salinity and zinc application effects on phytoavialability of cadmium and zinc // Soil Sci Soc. Am. J. – 2004. – Vol. 68. - P. 1885–1889.
6 Khoshgoftarmanesh A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee Seatm Cadmium and zinc in saline soil solutions and their concentrations in wheat // Soil Sci Soc Am J.- 2006. - Vol. 70. - P. 582–589.
7 El–Bassiouny H.M., Mostafa H.A., El–Khawas S.A., Hassanein R.A., Khalil S.I. and Abd El–Monem A.A. Physiological responses of wheat plant to foliar treatments with arginine or putrescine// Aus. J. Basic and Appl. Sci -2008 – V.2(4) – P.1390-1403.
8 Штеменко Н.Т., Сорочан О.О. Вілні амiинокислоти на раннiх фазах прорастаиня зерна кукурудзи. // Физиология и биохимия культурных растений. -2001. – Т. 33.- №5. – С.441-445.
9 Епринцев А.Т., Солодилова О.С., Хожаинова Г.Н. Роль свободных аминокислот в адаптивной реакции кукурузы в условиях солевого стресса // Вестник ВГУ. – 2003. – № 2. – C. 132-135.
10 Willem R., Li Y., Verbruggen I., Biesemans M., Jacobs M. Proline metabolism in wild-type and in salt-tolerant mutant of Nicotiana plumbaginifolia studied by C-nucler magnetic resonance imaging// Plannt physiology. - 1999. – V. 121. – P. 1281-1290.
11 Al.Asbahi А.А., Maqtari М.А.ABA biosynthesis defective mutants reduce some free amino acids accumulation under drought stress in tomato leaves in comparison with Arabidopsis plants tissues. // Journal of Stress Physiology & Biochemistry. – 2012. - V. 8. - № 2. - P. 179-192
12 Чиркова Т.В. «Физиологические основы устойчивости растений». Учебное пособие. – СПб.: Изд-во С.-Петерб. Ун-та, 2002. – 244 с.
13Zagdanska I. B. Influence of water stress upon photosynthetic carbon metabolism in wheat // Journal of Plant Physiology. – 1984. -V. 116. – P. 153-160.
14 Гордон Л.Х. Дыхание и водно-солевой обмен растительных тканей. – М.:Наука. – 1976. – 119 с.
15 Daschener K., Coues I., Binder S. The mitochondrial isovaleryl-coenzyme A dehydrogenase of Arabidopsis oxidizes intermediates of leucin and valincatabolism // Plant Physiol. -2001. – V. 126. – P. 601-612
16 Malekzadeh, P., J. Khara and R. Heidari. Effect of exogenous Gama-aminobutyric acid on physiological tolerance of wheat seedling exposed to chilling stress // Iranian Journal of Plant Physiology -2012- V. 3 (1). – P. 611 - 617.
17 Ingle R.A. Histidine Biosynthesis //The Arabidopsis Book. -2011. – V. 2. - P. 1-9.
References
1 Tasekeev M. Bioremediacija toksichnyh promyshlennyh othodov // Promyshlennost' Kazahstana. – 2004. – № 5 (26). – P. 59-63.
2 http://www.ca-oasis.info/oasis/?jrn=22&id=157.
3 Minocha R., Shortle W.C., Long S., Minocha S. C. A rapid and reliable procedure for extraction of cellular polyamines and inorganic ions from plant tissues // J. Plant Growth Regul. – 1994. – № 13 – Р. 187-193.
4 Kholodova V.P., Volkov K.S., Kuznetsov V.V. Adaptation of the common ice plant to high copper and zinc concentrations and their potential using for phytoremediation // Russ. J. Plant Physiol. - 2005. - Vol. 52. - P. 848–858.
5 Khoshgoftar A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee SEATM., Parker D.R. Salinity and zinc application effects on phytoavialability of cadmium and zinc // Soil Sci Soc. Am. J. – 2004. – Vol. 68. - P. 1885–1889.
6 Khoshgoftarmanesh A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee Seatm Cadmium and zinc in saline soil solutions and their concentrations in wheat // Soil Sci Soc Am J.- 2006. - Vol. 70. - P. 582–589.
7 El–Bassiouny H.M., Mostafa H.A., El–Khawas S.A., Hassanein R.A., Khalil S.I. and Abd El–Monem A.A. Physiological responses of wheat plant to foliar treatments with arginine or putrescine// Aus. J. Basic and Appl. Sci -2008 – V.2(4) – P.1390-1403.
8 Shtemenko N.T., Sorochan O.O. Vіlnі amiinokisloti na rannih fazah prorastainja zerna kukurudzi. // Fiziologija i biohimija kul'turnyh rastenij. -2001. – T. 33.- №5. – P.441-445.
9 Eprincev A.T., Solodilova O.S., Hozhainova G.N. Rol' svobodnyh aminokislot v adaptivnoj reakcii kukuruzy v uslovijah solevogo stressa // Vestnik VGU. – 2003. – № 2. – P. 132-135.
10 Willem R., Li Y., Verbruggen I., Biesemans M., Jacobs M. Proline metabolism in wild-type and in salt-tolerant mutant of Nicotiana plumbaginifolia studied by C-nucler magnetic resonance imaging// Plannt physiology. - 1999. – V. 121. – P. 1281-1290.
11 Al.Asbahi А.А., Maqtari М.А.ABA biosynthesis defective mutants reduce some free amino acids accumulation under drought stress in tomato leaves in comparison with Arabidopsis plants tissues. // Journal of Stress Physiology & Biochemistry. – 2012. - V. 8. - № 2. - P. 179-192
12 Chirkova T.V. «Fiziologicheskie osnovy ustojchivosti rastenij». Uchebnoe posobie. – SPb.: Izd-vo S.-Peterb. Un-ta, 2002. – 244 p.
13Zagdanska I. B. Influence of water stress upon photosynthetic carbon metabolism in wheat // Journal of Plant Physiology. – 1984. -V. 116. – P. 153-160.
14 Gordon L.H. Dyhanie i vodno-solevoj obmen rastitel'nyh tkanej. – M.:Nauka. – 1976. – 119 p.
15 Daschener K., Coues I., Binder S. The mitochondrial isovaleryl-coenzyme A dehydrogenase of Arabidopsis oxidizes intermediates of leucin and valincatabolism // Plant Physiol. -2001. – V. 126. – P. 601-612
16 Malekzadeh, P., J. Khara and R. Heidari. Effect of exogenous Gama-aminobutyric acid on physiological tolerance of wheat seedling exposed to chilling stress // Iranian Journal of Plant Physiology -2012- V. 3 (1). – P. 611 - 617.
17 Ingle R.A. Histidine Biosynthesis //The Arabidopsis Book. -2011. – V. 2. - P. 1-9.
1 Тасекеев М. Биоремедиация токсичных промышленных отходов // Промышленность Казахстана. – 2004. – № 5 (26). – С. 59-63.
2 http://www.ca-oasis.info/oasis/?jrn=22&id=157.
3 Minocha R., Shortle W.C., Long S., Minocha S. C. A rapid and reliable procedure for extraction of cellular polyamines and inorganic ions from plant tissues // J. Plant Growth Regul. – 1994. – № 13 – Р. 187-193.
4 Kholodova V.P., Volkov K.S., Kuznetsov V.V. Adaptation of the common ice plant to high copper and zinc concentrations and their potential using for phytoremediation // Russ. J. Plant Physiol. - 2005. - Vol. 52. - P. 848–858.
5 Khoshgoftar A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee SEATM., Parker D.R. Salinity and zinc application effects on phytoavialability of cadmium and zinc // Soil Sci Soc. Am. J. – 2004. – Vol. 68. - P. 1885–1889.
6 Khoshgoftarmanesh A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee Seatm Cadmium and zinc in saline soil solutions and their concentrations in wheat // Soil Sci Soc Am J.- 2006. - Vol. 70. - P. 582–589.
7 El–Bassiouny H.M., Mostafa H.A., El–Khawas S.A., Hassanein R.A., Khalil S.I. and Abd El–Monem A.A. Physiological responses of wheat plant to foliar treatments with arginine or putrescine// Aus. J. Basic and Appl. Sci -2008 – V.2(4) – P.1390-1403.
8 Штеменко Н.Т., Сорочан О.О. Вілні амiинокислоти на раннiх фазах прорастаиня зерна кукурудзи. // Физиология и биохимия культурных растений. -2001. – Т. 33.- №5. – С.441-445.
9 Епринцев А.Т., Солодилова О.С., Хожаинова Г.Н. Роль свободных аминокислот в адаптивной реакции кукурузы в условиях солевого стресса // Вестник ВГУ. – 2003. – № 2. – C. 132-135.
10 Willem R., Li Y., Verbruggen I., Biesemans M., Jacobs M. Proline metabolism in wild-type and in salt-tolerant mutant of Nicotiana plumbaginifolia studied by C-nucler magnetic resonance imaging// Plannt physiology. - 1999. – V. 121. – P. 1281-1290.
11 Al.Asbahi А.А., Maqtari М.А.ABA biosynthesis defective mutants reduce some free amino acids accumulation under drought stress in tomato leaves in comparison with Arabidopsis plants tissues. // Journal of Stress Physiology & Biochemistry. – 2012. - V. 8. - № 2. - P. 179-192
12 Чиркова Т.В. «Физиологические основы устойчивости растений». Учебное пособие. – СПб.: Изд-во С.-Петерб. Ун-та, 2002. – 244 с.
13Zagdanska I. B. Influence of water stress upon photosynthetic carbon metabolism in wheat // Journal of Plant Physiology. – 1984. -V. 116. – P. 153-160.
14 Гордон Л.Х. Дыхание и водно-солевой обмен растительных тканей. – М.:Наука. – 1976. – 119 с.
15 Daschener K., Coues I., Binder S. The mitochondrial isovaleryl-coenzyme A dehydrogenase of Arabidopsis oxidizes intermediates of leucin and valincatabolism // Plant Physiol. -2001. – V. 126. – P. 601-612
16 Malekzadeh, P., J. Khara and R. Heidari. Effect of exogenous Gama-aminobutyric acid on physiological tolerance of wheat seedling exposed to chilling stress // Iranian Journal of Plant Physiology -2012- V. 3 (1). – P. 611 - 617.
17 Ingle R.A. Histidine Biosynthesis //The Arabidopsis Book. -2011. – V. 2. - P. 1-9.
References
1 Tasekeev M. Bioremediacija toksichnyh promyshlennyh othodov // Promyshlennost' Kazahstana. – 2004. – № 5 (26). – P. 59-63.
2 http://www.ca-oasis.info/oasis/?jrn=22&id=157.
3 Minocha R., Shortle W.C., Long S., Minocha S. C. A rapid and reliable procedure for extraction of cellular polyamines and inorganic ions from plant tissues // J. Plant Growth Regul. – 1994. – № 13 – Р. 187-193.
4 Kholodova V.P., Volkov K.S., Kuznetsov V.V. Adaptation of the common ice plant to high copper and zinc concentrations and their potential using for phytoremediation // Russ. J. Plant Physiol. - 2005. - Vol. 52. - P. 848–858.
5 Khoshgoftar A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee SEATM., Parker D.R. Salinity and zinc application effects on phytoavialability of cadmium and zinc // Soil Sci Soc. Am. J. – 2004. – Vol. 68. - P. 1885–1889.
6 Khoshgoftarmanesh A.H., Shariatmadari H., Karimian N., Kalbasi M., Van der Zee Seatm Cadmium and zinc in saline soil solutions and their concentrations in wheat // Soil Sci Soc Am J.- 2006. - Vol. 70. - P. 582–589.
7 El–Bassiouny H.M., Mostafa H.A., El–Khawas S.A., Hassanein R.A., Khalil S.I. and Abd El–Monem A.A. Physiological responses of wheat plant to foliar treatments with arginine or putrescine// Aus. J. Basic and Appl. Sci -2008 – V.2(4) – P.1390-1403.
8 Shtemenko N.T., Sorochan O.O. Vіlnі amiinokisloti na rannih fazah prorastainja zerna kukurudzi. // Fiziologija i biohimija kul'turnyh rastenij. -2001. – T. 33.- №5. – P.441-445.
9 Eprincev A.T., Solodilova O.S., Hozhainova G.N. Rol' svobodnyh aminokislot v adaptivnoj reakcii kukuruzy v uslovijah solevogo stressa // Vestnik VGU. – 2003. – № 2. – P. 132-135.
10 Willem R., Li Y., Verbruggen I., Biesemans M., Jacobs M. Proline metabolism in wild-type and in salt-tolerant mutant of Nicotiana plumbaginifolia studied by C-nucler magnetic resonance imaging// Plannt physiology. - 1999. – V. 121. – P. 1281-1290.
11 Al.Asbahi А.А., Maqtari М.А.ABA biosynthesis defective mutants reduce some free amino acids accumulation under drought stress in tomato leaves in comparison with Arabidopsis plants tissues. // Journal of Stress Physiology & Biochemistry. – 2012. - V. 8. - № 2. - P. 179-192
12 Chirkova T.V. «Fiziologicheskie osnovy ustojchivosti rastenij». Uchebnoe posobie. – SPb.: Izd-vo S.-Peterb. Un-ta, 2002. – 244 p.
13Zagdanska I. B. Influence of water stress upon photosynthetic carbon metabolism in wheat // Journal of Plant Physiology. – 1984. -V. 116. – P. 153-160.
14 Gordon L.H. Dyhanie i vodno-solevoj obmen rastitel'nyh tkanej. – M.:Nauka. – 1976. – 119 p.
15 Daschener K., Coues I., Binder S. The mitochondrial isovaleryl-coenzyme A dehydrogenase of Arabidopsis oxidizes intermediates of leucin and valincatabolism // Plant Physiol. -2001. – V. 126. – P. 601-612
16 Malekzadeh, P., J. Khara and R. Heidari. Effect of exogenous Gama-aminobutyric acid on physiological tolerance of wheat seedling exposed to chilling stress // Iranian Journal of Plant Physiology -2012- V. 3 (1). – P. 611 - 617.
17 Ingle R.A. Histidine Biosynthesis //The Arabidopsis Book. -2011. – V. 2. - P. 1-9.
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Atabayeva, S. D., Zhardamalieva А., Nurmahanova А., Kenzhebayeva, S. S., & Asarandina, S. S. (2016). The combined effect of salinity (NaCl) and copper ions on biomass and amino acid content in wheat varieties. Experimental Biology, 63(1), 192–199. Retrieved from https://bb.kaznu.kz/index.php/biology/article/view/1027
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PHYSICO-CHEMICAL BIOLOGY AND NANOTECHNOLOGY
