Активность кислых и щелочных фосфатаз в микоризных растениях томата. Микоризды томат өсімдіктердің қышқыл және сілтілі фосфатазалар белсенділігі
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Кілттік сөздер:
кислые фосфатазы, щелочные фосфатазы, микоризация, , цианобактерии. қышқылды фосфатаза, сілтілі фосфатаза, цианобактериялар.Аннотация
В статье показано влияние 8 штаммов цианобактерий (Anabaenopsis sp. (T1), Anabaenopsis sp. (D6), Anabaena laxa, Amorphonostoc paludosum, Spheronostoc coeruleum, Oscillatoria willei, Calotrhix (Б1), Anabaena constricta) на активность кислых и щелочных фосфатаз в корнях микоризных растений томата (Lycopersicon esculentum Mill.) cорта Red cherry. Установлено, что активность кислых и щелочных фосфатаз повышается в присутствии Anabaena laxa, и напротив, снижается при действии D6 Anabaenopsis. Мақалада Red cherry cорты микоризды томат өсімдіктерінің тамырында қышқыл және сілтілі фосфатазалар белсенділігіне цианобактриялардың 8 штамының (Anabaenopsis sp. (T1), Anabaenopsis sp. (D6), Anabaena laxa, Amorphonostoc paludosum, Spheronostoc coeruleum, Oscillatoria willei, Calotrhix (Б1), Anabaena constricta) әсері көрсетілген. Anabaena laxa -ның әсерінен қышқыл және сілтілі фосфатазалар белсенділігі өседі, ал D6 Anabaenopsis-тың әсерінен белсенділігі төмендейді.Библиографиялық сілтемелер
1 BarretLennard E.D., Robson A.D., Greenway H. Effect of phosphorus deficiency and water deficit on phosphatase activities
from wheat leaves // J. Exp. Bot. – 1982. – V. 33. – P.682-693.
2 Sharma A.D., Thakur M., Rana M., Singh K. Effect of plant growth hormones and abiotic stresses on germination, growth and
phosphatase activities in Sorghum bicolor (L.) Moench seeds // Afr. J. Biotechnol. 2004. – V. 3. – P. 308-312.
3 Asmar F., Gahoonia T., Nielsen N. Barley genotypes differ in activity of soluble extracellular phosphatase and depletion of
organic phosphorous in the rhizosphere soil // Plant Soil. – 1995. – V. 172. – P.117-122.
4 Duff S.M.G., Sarath G., Plaxton W.C. The role of acid phosphatase in plant phosphorus metabolism // Physiol. Plant. – 1994. –
V. 90. – P. 791-800.
5 Tabaldi L.A., Ruppenthal R., Cargnelutti D., Morsch V.M., Pereira L.B., Schetinger M.R.C. Effects of metal elements on acid
phosphatase activity in cucumber (Cucumis sativus L.) seedlings // Environ. Exp. Bot. – 2007. – V. 59. – P. 43-48.
6 Mishra S., Dubey R.S. Changes in phosphate content and phosphatase activities in rice seedlings exposed to arsenite // Braz. J.
Plant. Physiol. – 2007. – V. 20. – P. 19-28.
7 Turner W.L., Plaxton W.C. Purification and Characterization of banana fruit acid phosphatase // Planta. – 2001. – V. 214. –
P. 243-249.
8 Ganjewala D., Nagaraja C., Nayak M.R., Devi S.A. Effects of sodium nitroprusside on activity of acid and alkaline invertases
and alkaline phosphatase in lemongrass (Cymbopogon flexuosus Steud) Wats. // International Journal of Plant Biology. – 2010. –
V. 1. – P. 9-12.
9 Julie E.H., Simpson R.J., Richardson A.E. The growth and phosphorus utilization of plants in sterile media when supplied with
inositol hexaphosphate, glucose-1-phosphate or inorganic phosphate // Plant Soil. – 2010. – V. 220. – P. 165-174.
10 Bozzo G.G., Raghothama K.G., Plaxton W.C. Purification and characterization of two secreted purple acid phosphatase
isozymes from phosphate starved tomato (Lycopersicon esculentum) cell cultures // Eur J. Biochem. – 2002. – V. 269. – P. 6278-6280.
11 Smith S.E., Read D.J. Mycorrhizal Symbiosis. - San Diego: Academic Press, 1997. – 405 p.
12 Harrison M.J., van Buuren M.L. A phosphate transporter from the mycorrhizal fungus Glomus versiforme // Nature. – 1995. – V.
378. – P. 626-629.
13 Sikes B.A., Cottenie K., Klironomos J.N. Plant and fungal identity determines pathogen protection of plant roots by arbuscular
mycorrhizas // J. Ecol. – 2009. – V. 97. – P. 1274-1280.
14 Sbrana C., Giovannetti M. Chemotropism in the arbuscular mycorrhizal fungus Glomus mosseae // Mycorrhiza. -2005. –
V. 15. – P. 539-545.
15 Hampp R., Ecke M., Schaeffer C., Wallenda T., Wingler A., Kottke I., Sundberg B. Axenic mycorrhization of wild type and
transgenic hybrid aspen expressing T-DNA indolacetic acidbiosynthesis genes // Trees. – 1996. – V. 11. – P. 59-64.
16 Ермаков А.И., Арасимович В.В., Смирнова-Иконникова М.И., Ярош Н.П., Луковникова Г.А. Методы биохимического
исследования растений. – Л.: Колос, 1972. – Изд. 2-е. – 456 с.
from wheat leaves // J. Exp. Bot. – 1982. – V. 33. – P.682-693.
2 Sharma A.D., Thakur M., Rana M., Singh K. Effect of plant growth hormones and abiotic stresses on germination, growth and
phosphatase activities in Sorghum bicolor (L.) Moench seeds // Afr. J. Biotechnol. 2004. – V. 3. – P. 308-312.
3 Asmar F., Gahoonia T., Nielsen N. Barley genotypes differ in activity of soluble extracellular phosphatase and depletion of
organic phosphorous in the rhizosphere soil // Plant Soil. – 1995. – V. 172. – P.117-122.
4 Duff S.M.G., Sarath G., Plaxton W.C. The role of acid phosphatase in plant phosphorus metabolism // Physiol. Plant. – 1994. –
V. 90. – P. 791-800.
5 Tabaldi L.A., Ruppenthal R., Cargnelutti D., Morsch V.M., Pereira L.B., Schetinger M.R.C. Effects of metal elements on acid
phosphatase activity in cucumber (Cucumis sativus L.) seedlings // Environ. Exp. Bot. – 2007. – V. 59. – P. 43-48.
6 Mishra S., Dubey R.S. Changes in phosphate content and phosphatase activities in rice seedlings exposed to arsenite // Braz. J.
Plant. Physiol. – 2007. – V. 20. – P. 19-28.
7 Turner W.L., Plaxton W.C. Purification and Characterization of banana fruit acid phosphatase // Planta. – 2001. – V. 214. –
P. 243-249.
8 Ganjewala D., Nagaraja C., Nayak M.R., Devi S.A. Effects of sodium nitroprusside on activity of acid and alkaline invertases
and alkaline phosphatase in lemongrass (Cymbopogon flexuosus Steud) Wats. // International Journal of Plant Biology. – 2010. –
V. 1. – P. 9-12.
9 Julie E.H., Simpson R.J., Richardson A.E. The growth and phosphorus utilization of plants in sterile media when supplied with
inositol hexaphosphate, glucose-1-phosphate or inorganic phosphate // Plant Soil. – 2010. – V. 220. – P. 165-174.
10 Bozzo G.G., Raghothama K.G., Plaxton W.C. Purification and characterization of two secreted purple acid phosphatase
isozymes from phosphate starved tomato (Lycopersicon esculentum) cell cultures // Eur J. Biochem. – 2002. – V. 269. – P. 6278-6280.
11 Smith S.E., Read D.J. Mycorrhizal Symbiosis. - San Diego: Academic Press, 1997. – 405 p.
12 Harrison M.J., van Buuren M.L. A phosphate transporter from the mycorrhizal fungus Glomus versiforme // Nature. – 1995. – V.
378. – P. 626-629.
13 Sikes B.A., Cottenie K., Klironomos J.N. Plant and fungal identity determines pathogen protection of plant roots by arbuscular
mycorrhizas // J. Ecol. – 2009. – V. 97. – P. 1274-1280.
14 Sbrana C., Giovannetti M. Chemotropism in the arbuscular mycorrhizal fungus Glomus mosseae // Mycorrhiza. -2005. –
V. 15. – P. 539-545.
15 Hampp R., Ecke M., Schaeffer C., Wallenda T., Wingler A., Kottke I., Sundberg B. Axenic mycorrhization of wild type and
transgenic hybrid aspen expressing T-DNA indolacetic acidbiosynthesis genes // Trees. – 1996. – V. 11. – P. 59-64.
16 Ермаков А.И., Арасимович В.В., Смирнова-Иконникова М.И., Ярош Н.П., Луковникова Г.А. Методы биохимического
исследования растений. – Л.: Колос, 1972. – Изд. 2-е. – 456 с.
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Как цитировать
Orazova, S. B., & Tashenova, A. A. (2015). Активность кислых и щелочных фосфатаз в микоризных растениях томата. Микоризды томат өсімдіктердің қышқыл және сілтілі фосфатазалар белсенділігі. ҚазҰУ Хабаршысы. Биология сериясы, 58(2), 42–46. вилучено із https://bb.kaznu.kz/index.php/biology/article/view/463
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