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Amelioration of $Cd^{++}$ Toxicity by $Ca^{++}$ on Germination, Growth and Changes in Anti-Oxidant and Nitrogen Assimilation Enzymes in Mungbean(Vigna mungo) Seedlings  

Kochhar Sunita (Division of Biotechnology and Plant Physiology, National Botanical Research Institute)
Ahmad Gayas (Division of Biotechnology and Plant Physiology, National Botanical Research Institute)
Kochhar Vinod Kumar (Division of Biotechnology and Plant Physiology, National Botanical Research Institute)
Publication Information
Journal of Plant Biotechnology / v.6, no.4, 2004 , pp. 259-264 More about this Journal
Abstract
The present study describes the ameliorating effect of $Ca^{++}\;on\;Cd^{++}$ toxicity on the germination, early growth of mungbean seedlings, nitrogen assimilation enzyme. s-nitrate reductase (NR), nitrite reductase (NIR), anti-oxidant enzymes (POD, CAT and SOD) and on the accumulation of hydrogen peroxide and sulphydryls. $Cd^{++}$ inhibited seed germination and root and shoot length of seedlings. While NR activity was down- regulated, the activities of NIR, POD and SOD were up- regulated with $Cd^{++}$ treatment. $Cd^{++}$ treatment also increased the accumulation of sulphydryls and peroxides, which is reflective of increased thiol rich proteins and oxidative stress. $Ca^{++}$ reversed the toxic effects of $Cd^{++}$ on germination and on early growth of seedlings as well as on the enzyme activities, which were in turn differentially inhibited with a combined treatment with calcium specific chelator EGTA. The results indicate that the external application of $Ca^{++}$ may increase the tolerance capacity of plants to environmental pollutants by both up and down regulating metabolic activities. Abbreviations: $Cd^{++}= cadmium,\;Ca^{++} = calcium$, NR= nitrate reductase, NIR=nitrite reductase, POD = peroxidse, SOD= superoxide dismutase, CAT= catalase, EGTA= ethylene glycol-bis( $\beta-aminoethyl ether$)-N,N,N,N-tetraacetic acid.
Keywords
Cadmium; antioxidant and nitrogen assimilation enzymes; calcium; signal transduction; sulphydryls and peroxide accumulation; Vigna mungo;
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1 Aebi ME (1983) Catalase in vitro. Methods Enzymol 105:121-126
2 Dhindsa RS, Dhindsa PP, Thrope TA (1981) Leaf senescence: correlated with increased levels of membrane permeability and lipid peroxidation and decreased levels of superoxide dismutase and catalase. J Exp Bot 32: 93-101
3 Forstner U, Prasi F (1979) Heavy metal pollution in fresh water ecosystems. In Ravera O (eds) Biological Aspects of Fresh water pollution, pp. 129-161. Pergamon Press, New York
4 Kocsy G, Galiba G, Brunold C (2001) Role of glutathione in adaptation and signalling during chilling and acclimation in plants. Physiol Plant 113:158-164
5 Ladror, US, Zielinski RE (1989) Protein kinase activities in tonoplast and plasmalemma membranes. Plant Physiol 9:151-158
6 Mehra R, Tripathi RD (2000) Phytochelatins and metal tolerance. In: Agrawal SB, Agrawal M (eds) Environmental Pollution and Plant Responses pp 327-382. CRC Press, LLC
7 Price AH, Taylor A, Ripley SJ, Griffths A, Trewavas AJ, Knight MR (1994) Oxidative stress in tobacco increase cytosolic calcium. Plant Cell 6:1301-1310
8 Sane PV, Kumar N, Baijal M, Singh KK, Kochhar VK (1987) Activation of nitrate reductase by calcium and calmodulin. Phytochemistry 26: 1289-1291
9 Sheen J (1996) Calcium dependent protein kinases and stress signal transduction. Science 274: 1900-1902
10 Lowry OH, Rosenbrough N, Farr A Randall RJ (1951) Protein measurement with Folin-phenol reagent. J Bioi Chem 193 : 263-275
11 Rengel Z (1992) Role of calcium in aluminium toxicity. New Phytol 121: 499-513
12 Knight H, Knight MR, (1999) Calcium signalling in plants responding to stress. In Smallwood MF, Calvert CM, Bowles OJ (eds) Plant Responses to Environmental Stress, pp 1-8. Bios Scientific Publishers, Oxford UK
13 Hepler KP, Wayne, RO (1985) Calcium and plant development. An Rev Plant Physiol 36: 397-439
14 Rai UN, Tripathi RD, Gupta M, Chandra P (1995) Induction of phytochelatins under cadmium stress in water lettuce (Pistia stratoies L.). J Environ Sci Health 30: 2007-2026
15 Sharma AK, Sopory S (1984) Independent effects of phytochrome and nitrate on nitrate reductase and nitrite reductase activities in maize. Photochem Photobiol 39: 491-493
16 Zaharieva T, Yamashita K, Matasumoto H (1999) Iron deficiency induced changes in ascorbate content and enzyme activities related to ascorbate metabolism in cucumberroots. Plant Cell Physiol 40:273-280
17 Hernanbez JA, Corpas M, Gomez, LA, Del, R, Sevillia E (1993) Salt induced oxidative stress mediated by activated oxygen species in pea leaf mitochondria. Plant Physiol 89: 103-110
18 Gupta M, Tripathi RD, Rai UN, Haq W (1999) Lead induced synthesis of metal binding peptides (phytochelatins) insubmerged macrophyte Val/isneria spira/is L. Physiol Mol Bioi Plants 5: 173-180