Anti-oxidative Potential Survival of E. crassipes Under Oxidative Stress

Sangya S. Bais¹ , Lawrence K.² , Priya S.³ , Gavhale V.⁴

Section:Research Paper, Product Type: Isroset-Journal
Vol.6 , Issue.3 , pp.97-104, Jun-2019

CrossRef-DOI:   https://doi.org/10.26438/ijsrbs/v6i3.97104

Online published on Jun 30, 2019

Copyright © Sangya S. Bais, Lawrence K., Priya S. , Gavhale V. . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
 

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Abstract :
The present study evaluates the kinetic constants of enzymatic assays in crude extracts of roots and shoots of E. crassipes growing in wastewater bodies situated in the trans-Ganges/Yamuna regions of Allahabad. The increased kinetic constants in crude extracts of shoots and roots of E. crassipes showing the ability to protect plants from heavy metal induced oxidative stress by activating multi-defense mechanisms and for better growth in polluted environments. This study demonstrates the phytoremediation potential of E. crassipes for the removal of polluted effluents and their ability to survive under oxidative stress.

Key-Words / Index Term :
Phytoremediation, kinetic constants, oxidative stress, wastewater, heavy metal, multi-defense mechanisms

References :
[1] Postel, S., and Richter, B. (2003). Rivers for Life: Managing Water for People and Nature, (220)., Island Press, Washington, D. C.
[2] Melissa Denchak, (2018). Water Pollution: Everything You Need to Know.
[3] Chu J., Chen J., Wang C., Fu P. (2004). Wastewater reuse potential analysis: implications for China’s water resource management. Water Research, 38, pp.2746-2756.
[4] Flathman P. E., Lanza G. R. (1998). Phytoremediation: current views on an emerging green technology. Journal of Soil Contamination, 7, pp. 415–432.
[5] Prasad M. N. V., Freitas H. (2003). Metal hyperaccumulation in plants—biodiversity prospecting for phytoremediation technology. Electronic Journal of Biotechnology, 6, pp. 285-321.
[6] Reed S. C., Crites R. W. and Middlebrooks E. J. (1995). Natural Systems for Waste Management and Treatment - 2nd ed. McGraw Hill, New York, pp. 173-284.
[7] Grodowitz M. J. (1998). An active approach to the use of insect biology control for the management of Non-Native Aquatic Plants. J. Aquatic plant Manage., 36, pp. 57 – 61.
[8] Home Back (2004). Water Hyacinths – A problem Aquatic plants in the Western USA. The western Aquatic Plant Mange. Soc., pp.5.
[9] De Biasi, M.G., S. Astolfi, A. Acampora, S. Zuchi, V. Fonzo, E. Satangelo, R. Caccia, M. Badiani & G.P. Soressi. 2003. A H2O2-forming peroxidase rather than a NAD(P)H-dependent O2 - synthase may be the major player in cell death responses controlled by the pto-Fen complex following fenthion treatment. Funct. Plant Biol. 30: 409-417.
[10] Matsumura, T., Tabayashi N., Kamagata Y., Souma C. and Saruyama H. (2002). Wheat catalase expressed in transgenic rice can improve tolerance against low temperature stress. Physiol. Plant., 116, pp. 317-327.
[11] Chance B. and Maehly A. C. (1955). Assay of catalase and peroxidase. In: Colowic, S.P.and N.O. Kaplan (Eds.). Methods of Enzymology, Academic Press, New York, USA, 2, pp. 764.
[12] Esterbauer H., Schwarql E., Hayn (1977). A rapid assay of catechol oxidase and laccase using 2-nitro-thiobenjoic acid, Anal. Biochem., 77, 486-494.
[13] Lowry, O.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J.Biol.Chem 193: 265 (The original method).
[14] Minai-Tehrani D, Tavakoli Temah A, Rashidfarokhi A, Noormohammadi A, Khodakarami A, Talebi M. (2012). The effect of light crude oilcontaminated soil on the growth and germination of Sorghum bicolor. In: Dobránszki J (Ed) Sorghum. The European Journal of Plant Science and Biotechnology 6 (Special Issue 1), 81-84.
[15] Gholamhoseinian, A., H. Fallah, F. Sharifi-Far and M. Mirtajaddini, 2008. Alpha mannosidase inhibitory effect of some Iranian plant extracts. Int. J. Pharmacol., 4: 460-465.
[16] Sutay (2003). Isolation, characterization and immobilization of polyphenol oxidases from mulberry (morus alba) leaf tissues.
[17] Geetha Rani Y. (2013). Studies on kinetic parameters and biochemical characteristics of polyphenol oxidase purified from jackfruit (artocarpus heterophyllus) waste.
[18] Ebiloma U.G., Arobgba and Aminu O.R. (2011).Some activities of peroxidase from Mango (Mangifera indica L.Var. Mapulehu) Kernel. Int. J. of Biological Chemistry. 5(3), pp.200-206.
[19] Yamaguchi B.M., Cormier M.J. and Dowson J.Y. (2004). Peroxidase isozymes from Horseradish roots. Isolation and physical properties. J. Chem., 10, pp. 6179-6186.
[20] Shukla S.P., Modi K., Ghosh P. K., and Devi S. (2004). Immobilization of horseradish peroxidase by entrapment in natural polysaccharide. J. Applied Polym. Sci., 91, pp.2063-2071.
[21] Yu, J., K.E. Taylor, H. Zou, N. Biswas and J.K. Bewtra, 1994. Phenol conversion and dimeric intermediates in horseradish peroxidase-catalyzed phenol removal from water. J. Environ. Sci. Technol., 28: 2154-2160.
[22] L. Ghamsari, Ezzatollah Keyhani, Shokoofeh Golkhoo (2007). Kinetics Properties of Guaiacol Peroxidase Activity in Crocus sativus L. Corm during Rooting.
[23] Ila Bania and Rita Mahanta (2012). Evaluation of peroxidases from various plant sources. International Journal of Scientific and Research Publications, Volume 2, Issue 5, May 2012 1 ISSN 2250-3153.
[24] Attar F, Khavari-Nejad S, Keyhani J, Keyhani, E. (2009). Structural and functional alterations of CAT induced by acriflavine, a compound causing apoptosis and necrosis. Annals of the New York Academy of Science 1171: 292-299.
[25] Cheeseman J. M. (2007). Hydrogen peroxide and plant stress: A challenging relationship. Plant Stress 1, 4-15.
[26] Bolwell G. P. (1999). Role of active oxygen species and NO in plant defense responses. Current Opinion in Plant Biology 2, 287-294.
[27] Marques A. P. G. C., Rangel A. O. S. S., Castro P.M.L. (2009). Remediation of heavy metal contaminated soils: Phytoremediation as a potentially promising clean-up technology. Critical Reviews in Environmental Science and Technology, 39, pp.622–654.
[28] Blikhina O. Virolainen E., Fagerstedt K.V. (2003). Antioxidants, oxidative damage and oxygen deprivation stress. A review. Ann. Bot. 91:179-194.
[29] Geetha Rani Y., Arulvel R., Selvarajan E. (2014). Studies on kinetic parameters and biochemical characteristics of polyphenol oxidase purified from Jackfruit (ARTOCARPUS HETEROPHYLLUS) waste. Int J Pharm Pharm Sci, Vol 6, Issue 9, 473-478.
[31] Zhang Y, Qi H, Taylor R, Xu W, Liu LF, Jin S. (2007) The role of autophagy in mitochondria maintenance: characterization of mitochondrial functions in autophagy-deficient S. cerevisiae strains. Autophagy, 3(4):337-46.