PENGARUH Mangan (Mn) TERHADAP OKSIDASI KROMIUM TRIVALEN DAN PERTUMBUHAN Tagetes sp.

Margareta Prameswati, Sri Kasmiyati, Sucahyo Sucahyo
| Abstract views: 398

Abstract

Chromium can be found in 2 oxidation states, trivalent chromium (Cr3+) and hexavalent chromium (Cr6+) in environment. Trivalent chromium can be oxidized by manganese oxide to hexavalent chromium (Cr6+). The aim of the study was to determine the effect of Mn on the oxidation of Cr³⁺and plant growth of Tagetes. The study was conducted experimentally using a completely randomized design. The Tagetes plants grown in media with 2 treatment factors, namely Cr3+ (CrCl3) with 3 concentrations of 0, 100 and 500 mg/l) and Mn (MnSO4) with 4 concentrations of 0, 1, 5 and 10 mg/l. The plant growth and Cr6+ content in roots and shoots were measured to determine the effect and to detect the occurrence of Cr3+ oxidation. The addition of Mn in the media of Tagetes containing Cr3+ increased the Cr3+ oxidation process, indicated by the detection of Cr6+ in the roots and shoots of Tagetes. The highest Cr6+ content was found in the roots and shoots of Tagetes sp. treated with Cr3+ 500 mg/l and Mn 10 mg/l at 0.059 and 0.035 g/l, respectively. The interaction of Cr3+ and Mn treatments significantly affected the growth of Tagetes plants. Cr3+ and Mn at high concentrations increased plant height, root length, root and shoot dry weight. The interaction of Cr3+ and Mn at high concentrations inhibited the increase in the number of leaves of Tagetes.

Keywords

trivalent chromium, reduction-oxidation, Tagetes sp., manganese, toxicity

References

Akinci, I.E., and Akinci, S., 2010. Effect of chromium toxicity on germination and early seedling growth in melon (Cucumis melo L.). African Journal of Biotechnology, 9(29), pp. 4589-4594

Augustynowicz, J., Grosicki, M., Hanus-Fajerska, E., Lekka, M., Andrzej Waloszek, A., Kołoczek, H., 2010. Chromium(VI) bioremediation by aquatic macrophyte Callitriche cophocarpa Sendtn. Chemosphere, 79, pp. 1077-1083

Chitraprabha, K., and Sathyavathi, S., 2018. Phytoextraction of chromium from electroplating effluent by Tagetes erecta (L.). Sustainable Environment Research, 128, pp. 128-134

Coelho, L.C., Bastos, A.R.B., Pinho, P.J., Souza, G.A., Carvalho, J.G., Coelho, V.A.T., Oliveira, L.C.A., Domingues, R.R., and Faquin, V., 2017. Marigold (Tagetes erecta): The potential value in phytoremediasi of chromium. Pedosphere, 27(3), pp. 559-567

Emamverdian, A., Ding, Y., Mokhberdoran, F., and Xie, Y., 2015. Heavy metal stress and some mechanisms of plant defense response. The Scientific World Journal, 2015, pp. 1–18.

Gheju, M., Balcu, I., and Ciopec, M., 2009. Analysis of hexavalent chromium uptake by plants in polluted soils. Ovidius University Annals of Chemistry, 20(1), pp. 127-131

Gomes, M.A.C., Hauser-Davis, R.A., Suzukia, M.S., and Vitória, A.P., 2017. Review. Plant chromium uptake and transport, physiological effects and recent advances in molecular investigations. Ecotoxicology and Environmental Safety, 140, pp. 55-64

Haokip, N., and Gupta, A., 2020. Phytoremediation of chromium and manganese by Ipomoea aquatica Forssk. from aqueous medium containing chromium-manganese mixtures in microcosms and mesocosms. Water and Environment Journal

Hawley, E.L., Deeb, R.A., Kavanaugh, M.C., and Jacobs, J.A., 2004. Treatment Technologies for Chromium(VI). In: Guertin, J., Jacobs, J.A., and Avakian, C.P. (Eds.), Chromium (VI) Handbook. CRC Press, Boca Raton, pp. 273–308

Henderson, T., 1994. Geochemical reduction of hexavalent chromium in the trinity sand aquifer. Ground Water, 32(3), pp. 477-486

Hemalatha, G., Sujitha, S., and Pavithra, G.S., 2014. Studies on reduction and removal of hexavalent chromium in industrial waste water by Alternanthera sessilis and Tagetes erecta. Bio Technology an Indian Journal, 9(4), pp. 147-152

Henriques, F. S., 2010. Changes in biomass and photosynthetic parameters of tomato plants exposed to trivalent and hexavalent chromium. Biologia Plantarum, 54(3), pp. 583-586

James, B.R. and Bartlett, R.J., 1983. Behavior of chromium in soils: V. fate of organically complexed Cr(II) added to soil. Journal of Environmental Quality, 12(2), pp. 169-172

James, B.R., 2002. Chemical transformations of chromium in soils: relevance to mobility, bio-availability and remediation. The Chromium File from the International Chromium Development Association, 8, 8 p

Karuppanapandian, T., Sinha, P.B., Haniya, A. M. K., and Manoharan, K., 2006. Differential antioxidative responses of ascorbate-glutathione cycle enzymes and metabolites to chromium stress in green gram (Vigna radiata L. Wilczek) leaves. Journal of Plant Biology, 49(6), pp. 440-447

Kasmiyati, S., dan Sucahyo, 2014. Deteksi cekaman oksidatif akibat toksisitas krom pada Sonchus oleraceus melalui penentuan spesies oksigen reaktif secara spektrofotometri dan histokimia. Agric, 26 (1&2), pp. 85-98.

Kasmiyati, S., Santosa, Priyambada, I.D., Dewi, K., dan Sandradewi, R., 2015. Perkecambahan biji dan pertumbuhan kecambah varietas sorgum (Sorghum bicolor L.) pada cekaman krom heksavalen. Bioma, 17(1), 41-54

Kasmiyati, S., Santosa, Priyambada, I.D., Dewi, K., Sucahyo, and Sandradewi, R., 2016. Growth response of Sorghum bicolor cultivars to trivalent chromium stress. Biosaintifika, 8(1), pp. 73-86

Kasmiyati, S., 2016. Mekanisme Toleransi Sorghum bicolor (L.) Moench. Terhadap Cekaman Krom: Kajian Fisiologis, Anatomis, Biokimia dan Molekular. Dissertation. Universitas Gadjah Mada, Yogyakarta. Indonesia

Kim, J.G., Dixon, J.B., Chusuei, C.C., and Deng, Y., 2002. Oxidation of chromium (III) to (VI) by manganese oxides. Soil Science Society of America Journal, 66(1), pp. 306-315

Kotas, J., and Stasicka, Z., 2000. Commentary: chromium occurrence in the environment and methods of its speciation. Environmental Pollution, 107(3), pp. 263-283

Kuntal Shah, K., Mankad, A.U., and Reddy, M.N., 2017. Cadmium accumulation and its effects on growth and biochemical parameters in Tagetes erecta L. Journal of Pharmacognosy and Phytochemistry, 6(3), pp. 111-115

Kuntal Shah, K., Mankad, A.U., and Reddy, M.N., 2017. Lead accumulation and its effects on growth and biochemical parameters in Tagetes erecta L. International Journal of Life Sciences Scientific Research, 3(4), pp. 1142-1147

Liu, J., Duan, C. Q., Zhang, X. H., Zhu, Y. N, and Hu, C., 2011. Characteristics of chromium(III) uptake in hyperaccumulator Leersia hexandra Swartz. Environmental and Experimental Botany, 74, pp. 122-126

Madanan, M.T., Shah, I.K., Varghese, G.K., and Kaushal, R.K., 2018. Application of Aztec Marigold (Tagetes erecta L.) for phytoremediation of heavy metal polluted lateritic soil. Environmental Chemistry and Ecotoxicology, 3, pp. 17-22

Maryani, Amalia, N.N., and Agustina, T., 2020. Batik Liquid Waste Inhibited Germination and Degraded Root Tissues of Tagetes erecta L. and Zinnia violacea Cav. AIP Conference Proceedings, pp. 1-7

Mei, B., Puryear, J. D., and Newton, R. J., 2002. Assessment of Cr tolerance and accumulation in selected plant species. Plant and Soil, 247(2), pp. 223-231

Parihar, A., and Malaviya, P., 2015. Effect of textile effluent on the growth and pigment content of Tagetes erecta L. (var. Pusa Basanti). Indian Journal of Applied Research, 5(5), pp. 1-3

Prado, C., Ponce, C.S., Pagano, E., Prado, F.E., Rosa, M., 2016. Differential physiological responses of two Salvinia species to hexavalent chromium at a glance. Aquatic Toxicology, 175, pp. 213–221

Ramana, S., Biswas, A. K., Ajay, Singh, A.B., Ahirwar, N.K., 2012. Phytoremediation of chromium by tuberose. National Academy Science Letters, 35, pp. 71-73

Shanker, A.K., Cervantes, C., Loza-Tavera, H., and Avudainayagam, S., 2005. Chromium toxicity in plants. Environment International, 31(5), pp. 739-753

Shahid, M., Shamshad, S., Rafiq, M., Khalid, S., Bibi, I., Niazi, N.K., Dumat, C., Rashid, M.I., 2017. Chromium speciation, bioavailability, uptake, toxicity and detoxification in soil-plant system: A review. Chemosphere, 178, pp. 513–533

Sharma, A., Kapoor, D., Wang, J., Shahzad, B., Kumar, V., Aditi Shreeya Bali, A.S., Jasrotia, S., Zheng, B., Yuan, H., and Yan, D., 2020. Chromium bioaccumulation and its impacts on plants: an overview. Plants, 9(100), pp. 1-17

Shafique, F., Ali, Q., Saleem, M.Z., Bhatti, T.Y., Zikrea, A., Saifullah, Akhter, S., and Malik, A., 2021. Effect of manganese and chromium toxicity on growth and photosynthetic pigmens of maize. Plant Cell Biotechnology and Molecular Biology, 22(1&2), pp. 58-64

Yu, X.Z., and Gu, J.D., 2007. Accumulation and distribution of trivalent chromium and effects on hybrid willow (Salix matsudana Koidz x alba L.) metabolism. Archives of Environmental Contamination and Toxicology, 52, pp. 503-511

Zayed, A.M., and Terry, N., 2003. Chromium in the environment: factor affecting biological remediation. Plant and Soil, 249, pp. 139-156

Zhang, X., Liu, J., Wang, D., Zhu, Y., Hu, C., and Sun, J., 2009. Bioaccumulation and chemical form of chromium in Leersia hexandra Swartz. Bulletin of Environmental Contamination Toxicology, 82(3), pp. 358-362.


Refbacks

  • There are currently no refbacks.