Responses of Rhizophora mangle L. to effluents from textile Industry in Kano, Nigeria

Authors

  • Iwuala Emmanuel Department of Plant Science and Biotechnology, Federal University, Oye Ekiti, Ekiti State, Nigeria
  • Afroz Alam Department of Bioscience and Biotechnology, Banasthali University, Rajasthan, India
  • Ajiboye Abiodun Department of Plant Science and Biotechnology, Federal University, Oye Ekiti, Ekiti State, Nigeria

DOI:

https://doi.org/10.14719/pst.2017.4.4.333

Abstract

Polluted water discharge sourced from industrial effluent has emerge a distressing happening owing to its harmful effects on health, lives and safety of organisms. The extent of this unpleasant situation by and large remains unidentified. Thus, in the present study, the toxic effects of effluents from textile are analyzed through Rhizophora mangle L., by leaving it to polluted surface water by effluent from the Challawa stream.  An observation on the effects of textile effluent polluted water was analyzed on the growth, chlorophyll content, heavy metal quantification and membrane integrity in R. mangle was carried out. Seedlings raised from viviparous seeds (propagules) were grown in 50L effluent water from textile industry for 4 weeks.  Growth, physiological, biochemical parameters as well as quantification analysis of heavy metals of the seedlings were analysed immediately after the treatment period. The results proved that R. mangle seedlings were sensitive to metal toxicity. The treatment significantly reduced the growth index and chlorophyll contents evaluated. MDA content, catalase enzyme and heavy metal content (Fe, Ni and Cu) significantly increase when plants were grown in effluent water indicating ROS production. Therefore, this result implies that metals present in the textile effluent induce oxidative stress and membrane damage in R. mangle.

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References

1. WHO. 2002. Water Pollutants, Biological Agents, Dissolved Chemicals, Non-dissolved Chemicals, Sediments, Heat, WHO CEHA, and Amman, Jordan.

2. Gomez N, Sierra MV, Cortelezzi Rodrigues A, Capitulo A. Effects of discharges from the textile industry on the biotic integrity of benthic assemblages. Ecotoxicology and Environmental Safety 2008; 69: 472-479. doi: 10.1016/j.ecoenv.2007.03.007

3. Sacan MT, Balcioglu IA. A case study on algal response to raw and treated effluents from an aluminum plating plant and a pharmaceutical plant. Ecotoxicology and Environmental Safety 2006; 64: 234-243. doi: 10.1016/j.ecoenv.2005.03.017

4. Lin CF, Hao OJ, Jeng FT. Microtox evaluation of industrial wastewaters. Water Science and Technology 1994; 30: 97-106.

5. Ternes TA. Occurrence of drugs in German sewage treatment plants and rivers. Water Research 1998; 32:3245-3260. doi: 10.1016/S0043-1354(98)00099-2

6. Odjegba JV, Bamgbose NM. Toxicity assessment of treated effluents from a textile industry in Lagos, Nigeria. African Journal of Environmental Science and Technology 2012; 6(11): 438-445. doi: 10.5897/AJEST12.133

7. Whitehouse P, Dijk P. The precision of aquatic toxicity tests: the implications for the control of effluents by direct toxicity assessment. In: Tapp JF, Wharfe JR, Hunt SM (eds), Toxic Impacts of Wastes on the Aquatic Environment. Cambridge; 1996.

8. Guo J, Yang Y, Wang G, Yang L, Sun X. Ecophysiological responses of Abiesfabri seedlings to drought stress and nitrogen supply. Physiologia Plantarum 2010; 139: 335-347

9. Arnon DI. Copper enzymes in isolated chloroplast, polyphenol-oxidase in Beta vulgaris. Plant Physiology 1949; 24: 1-15. doi: 10.1104/pp.24.1.1

10. Alia KV, Prasad SK, Pardha SP. Effect of zinc on free radical and proline in Brassica juncea and Cajanus cajan. Phytochemistry 1995; 39: 45–47. doi: 10.1016/0031-9422(94)00919-K

11. Isaac RA, Kerber JD. Atomic absorption and flame photometry techniques and uses in soil, plant and water analysis. In: Instrumental Methods for Analysis of Soils and Plant Tissue, ed. L. M. Walsh, Madison, WI: SSSA. 1971. p. 17–37.

12. Aebi H. Catalase in vitro. Methods in Enzymology 1984; 105: 121–126. doi: 10.1016/S0076-6879(84)05016-3

13. Khan TI, Jain V. Effect of textile industry waste water on the growth and some biochemical parameters on Triticum aestivum. Journal of Environment Pollution 1995; 2: 47-50.

14. Pandey SN, Nautiyal BD, Sharma CP. Pollution level in distillery effluent and its phytotoxic effect on seed germination and early growth of maize and rice. Journal of Environmental Biology 2008; 29: 267-270.

15. Odjegba J, Adeniyi M. Responses of Celosia argentea L. to simulated drought and exogenous salicylic acid. Nature and Science 2012; 10(12): 2-6.

16. Murch SJ, Haq K, Rupasinghe VHP, Saxena PK. Nickel contamination growth and secondary metabolite composition of St. Johns Wort (Hypericum perforatum L.). Environmental and Experimental Botany 2003; 49: 251-257. doi: 10.1016/S0098-8472(02)00090-4

17. Onwordi CT, Dan-Sulaiman SB. Physico-chemical characterization and heavy metals of effluents from glass processing plant in Agbara Industrial Estate, Ogun, Nigeria Archives of Applied Science Research 2010; 2(1): 212-217.

18. Acworth IN, Bailey B. Reactive oxygen species. In: Acworth, IN and B. Bailey (eds). The handbook of oxidative metabolism. ESA Inc., Massachusetts. 1997. p. 1-4.

19. Mishra A, Choudhuri MA. Effects of salicylic acid on heavy metal-induced membrane deterioration mediated by lipoxygenase in rice. Biologia Plantarum. 1999; 42: 409-415. doi: 10.1023/A:1002469303670

20. Wang YS, Wang J, Yang ZM, Wang QY, Li B, Li SQ, Lu YP, Wang SH, Sun X. Salicylic acid modulates aluminum-induced oxidative stress in roots of Cassia tora. Acta Botanica Sinica 2004; 46: 816-828.

21. Shi Q, Zhu Z. Effects of exogenous salicylic acid on manganese toxicity, element contents and ant oxidative system in cucumber. Environmental and Experimental Botany 2008; 63: 317-326. doi: 10.1016/j.envexpbot.2007.11.003

22. Halliwell B, Gutteridge JMC. Free Radicals in Biology and Medicine 3rd ed. Oxford Science Publications, New York. 1999. p. 936.

23. Zhang F, Wang Z, Dong J. Effect of heavy metal stress on antioxidative enzymes and lipid peroxidation in leaves and roots of two mangrove plant seedlings (Kandelia candel and Bruguira gymnorrhiza). Chemosphere 2007; 67: 44-50. doi: 10.1016/j.chemosphere.2006.10.007

24. Sharma V, Parmar P, Kumari N. Differential cadmium stress tolerance in wheat genotypes under mycorrhizal association. Journal of Plant Nutrition 2016; 36(4): 1–12. doi: 10.1080/01904167.2016.1170851

25. Sairam RK, Tyagi A. Physiology and molecular biology of salinity stress tolerance in plants. Current Science 2004; 86: 407-421

26. Mittal S, Kumari N, Sharma V. Differential response of salt stress on Brassica juncea; Photosynthetic performance, Protein, Proline, D1 and antioxidant enzymes. Journal of plant biochemistry & physiology 2012; 4: 17-26 doi: 10.1016/j.plaphy.2012.02.003

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Published

30-11-2017

How to Cite

1.
Emmanuel I, Alam A, Abiodun A. Responses of Rhizophora mangle L. to effluents from textile Industry in Kano, Nigeria. Plant Sci. Today [Internet]. 2017 Nov. 30 [cited 2024 Nov. 22];4(4):202-8. Available from: https://horizonepublishing.com/journals/index.php/PST/article/view/333

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