Root structural changes of two remediator plants as the first defective barrier against industrial pollution, and their hyperaccumulation ability
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In the present day, plants are increasingly being utilized to safeguard the environment. In this study, we used Salsola crassa M. B. and Suaeda maritima L. Dumort for phytoremediation of water contaminated with heavy metals and simultaneous examination of the effect of industrial pollution on their root structures. After irrigation of a treatment group with wastewater and a control group with fresh water for 3 months, we fixed the root parts in the FAA fixator for developmental study, and measured the concentrations of Co, Ni, Zn, As, Cu, and Pb in the roots, shoots, soil, and irrigating water. The plants irrigated with wastewater showed significant accumulation of heavy metals in the roots and some translocation of heavy metals from the roots to the shoots. We also performed an experiment with two 0.3 m3 pools to more closely study the feasibility of these plants for filtering water of contaminants, including mineral compounds, and altering its chemical characteristics. In our anatomical studies, the cells of the treatment roots showed irregularities and abnormal appearances in all tissue layers. The diameter and area of the xylem and the size of the cortical parenchyma have increased in the treatment plants of both species, confirmed by Stereolite software. Phytoremediation studies indicated that S. crassa accumulated As, Cu, Zn, Pb, Co, and Ni, and S. maritima accumulated As, Co, Zn, and Cu. S. crassa accumulated more heavy metals in its roots, whereas S. maritima accumulated more in its shoots. The biological oxygen demand and chemical oxygen demand were also significantly reduced in the wastewater passed through pools with S. crassa. Our results indicate that both genera are hyperaccumulators of heavy metals and therefore hold promise for industrial wastewater treatment, especially the absorption of As.
KeywordsS. crassa S. maritima Root development Stereological studies Phytoremediation Heavy metals BOD COD
The authors wish to thank Mr. H. Argasi at the Research Consultation Center (RCC) at Shiraz University of Medical Sciences for his invaluable assistance in editing this manuscript.
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Conflict of interest
The authors declare that they have no conflict of interest.
- D’Alessandro, D., Arletti, S., Azara, A., Buffoli, M., Capasso, L., Cappuccitti, A., Casuccio, A., Cecchini, A., Costa, G., De Martino, A. M., Dettori, M., Di Rosa, E., Fara, G. M., Ferrante, M., Giammanco, G., Lauria, A., Melis, G., Moscato, U., Oberti, I., Patrizio, C., Petronio, M. G., Rebecchi, A., Romano Spica, V., Settimo, G., Signorelli, C., & Capolongo, S. (2017). Strategies for disease prevention and health promotion in urban areas: the Erice 50 charter. Annali Di Igiene Medicina Preventiva E Di ComunitàISSN: 1120–9135, 29(6), 481–493. https://doi.org/10.7416/ai.2017.2179.CrossRefGoogle Scholar
- Gomes, M. P., de Sá e Melo Marques, T. C. L. L., de Oliveira Gonçalves Nogueira, M., de Castro, E. M., & Soares, Â. M. (2011). Ecophysiological and anatomical changes due to uptake and accumulation of heavy metal in Brachiaria decumbens. Scientia Agricola (Piracicaba, Braz.), 68(5), 566–573.CrossRefGoogle Scholar
- Grigore, M. N., Toma, C. (2007). Histo-anatomical strategies of chenopodiaceae halophytes: adaptive, ecological and evolutionary implications. WSEAS Transcriptions on Biology and Biomedicine, 4(12), 204-218.Google Scholar
- Grigore, M. N., Ivanescu, L., & Toma, C. (2014). Halophytes: an integrative anatomical study. Springer International Publishing. https://doi.org/10.1007/978-3-319-05729-3.
- Hossain, M. A., Piyatida, P., da Silva, J. A. T., & Fujita, M. (2012). Molecular mechanism of heavy metal toxicity and tolerance in plants: central role of glutathione in detoxification of reactive oxygen species and methylglyoxal and in heavy metal chelation. Journal of Botany, 2012, 1–37.CrossRefGoogle Scholar
- Kraehmer, H., & Baur, P. (2013). In: Weed anatomy (Vol. 8, p. 258). A John Wiley & Sons, Ltd. Publication. https://doi.org/10.1002/9781118503416
- Peer, W., Baxter, I., Richards, E., Freeman, J., & Murphy, A. (2005). Phytoremediation and hyperaccumulator plants. In M. J. Tamás & E. Martinoia (Eds.), Molecular biology of metal homeostasis and detoxification. (Topics in current genetics) (Vol. 14, pp. 299–340). Berlin: Springer.CrossRefGoogle Scholar
- Redondo-Gomez, S., Mateos-Naranjo, E., Vecino-Bueno, I., & Feldman, S. R. (2011). Accumulation and tolerance characteristics of chromium in a cord grass Cr-hyperaccumulator, Spartina argentinensis. Journal of Hazardous Materials, 185(2–3), 826–829.Google Scholar
- Rice, E. W., Baird, R. B., Eaton, A. D., & Clesceri, L. S. (2012). Standard methods for the examination of water and wastewater. Washington DC: American Public Health Association/American Water Works Association/Water Environment Federation.Google Scholar
- Ruzin, S. E. (1999). Plant microtechnique and microscopy (pp. 322). Oxford, New York: Oxford University Press.Google Scholar