Heavy Metal Stress Management through Phytoremediation to Mitigate Climate Change Impacts: An Overview

Abhishek Maitry

Department of Forestry, Wildlife and Environmental Sciences, Guru Ghasidas Vishwavidyalaya, Bilaspur, Chhattisgarh-495009, India.

Gunjan Patil *

Department of Forestry, Wildlife and Environmental Sciences, Guru Ghasidas Vishwavidyalaya, Bilaspur, Chhattisgarh-495009, India.

Preety Dubey

Department of Forestry, Wildlife and Environmental Sciences, Guru Ghasidas Vishwavidyalaya, Bilaspur, Chhattisgarh-495009, India.

Ramesh

Department of Forestry, Wildlife and Environmental Sciences, Guru Ghasidas Vishwavidyalaya, Bilaspur, Chhattisgarh-495009, India.

*Author to whom correspondence should be addressed.


Abstract

Plant stresses are the conditions that adversely affect the growth, development, or productivity of plants/trees and can be caused by various physical, chemical, and biological factors. However, stress caused by the influence of heavy metals has a notable adverse effect on plant growth and productivity. These heavy metal contaminations are responsible for the harmful effects on biotic (plants and associated organisms) and the abiotic (soil, water, and air) environment. If not properly managed, mining activities are considered to be the prime source of heavy metal contamination in the surrounding environment. Phytoremediation may effectively remediate a wide range of heavy metal contaminants in different environments and hence offers an effective, carbon-neutral, and ecologically beneficial method for the removal of hazardous heavy metal contaminants. Phytoremediation enhances the growth and development of plants and nourishes the environment resulting in the ill effects of climate extremes in disturbed areas and hence mitigating the impacts of climate change. Phytoremediation has been widely studied for the remediation of heavy metal stress but it hasn't yet achieved commercial viability in degraded ecosystems of India where it is required the most. Through this review article, we tried to minimize this gap by reviewing some important phytoremediation studies in India which successfully reduced the negative impacts of heavy metals in different degraded ecosystems.

Keywords: Climate change, degradation, heavy metals, phytoremediation, stress


How to Cite

Maitry, A., Patil, G., Dubey, P., & Ramesh. (2024). Heavy Metal Stress Management through Phytoremediation to Mitigate Climate Change Impacts: An Overview. International Journal of Environment and Climate Change, 14(4), 708–718. https://doi.org/10.9734/ijecc/2024/v14i44152

Downloads

Download data is not yet available.

References

Verma S, Nizam S, Verma PK. Biotic and abiotic stress signalling in plants. Stress Signaling in Plants: Genomics and Proteomics Perspective. 2013;1:25-49.

Bhandari S, Kukreja S, Singh B, Kumar V, Gautam S, Sharma V, Goutam U. Role of beneficial microbes in biotic and abiotic stress. In Relationship Between Microbes and the Environment for Sustainable Ecosystem Services. Elsevier. 2023;3:243-259.

Yang X, Ren J, Li J, Lin X, Xia X, Yan W, Ke Q. Meta-analysis of the effect of melatonin application on abiotic stress tolerance in plants. Plant Biotechnology Reports. 2023;17(1):39-52.

García-Montelongo AM, Montoya-Martínez AC, Morales-Sandoval PH, Parra-Cota FI, De los Santos-Villalobos S. Beneficial microorganisms as a sustainable alternative for mitigating biotic stresses in crops. Stresses. 2023;3(1):210-228.

Gull A, Lone AA, Wani NUI. Biotic and Abiotic Stresses in Plants. In (Ed.), Abiotic and Biotic Stress in Plants. Intech Open; 2019. Available:https://Doi.Org/10.5772/Intechopen.85832.

Devi P, Kumar P. Concept and application of phytoremediation in the fight of heavy metal toxicity. Journal of Pharmaceutical Sciences and Research. 2020;12(6):795-804.

Adnan M, Xiao B, Xiao P, Zhao P, Li R, Bibi S. Research progress on heavy metals pollution in the soil of smelting sites in China. Toxics. 2022;10(5):231.

Chen D, Wang X, Luo X, Huang G, Tian Z, Li W, Liu F. Delineating and identifying risk zones of soil heavy metal pollution in an industrialized region using machine learning. Environmental Pollution. 2023; 318:120932.

Li FJ, Yang HW, Ayyamperumal R, Liu Y. Pollution, sources, and human health risk assessment of heavy metals in urban areas around industrialization and urbanization-Northwest China. Chemosphere. 2022;308:136396.

Boum-Nkot SN, Nlend B, Komba D, Ndondo GN, Bello M, Fongoh EJ, Etame J. Hydrochemistry and assessment of heavy metal groundwater contamination in an industrialized city of sub- Saharan Africa (Douala, Cameroon). Implication on human health. Hydro Research; 2023.

Ulutaş K. Risk assessment and spatial distribution of heavy metal in street dusts in the densely industrialized area. Environmental Monitoring and Assessment. 2022;194(2):99.

Shah P, Patil G, Sharma D. Assessment of ecological restoration success and vegetation dynamics through spatial-temporal change detection in Gevra opencast mine, Korba coalfield, India. Ecology, Environment and Conservation. 2022;28:496-503 Available:https://doi.org/10.53550/EEC.2022.v28i08s.075

Rai GK, Bhat BA, Mushtaq M, Tariq L, Rai PK, Basu U, Bhat JA. Insights into decontamination of soils by phytoremediation: A detailed account on heavy metal toxicity and mitigation strategies. Physiologia Plantarum. 2021; 173(1):287-304.

Geleta GS. A colorimetric aptasensor based on two dimensional (2d) nanomaterial and gold nanoparticles for detection of toxic heavy metalions: A review. Food Chemistry Advances. 2023;100184.

Rahman SU, Nawaz MF, Gul S, Yasin G, Hussain B, Li Y, Cheng H. State-of-the-art OMICS strategies against toxic effects of heavy metals in plants: A review. Ecotoxicology and Environmental Safety. 2022;242:113952.

Yan X, An J, Yin Y, Gao C, Wang B, Wei S. Heavy metals uptake and translocation of typical wetland plants and their ecological effects on the coastal soil of a contaminated bay in Northeast China. Science of the Total Environment. 2022;803:149871.

Dixit R, Malaviya D, Pandiyan K, Singh UB, Sahu A, Shukla R, Paul D. Bioremediation of heavy metals from soil and aquatic environment: An overview of principles and criteria of fundamental processes. Sustainability. 2015;7(2):2189-2212.

Fashola MO, Ngole-Jeme VM, Babalola OO. Heavy metal pollution from gold mines: Environmental effects and bacterial strategies for resistance. International Journal of Environmental Research and Public Health. 2016;13(11):1047.

Zukauskaite A, Jakubauskaite V, Belous O, Ambrazaitiene D, Stasiskiene Z. Impact of heavy metals on the oil products biodegradation process. Waste Management and Research. 2008;26(6): 500-507.

Zerizghi T, Guo Q, Tian L, Wei R, Zhao C. An integrated approach to quantify ecological and human health risks of soil heavy metal contamination around coal mining area. Science of the Total Environment. 2022;814:152653.

Rashid A, Ayub M, Ullah Z, Ali A, Sardar T, Iqbal J, Khan S. groundwater quality, health risk assessment, and source distribution of heavy metals contamination around chromite mines: Application of GIS, sustainable groundwater management, Geostatistics, pcamlr, and pmf receptor model. International Journal of Environmental Research and Public Health. 2023;20(3):2113.

Singh S, Maiti SK, Raj D. An approach to quantify heavy metals and their source apportionment in coal mine soil: A study through PMF model. Environmental Monitoring and Assessment. 2023; 195(2):306.

Ahmad Z, Khan SM, Page SE, Balzter H, Ullah A, Ali S, Mukhamezhanova AS. Environmental sustainability and resilience in a polluted ecosystem via phytoremediation of heavy metals and plant physiological adaptations. Journal of Cleaner Production. 2023;385:135733.

Sharma A, Kapoor D, Gautam S, Landi M, Kandhol N, Araniti F, Zheng B. Heavy metal induced regulation of plant biology: Recent insights. Physiologia Plantarum. 2022;174(3):e13688.

Patil G, Umadevi M. Cadmium and lead effect on growth parameters of Four Eucalyptus species. Int. J. Biosci. 2014;5: 72-79.

DalCorso G, Farinati S, Furini A. Regulatory networks of cadmium stress in plants. Plant Signalling and Behavior. 2010;5(6):663-667.

Collin S, Baskar A, Geevarghese DM, Ali MNVS, Bahubali P, Choudhary R, Swamiappan S. Bioaccumulation of lead (Pb) and its effects in plants: A review. Journal of Hazardous Materials Letters. 2022;100064.

Riyazuddin R, Nisha N, Ejaz B, Khan MIR, Kumar M, Ramteke PW, Gupta R. A comprehensive review on the heavy metal toxicity and sequestration in plants. Biomolecules. 2022;12(1):43.

Gamalero E, Lingua G, Berta G, Glick BR. Beneficial role of plant growth promoting bacteria and arbuscular mycorrhizal fungi on plant responses to heavy metal stress. Canadian Journal of Microbiology. 2009; 55(5):501-514.

Patil G, Faizan M. Effect of lead and cadmium on the fungal population in rhizosphere soils of eucalyptus species. Environment and Ecology. 2017;35(4A): 2965-2970.

Zaynab M, Al-Yahyai R, Ameen A, Sharif Y, Ali L, Fatima M, Li S. Health and environmental effects of heavy metals. Journal of King Saud University-Science. 2022;34(1):101653.

Triassi M, Cerino P, Montuori P, Pizzolante A, Trama U, Nicodemo F, Limone A. Heavy metals in groundwater of southern Italy: Occurrence and potential adverse effects on the environment and human health. International Journal of Environmental Research and Public Health. 2023;20(3):1693.

Bhat NA, Bhat AA, Guha DB, Singh BP. Vertical distribution of heavy metals in Karewa deposits of South Kashmir: Environmental contamination and health risk assessment. International Journal of Environmental Science and Technology. 2023;20(1):369-382.

Zheng K, Zeng Z, Tian Q, Huang J, Zhong Q, Huo X. Epidemiological evidence for the effect of environmental heavy metal exposure on the immune system in children. Science of the Total Environment. 2023;161691.

Gunwal I, Mathur R, Agrawal Y, Mago P. Plants useful for phytoremediation of soil and water in India. Asian Journal of Plant and Soil Sciences. 2021;6(3):1-8.

Sharma JK, Kumar N, Singh NP, Santal AR. Phytoremediation technologies and its mechanism for removal of heavy metal from contaminated soil: An approach for a sustainable environment. Frontiers in Plant Science. 2023;14:78.

Saravanan A, Kumar PS, Ramesh B, Srinivasan S. Removal of toxic heavy metals using genetically engineered microbes: Molecular tools, risk assessment and management strategies. Chemosphere. 2022;134341.

Bhat SA, Bashir O, Haq SAU, Amin T, Rafiq A, Ali M, Sher F. Phytoremediation of heavy metals in soil and water: An eco-friendly, sustainable and multidisciplinary approach. Chemosphere. 2022; 303:134788.

Yang L, Wang J, Yang Y, Li S, Wang T, Oleksak P, Kuca K. Phytoremediation of heavy metal pollution: Hotspots and future prospects. Ecotoxicology and Environmental Safety. 2022;234:113403.

Ali H, Khan E, Sajad MA. Phytoremediation of heavy metals—concepts and applications. Chemosphere. 2013;91(7):869-881.

Tiwari S, Lata C. Heavy metal stress, signaling, and tolerance due to plant-associated microbes: An overview. Frontiers in Plant Science. 2018;9:452.

Oladoye PO, Olowe OM, Asemoloye MD. Phytoremediation technology and food security impacts of heavy metal contaminated soils: A review of literature. Chemosphere. 2022;288:132555.

Parihar JK, Parihar PK, Pakade YB, Katnoria JK. Bioaccumulation potential of indigenous plants for heavy metal phytoremediation in rural areas of Shaheed Bhagat Singh Nagar, Punjab (India). Environmental Science and Pollution Research. 2021;28:2426-2442. Available:https://doi.org/10.1007/s11356-020-10454-3.

Agarwal S, Albeshr MF, Mahboobb S, Atique U, Pramanick P, Mitra A. Bioaccumulation Factor (BAF) of heavy metals in green seaweed to assess the phytoremediation potential. Journal of King Saud University-Science. 2022;34(5): 102078.

Madanan MT, Shah IK, Varghese GK, Kaushal RK. Application of Aztec Marigold (Tagetes erecta L.) for phytoremediation of heavy metal polluted lateritic soil. Environmental Chemistry and Ecotoxicology. 2021;3:17-22.

Kumar V, Kumar P, Singh J, Kumar P. Potential of water fern (Azolla pinnata R. Br.) in phytoremediation of integrated industrial effluent of SIIDCUL, Haridwar, India: Removal of physicochemical and heavy metal pollutants. International Journal of Phytoremediation. 2020;22(4):392-403.

Shanker AK, Ravichandran V, Pathmanabhan G. Phytoaccumulation of chromium by some multipurpose-tree seedlings. Agroforestry Systems. 2005;64:83-87.

Ali MB, Tripathi RD, Rai UN, Pal A, Singh SP. Physico chemical characteristics of lake Nainital (UP) India. Role of macrophytes and phytoplankton in biomonitoring and phytoremediation of toxic metalions. Chemosphere. 1999;39: 2172-2182.

Najila N, Anila G. Heavy metal absorption and phytoremediation capacity of macrophytes of Polachira wetland of Kollam district, Kerala, India. Research Journal of Chemistry and Environment. 2022;26(1):90-96.

Bora MS, Sarma KP. Phytoremediation of heavy metals/metalloids by native herbaceous macrophytes of wetlands: Current research and perspectives. Emerging Issues in the Water Environment during Anthropocene: A South East Asian Perspective. 2020;261-284.

Ghosh S. Wetland macrophytes as toxic metal accumulators. International Journal of Environmental Sciences. 2010;1(4):523-528.

Adhikari T, Kumar A, Singh MV, Rao AS. Phytoaccumulation of lead by selected wetland plant species. Communications in Soil Science and Plant Analysis. 2010;41(22):2623-2632.

Chandra R, Yadav S. Potential of Typha angustifolia for phytoremediation of heavy metals from aqueous solution of phenol and melanoidin. Ecological Engineering. 2010;36(10):1277-1284.

Maiti SK, Jaiswal S. Bioaccumulation and translocation of metals in the natural vegetation growing on fly ash lagoons: A field study from Santaldih thermal power plant, West Bengal, India. Environmental Monitoring and Assessment. 2008;136:355-370. Available:https://doi.org/10.1007/s10661-007-9691-5.

Prasad MNV. Phytoremediation in India. Phytoremediation: Methods and Reviews. 2007;435-454.

Singh M, Guleria N, Prakasa Rao EV, Goswami P. Efficient C sequestration and benefits of medicinal vetiver cropping in tropical regions. Agronomy for Sustainable Development. 2014;34:603-607.

Lal K, Minhas PS, Chaturvedi RK, Yadav RK. Cadmium uptake and tolerance of three aromatic grasses on the Cd-rich soil. Journal of the Indian Society of Soil Science. 2008;56(3):290-294.

Purakayastha TJ, Bhadraray S, Chhonkar PK. Screening of Brassica species for hyper-accumulation of zinc, copper, lead, nickel and cadmium. Indian Journal of Plant Physiology. 2009;14(4):344-352.

Lal K, Minhas PS, Chaturvedi RK, Yadav RK. Extraction of cadmium and tolerance of three annual cut flowers on Cd-contaminated soils. Bioresource Technology. 2008;99(5):1006-1011.

Rathore SS, Shekhawat K, Dass A, Kandpal BK, Singh VK. Phytoremediation mechanism in Indian mustard (Brassica juncea) and its enhancement through agronomic interventions. Proceedings of the National Academy of Sciences, India Section B: Biological Sciences. 2019; 89:419-427.

Ramana S, Biswas AK, Rao AS. Phytoextraction of lead by marigold and chrysanthemum. Indian Journal of Plant Physiology (India); 2008.

Ramana S, Biswas AK, Ajay SA, Subba Rao A. Tolerance and bioaccumulation of cadmium and lead by gladiolus. Natl Acad Sci Lett. 2008;31(11and12):327-332.

Ramana S, Biswas AK, Rao AS. Phytoremediation of cadmium contaminated soils by marigold and chrysanthemum. National Academy Science Letters. 2009;32(11/12):333-336.

Ramana S, Biswas AK, Singh AB, Ahirwar NK. Phytoremediation of chromium by tuberose. National Academy Science Letters. 2012;35:71-73.

Ramana S, Biswas AK, Singh AB, Kumar PN, Ahirwar NK, Behera SK, Rao AS. Phytoremediation of cadmium contaminated soils by tuberose. Indian Journal of Plant Physiology. 2012;17(1): 61-64.

Ghosh M, Singh SP. A review on phytoremediation of heavy metals and utilization of it’s by products. Asian J Energy Environ. 2005;6(4):18.

Chauhan P, Mathur J. Phytoremediation efficiency of Helianthus annuus L. for reclamation of heavy metals-contaminated industrial soil. Environmental Science and Pollution Research. 2020;27:29954-29966.

Chowdhury A, Naz A, Maiti SK. Bioaccumulation of potentially toxic elements in three mangrove species and human health risk due to their ethnobotanical uses. Environmental Science and Pollution Research. 2021;28:33042-33059. Available:https://doi.org/10.1007/s11356-021-12566-w.

Das I, Ghosh K, Sanyal SK. Phytoremediation: A potential option to mitigate arsenic contamination in soil-water-plant system. Everyman’s Sci. 2005;40(2):115-123.

Baretha G, Maitry A, Shah P. Assisted natural regeneration: A tool for ecosystem service benefits to achieve sustainable development goals. In: Patil G. Ecosystem Services with Sustainable Development, International Research Academic Publication, New Delhi, India. 2022;91-99.

Pradeep KMR, Subbarayappa CT, Prakasha HC, Devakumar AS, Muthuraju R. Soil quality assessment under different land use systems of Gandhi Krishi Vigyana Kendra, Bengaluru; 2023.

Ramesh, Patil G, Shah P, Sharma D, Kamesh, Maitry A. Impacts of fly ash on different vegetation near industrial areas: A review. Environment and Ecology. 2024;42(2):470-478.

Patil G, Divya MP, Shah P, Maitry A. Metal accumulation ability of different Eucalyptus species at the early stage. Forestist. 2024;74(1):26-34.

Govindaraju M, Fowmitha Banu J, Senthamil selvi S, Goel M. CO 2 sequestration through phytoremediation techniques with special emphasis on urban forestry to mitigate climate change impact. Climate Change and Green Chemistry of CO2 Sequestration. 2021;263-271.