Abstract
Heavy metals, also known as trace elements, are hazardous even at low concentrations and are becoming a growing issue in many countries, including India. Human activities ranging from agriculture to mining to power generation in power plants are the major sources of heavy metals in environment. Lead (Pb) is the second most harmful environmental toxin after arsenic, and its deposition in the environment is steadily increasing due to anthropogenic activity. Pb significantly harms plants, affecting their morphophysiological and biochemical traits, such as irregular cell division during mitosis, subordinate growth of seedlings, and chlorosis. The latter changes the biochemistry of fruits and flowers, which negatively affects the rate of photosynthetic activity. Pb also damages nutrient interactions, photosynthesis, respiration, oxidative damage, and antioxidant defence mechanisms in various plant species. Soil remediation methods, such as biochar supplements and phytoremediation technology, can help address Pb-contaminated soils. Hyperaccumulating plants have developed molecular processes that enable their use in environmental bioremediation. However, efficacy of these methods still needs to be evaluated by rigorous research activities, and new ecologically acceptable remediation techniques need to be developed to reduce lead toxicity.
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Jagota, N., Singh, S., Kaur, H., Kaur, R., Sharma, A. (2024). Oxidative Stress in Lead Toxicity in Plants and Its Amelioration. In: Kumar, N., Jha, A.K. (eds) Lead Toxicity Mitigation: Sustainable Nexus Approaches. Environmental Contamination Remediation and Management. Springer, Cham. https://doi.org/10.1007/978-3-031-46146-0_14
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