School of Pharmaceutical Sciences, CSJM University 208024, Kanpur, Uttar Pradesh, India.
Faculty of Pharmacy, Uttar Pradesh University of Medical Sciences Saifai 206130, Etawah, India.
Biomed Res Int. 2024 Nov 9;2024:9582237. doi: 10.1155/2024/9582237. eCollection 2024.
Heavy metals are lethal and hazardous pollutants for the ecosystem owing to their virtues including acute toxicity, prolonged persistence, and bioaccumulation. These contaminants are not only a threat to aquatic/terrestrial biota but also pose serious health issues to humans. Natural and anthropologic processes consistently upsurge heavy metal concentration beyond acceptable limits and mobilization and hence disturb biogeochemical cycles and the food chain, although several conventional strategies including adsorption, chemical precipitation, ion exchange, and membrane separation methods are being employed for the removal of these lethal heavy metals from the ecosystem but failed due to lower efficiency rates and high application charges. The current scenario highly demands advanced biosorption or bioaccumulation processes that slow down heavy metal mobilization within the acceptable limit in the ecosystem. Genetically modified microorganisms (GMMs) with desired features are developed through interdisciplinary participation of genomics, molecular microbiology, and bioinformatics that have more potential to bioremediate heavy metals than the native microbes from polluted ecosystems. The study focuses on different sources of heavy metals, their impact on the ecosystem, and the bioremediation of toxic heavy metals via GMMs.
重金属因其急性毒性、持久性和生物累积性等优点,对生态系统是致命和危险的污染物。这些污染物不仅对水生/陆地生物群构成威胁,而且对人类健康也构成严重威胁。自然和人为过程不断将重金属浓度提高到超出可接受的限度,并使其发生迁移,从而扰乱了生物地球化学循环和食物链。尽管目前正在采用包括吸附、化学沉淀、离子交换和膜分离方法在内的几种常规策略来从生态系统中去除这些致命重金属,但由于效率较低和应用费用较高,这些方法都失败了。当前的情况迫切需要先进的生物吸附或生物累积过程,以在生态系统中可接受的限度内减缓重金属的迁移。通过基因组学、分子微生物学和生物信息学的跨学科参与,开发出具有所需特性的基因修饰微生物(GMM),它们比来自污染生态系统的天然微生物更有潜力来生物修复重金属。本研究重点关注重金属的不同来源、它们对生态系统的影响以及通过 GMM 进行有毒重金属的生物修复。
