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Advances in mechanism for the microbial transformation of heavy metals: implications for bioremediation strategies

Chunlian Ding, Zihan Ding, Qingcai Liu, Weizao Liu, Liyuan Chai

2024Chemical Communications43 citationsDOI

Abstract

detoxification or resistance, playing a pivotal role in the speciation, bioavailability, and mobility of heavy metals. Therefore, studies on the mechanism for the microbial transformation of heavy metals are of great importance and can provide guidance for heavy metal bioremediation. Current research studies on the microbial transformation of heavy metals mainly focus on the single oxidation, reduction and methylation pathways. However, complex microbial transformation processes and corresponding bioremediation strategies have never been clarified, which may involve the inherent physicochemical properties of heavy metals. To uncover the underlying mechanism, we reclassified heavy metals into three categories based on their biological transformation pathways, namely, metals that can be chelated, reduced or oxidized, and methylated. Firstly, we comprehensively characterized the difference in transmembrane pathways between heavy metal cations and anions. Further, biotransformation based on chelation by low-molecular-weight organic complexes is thoroughly discussed. Moreover, the progress and knowledge gaps in the microbial redox and (de)methylation mechanisms are discussed to establish a connection linking theoretical advancements with solutions to the heavy metal contamination problem. Finally, several efficient bioremediation strategies for heavy metals and the limitations of bioremediation are proposed. This review presents a solid contribution to the design of efficient microbial remediation strategies applied in the real environment.

Topics & Concepts

BioremediationMechanism (biology)Transformation (genetics)Biochemical engineeringHeavy metalsEnvironmental scienceEnvironmental chemistryChemistryContaminationBiologyEcologyEngineeringBiochemistryPhysicsQuantum mechanicsGeneMercury impact and mitigation studiesHeavy metals in environmentChromium effects and bioremediation
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