DefinePK

Abstract

Radiation pollution, stemming from both natural and anthropogenic sources, poses significant environmental and health risks due to the damaging effects of ionizing radiation on biological systems. Microorganisms, ubiquitous in diverse environments, exhibit remarkable resilience and unique mechanisms to interact with radionuclides. This review article explores the multifaceted impact of radiation pollution on microbial communities, detailing how it alters their diversity, composition, and induces DNA damage and cellular stress. We delve into the sophisticated mechanisms employed by microorganisms to interact with radionuclides, including bioreduction (direct and indirect), biomineralization/bioprecipitation, biosorption, and bioaccumulation, which collectively transform mobile radioactive elements into less hazardous forms. Furthermore, the article highlights the extraordinary adaptations of microorganisms to radioactive environments, such as extreme radiation resistance through efficient DNA repair and antioxidant systems, and metabolic versatility, including the use of radionuclides as electron acceptors. Finally, we discuss the promising applications of these microbial capabilities in bioremediation, particularly through the use of naturally occurring and genetically engineered microorganisms for radioactive waste management. While significant progress has been made, challenges remain in scaling up these solutions and understanding long-term stability. Future research should focus on leveraging 'omics' technologies to further unravel microbial dynamics in radioactive environments and integrate microbial approaches with other remediation strategies to develop comprehensive and sustainable solutions for radiation pollution.