Uranium mining fuels evolution in deep groundwater microbiomes

Microbial communities in the deep biosphere underpin global biogeochemical cycles, yet their evolutionary responses to extensive anthropogenic disturbances remain unclear. Uranium in-situ leaching (ISL), a dominant mining strategy, creates persistent radiochemical and redox gradients in aquifers, providing a unique system for studying subsurface microbial evolution. Here, by exploiting metagenomics and metatranscriptomics in examining microbial responses through various mining stages at neutral U ISL sites, we show that geochemical changes accompany significant alterations in microbial community composition, oxidative stress, biogeochemical cycling, and overexpression of DNA repair genes. Comparative metagenomics and metatranscriptomics revealed elevated non-synonymous to synonymous polymorphism ratios and altered nucleotide diversity correlated with radiochemical gradients, underscoring the influence of environmental stress in promoting microbial evolution. Our results demonstrate that neutral ISL drives adaptive genetic and functional diversification of subsurface microbiomes and extend core microbial evolutionary frameworks to anthropogenically modified subsurface environments, redefining the deep biosphere as a dynamic, responsive system.