Parvimonas micra alters gut microbiota and promotes tumor growth through DNA methylation

Oral commensals such as Parvimonas micra are increasingly implicated in sporadic colorectal cancer (CRC). Several findings support an emerging notion that alterations in host DNA methylation constitute a mechanism by which P. micra adapts to the host microenvironment and contributes to pathogenic processes. However, multiple limitations hinder definitive conclusions, including the correlative nature of the human studies and the absence of human microbiota in mouse models. Here, we investigated how a complex human microbiome influences the adaptation and oncogenic potential of P. micra in a spontaneous mouse model of polyposis. Adult mice, following antibiotic conditioning, received fecal microbiota transplants (FMT) from a healthy human donor, with or without supplementation of P. micra. P. micra caused significant reshaping of the gut microbial community and altered co-occurrence network structures, which however largely recovered within 21 days post FMT. Despite the transient nature of these changes, P. micra caused a marked increase in both the number and invasive potential of intestinal polyps. Epigenomic profiling of polyp crypts revealed global DNA hypomethylation alongside gene-specific hypermethylation, accompanied by transcriptional changes in key oncogenic pathways. Affected pathways included Wnt signaling, epithelial-to-mesenchymal transition, circadian rhythm regulation, and host–microbe interactions. These findings demonstrate that P. micra exerts a profound influence on microbial ecology, host epigenetic programming, and tumorigenesis in a genetically predisposed host, highlighting its role as a microbial driver of intestinal carcinogenesis.