The microbiome and mucosal immunity in cervical cancer disparities African American women living in the United States continue to experience an undue higher burden of cervical cancer and a >2 times higher mortality rate than European American women. This survival disparity persists after accounting for socioeconomic status and disease stage. The presence of high-risk human papillomavirus (HPV) is the major cause of cervical cancer and cervical intraepithelial neoplasia. Prophylactic vaccines are available against the most carcinogenic types and are highly effective, but disparities persist and the number of people receiving the vaccine remains suboptimal especially for African American women, and the vaccine is ineffective for the 40% of female US population already infected with genital HPV. Treatment options for advanced stages are limited, and metastatic cancer is incurable. New therapeutic approaches are therefore needed but the mucosal mechanisms contributing to disease pathogenesis in African American women are not well understood. Therefore, identifying mucosal processes and/or mediators which modify HPV persistence vs clearance and progression vs remission of cervical neoplasia could lead to new or improved treatments and better CC outcomes for women. In this proposal we will investigate the contribution of the microbiome and mucosal immunity in the female genital tract to health disparities in cervical cancer in African American women. This is built upon considerable data from our lab and others that show that African American women have higher proportion of vaginal microbial dysbiosis; that vaginal microbial dysbiosis is linked to pro-inflammatory and cancer pathways in cervical mucosa; that these bacteria produce metabolites that are linked to an immunosuppressive phenotype; that dysbiotic bacteria can induce cancer pathways in vitro; and cervical cancer tissue gene expression data from African American women show increased activation inflammatory pathways compared to European American women. In this concept we will utilize state-of-the-art systems biology techniques, including metagenomics, metaproteomics, metabolomics, single cell RNA sequencing and flow cytometry to study vaginal mucosal biology in prospective studies of African American women, coupled with functional studies in PV-associated cervical cancer mouse models, to better understand these relationships.