Project Summary T-cell-dependent (TD) immunoglobulin A (IgA) responses regulate the composition of the gut microbiota. How B-cell-intrinsic MHCII signaling, which is central to the development of TD IgA responses, influences host- microbiota interactions is unknown. MHCII is widely assumed to promote clonal diversity in effector lymphocyte populations, but this has not been tested. Here, we present evidence in support of the argument that B cell- intrinsic MHCII signaling controls GC dynamics, IgA repertoire diversity, and microbiota composition. Additionally, evidence from our experiments also indicate that both B-cell-intrinsic ablation of MHCII and specific MHC genotypes are associated with enhanced bacterial dissemination from the gut. Based on these observations and previous work by Dr. Kubinak, this R01 seeks to address the hypothesis that B-cell-intrinsic MHCII signaling is a diversifying force of selection promoting clonal diversity in IgA plasma cell pools and individuality in microbiota composition. The objective of Specific Aim #1 is to define the B-cell-intrinsic role of MHCII during GC reactions in the gut; specifically focusing on its role in shaping plasma cell repertoire diversity. A 'Confetti' mouse model will be used to visually demonstrate the effect of MHCII ablation on GC B cell clonal diversity in the gut. IgH sequencing will be used to determine the effect of MHCII polymorphisms and MHC heterozygosity on IgA repertoire diversity in the gut. scRNA sequencing will be used to determine how MHCII influences overlap in clonal diversity between mucosal and systemic plasma cell pools. RAG1-/- bone marrow (BM) chimeras will be used to quantify the effect of MHCII on cross-seeding of gut-derived plasma cells into the BM. Reciprocal BM chimeras will be used to determine the necessity/sufficiency of defects in B-cell-intrinsic MHCII in regulating bacterial dissemination from the gut. The objective of Specific Aim #2 is to test that microbiota composition is an MHCII-dependent phenotype. RAG1-/- and RAG1-/-IL7R-/- BM chimeras will be used to determine the role gut peyer's patches play in driving MHCII-mediated IgA selection in the gut. Microbial colonization experiments in germfree GF RAG1-/- BM chimeras will determine the effect of B-cell-intrinsic MHCII on IgA-targeting of commensal bacteria. A RAG1-/- adoptive transfer model will be used to determine if MHCII surface density influences IgA-mediated targeting of commensals and microbiota composition. Finally, a novel germfree MHC congenic model will be used to explicitly define the role IgA plays in driving individuality in microbiota composition. Results from these studies will address the B-cell-intrinsic role of MHCII in regulating mucosal IgA responses, microbiota composition, and host health. This is a critical gap in our knowledge that is highly relevant to human health. IgA deficiency is the most common form of antibody-deficiency in humans, is strongly linked to genetic varia...