Abstract The diversity of protein antigens the adaptive immune system can respond to is governed by polymorphic major histocompatibility complex (MHC) molecules. Because MHC alleles are co-dominantly expressed, MHC heterozygosity should allow for a wider diversity of antigens to activate T cells. B cells present antigen via MHC molecules to T cells, and through the ensuing T cell interaction, differentiate into plasma cells. Because of this, MHC heterozygosity should result in the generation of a plasma cell pool able to generate antibodies that target a wider array of antigens. To investigate this claim, we compared B cell selection dynamics between homozygote and heterozygote MHC congenic mice within the germinal centers (GCs) of Peyer’s patches; the major secondary lymphoid tissues of the gut where plasma cells develop in response to the microbiota. I have observed differences in the distribution of GC B cells between the dark zone (DZ) and light zone (LZ) of GCs. Specifically, GC B cells in MHC heterozygotes are found in greater abundance in the LZ and lower abundance in the DZ compared the GC B cells from MHC homozygote mice, which suggests that B cells are more capable of interacting with T cells in MHC heterozygotes. MHC heterozygotes also have significantly higher abundance of GC-T FHcells in their Peyer’s patches. I have observed that MHC heterozygote mice show enhanced binding of IgA to SI-resident bacteria. Future experiments seek to sort-purify IgA-bound SI-resident bacteria from MHC heterozygotes and homozygotes for 16S analysis to determine if MHC heterozygotes bind a more diverse array of bacterial species. We will also perform IgH-sequencing to define the effect of MHC heterozygosity on repertoire diversity of plasma cell populations. Supported by grants from the NIH (R21AI142409, R01AII55887)