For dietary metabolite analysis, diet pellets were suspended in 5?ml deuterium oxide per gram diet and allowed to fully dissolve overnight at 4?C before clarification by centrifugation at 14,000??for 5?min at 4?C. link between dietary macronutrient composition, gut microbial extracellular vesicles release and host secretory IgA response. Subject terms: Mucosal immunology, Microbiome, Antibodies, PSI-6206 Bacterial host response Secretory IgA plays vital roles interfacing between the host immune system and the resident microbiota at the mucosal surface. Here the authors explore the effect of dietary protein on the production of secretory IgA, driven by the production of extracellular vesicles by the intestinal microbiota. Introduction The gut microbiota, defined by the trillions of bacteria that inhabit the gut, play a critical role in the physiology and immunity of the host1. To maintain a symbiotic relationship, strategies have been developed by the host to regulate its interaction with the gut microbiota. Mucosal secretory IgA (sIgA) plays a key role in this host-microbiota mutualism by excluding pathobionts and pathogens and limiting bacterial attachment to the epithelium2. While patients with selective IgA deficiency appear healthy, they are more susceptible to various diseases, including gastrointestinal disorders and allergies3, highlighting the importance of IgA in mucosal homoeostasis. Under homoeostatic conditions, IgA is primarily produced by plasma cells local to the small intestine lamina propria through a T cell-independent pathway4,5. The majority of commensal bacteria induce T-cell-independent IgA responses6, and sIgA generated via this pathway is of low affinity and polyreactive towards common bacterial antigens, limiting the attachment of a diverse range of bacteria to the host epithelium7. The induction of sIgA is regulated by the local cytokine environment, with the increase in class switch recombination (CSR) cytokines, APRIL and BAFF, produced by epithelial cells, promoting the differentiation of IgM+ B cells into IgA-producing plasma cells5,8. These cytokines are produced as a result of toll-like receptor (TLR) activation, particularly TLR4, which recognises bacterial lipopolysaccharide (LPS)9. TLR activation by commensal bacteria is critical both for the recruitment of IgM+ B cells in the lamina propria, by increasing the expression of the gut homing chemokine CCL289, and for the induction IgA CSR by upregulating APRIL10. TLR4 is the major TLR expressed on the epithelium and its overstimulation in TLR4 transgenic mice has been shown to promote CCL28 and APRIL production and accumulation of IgA in the lamina propria and gut lumen9. The majority of IgA produced in the gut is in dimeric form, which can be transported through the epithelium into the lumen by binding the polymeric immunoglobulin receptor (pIgR)11. Similarly, pIgR expression can be upregulated by several inflammatory cytokines such as IFN-, IL-1, PSI-6206 IL-17, TNF, and IL-4, following TLR4/NFB signalling12. Of note, IL-4 can have a dual role by also promoting IgA CSR. Seminal work utilising germ-free mice has established that the presence of gut bacteria is the main driver of sIgA response, and transient colonisation of germ-free animals with leads to transient sIgA production13. However, how dynamic changes to the gut microbiota composition affect sIgA is less clear. Diet composition is a major driver of the microbiota composition with most studies focusing on microbiota profiling in the caecum and the colon14, where IgA production is minimal, compared to the small intestine. How dietary macronutrient composition (i.e., protein, fat and carbohydrate) affects the dynamic interplay between the small intestine microbiota and mucosal IgA remains unknown. This knowledge could establish which diet compositions are beneficial for restoring gut homoeostasis and which diets are detrimental. In our approach, we fed mice on one of Rabbit polyclonal to BMP7 10 different isocaloric diets varying in their macronutrient composition, which identified an association between dietary protein and sIgA levels using mixture modelling. We validated and explored these results further using a subset of the 10 diets, representing a high-protein, high-carbohydrate or high-fat diet. We found that the high-protein diet had the highest intestinal sIgA levels, and this was associated with increased expression of CCL28 and APRIL in the small intestine. These changes were correlated with the increased capacity of the microbiota to stimulate TLR4 directly or indirectly via increased production of gut microbiota-derived extracellular vesicles (EV). We also established that PSI-6206 EV derived from high-protein diet microbiota could directly promote the expression of CCL28. Our work highlights the key role of dietary protein on sIgA production and identifies bacterial-derived EV as a mediator of gut microbiota-host mutualism. Results High protein feeding promotes high lamina propria IgA production and higher secretion of luminal sIgA To determine how dietary macronutrients might affect.