The intestinal mucosa is the largest body surface exposed to the environment. While there are common features when comparing immune responses along the intestinal mucosa, the small bowel and colon exhibit striking differences in their mechanisms driving immune regulation. The vitamin A (VA) metabolite all-trans retinoic acid (RA) signaling via RA nuclear receptors plays a key role in immune homeostasis in the small bowel, and recent work indicates that RA is required for establishing immune tolerance to dietary antigens in the upper intestinal tract by inducing α4β7(+)CCR9(+) gut-tropic TREG. In contrast, microbiota-specific TREG in the colon do not appear to require RA, but can be regulated by short-chain fatty acids (SCFA), microbial metabolites that signal through the G protein-coupled receptor GPR43. Moreover, TREG do not need CCR9 to home to the colon, but utilize another G protein-coupled receptor, GPR15, which is upregulated by SCFA. Thus, the mechanisms governing intestinal tolerance to dietary antigens in the upper digestive tract differ from those controlling tolerance to the microbiota in the colon, with RA and SCFA playing key complementary roles in their respective compartments. In addition to VA and SCFA, recent studies have highlighted the roles of other dietary and microbial metabolites that influence immune cell homeostasis across the small and large bowel including dietary ligands for aryl hydrocarbon receptor and microbiota-modified bile acids. Understanding the complex and dynamic interplay between dietary metabolites and commensal microbiota within the intestinal microenvironment could therefore inform novel strategies for the treatment of food allergies and inflammatory bowel diseases.
2014 Nestec Ltd., Vevey/S. Karger AG, Basel.