Antidiabetogenic MHC class II promotes the differentiation of MHC-promiscuous autoreactive T cells into FOXP3+ regulatory T cells

Polymorphisms in MHC class II molecules, in particular around β-chain position-57 (β57), afford susceptibility/resistance to multiple autoimmune diseases, including type 1 diabetes, through obscure mechanisms. Here, we show that the antidiabetogenic MHC class II molecule I-A^b affords diabetes resistance by promoting the differentiation of MHC-promiscuous autoreactive CD4⁺ T cells into disease-suppressing natural regulatory T cells, in a β56–67-regulated manner. We compared the tolerogenic and antidiabetogenic properties of CD11c promoter-driven transgenes encoding I-A^b or a form of I-A^b carrying residues 56–67 of I-Aβ^g7 (I-A^b-g7) in wild-type nonobese diabetic (NOD) mice, as well as NOD mice coexpressing a diabetogenic and I-A^g7–restricted, but MHC-promiscuous T-cell receptor (4.1). Both I-A transgenes protected NOD and 4.1-NOD mice from diabetes. However, whereas I-A^b induced 4.1-CD4⁺ thymocyte deletion and 4.1-CD4⁺Foxp3⁺ regulatory T-cell development, I-A^b-g7 promoted 4.1-CD4⁺Foxp3⁺ Treg development without inducing clonal deletion. Furthermore, non–T-cell receptor transgenic NOD.CD11cP-I-A^b and NOD.CD11cP-IA^b-g7 mice both exported regulatory T cells with superior antidiabetogenic properties than wild-type NOD mice. We propose that I-A^b, and possibly other protective MHC class II molecules, afford disease resistance by engaging a naturally occurring constellation of MHC-promiscuous autoreactive T-cell clonotypes, promoting their deviation into autoregulatory T cells.