Exceptional stability of the HLA-DQA1*0102/DQB1*0602 alpha beta protein dimer, the class II MHC molecule associated with protection from insulin-dependent diabetes mellitus.

HLA-DQ alleles are closely associated with susceptibility and resistance to insulin-dependent diabetes mellitus (IDDM) but the immunologic mechanisms involved are not understood. Structural studies of the IDDM-susceptible allele, HLA-DQA10301/DQB10302, have classified it as a relatively unstable dimer, particularly at neutral pH. This is reminiscent of studies in the nonobese diabetic mouse, in which I-A(g7) is relatively unstable, in contrast to other murine I-A alleles, suggesting a correlation between unstable MHC class II molecules and IDDM susceptibility. We have addressed this question by analysis of dimer stability patterns among various HLA-DQ molecules. In EBV-transformed B-lymphoblastoid cell lines and PBL, the protein encoded by the IDDM-protective allele HLA-DQA10102/DQB10602 was the most SDS stable when compared with other HLA-DQ molecules, including HLA-DQA10102/DQB10604, a closely related allele that is not associated with protection from IDDM. Expression of six different HLA-DQ allelic proteins and three different HLA-DR allelic proteins in the bare lymphocyte syndrome cell line, BLS-1, revealed that HLA-DQA10102/DQB10602 is SDS stable even in the absence of HLA-DM, while other HLA class II molecules are not. These results suggest that the molecular property of HLA-DQ measured by resistance to denaturation of the alphabeta dimer in SDS may play a role in IDDM protection.