Specific overexpression of rheumatoid arthritis-associated HLA-DR alleles and presentation of low-affinity peptides.

International audienceObjective To compare levels of HLA–DR expression in rheumatoid arthritis (RA) patients and healthy controls for whom an ordered expression according to the DR alleles is demonstrated and to test the functional consequences of this expression on peptide presentation. Methods Using monoclonal antibodies that recognize different DRB1 alleles, DR molecules were quantitated at the surface of the peripheral blood B cells of 23 RA patients and 17 healthy subjects. The functional consequences of the level of DR surface expression was tested using a universal model of antigen presentation and mutated peptides with variable affinities for the T cell receptor. Results In healthy subjects, surface HLA–DR molecules were expressed at different levels according to allele (DR53, DR4, and DR11 less than DR1 less than DR7 less than DR15). In RA patients, this hierarchy was not conserved and, furthermore, the density of RA‐associated DR4 and DR1 molecules was enhanced in patients compared with the basal density in healthy individuals. We demonstrated that an increased expression of DR molecules at the surface of antigen‐presenting cells allowed a noteworthy presentation of low‐affinity peptides that under normal conditions are not efficient in generating a T cell response at physiologic surface density of the DR molecules. Conclusion Our results suggest that the specific overexpression of RA‐associated HLA molecules could be responsible for the presentation of low‐affinity autopeptides and therefore the activation of peripheral autoreactive T cells

Regulation of major histocompatibility complex class II gene expression, genetic variation and disease.

Major histocompatibility complex (MHC) class II molecules are central to adaptive immune responses and maintenance of self-tolerance. Since the early 1970s, the MHC class II region at chromosome 6p21 has been shown to be associated with a remarkable number of autoimmune, inflammatory and infectious diseases. Given that a full explanation for most MHC class II disease associations has not been reached through analysis of structural variation alone, in this review we examine the role of genetic variation in modulating gene expression. We describe the intricate architecture of the MHC class II regulatory system, indicating how its unique characteristics may relate to observed associations with disease. There is evidence that haplotype-specific variation involving proximal promoter sequences can alter the level of gene expression, potentially modifying the emergence and expression of key phenotypic traits. Although much emphasis has been placed on cis-regulatory elements, we also examine the role of more distant enhancer elements together with the evidence of dynamic inter- and intra-chromosomal interactions and epigenetic processes. The role of genetic variation in such mechanisms may hold profound implications for susceptibility to common disease