Functional effects of a natural polymorphism in the transcriptional regulatory sequence of HLA-DQB1.

DNA sequence polymorphism in the genes encoding HLA class II proteins accounts for allelic diversity in antigen recognition and presentation and, thus, in the role of these cell surface glycoproteins as determinants of the scope of the T-cell repertoire. In addition, sequence polymorphism in the promoter-proximal transcriptional regulatory regions of these genes has been described, particularly for the HLA-DQB1 locus, where these differences may contribute to variation in locus- and allele-specific expression. In this study, we measured the effect of such regulatory sequence polymorphism on the expression of endogenous alleles of DQB1 in heterozygous cells. Quantitative reverse transcriptase-mediated PCR analysis showed that expression of the DQB10301 allele responded more rapidly to gamma interferon induction than that of DQB10302. We have analyzed functional effects of a prominent allelic polymorphism that consists of a TG dinucleotide present between the W and X1 consensus elements in the DQB10302 allele but missing in the DQB10301 allele. The dominant effect of this polymorphism was to introduce a variation in the spacing between the W and X1 elements of these two alleles. A secondary compensatory effect was specific for the TG dinucleotide itself, which was essential for the binding of a nuclear protein complex to the *0302 regulatory region immediately 5' of the X1 element. Derivatives of the DQB1 5' regulatory region were used to drive expression of the chloramphenicol acetyltransferase gene in transient transfections of human B-lymphoblastoid and gamma interferon-treated melanoma cell lines, demonstrating that the additional spacing between the W and X1 elements caused by the presence of the TG dinucleotide in the *0302 allele resulted in reduced expression compared with that driven by the *0301 fragment; this difference overshadowed an up-regulating effect on expression which corresponded to the binding of the TG-dependent nuclear protein complex. The presence of this polymorphism in multiple HLA-DQB1 alleles and in several species suggests selection for two alternative transcriptional regulatory mechanisms influencing expression of alleles of the same HLA locus.