Differences in DNA sequence specificity among MHC class II X box binding proteins

The class II (Ia) MHC Ag are integral membrane proteins whose expression is limited to specific cell types. A pair of consensus sequences, X and Y, is found upstream from all class II genes and deletion of each of these sequences eliminates expression of transfected genes. Cells that express Ia demonstrate a coordinate response to lymphokines and other stimuli. These conserved sequences might, therefore, play a role in tissue specificity or lymphokine inducibility of Ia gene expression. The X box sequence of the murine class II A alpha gene diverges much more substantially from the X consensus than does the Y box motif of this gene. We demonstrate that this X box motif is nonetheless recognized by sequence-specific DNA-binding proteins, as is the more closely conserved Y box. Gel retardation assays and DNase I footprints were compared for a panel of Ia+ and Ia- cells as well as for cells stimulated with the Ia-inducing lymphokines IL-4 and IFN-gamma. The level, retardation pattern and region of DNA contact were comparable in all instances. Thus the availability of active DNA-binding X and Y box factors cannot alone account for the regulation of A alpha expression. To test whether the same set of proteins binds all class II MHC conserved motifs, oligonucleotide probe binding and cross-competition experiments with X box sequences from A alpha, E alpha, and E beta genes were performed. These studies demonstrated A alpha, E alpha, and E beta DNA-protein complexes with unique mobilities and specificities. In addition, all three X box oligonucleotide probes generated one faint complex with an affinity profile of E beta greater than E alpha much greater than A alpha. These three complexes comigrated and thus may represent a communal binding protein. The data are most consistent with the conclusion that multiple proteins bind class II MHC X boxes. For A alpha, the predominant complexes represent different specificities from the predominant E alpha and E beta X box binding proteins.     

Congenital immunodeficiency with a regulatory defect in MHC class II gene expression lacks a specific HLA-DR promoter binding protein, RF-X

The expression of MHC class II genes is tightly regulated. One form of congenital severe combined immunodeficiency (SCID) is characterized by a regulatory defect that precludes expression of HLA class II genes. B lymphocyte cell lines from such SCID patients provide a tool for identifying putative regulatory proteins that bind to class II gene promoters. We have identified three proteins binding to specific segments of the HLA-DRA promoter, two of which interact to form the predominant DNA-protein complex observed. One of these proteins, defined as an X box binding protein (RF-X), is specifically missing in cells from class II deficient SCID patients. We propose that the molecular defect in this congenital HLA class II regulatory deficiency is a lack of RF-X and that this factor plays an important role in the normal regulation of MHC class II gene expression.     

Mutations in the bare lymphocyte syndrome define critical steps in the assembly of the regulatory factor X complex

The regulatory factor X (RFX) complex, which contains RFXANK(B), RFXAP, and RFX5, binds to X and S boxes in major histocompatibility complex class II (MHC II) promoters. In the bare lymphocyte syndrome (BLS), which is a human severe combined immunodeficiency, MHC II promoters are neither occupied nor transcribed. Thus, the absence of any one subunit prevents the formation of the RFX complex. Nevertheless, except for a weak binding between RFX5 and RFXAP, no other interactions between RFX proteins have been described. In this study, we demonstrate that RFXANK(B) binds to RFXAP to form a scaffold for the assembly of the RFX complex, which then binds to DNA. Moreover, mutant RFXANK(B) and RFXAP proteins from complementation groups B and D of BLS, respectively, cannot support this interaction. Our data elucidate an intriguing medical situation, where a genetic disease targets two different surfaces that are required for the nucleation of a multisubunit DNA-protein complex.     

Two DNA-binding proteins discriminate between the promoters of different members of the major histocompatibility complex class II multigene family.

The regulation of major histocompatibility complex (MHC) class II gene expression is a key feature of the control of normal and abnormal immune responses. In humans, class II alpha - and beta-chain genes are organized in a multigene family with three distinct subregions, HLA-DR, -DQ, and -DP. The regulation of these genes is generally coordinated, and their promoters contain highly conserved motifs, in particular the X and Y boxes. We have identified five distinct proteins that bind to specific DNA sequences within the first 145 base pairs of the HLA-DR promoter, a segment known to be functionally essential for class II gene regulation. Among these, RF-X is of special interest, since mutants affected in the regulation of MHC class II gene expression have a specific defect in RF-X binding. Unexpectedly, RF-X displays a characteristic gradient of binding affinities for the X boxes of three alpha-chain genes (DRA greater than DPA much greater than DQA). The same observation was made with recombinant RF-X. We also describe a novel factor, NF-S, which bound to the spacer region between the X and Y boxes of class II promoters. NF-S exhibited a reverse gradient of affinity compared with RF-X (DQA greater than DPA much greater than DRA). As expected, RF-X bound well to the mouse IE alpha promoter, while NF-S bound well to IA alpha. The drastic differences in the binding of RF-X and NF-S to different MHC class II promoters contrasts with the coordinate regulation of HLA-DR, -DQ, and -DP genes.