RFX proteins, a novel family of DNA binding proteins conserved in the eukaryotic kingdom.

Until recently, the RFX family of DNA binding proteins consisted exclusively of four mammalian members (RFX1-RFX4) characterized by a novel highly conserved DNA binding domain. Strong conservation of this DNA binding domain precluded a precise definition of the motif required for DNA binding. In addition, the biological systems in which these RFX proteins are implicated remained obscure. The recent identification of four new RFX genes has now shed light on the evolutionary conservation of the RFX family, contributed greatly to a detailed characterization of the RFX DNA binding motif, and provided clear evidence for the function of some of the RFX proteins. RFX proteins have been conserved throughout evolution in a wide variety of species, including Saccharomyces cerevisiae, Schizosaccharomyces pombe, Caenorhabditis elegans, mouse and man. The characteristic RFX DNA binding motif has been recruited into otherwise very divergent regulatory factors functioning in a diverse spectrum of unrelated systems, including regulation of the mitotic cell cycle in fission yeast, the control of the immune response in mammals, and infection by human hepatitis B virus.     

A consensus motif in the RFX DNA binding domain and binding domain mutants with altered specificity.

The RFX DNA binding domain is a novel motif that has been conserved in a growing number of dimeric DNA-binding proteins, having diverse regulatory functions, in eukaryotic organisms ranging from yeasts to humans. To characterize this novel motif, we have performed a detailed dissection of the site-specific DNA binding activity of RFX1, a prototypical member of the RFX family. First, we have performed a site selection procedure to define the consensus binding site of RFX1. Second, we have developed a new mutagenesis-selection procedure to derive a precise consensus motif, and to test the accuracy of a secondary structure prediction, for the RFX domain. Third, a modification of this procedure has allowed us to isolate altered-specificity RFX1 mutants. These results should facilitate the identification both of additional candidate genes controlled by RFX1 and of new members of the RFX family. Moreover, the altered-specificity RFX1 mutants represent valuable tools that will permit the function of RFX1 to be analyzed in vivo without interference from the ubiquitously expressed endogenous protein. Finally, the simplicity, efficiency, and versatility of the selection procedure we have developed make it of general value for the determination of consensus motifs, and for the isolation of mutants exhibiting altered functional properties, for large protein domains involved in protein-DNA as well as protein-protein interactions.     

The genes for MHC class II regulatory factors RFX1 and RFX2 are located on the short arm of chromosome 19.

RFX1 is a transacting DNA-binding regulatory factor involved in the control of MHC class II gene expression. RFX2 is a structurally very similar protein with identical DNA binding features. A member of the family of RFX factors is affected in an autosomal recessive disease, MHC class II deficient combined immunodeficiency (CID), caused by a defect in a trans-acting regulatory factor controlling MHC class II gene expression. In situ hybridization with 3H-labeled RFX1 cDNA has allowed us to identify two distinct targets on the short arm of chromosome 19 (19p13.1 and 19p13.2-p13.3). With the use of biotinylated genomic cosmid clones specific for RFX1 and RFX2, respectively, it was then possible to localize RFX1 at 19p13.1 and RFX2 at 19p13.2-p13.3. These two regulatory genes are thus assigned to a region of high gene density and RFX1 is close to another DNA-binding factor, LYL1.     

Characterization of the RFX complex and the RFX5(L66A) mutant: implications for the regulation of MHC class II gene expression

Major histocompatability complex class II (MHCII) molecules are an essential component of the mammalian adaptive immune response. The expression of MHCII genes is regulated by a cell-specific multiprotein complex, termed the MHCII enhanceosome. The heterotrimeric RFX complex is the key DNA-binding component of the MHCII enhanceosome. The RFX complex is comprised of three proteins, RFXB, RFXAP, and RFX5, all of which are required for DNA binding and activation of MHCII gene expression. Static light scattering and chemical cross-linking of the three RFX proteins show that RFXB and RFXAP are monomers and that RFX5 dimerizes through two separate domains. One of these domains, the oligomerization domain, promotes formation of a dimer of dimers of RFX5. In addition, we show that the RFX complex forms a 2:1:1 complex of RFX5.RFXAP.RFXB, which can associate with a further dimer of RFX5 to form a 4:1:1 complex through the oligomerization domain of RFX5. On the basis of these studies, we propose DNA-binding models for the interaction between the RFX complex and the MHCII promoter including a DNA looping model. We also provide direct evidence that the RFX5(L66A) point mutation prevents dimerization of the RFX complexes and propose a model for how this results in a loss of MHCII gene expression.