Cloning of the major histocompatibility complex class II promoter binding protein affected in a hereditary defect in class II gene regulation

RFX1, a transactivator of hepatitis B virus enhancer I, belongs to a novel family of homodimeric and heterodimeric DNA-binding proteins

RFX1 is a transactivator of human hepatitis B virus enhancer I. We show here that RFX1 belongs to a previously unidentified family of DNA-binding proteins of which we have cloned three members, RFX1, RFX2, and RFX3, from humans and mice. Members of the RFX family constitute the nuclear complexes that have been referred to previously as enhancer factor C, EP, methylation-dependent DNA-binding protein, or rpL30 alpha. RFX proteins share five strongly conserved regions which include the two domains required for DNA binding and dimerization. They have very similar DNA-binding specificities and heterodimerize both in vitro and in vivo. mRNA levels for all three genes, particularly RFX2, are elevated in testis. In other cell lines and tissues, RFX mRNA levels are variable, particularly for RFX2 and RFX3. RFX proteins share several novel features, including new DNA-binding and dimerization motifs and a peculiar dependence on methylated CpG dinucleotides at certain sites.

RFX1, a transactivator of hepatitis B virus enhancer I, belongs to a novel family of homodimeric and heterodimeric DNA-binding proteins

RFX1 is a transactivator of human hepatitis B virus enhancer I. We show here that RFX1 belongs to a previously unidentified family of DNA-binding proteins of which we have cloned three members, RFX1, RFX2, and RFX3, from humans and mice. Members of the RFX family constitute the nuclear complexes that have been referred to previously as enhancer factor C, EP, methylation-dependent DNA-binding protein, or rpL30 alpha. RFX proteins share five strongly conserved regions which include the two domains required for DNA binding and dimerization. They have very similar DNA-binding specificities and heterodimerize both in vitro and in vivo. mRNA levels for all three genes, particularly RFX2, are elevated in testis. In other cell lines and tissues, RFX mRNA levels are variable, particularly for RFX2 and RFX3. RFX proteins share several novel features, including new DNA-binding and dimerization motifs and a peculiar dependence on methylated CpG dinucleotides at certain sites.

Function of major histocompatibility complex class II promoters requires cooperative binding between factors RFX and NF-Y

Transcription of major histocompatibility complex (MHC) class II genes is controlled largely by the conserved promoter elements called the X and Y boxes. We show here that RFX, the X box-binding protein deficient in certain MHC class II-deficient immunodeficiency patients (CID), and the Y box-binding protein NF-Y bind cooperatively. Functional relevance of this protein-protein interaction is suggested by the fact that promoter activity correlates with cooperative binding of RFX and NF-Y rather than with binding of RFX or NF-Y alone. Stability of the RFX/NF-Y complex is affected by alterations in X-Y box spacing. These results are consistent with the fact that MHC class II promoter function is dependent on correct stereospecific alignment of the X and Y boxes. Cooperative binding involving RFX, NF-Y, and perhaps other MHC class II promoter-binding proteins may explain why the highly specific defect in binding of RFX observed in CID cells is associated in vivo with a bare promoter in which all of the cis-acting elements, including the X and Y boxes, are unoccupied.

The MHC class II E beta promoter: a complex arrangement of positive and negative elements determines B cell and interferon-gamma (IFN-gamma) regulated expression

The 5' proximal region of the E beta gene was studied with respect to B lymphoid expression and responsiveness to cytokines, revealing a complex array of general and cell type specific cis-elements and factors. Full lymphoid activity and response to interferon-gamma (IFN-gamma) is generated by the concerted action of the MHC boxes (H, X and Y) and additional elements. Combinatorial interactions between elements and their cognate factors are indicated by several lines of evidence. Thus, mutations within the X box in the promoter context are strongly deleterious to both B lymphoid activity and IFN-gamma regulation. However, the X box alone has minimal lymphoid activity upon heterologous promoters. Data from deletion, insertion and site directed mutagenesis demonstrate that sequences extending approximately 35 bp 5' of the X box (designated as Cytokine Response Sequence--CRS) have a dual role: they are required for cytokine-regulated expression as well as serving as an enhancer element for cell-specific constitutive expression. A region that carries X and CRS permits both lymphoid activity and IFN-gamma response. In contrast, sequences that include X and the downstream Y box are constitutively active in all cell types tested. Combination of the sequences both upstream and downstream of the X box results in a tissue-specific and cytokine-regulated enhancer of full strength. In vivo competition studies show that titratable trans-acting factors, shared by Class I and Class II promoters, mediate the CRS-dependent IFN-gamma response. We report here the identification of novel nuclear complexes that bind to the CRS and recognize sites which correlate with its negative or positive elements. One of these complexes is present in B lymphoid cells only. Three other CRS complexes that are upregulated by either IFN-alpha and IFN-gamma are competed by a non-Class II, IFN-alpha stimulated response element (ISRE), providing evidence for the functional interconnection of these cytokines.

The major histocompatibility complex class II promoter-binding protein RFX (NF-X) is a methylated DNA-binding protein

A mammalian protein called RFX or NF-X binds to the X box (or X1 box) in the promoters of a number of major histocompatibility (MHC) class II genes. In this study, RFX was shown to have the same DNA-binding specificity as methylated DNA-binding protein (MDBP), and its own cDNA was found to contain a binding site for MDBP in the leader region. MDBP is a ubiquitous mammalian protein that binds to certain DNA sequences preferentially when they are CpG methylated and to other related sequences, like the X box, irrespective of DNA methylation. MDBP from HeLa and Raji cells formed DNA-protein complexes with X-box oligonucleotides that coelectrophoresed with those containing standard MDBP sites. Furthermore, MDBP and X-box oligonucleotides cross-competed for the formation of these DNA-protein complexes. DNA-protein complexes obtained with MDBP sites displayed the same partial supershifting with an antiserum directed to the N terminus of RFX seen for complexes containing an X-box oligonucleotide. Also, the in vitro-transcribed-translated product of a recombinant RFX cDNA bound specifically to MDBP ligands and displayed the DNA methylation-dependent binding of MDBP. RFX therefore contains MDBP activity and thereby also EF-C, EP, and MIF activities that are indistinguishable from MDBP and that bind to methylation-independent sites in the transcriptional enhancers of polyomavirus and hepatitis B virus and to an intron of c-myc.

Antisense oligonucleotides specific for regulatory factor RFX-1 inhibit inducible but not constitutive expression of all major histocompatibility complex class II genes

The regulation of major histocompatibility complex (MHC) class II genes expression, which can be constitutive, inducible or both, is a crucial aspect of the control of an immune response. It involves binding of various regulatory factors to cis-acting sequences of MHC class II promoters. Antisense oligonucleotides specific for RFX-1, a regulatory factor binding to the functionally essential X box motive of MHC class II promoters, were designed to study the role of RFX-1 in the various modes of MHC class II regulation and explore the possibility of experimentally modulating the level of expression of MHC class II genes by transcriptional intervention. RFX-1 antisense oligonucleotides were first tested in cell-free translation, selected for an inhibitory effect on RFX-1 in vitro translation and then assayed in cell cultures for an effect on human histocompatibility leukocyte antigen (HLA) class II expression. We show that an RFX-1 specific antisense oligonucleotide drastically inhibits induction of HLA-DR,-DQ, and -DP molecules by interferon gamma in monocytic cells. Unexpectedly, the same agent has no effect on the constitutive expression of the same genes either in these cells or in B lymphocytes, indicating an uncoupling of the constitutive and inducible modes of class II regulation. This transient and reversible experimental modulation of MHC class II expression in live cells by transcriptional intervention provides a new tool to study the function of class II molecules in various biological models.

The major histocompatibility complex class II promoter-binding protein RFX (NF-X) is a methylated DNA-binding protein

A mammalian protein called RFX or NF-X binds to the X box (or X1 box) in the promoters of a number of major histocompatibility (MHC) class II genes. In this study, RFX was shown to have the same DNA-binding specificity as methylated DNA-binding protein (MDBP), and its own cDNA was found to contain a binding site for MDBP in the leader region. MDBP is a ubiquitous mammalian protein that binds to certain DNA sequences preferentially when they are CpG methylated and to other related sequences, like the X box, irrespective of DNA methylation. MDBP from HeLa and Raji cells formed DNA-protein complexes with X-box oligonucleotides that coelectrophoresed with those containing standard MDBP sites. Furthermore, MDBP and X-box oligonucleotides cross-competed for the formation of these DNA-protein complexes. DNA-protein complexes obtained with MDBP sites displayed the same partial supershifting with an antiserum directed to the N terminus of RFX seen for complexes containing an X-box oligonucleotide. Also, the in vitro-transcribed-translated product of a recombinant RFX cDNA bound specifically to MDBP ligands and displayed the DNA methylation-dependent binding of MDBP. RFX therefore contains MDBP activity and thereby also EF-C, EP, and MIF activities that are indistinguishable from MDBP and that bind to methylation-independent sites in the transcriptional enhancers of polyomavirus and hepatitis B virus and to an intron of c-myc.

RFX1 is identical to enhancer factor C and functions as a transactivator of the hepatitis B virus enhancer

Hepatitis B virus gene expression is to a large extent under the control of enhancer I (EnhI). The activity of EnhI is strictly dependent on the enhancer factor C (EF-C) site, an inverted repeat that is bound by a ubiquitous nuclear protein known as EF-C. Here we report the unexpected finding that EF-C is in fact identical to RFX1, a novel transcription factor previously cloned by virtue of its affinity for the HLA class II X-box promoter element. This finding has allowed us to provide direct evidence that RFX1 (EF-C) is crucial for EnhI function in HepG2 hepatoma cells; RFX1-specific antisense oligonucleotides appear to inhibit EnhI-driven expression of the hepatitis B virus major surface antigen gene, and in transfection assays, RFX1 behaves as a potent transactivator of EnhI. Interestingly, transactivation of EnhI by RFX1 (EF-C) is not observed in cell lines that are not of liver origin, suggesting that the ubiquitous RFX1 protein cooperates with liver-specific factors.

RFX1 is identical to enhancer factor C and functions as a transactivator of the hepatitis B virus enhancer

Hepatitis B virus gene expression is to a large extent under the control of enhancer I (EnhI). The activity of EnhI is strictly dependent on the enhancer factor C (EF-C) site, an inverted repeat that is bound by a ubiquitous nuclear protein known as EF-C. Here we report the unexpected finding that EF-C is in fact identical to RFX1, a novel transcription factor previously cloned by virtue of its affinity for the HLA class II X-box promoter element. This finding has allowed us to provide direct evidence that RFX1 (EF-C) is crucial for EnhI function in HepG2 hepatoma cells; RFX1-specific antisense oligonucleotides appear to inhibit EnhI-driven expression of the hepatitis B virus major surface antigen gene, and in transfection assays, RFX1 behaves as a potent transactivator of EnhI. Interestingly, transactivation of EnhI by RFX1 (EF-C) is not observed in cell lines that are not of liver origin, suggesting that the ubiquitous RFX1 protein cooperates with liver-specific factors.

Mapping cis-acting defects in promoters of transcriptionally silent DQA2, DQB2, and DOB genes

Defects in promoters of the nonexpressed DQA2, DQB2, and DOB genes from the class II major histo-compatibility complex were mapped by placing Z and X boxes of these silent genes into a synthetic DRA promoter. These conserved upstream sequences confer B-cell-specific and gamma-interferon-inducible expression to the DRA gene. Since DRA promoters containing the X box from the DQA2 gene and Z boxes from DQA2, DQB2, and DOB genes were neither expressed constitutively in B cells nor inducible by gamma interferon in fibroblastic cells, these conserved upstream sequences are implicated in the transcriptional defects of these silent genes.

Mutant human cells defective in induction of major histocompatibility complex class II genes by interferon gamma

Using immunoselection, we have isolated 11 independent mutant HT1080 fibrosarcoma cell lines defective in the induction by interferon gamma (IFN-gamma) of the expression of the human leukocyte antigen HLA-DRA. The mutations are recessive and fall into five complementation groups. All the mutants are affected mainly in the expression of major histocompatibility complex class II and invariant-chain genes. Type I mutants (three complementation groups) are completely defective in induction of the invariant-chain and class II HLA-DP, -DQ, -DR, and -DM genes, whereas type II mutants (two complementation groups) induce these genes weakly in response to IFN-gamma, in the order DPB > DRA > invariant chain. The induction by IFN-gamma of the mRNAs for class I, TAP1, LMP7, and 9-27 is partially defective and the induction of the proteins IRF-1 and ICAM-1 is normal in both types of mutants. All the mutants respond normally to IFN-alpha. The mutants are stable and thus can be used to clone the affected genes by reversion.

Techniques for cloning cDNAs encoding interactive transcriptional regulatory proteins

Several approaches aimed at detecting and cloning interactive transcriptional regulatory proteins have been presented. All of the techniques can effectively identify specific interactions between two transcription proteins. However, interaction cloning and the two hybrid system have the added advantage of yielding a cDNA expression clone directly. The other methods, EMSA-mediated cloning, co-immunoprecipitation, oligonucleotide/PCR-facilitated cloning, Southwestern, and Farwestern, require additional manipulations to obtain a cDNA clone. Clearly, the interactive cloning system of choice will depend on the proteins under investigation.

Polymorphism in the regulatory region of HLA-DRB genes correlating with haplotype evolution

Class II genes of the human major histocompatibility complex (MHC) are polymorphic. Allelic variation of the coding region of these genes is involved in the antigen presentation and is associated with susceptibility to certain autoimmune diseases. The DR region is unique among human class II regions in that multiple DRB genes are expressed. Differential expression of the different DRB loci has been demonstrated, and we sequenced the proximal promoter region of the HLA-DRB genes, known to be involved in the regulation of these genes. We found locus-specific and allele-specific nucleotide variations in their regulatory regions and we determined the relationship between the regulatory regions of HLA-DRB genes. This polymorphism found in the regulatory conserved boxes could be involved in the observed differential expression of DRB loci. In addition, we found a polymorphism between the regulatory regions of DRB1 alleles which might be involved in an allele-specific regulation and therefore could be considered as an additional factor in susceptibility to autoimmune diseases.

Current concepts in DRA gene regulation

The purpose of this review is to provide an interpretative view of work from our laboratory on the DRA gene, and incorporate it with work from other laboratories. Specially, we will deal with: (a) the functional roles of transcription factors in DRA gene regulation; (b) the mechanisms of DRA induction by cytokines; (c) the analysis of DRA gene control in primary untransformed cells, and (d) interactions among transcription factors critical for DRA gene expression.

Reversion of a transcriptionally defective MHC class II-negative human B-cell mutant

RJ2.2.5, a mutant derived from the human B-lymphoma cell, Raji, is unable to express the MHC class II genes because of a recessive transcriptional defect attributed to the lack of an activator function. We report the isolation of a RJ2.2.5 revertant, namely AR, in which the expression of the mRNAs encoded by these genes is restored. Comparison of the binding of nuclear extracts or of partially purified nuclear preparations from the wild-type, the mutant and the revertant cells to a conserved MHC class II promoter element, the X-box, showed no alteration in the mobility of the complexes thus formed. However, in extracts from RJ2.2.5, and other MHC class II negative cell lines, such as HeLa, the amount of complex observed was significantly higher than in wild-type Raji cells. Furthermore, the binding activity exhibited by the AR revertant was lower than that of the RJ2.2.5 and higher than that of Raji. The use of specific monoclonal antibodies indicated that in all cases c-Jun and c-Fos or antigenically related proteins were required for binding. An inverse correlation between the level of DNA-protein complex formed and the level of MHC class II gene mRNA expressed in the three cell lines was apparent, suggesting that overexpression of a DNA binding factor forming complexes with class II promoter elements may cause repression of MHC class II transcription. A model which reconciles the previously ascertained recessivity of the phenotype of the mutation carried by RJ2.2.5 with the findings reported here is discussed.

Allele-specific DNA-protein interactions associated with the X-box regulatory region of the DQB1*0302 gene

The X box is an essential transcriptional regulatory region for both constitutive and inducible expression of HLA-class II genes, and, while highly conserved among class II genes, both locus- and allele-specific polymorphisms exist. Using gel regardation analysis, we have analyzed the binding of B cell nuclear proteins to the X box regions of the DQB1*0302, *0301, and DRA genes and have identified two distinct X box binding complexes which differ for the diabetes-associated DQB1*0302 allele.

Activation of the HLA-DRA gene in primary human T lymphocytes: novel usage of TATA and the X and Y promoter elements

Human T lymphocytes express human leukocyte antigen (HLA)-DR-alpha (DRA) upon mitogenic or antigenic stimulation. DR+ T cells are also found in a number of inflammatory and autoimmune diseases and have a proposed role in these diseases. The molecular mechanism of DR regulation in untransformed blood T lymphocytes was studied here by transient transfection of DRA-chloramphenicol acetyltransferase reporter gene constructs. Several novel features of this regulation were observed. During the early stages of T-cell activation by mitogens or antigens, strong promoter induction was exhibited with the proximal 43 bp of the DRA promoter which contains a TATTA motif. Addition of upstream X and Y DNA elements augmented the response. This contrasts with data from transformed cell lines in which the proximal 43 bp produced no detectable promoter function, and the inclusion of X and Y elements is essential for basal level expression. Mutation of the TATTA motif or substitution with a functional but different TATA element produced errant initiation and greatly reduced gene expression. Interestingly, T lymphocytes from a normal donor were DR+ prior to in vitro stimulation, and again, strong promoter activity was observed with 43 bp of proximal sequence. Unexpectedly, the presence of the X and Y elements correlated with a suppression of class II promoter function and surface antigen expression. This study of nontransformed lymphocytes reveals several novel features of DRA gene regulation and underscores the value and necessity of such studies.

Activation of the HLA-DRA gene in primary human T lymphocytes: novel usage of TATA and the X and Y promoter elements

Human T lymphocytes express human leukocyte antigen (HLA)-DR-alpha (DRA) upon mitogenic or antigenic stimulation. DR+ T cells are also found in a number of inflammatory and autoimmune diseases and have a proposed role in these diseases. The molecular mechanism of DR regulation in untransformed blood T lymphocytes was studied here by transient transfection of DRA-chloramphenicol acetyltransferase reporter gene constructs. Several novel features of this regulation were observed. During the early stages of T-cell activation by mitogens or antigens, strong promoter induction was exhibited with the proximal 43 bp of the DRA promoter which contains a TATTA motif. Addition of upstream X and Y DNA elements augmented the response. This contrasts with data from transformed cell lines in which the proximal 43 bp produced no detectable promoter function, and the inclusion of X and Y elements is essential for basal level expression. Mutation of the TATTA motif or substitution with a functional but different TATA element produced errant initiation and greatly reduced gene expression. Interestingly, T lymphocytes from a normal donor were DR+ prior to in vitro stimulation, and again, strong promoter activity was observed with 43 bp of proximal sequence. Unexpectedly, the presence of the X and Y elements correlated with a suppression of class II promoter function and surface antigen expression. This study of nontransformed lymphocytes reveals several novel features of DRA gene regulation and underscores the value and necessity of such studies.

Tumor necrosis factor alpha response elements in the HLA-DRA promoter: identification of a tumor necrosis factor alpha-induced DNA-protein complex in astrocytes

The cytokine tumor necrosis factor alpha (TNF-alpha) alone does not induce class II major histocompatibility complex (MHC) expression in most primary cells but can regulate ongoing class II expression in either a positive or negative fashion. The mechanism(s) by which TNF-alpha enhances interferon gamma (IFN-gamma)-induced class II expression was examined in a primary cell type, the astrocyte, by transient transfection of the HLA-DRA promoter linked to a chloramphenicol acetyltransferase reporter gene (DRA-CAT). We show that TNF-alpha, while having no effect on its own, can synergize with IFN-gamma to increase the level of promoter activity of a DRA-CAT construct. Three known sequences--W, X, and Y--are required for TNF-alpha enhancement of IFN-gamma-induced promoter activity. The corollary effect of TNF-alpha on DNA-binding proteins specific for these elements was examined. A previous report described a DNA-binding protein, IFN-gamma-enhanced factor X (IFNEX), which is upregulated by IFN-gamma in astrocytes and is specific for the X box of the DRA promoter. In this study, we found that TNF-alpha alone did not induce any nuclear proteins; however, combined treatment of astrocytes with both IFN-gamma and TNF-alpha induced a DNA-protein complex of slower electrophoretic mobility than IFNEX. The TNF-alpha-induced complex (TIC-X) has specificity for the X element of the DRA promoter. These results suggest a mechanism by which TNF-alpha enhances IFN-gamma-induced class II MHC expression via the formation of TIC-X.

A cDNA clone for a novel nuclear protein with DNA binding activity

In an effort to identify trans-acting factors regulating specific genes, we cloned a novel human gene, DBP-5. The cDNA clone contains a predicted open reading frame coding for a potential 1,179 amino acid protein. The mRNA corresponding to DBP-5 is ubiquitously distributed, and the gene is phylogenetically conserved. Immunofluorescence analyses with several cell lines indicate that the protein is localized to the nucleus. Sequence analysis revealed unusual features of the predicted protein structure, including four completely conserved repeats. The phylogenetic conservation of DBP-5, the ubiquity of its expression, its nuclear localization, and its ability to bind DNA sequences, raise the possibility that DBP-5 may play a role in the organization of interphase chromatin and/or in transcriptional regulation.

The DNA-binding defect observed in major histocompatibility complex class II regulatory mutants concerns only one member of a family of complexes binding to the X boxes of class II promoters

The X box of major histocompatibility complex class II promoters is essential for proper expression of class II genes. Here we show that two distinct protein-DNA complexes (A and B), which exhibit similar binding characteristics and identical contact points on the X box, can be formed. This suggests the existence of a family of related X box-binding factors. Complex B (and not complex A) is specifically affected in primary combined immunodeficiency, a congenital defect in class II gene regulation. RFX1, the first X box-binding protein cloned, encodes a functionally relevant factor present in complex A and not in complex B as originally suspected. This report also illustrates the need for caution in correlating specific cloned proteins with nuclear factors identified by DNA-binding assays, particularly when dealing with families of related proteins.

The DNA-binding defect observed in major histocompatibility complex class II regulatory mutants concerns only one member of a family of complexes binding to the X boxes of class II promoters

The X box of major histocompatibility complex class II promoters is essential for proper expression of class II genes. Here we show that two distinct protein-DNA complexes (A and B), which exhibit similar binding characteristics and identical contact points on the X box, can be formed. This suggests the existence of a family of related X box-binding factors. Complex B (and not complex A) is specifically affected in primary combined immunodeficiency, a congenital defect in class II gene regulation. RFX1, the first X box-binding protein cloned, encodes a functionally relevant factor present in complex A and not in complex B as originally suspected. This report also illustrates the need for caution in correlating specific cloned proteins with nuclear factors identified by DNA-binding assays, particularly when dealing with families of related proteins.

In vivo footprint analysis of the HLA-DRA gene promoter: cell-specific interaction at the octamer site and up-regulation of X box binding by interferon gamma

Analysis of the major histocompatibility complex class II gene promoter DRA has previously identified at least five cis-acting regions required for maximal expression. We have examined the DRA promoter for protein-DNA interactions in the intact cell, which may mediate transcriptional activation. Using in vivo genomic footprinting we identified interactions in B-cell lines at the octamer site and the Y, X1, and X2 boxes. Class II antigen expressing T-cell lines maintained contacts identical to B-cell lines, while class II-negative T-cell lines exhibited no interactions. In lymphoid cell lines, the octamer site is occupied and required for maximal expression. This is most likely due to the presence of the lymphoid-specific OTF-2 factor. In contrast, the class II-positive nonlymphoid glioblastoma cell line does not exhibit interactions at the octamer site despite the presence of the ubiquitous OTF-1 factor and an open binding site. Thus, the DRA promoter discriminates against OTF-1 activation at the level of DNA binding in the glioblastoma line. Interferon gamma induces class II expression in this glioblastoma cell line and, in parallel, up-regulates X1 and X2 box protein-DNA interactions, while all other interactions remain unchanged. These results suggest that interferon gamma functions on a poised promoter by altering weak, nonproductive interactions at the X boxes to strong interactions. These findings provide direct in vivo evidence to strongly suggest that the modulation of X1 and X2 interactions is an important constituent of the interferon gamma induction pathway.

B-cell factor 1 is required for optimal expression of the DRA promoter in B cells

The X box in the DRA promoter of the human histocompatibility complex is required for expression of the DRA gene in B cells. We show that a B-cell factor binds to a sequence that is clearly distinguishable from binding sites for the previously described X box binding nuclear proteins RF-X, NF-X, NF-Xc, NF-S, hXBP, and AP-1. Mutations in the DRA X box that disrupt the binding of this factor result in a lower level of gene expression, as does the presence of Id (a trans-dominant regulatory protein that negatively regulates helix-loop-helix proteins). Furthermore, this factor is recognized by antibodies directed against the helix-loop-helix protein A1, a mouse homolog of the immunoglobulin enhancer binding proteins E12/E47, and it binds to sequences in other genes that were previously shown to bind these proteins. By these criteria, this factor is BCF-1.

B-cell factor 1 is required for optimal expression of the DRA promoter in B cells

The X box in the DRA promoter of the human histocompatibility complex is required for expression of the DRA gene in B cells. We show that a B-cell factor binds to a sequence that is clearly distinguishable from binding sites for the previously described X box binding nuclear proteins RF-X, NF-X, NF-Xc, NF-S, hXBP, and AP-1. Mutations in the DRA X box that disrupt the binding of this factor result in a lower level of gene expression, as does the presence of Id (a trans-dominant regulatory protein that negatively regulates helix-loop-helix proteins). Furthermore, this factor is recognized by antibodies directed against the helix-loop-helix protein A1, a mouse homolog of the immunoglobulin enhancer binding proteins E12/E47, and it binds to sequences in other genes that were previously shown to bind these proteins. By these criteria, this factor is BCF-1.

Two B cell factors bind the HLA-DRA X box region and recognize different subsets of HLA class II promoters

The class II genes of the human Major Histocompatibility Complex (MHC) encode three isotypes of alpha/beta heterodimeric proteins, HLA-DR, -DQ, and -DP, which are responsible for presenting processed antigens to T helper lymphocytes. These MHC class II genes are expressed in a coordinate manner. The promoter regions of all MHC class II genes share a set of highly conserved elements that mediate different levels of tissue-specific and inducible transcription. One element, the X box, appears to be the major positive element in B cell-specific expression, and nuclear protein binding studies have subdivided this region into the X1 and X2 boxes. Regulatory Factor X (RFX) binds to the X1 box whereas several other factors have been described that bind to the X2 box. In this report, we further characterize the X1 binding protein RFX and show that RFX binds poorly to beta chain gene promoters. In particular, RFX does not bind to the DRB gene, which is expressed at the highest levels of all beta chain genes. In addition, we have identified an X2 box binding activity in human B cell extracts that binds with high affinity to the HLA-DRA promoter. This X2 binding protein, X2BP, binds to a different subset of class II promoters than does RFX. These findings suggest that coordinate regulation of class II expression may involve different combinations or arrangements of transcriptional elements and factors instead of a common set.

Delineation of a previously unrecognized cis-acting element required for HLA class II gene expression

The cis-acting DNA sequences that control expression of the HLA-DPA and HLA-DQB promoters have been investigated in detail. A set of recombinant plasmids containing 5' promoter deletions as well as site-directed mutants of the DPA and DQB genes were fused to a reporter gene and transfected into human B and interferon gamma (IFN-gamma)-inducible cells. A previously unrecognized cis element, which is essential both for transcription induced by IFN-gamma in several cell types and for constitutive class II expression in B cells, in addition to the well known X and Y boxes, has been defined. This sequence, which spans nucleotides -107 to -98 and -146 to -137 of the DPA and DQB promoters, respectively, has been called the J element. Some evidence for function of a fourth element, the S element, is also presented.

DNA binding properties of YB-1 and dbpA: binding to double-stranded, single-stranded, and abasic site containing DNAs

A number of eukaryotic DNA binding proteins have been isolated by screening phage expression libraries with DNA probes containing the binding site of the DNA-binding protein. This methodology was employed here to isolate clones of the factor that interacts with the W box element of the human major histocompatibility complex HLA-DQB gene. Surprisingly, several cDNA clones of YB-1, a cDNA clone that was previously isolated with a CCAAT element-containing sequence were found. Independently, the screening of phage expression libraries with depurinated DNA resulted in the isolation of YB-1 and dbpA, a previously isolated cDNA that has homology to YB-1. Additional characterization of YB-1 showed that it bound a wide variety of DNA sequences and suggested that the binding of this protein is promiscuous. Furthermore, we show that both YB-1 and dbpA bind to depurinated DNA better than undamaged DNA and that the extent of specificity of binding is influenced by Mg2+. Due to the lack of sequence specificity and high degree of binding to depurinated DNA, we suggest that these proteins might be involved in chromosome functions such as maintenance of chromatin structure or DNA repair that do not require sequence-specific binding.

Stereospecific alignment of the X and Y elements is required for major histocompatibility complex class II DRA promoter function

The regulatory mechanisms controlling expression of the major histocompatibility complex (MHC) class II genes involve several cis-acting DNA elements, including the X and Y boxes. These two elements are conserved within all murine and human class II genes and are required for accurate and efficient transcription from MHC class II promoters. Interestingly, the distance between the X and Y elements is also evolutionarily conserved at 18 to 20 bp. To investigate the function of the invariant spacing in the human MHC class II gene, HLA-DRA, we constructed a series of spacing mutants which alters the distance between the X and Y elements by integral and half-integral turns of the DNA helix. Transient transfection of the spacing constructs into Raji cells revealed that inserting integral turns of the DNA helix (+20 and +10 bp) did not reduce promoter activity, while inserting or deleting half-integral turns of the DNA helix (+15, +5, and -5 bp) drastically reduced promoter activity. The loss of promoter function in these half-integral turn constructs was due neither to the inability of the X and Y elements to bind proteins nor to improper binding of the X- and Y-box-binding proteins. These data indicate that the X and Y elements must be aligned on the same side of the DNA helix to ensure normal function. This requirement for stereospecific alignment strongly suggests that the X- and Y-box-binding proteins either interact directly or are components of a larger transcription complex which assembles on one face of the DNA double helix.

Class II-antigen-negative patient and mutant B-cell lines represent at least three, and probably four, distinct genetic defects defined by complementation analysis

Expression of class II major histocompatibility complex antigens in defective B-lymphoblastoid cell lines from patients with class II antigen deficiency and from in vitro mutants generated with the same phenotype was studied. By heterogenetic fusion experiments, at least three, and probably four, complementation groups were defined. Furthermore, clone 13 (a DR-, DP-, but DQ+ cell line) appeared to belong to the RJ2.2.5 complementation group, for which all other members are DR-, DP-, and also DQ-. Thus, it is hypothesized that the cell lines of this group lack the activity of a gene that can differentially regulate the DR/DP and the DQ promoters.

Transcription of a subset of human class II major histocompatibility complex genes is regulated by a nucleoprotein complex that contains c-fos or an antigenically related protein

Transcriptional regulation of the human major histocompatibility complex class II genes requires at least two upstream elements, the X and Y boxes, located in the -50- to -150-base-pair region of all class II promoters. The DRA and DPB promoters contain phorbol ester-responsive elements overlapping the 3' side of their X boxes. Mutation of this sequence down-regulates the efficiency of the DRA promoter, suggesting that a positive regulator(s) binds to this site. In this report, anti-sense c-fos RNA and an anti-c-fos antibody were used to show that the product of the protooncogene c-fos or an antigenically related protein is a component of a complex that binds to the X box and is required for maximal transcription from the DRA and DPB promoters. As c-fos (or its related proteins) cannot bind alone to DNA, these results suggest that it may dimerize with other members of the JUN/AP-1 family, such as hXBP1, to participate in the activation of a subset of class II major histocompatibility complex genes.

Human X-box-binding protein 1 is required for the transcription of a subset of human class II major histocompatibility genes and forms a heterodimer with c-fos

A complementary DNA encoding a member of the leucine-zipper class of proteins (human X-box-binding protein, hXBP-1) that binds to the 3' end of the conserved X box (X2) of the HLA-DRA major histocompatibility complex gene was recently described. Further gel-retardation analysis has demonstrated that hXBP-1 also binds to HLA-DPB X2 but not to other X2 sequences. Transient transfection of a mammalian expression vector with the hXBP-1 cDNA inserted in the antisense orientation represses the surface expression of HLA-DR and HLA-DP in Raji cells. Cotransfection of the antisense hXBP-1 vector with a HLA-DRA/chloramphenicol acetyltransferase (but not a HLA-DQB/chloramphenicol acetyltransferase) reporter plasmid decreases chloramphenicol acetyltransferase activity in Raji cells and in gamma-interferon-treated HeLa cells relative to cells cotransfected with a control antisense vector. Moreover, hXBP-1 is shown to form a stable heterodimer with the product of the c-fos protooncogene. These data suggest that the hXBP-1 c-fos heterodimer is critical for the transcription of a subset of the human class II major histocompatibility complex genes and that the regulatory mechanisms for the different class II genes are distinct.

Stereospecific alignment of the X and Y elements is required for major histocompatibility complex class II DRA promoter function

The regulatory mechanisms controlling expression of the major histocompatibility complex (MHC) class II genes involve several cis-acting DNA elements, including the X and Y boxes. These two elements are conserved within all murine and human class II genes and are required for accurate and efficient transcription from MHC class II promoters. Interestingly, the distance between the X and Y elements is also evolutionarily conserved at 18 to 20 bp. To investigate the function of the invariant spacing in the human MHC class II gene, HLA-DRA, we constructed a series of spacing mutants which alters the distance between the X and Y elements by integral and half-integral turns of the DNA helix. Transient transfection of the spacing constructs into Raji cells revealed that inserting integral turns of the DNA helix (+20 and +10 bp) did not reduce promoter activity, while inserting or deleting half-integral turns of the DNA helix (+15, +5, and -5 bp) drastically reduced promoter activity. The loss of promoter function in these half-integral turn constructs was due neither to the inability of the X and Y elements to bind proteins nor to improper binding of the X- and Y-box-binding proteins. These data indicate that the X and Y elements must be aligned on the same side of the DNA helix to ensure normal function. This requirement for stereospecific alignment strongly suggests that the X- and Y-box-binding proteins either interact directly or are components of a larger transcription complex which assembles on one face of the DNA double helix.

Regulatory factor-X binding to mutant HLA-DRA promoter sequences

The class II genes of the major histocompatibility complex (MHC) encode a family of cell surface glycoproteins that present processed antigen to the T cell receptor. Class II genes are regulated coordinately, responding to both immunologic and developmental signals. Conserved sequence elements 5' to class II genes have been shown to be important in transcriptional control. One of these sequences, the X box, is a specific target for the binding of the factor RF-X. In the hereditary HLA class II deficiency, a form of primary immunodeficiency, a regulatory defect in expression of class II genes is associated with a defect in the binding of RF-X. To determine the basepairs that are important for this binding interaction, a series of single basepair substitutions spanning the X box motif of the DRA gene was constructed and tested for binding of RF-X by gel electrophoresis mobility shift assays (EMSAs). Several, but not all, of the mutants severely affected binding of RF-X. In addition, the binding of both the natural and the recombinant form of RF-X was affected with the same specificity. A comparison of X box basepair positions important for RF-X binding to DRA with sequences conserved between X boxes of other class II alpha chain genes suggests that high affinity RF-X binding is important for a high level of expression and may explain differences in the levels of class II expression of different class II alpha chains.

Affinity-purified CCAAT-box-binding protein (YEBP) functionally regulates expression of a human class II major histocompatibility complex gene and the herpes simplex virus thymidine kinase gene

Efficient major histocompatibility complex class II gene expression requires conserved protein-binding promoter elements, including X and Y elements. We affinity purified an HLA-DRA Y-element (CCAAT)-binding protein (YEBP) and used it to reconstitute Y-depleted HLA-DRA in vitro transcription. This directly demonstrates a positive functional role for YEBP in HLA-DRA transcription. The ability of YEBP to regulate divergent CCAAT elements was also assessed; YEBP was found to partially activate the thymidine kinase promoter. This functional analysis of YEBP shows that this protein plays an important role in the regulation of multiple genes.

Allelic polymorphism in transcriptional regulatory regions of HLA-DQB genes

Class II genes of the human major histocompatibility complex (MHC) are highly polymorphic. Allelic variation of structural genes provides diversity in immune cell interactions, contributing to the formation of the T cell repertoire and to susceptibility to certain autoimmune diseases. We now report that allelic polymorphism also exists in the promoter and upstream regulatory regions (URR) of human histocompatibility leukocyte antigen (HLA) class II genes. Nucleotide sequencing of these regulatory regions of seven alleles of the DQB locus reveals a number of allele-specific polymorphisms, some of which lie in functionally critical consensus regions thought to be highly conserved in class II promoters. These sequence differences also correspond to allelic differences in binding of nuclear proteins to the URR. Fragments of the URR of two DQB alleles were analyzed for binding to nuclear proteins extracted from human B lymphoblastoid cell lines (B-LCL). Gel retardation assays showed substantially different banding patterns to the two promoters, including prominent variation in nuclear protein binding to the partially conserved X box regions and a novel upstream polymorphic sequence element. Comparison of these two polymorphic alleles in a transient expression system demonstrated a marked difference in their promoter strengths determined by relative abilities to initiate transcription of the chloramphenicol acetyltransferase reporter gene in human B-LCL. Shuttling of URR sequences between alleles showed that functional variation corresponded to both the X box and upstream sequence polymorphic sites. These findings identify an important source of MHC class II diversity, and suggest the possibility that such regulatory region polymorphisms may confer allelic differences in expression, inducibility, and/or tissue specificity of class II molecules.

Interferon-gamma activates co-ordinate transcription of HLA-DR, DQ, and DP genes in cultured keratinocytes and requires de novo protein synthesis

The purpose of this study was to determine the effect of interferon-gamma on keratinocyte major histocompatibility complex class II gene transcription. Transformed human foreskin keratinocytes (SVK14 cells) were incubated with recombinant IFN-gamma in the presence or absence of the protein synthesis inhibitor cycloheximide. Total cellular RNA was extracted from the cells and Northern blot analysis carried out using cDNA probes for all the functional class II genes. We report that 1) there is co-ordinate activation of all the class-II genes; 2) the rate of transcription varies between gene loci after activation; and 3) de novo protein synthesis is required for IFN-gamma activation of class II transcription.

Interferon gamma response region in the promoter of the human DPA gene

The interferon gamma (IFN-gamma) response region of the human class II major histocompatibility complex gene, DPA, has been localized to a 52-base-pair (bp) DNA fragment in the proximal promotor at -107 to -55 bp after transfection into HeLa cells of a series of 5', 3', and gap deletion mutants linked to a reporter gene, human growth hormone, as well as of synthetic oligonucleotides fused to the heterologous promoter thymidine kinase. The 52-mer sequence contains the X and Y box elements conserved in all class II genes; their presence is indispensable for IFN-gamma inducibility. Furthermore, an additional 5 bp immediately 5' of the X box of the DPA gene are necessary and sufficient for IFN-gamma induction. This region may contain an IFN-gamma response element. A closely related sequence has also been found in the vicinity of the critical deletion sites of three other well-studied class II gene promoters, all of which require a much longer sequence 5' of the X box. A fourth element, the W element, located about 15 bp 5' of the X box in all class II genes, is clearly of little importance in IFN-gamma inducibility of the DPA gene.

X-box-binding proteins positively and negatively regulate transcription of the HLA-DRA gene through interaction with discrete upstream W and V elements

Previous reports have identified that the class II box, consisting of the positive regulatory X and Y boxes, is important for expression of all class II major histocompatibility genes. In this paper, we identify additional sequences upstream from the class II box that regulate constitutive transcription of a human class II gene, HLA-DRA, in the B-lymphoblastoid cell line Raji. Using 5' promoter deletions, substitution mutants, and nuclease S1 protection assays, we mapped a positive element, called W, between -135 and -117 base pairs and a negative element, called V, from -193 to -179 base pairs. Sequence comparisons revealed that W and V share homology with the HLA-DRA X box situated downstream. Gel-mobility-shift assays confirmed that the Raji nuclear proteins that bound to W and V elements were competed with by an HLA-DRA X-box oligonucleotide. These results suggest that X-box-binding proteins mediate both positive and negative effects on transcription by means of interaction with multiple elements (W, V, and X) within the same HLA-DRA gene.

MHC class II regulatory factor RFX has a novel DNA-binding domain and a functionally independent dimerization domain

The regulation of MHC class II gene expression controls T-cell activation and, hence, the immune response. Among the nuclear factors observed to bind to conserved DNA sequences in human leukocyte antigen (HLA) class II gene promoters, RFX is of special interest: Its binding is defective in congenital HLA class II deficiency, a disease of class II gene regulation. The cloning of an RFX cDNA has allowed us to show by transfection of a plasmid directing the synthesis of antisense RFX RNA that RFX is a class II gene regulatory factor. RFX is a novel 979-amino-acid DNA-binding protein that contains three structurally and functionally separate domains. The 91-amino-acid DNA-binding domain is distinct from other known DNA-binding motifs but may be distantly related to the helix-loop-helix motif. The most striking property of RFX is that it can bind stably to the class II X box as either a monomer or a homodimer and that the domain responsible for dimerization is distant from and functionally independent of the DNA-binding domain. This distinguishes RFX from other known dimeric DNA-binding proteins. It also implies that an RFX homodimer has two potential DNA-binding sites. We therefore speculate that RFX could form a DNA loop by cross-linking the two X-box sequences found far apart upstream of MHC class II genes.

The X boxes from promoters of HLA class II B genes at different loci do not complete for nuclear protein-specific binding

Expression of HLA class II genes is coordinately regulated by cis-acting elements present in their promoter regions immediately upstream from the 5' end of their transcription start sites. Trans-acting factors from the nuclear proteins of the cell are able to positively or negatively regulate transcription of these genes by binding to highly conserved sequences, called boxes. After cloning the promoter regions of all the transcribed class II B genes present in the cell line Priess, we were able to identify certain protein-box complexes and to determine the affinity of these proteins for their respective boxes by comparing promoter boxes of each gene to those of the other genes. Different nuclear proteins seemed to bind to the X boxes of the different class II B genes tested. In the case of the Y box-protein complexes, the various Y boxes competed with similar affinities. The protein(s) which specifically bound to the DRB1-CCAAT box also bound to DPB1-CCAAT box, but completely failed to bind the homologous box from DQB1. Further, CCAAT box-specific protein(s) did not bind to the Y box of the same gene, excluding the possibility that these proteins just recognize the reverse CCAAT box (ATTGG) present within Y.

Transcription analysis of class II human leukocyte antigen genes from normal and immunodeficient B lymphocytes, using polymerase chain reaction

The RNA transcript levels of all human leukocyte antigen class II loci were determined from class II congenital immunodeficient B cells by polymerase chain reaction amplification of cDNA. No mRNA was observed under conditions in which 0.01% normal levels could be visualized. Pre-mRNA could be amplified from normal B cells but not from immunodeficient B cells, indicating a transcription defect.

Transcription analysis of class II human leukocyte antigen genes from normal and immunodeficient B lymphocytes, using polymerase chain reaction

The RNA transcript levels of all human leukocyte antigen class II loci were determined from class II congenital immunodeficient B cells by polymerase chain reaction amplification of cDNA. No mRNA was observed under conditions in which 0.01% normal levels could be visualized. Pre-mRNA could be amplified from normal B cells but not from immunodeficient B cells, indicating a transcription defect.

Regulation of the class II-associated invariant chain gene in normal and mutant B lymphocytes

The invariant chain protein is intracellularly associated with class II major histocompatibility proteins. In many cases, the expression of these molecules appears to be regulated in a similar manner. Contained within the promoter of the invariant chain gene are sequences (X and I gamma 1) that are similar to the X and Y box elements of class II genes, suggesting that these sequences might be involved in its regulation. DNase I footprinting reveals additional cis-acting elements (I gamma 2 and I gamma 3) that contain sequence similarities to NF-kappa B and/or H2TF1/KBF1 recognition sequences. A series of fusion constructs with the chloramphenicol acetyltransferase reporter gene were used to analyze the role of these sequences (I gamma 1, I gamma 2, I gamma 3, and X and Y elements) in both normal and mutant B lymphocytes. These data suggest the likelihood of multiple X box proteins in B cells, which can act as both negative and positive regulatory factors.

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.