How different DNA sequences are recognized by a DNA-binding protein: effects of partial proteolysis

RFX1, a single DNA-binding protein with a split dimerization domain, generates alternative complexes

The transcription of various viral and cellular genes is regulated by palindromic and nonpalindromic DNA sites resembling the EP element of the hepatitis B virus enhancer, which generate similar DNA-protein complexes. The upper EP complex contains homodimers of the transcription regulator RFX1. We show that RFX1 possesses a split, extended dimerization domain composed of several evolutionarily conserved boxes, one of which was previously shown to mediate dimerization. Such an unusually long and complex dimerization domain could potentially serve for generating multiple complexes. In addition to the previously characterized complex, RFX1 generated a novel DNA-protein complex of extremely low mobility, formed only with palindromic DNA sites. Different deletions within the dimerization domain altered the relative abundance of the two complexes, suggesting an interplay between them. Formation of the low mobility complex correlated with transcriptional repression, in that both activities were mediated by several portions of the conserved region. Our results propose a mechanism by which the extended dimerization domain mediates the formation of alternative homodimeric complexes, which differ in the nature of the intersubunit interaction. By participating in different types of interactions, this domain may regulate the relative abundance of the different complexes, thus affecting transcriptional activity.

Increasing binding of a transcription factor immediately downstream of the cap site of a cytomegalovirus gene represses expression

A closely related family of ubiquitous DNA binding proteins, called MDBP, binds with high affinity to two 14 base pair (bp) sites within the human cytomegalovirus immediate early gene 1 (CMV IE1) enhancer and with low affinity to one site beginning 5 bp downstream of the CMV IE1 transcription start point (+5 site). Unlike several cap position downstream MDBP sites in mammalian genes, these MDBP sites do not require cytosine methylation for optimal binding. Mutation of one of the enhancer MDBP sites to prevent MDBP recognition modestly increased the function of a neighboring CREB binding site in a transient transfection assay in the context of one promoter construct. A much larger effect on reporter gene expression (a 10-fold reduction) was seen when the low affinity MDBP recognition sequence at position +5 was converted to a high affinity site in a plasmid containing the CMV IE1 promoter upstream of the reporter gene. Evidence that the increased binding of MDBP at the mutant site is largely responsible for the observed results was provided by transfection experiments with this high affinity MDBP +5 site re-mutated to a non-binding site and by in vitro transcription assay.

Interaction of EF-C/RFX-1 with the inverted repeat of viral enhancer regions is required for transactivation

The hepatitis B virus (HBV) and polyomavirus (Py) enhancer regions contain multiple cis-acting elements that contribute to enhancer activity. The EF-C binding site was previously shown to be an important functional component of each enhancer region. EF-C is a ubiquitous binding activity that interacts with an inverted repeat sequence in the HBV and Py enhancer regions. Although the EF-C binding site is required for optimal enhancer function, the EF-C site does not possess intrinsic enhancer activity when assayed in the absence of flanking elements. With both the HBV and Py enhancer regions, EF-C stimulates the activity of adjacent enhancer elements in a synergistic manner. EF-C corresponds to RFX-1, a protein that binds to a conserved and functionally important site in major histocompatibility complex (MHC) class II antigen promoter regions. Interestingly, the RFX-1 binding site in MHC class II promoters only contains an EF-C half-site, maintaining one arm of the inverted repeat in an EF-C binding site. We have investigated the binding of purified EF-C and RFX-1 to sites in the Py and HBV enhancer regions that carry mutations that either disrupt one arm of the EF-C inverted repeat, or alter the spacing between the repeats. Our results show that the interaction of EF-C and RFX-1 with an intact inverted repeat is required for functional activity of these viral enhancer regions. Chemical footprinting and modification interference assays show that the interaction of EF-C and RFX-1 with the DRA MHC class II promoter truly represents half-site interaction, and that this binding is unstable. In contrast, the binding of EF-C and RFX-1 to the viral inverted repeats is stable. These results suggest that an additional activity may be required to stabilize EF-C/RFX-1 interaction with the MHC class II promoter, and that viral enhancer regions have evolved high affinity binding sites to sequester dimeric EF-C/RFX-1.

Binding of AP-1/CREB proteins and of MDBP to contiguous sites downstream of the human TGF-beta 1 gene

Transcription of the human gene encoding transforming growth factor beta 1 (TGF-beta 1), which is a key regulator of cell growth and differentiation, is inducible by phorbol esters. DNA sequences resembling phorbol ester response elements (TREs) are present upstream and downstream of this gene. TREs are recognized by proteins from the AP-1 family of transcription factors. We examined a 16 basepair (bp) sequence downstream of the TGF-beta 1 gene that contains three putative TREs. This sequence had been shown to stimulate reporter gene expression from a downstream location in response to phorbol ester treatment. Electrophoretic mobility shift assays suggest that minor proteins from the related AP-1 and CREB families of transcription factors bind to the overlapping TREs within the 16 bp element. A site beginning at the end of this 16 bp element matches the consensus sequence of a DNA-binding protein called MDBP and was shown to bind to this protein. When the intact MDBP site was present in a reporter gene construct in addition to the TREs, the phorbol ester-induced stimulation of reporter gene expression was no longer observed. This suggests that MDBP can counteract the stimulation of transcription by AP-1/CREB-like proteins binding to this downstream enhancer element.

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.

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.

Characterization of DBPm, a plant protein that binds to DNA containing 5-methylcytosine

A protein (DBPm) has been isolated from nuclear extracts of soybean seeds, cauliflower florets, corn seed, wheat germ, and pea hypocotyl, seeds, apices, roots, and leaves that specifically binds to double-strand DNA containing 5-methylcytosine residues. In electrophoretic mobility shift assays, non-methylated duplex DNAs competed only slightly, while methylated DNAs were strong competitors. Specific binding still occurred after partial proteolysis of DBPm, but not after heating at 45 degrees C. By ultraviolet light-crosslinking and sodium dodecyl sulfate polyacrylamide gel electrophoresis and gel filtration, the size of pea seed DBPm was estimated to be in the range 70-90 kDa. From equilibrium binding studies the equilibrium constant for binding of pea seed DBPm to a 34 bp duplex deoxyoligonucleotide containing 12 5-methylcytosine residues was 1.2 x 10(9) M-1. The binding properties of DBPm make it a good candidate for a plant protein capable of mediating the effects of DNA methylation on the activity of some plant genes.

Increasing the activity of affinity-purified DNA-binding proteins by adding high concentrations of nonspecific proteins

A large decrease in the activity of two sequence-specific DNA-binding proteins implicated in transcription control was seen when these were affinity purified and assayed under standard conditions in electrophoretic mobility shift assays. Increasing the concentration of bovine serum albumin in the reaction mixtures from 0.1 to 5 mg/ml stimulated the DNA-binding activity of these affinity-purified proteins, human CREB (cyclic AMP response element binding protein) and MDBP (methylated DNA-binding protein), approximately 5-to more than 20-fold. In the case of affinity-purified MDBP, adding back the affinity flow-through fraction to the assay mixture gave similar extents of stimulation at much lower final protein concentrations. The specific DNA-binding activity of the affinity-purified CREB, but not that of MDBP, was also increased by adding a nonionic detergent to the binding reaction buffer although not as much. The large increase in the amount of MDBP.DNA complex seen upon supplementation of the affinity-purified MDBP with the affinity flow-through fraction or 5 mg/ml of BSA was shown to be due to stimulation, by nonspecific proteins, of specific complex formation and not to prevention of activity losses by adsorption or denaturation during the assay.

Methylation-dependent and -independent DNA binding of nuclear factor EF-C

Nuclear factor EF-C binds to important functional sites in the hepatitis B virus and polyomavirus enhancer regions. In this paper, we have characterized new and divergent EF-C binding sites in several viral regulatory regions. We also have demonstrated that EF-C binds to certain DNA sites only when CpG dinucleotide base pairs are methylated (m5C). EF-C binds to other sites in a methylation-independent manner. Based on similar binding properties and identical binding sites, it is very likely that EF-C corresponds to the nuclear protein MDBP previously identified by virtue of binding to methylated DNA.

Binding sites in mammalian genes and viral gene regulatory regions recognized by methylated DNA-binding protein

Methylated DNA-binding protein (MDBP), a ubiquitous mammalian protein, recognizes a variety of related DNA sequences. Some of these sequences require methylation of their CpG dinucleotides for binding and others do not. We report that MDBP binds, in a DNA methylation-independent fashion, to two sites in the mouse polyomavirus enhancer, one in the enhancer of the human hepatitis B virus, and to one in the long terminal repeat of equine infectious anemia proviral DNA. We have also found a number of MDBP sites in human and rodent DNAs which bind much better to MDBP when they are methylated at CpG dinucleotides within the recognition site. These include sites at the beginning of the human genes for hypoxanthine phosphoribosyl transferase, HLA-A2, -A3, and -A25 antigens, and alpha-galactosidase A. In the case of methylation-responsive MDBP sites, changes in their methylation status during differentiation or DNA replication could help drive development by modulating transcription.

Highly repeated sites in the apolipoprotein(a) gene recognized by methylated DNA-binding protein, a sequence-specific DNA-binding protein

Methylated DNA-binding protein (MDBP), a sequence-specific DNA-binding protein, was found to recognize more than 30 sites within an allele of the human apolipoprotein(a) gene. High plasma levels of apolipoprotein(a), a risk factor for atherosclerosis, have been correlated with genetically inherited lower-molecular-mass isoforms of this protein. MDBP might help down modulate the expression of the apolipoprotein(a) gene in a manner dependent on the length of a given allele of the gene and the number of MDBP sites in it.

Nuclear factors interact with conserved A/T-rich elements upstream of a nodule-enhanced glutamine synthetase gene from French bean

The gln-gamma gene, encoding the gamma subunit of glutamine synthetase in French bean (Phaseolus vulgaris), is strongly induced during nodule development. We have determined the nucleotide sequence of a 1.3-kilobase region at its 5' end and have identified several sequences common to the promoter regions of late nodulin genes from other legume species. The 5'-flanking region was analyzed for sequence-specific interactions with nuclear factors from French bean. A factor from nodules (PNF-1) was identified that binds to multiple sites between -860 and -154, and a related but distinct factor (PRF-1) was detected in extracts from uninfected roots. PNF-1 and PRF-1 bound strongly to a synthetic oligonucleotide containing the sequence of an A/T-rich 21-base pair imperfect repeat found at positions -516 and -466. The same factors also had a high affinity for a protein binding site from a soybean leghemoglobin gene and appeared to be closely related to the soybean nodule factor NAT2, which binds to A/T-rich sequences in the lbc3 and nodulin 23 genes [Jacobsen et al. (1990). Plant Cell 2, 85-94]. Comparison of NAT2/PNF-1 binding sites from a variety of nodulin genes revealed the conservation of the short consensus core motif TATTTWAT, and evidence was obtained that this sequence is important for protein recognition. Cross-recognition by PNF-1 of a protein binding site in a soybean seed protein gene points to the existence of a ubiquitous family of factors with related binding affinities. Our data suggest that PNF-1 and PRF-1 belong to an evolutionarily conserved group of nuclear factors that interact with specific A/T-rich sequences in a diverse set of plant genes. We consider the possible role of these factors in coregulating the expression of gln-gamma and other late nodulin genes.

Highly repeated sites in the apolipoprotein(a) gene recognized by methylated DNA-binding protein, a sequence-specific DNA-binding protein

Methylated DNA-binding protein (MDBP), a sequence-specific DNA-binding protein, was found to recognize more than 30 sites within an allele of the human apolipoprotein(a) gene. High plasma levels of apolipoprotein(a), a risk factor for atherosclerosis, have been correlated with genetically inherited lower-molecular-mass isoforms of this protein. MDBP might help down modulate the expression of the apolipoprotein(a) gene in a manner dependent on the length of a given allele of the gene and the number of MDBP sites in it.

The major transcriptional regulatory protein of herpes simplex virus type 1 includes a protease resistant DNA binding domain

Herpes simplex virus type 1 expresses five immediate-early (IE) polypeptides. In the absence of functional Vmw175 (the product of IE gene 3) activation of transcription of later classes of viral genes and repression of IE gene expression does not occur. The recognition of specific DNA sequences by Vmw175 requires, as determined by sensitivity to mutation, a part of the protein highly conserved in the corresponding proteins of related herpes viruses. However, mutations in other parts of the protein can also disrupt specific DNA binding. This paper shows that the DNA binding domain of Vmw175 can be liberated as a functional unit by digestion with proteinase K. Analysis of mutant Vmw175 proteins showed that the proteinase K resistant domain has an amino terminus between amino acid residues 229 and 292, while its carboxy terminus is between residues 495 and 518. Mutations outside this region which affect DNA binding by the intact protein do not eliminate binding of the proteinase K resistant domain. This implies that direct DNA binding by Vmw175 involves a linear subsection of the polypeptide, and that mutations in other parts of the polypeptide which affect DNA binding of the whole protein do so by indirect means.