UNIPROT:P06889 - FACTA Search

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Efficient human T-cell leukemia virus type 1 (HTLV-1) replication and viral gene expression are dependent upon the virally encoded oncoprotein Tax. To activate HTLV-1 transcription, Tax interacts with the cellular DNA binding protein cyclic AMP-responsive element binding protein (CREB) and recruits the coactivator CREB binding protein (CBP), forming a nucleoprotein complex on the three viral cyclic AMP-responsive elements (CREs) in the HTLV-1 promoter. Short stretches of dG-dC-rich (GC-rich) DNA, immediately flanking each of the viral CREs, are essential for Tax recruitment of CBP in vitro and Tax transactivation in vivo. Although the importance of the viral CRE-flanking sequences is well established, several studies have failed to identify an interaction between Tax and the DNA. The mechanistic role of the viral CRE-flanking sequences has therefore remained enigmatic. In this study, we used high resolution methidiumpropyl-EDTA iron(II) footprinting to show that Tax extended the CREB footprint into the GC-rich DNA flanking sequences of the viral CRE. The Tax-CREB footprint was enhanced but not extended by the KIX domain of CBP, suggesting that the coactivator increased the stability of the nucleoprotein complex. Conversely, the footprint pattern of CREB on a cellular CRE lacking GC-rich flanking sequences did not change in the presence of Tax or Tax plus KIX. The minor-groove DNA binding drug chromomycin A3 bound to the GC-rich flanking sequences and inhibited the association of Tax and the Tax-CBP complex without affecting CREB binding. Tax specifically cross-linked to the viral CRE in the 5'-flanking sequence, and this cross-link was blocked by chromomycin A3. Together, these data support a model where Tax interacts directly with both CREB and the minor-groove viral CRE-flanking sequences to form a high-affinity binding site for the recruitment of CBP to the HTLV-1 promoter.
Mol Cell Biol 1998 Feb
PMID:Human T-cell leukemia virus type 1 Tax requires direct access to DNA for recruitment of CREB binding protein to the viral promoter. 944 68

The HIV-LTR region contains binding sites for, and is regulated by, a number of transcription factors including Sp1 and NF-kB. The wild-type p53 tumor suppressor protein represses transcription from the HIV-LTR promoter while oncogenic mutant forms of p53 stimulate expression from the HIV-LTR. We have shown previously that wild-type p53 is a site specific DNA binding protein that binds to a region of the SV40 virus which contains GC-box DNA binding sites for the ubiquitously expressed transcription factor Sp1. In this study using DNase I footprinting, we have shown that purified p53 is able to protect the Sp1 binding sites and the adjacent NF-kB site of the HIV-LTR. Furthermore we have demonstrated that when p53 and Sp1 are mixed together both proteins change each other's interaction with DNA. Interestingly, we noted that oncogenic mutant p53 is also able to change the interaction of Sp1 with DNA. We confirmed p53 dependent repression of HIV-LTR driven transcription by comparing the expression from an HIV-LTR reporter construct in the presence and absence of p53. EMSA of an oligonucleotide sequence derived from the HIV-LTR sequence demonstrated a slight decrease in Sp1 DNA binding activity with nuclear extract derived from the cell line expressing a high level of wild-type p53. These data suggest that the influence of p53 on the transcription of promoters with Sp1 binding sites may be partially due to a change in the DNA binding ability of Sp1.
Cell Mol Biol (Noisy-le-grand) 1997 Nov
PMID:p53 represses Sp1 DNA binding and HIV-LTR directed transcription. 944 26

Phage lambda encodes two recombination proteins that are required for homologous recombination in a recA- host strain. Of these two recombination proteins, one is an exonuclease whose action on double-stranded DNA produces 3' single-stranded ends; the other, called beta protein, is a DNA binding protein that promotes the renaturation of complementary single strands. The enzymes of phage lambda provide a model for understanding a recombination pathway called "single-strand annealing". Further investigation of the binding of beta protein to DNA has revealed a new mechanism of renaturation. As reported before, beta protein binds directly to single-stranded DNA, but not to double-stranded DNA. However, in the experiments reported here, we observed that beta protein bound more strongly to a presumed intermediate in the renaturation reaction that beta itself catalyzed, and beta thereby protected all of a renatured duplex 83-mer oligonucleotide from nuclease digestion.
J Mol Biol 1998 Mar 06
PMID:The beta protein of phage lambda binds preferentially to an intermediate in DNA renaturation. 950 Sep 24

We have characterized a DNA binding protein (DBNP-B) from the thermoacidophilic archaeon Sulfolobus acidocaldarius with respect to its interaction with single and double stranded DNA. The protein in solution exists predominantly as dimer as indicated by cross linking studies. Binding of DBNP-B to etheno DNA and poly (dA) resulted in fluorescence enhancement and hyperchromicity respectively. Ethidium bromide intercalated into DNA was completely displaced by DBNP-B. DNase I digestion of dsDNA was increased at subsaturating concentration of the protein and was inhibited at higher concentrations. These results and electron microscopy indicate that the protein forms different types of novel complexes with DNA at different protein to DNA ratios.
Biochem Mol Biol Int 1998 Feb
PMID:An archaeal DNA binding protein from thermophilic Sulfolobus acidocaldarius forms different types of complexes with DNA. 953 May 10

The adenovirus DNA binding protein (DBP) binds cooperatively to single-stranded (ss) DNA and stimulates both initiation and elongation of DNA replication. DBP forms protein filaments via a C-terminal arm that hooks into a neighbouring molecule. This multimerization is the driving force for ATP-independent DNA unwinding by DBP during elongation. Another conserved part of DBP forms an unstructured flexible loop that is probably directly involved in contacting DNA. By making appropriate deletion mutants that do not distort the overall DBP structure, the influence of the C-terminal arm and the flexible loop on the kinetics of ssDNA binding and on DNA replication was studied. Employing surface plasmon resonance we show that both parts of the protein are required for high affinity binding. Deletion of the C-terminal arm leads to an extremely labile DBP-ssDNA complex indicating the importance of multimerization. The flexible loop is also required for optimal stability of the DBP-ssDNA complex, providing additional evidence that this region forms part of the ssDNA-binding surface of DBP. Both deletion mutants are still able to stimulate initiation of DNA replication but are defective in supporting elongation, which may be caused by the fact that both mutants have a reduced DNA unwinding activity. Surprisingly, mixtures containing both mutants do stimulate elongation. Mixing the purified mutant proteins leads to the formation of mixed filaments that have a higher affinity for ssDNA than homogeneous mutant filaments. These results provide evidence that the C-terminal arm and the flexible loop have distinct functions in unwinding during replication. We propose the following model for ATP-independent DNA unwinding by DBP. Multimerization via the C-terminal arm is required for the formation of a protein filament that saturates the displaced strand. A high affinity of a DBP monomer for ssDNA and subsequent local destabilization of the replication fork requires the flexible loop.
J Mol Biol 1998 Apr 10
PMID:ATP-independent DNA unwinding by the adenovirus single-stranded DNA binding protein requires a flexible DNA binding loop. 954 75

When demand for cholesterol rises in mammalian cells, the sterol regulatory element (SRE) binding proteins (SREBPs) are released from their membrane anchor through proteolysis. Then, the N-terminal region enters the nucleus and activates genes of cholesterol uptake and biosynthesis. Basic helix-loop-helix (bHLH) proteins such as SREBPs bind to a palindromic DNA sequence called the E-box (5'-CANNTG-3'). However, SREBPs are special because they also bind direct repeat elements called SREs. Importantly, sterol regulation of all promoters studied thus far is mediated by SREBP binding only to SREs. To study the reason for this we converted the direct repeat SRE from the sterol-regulated low-density lipoprotein receptor promoter into an E-box. In this report we show that SREBPs are still able to bind and activate this promoter however, sterol regulation is lost. The results are consistent with the mutant promoter being a target for promiscuous activation by constitutively expressed E-box binding bHLH proteins that are not regulated by cholesterol. Kim and coworkers [Kim, J. B., Spotts, G. D., Halvorsen, Y.-D., Shih, H.-M., Ellenberger, T., Towle, H. C. & Spiegelman, B. M. (1995) Mol. Cell. Biol. 15, 2582-2588] demonstrated that the dual DNA binding specificity of SREBPs is caused by a specific tyrosine in the conserved basic region of the DNA binding domain that corresponds to an arginine in all other bHLH proteins that recognize only E-boxes. Taken together the data suggest an evolutionary mechanism where a DNA binding protein along with its recognition site have coevolved to ensure maximal specificity and sensitivity in a crucial nutritional regulatory response.
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PMID:Specificity in cholesterol regulation of gene expression by coevolution of sterol regulatory DNA element and its binding protein. 956 Feb 6

Cells from complementation groups A through G of the heritable sun-sensitive disorder xeroderma pigmentosum (XP) show defects in nucleotide excision repair of damaged DNA. Proteins representing groups A, B, C, D, F, and G are subunits of the core recognition and incision machinery of repair. XP group E (XP-E) is the mildest form of the disorder, and cells generally show about 50% of the normal repair level. We investigated two protein factors previously implicated in the XP-E defect, UV-damaged DNA binding protein (UV-DDB) and replication protein A (RPA). Three newly identified XP-E cell lines (XP23PV, XP25PV, and a line formerly classified as an XP variant) were defective in UV-DDB binding activity but had levels of RPA in the normal range. The XP-E cell extracts did not display a significant nucleotide excision repair defect in vitro, with either UV-irradiated DNA or a uniquely placed cisplatin lesion used as a substrate. Purified UV-DDB protein did not stimulate repair of naked DNA by DDB- XP-E cell extracts, but microinjection of the protein into DDB- XP-E cells could partially correct the repair defect. RPA stimulated repair in normal, XP-E, or complemented extracts from other XP groups, and so the effect of RPA was not specific for XP-E cell extracts. These data strengthen the connection between XP-E and UV-DDB. Coupled with previous results, the findings suggest that UV-DDB has a role in the repair of DNA in chromatin.
Mol Cell Biol 1998 Jun
PMID:Relationship of the xeroderma pigmentosum group E DNA repair defect to the chromatin and DNA binding proteins UV-DDB and replication protein A. 958 59

Reb1p is a DNA binding protein of Saccharomyces cerevisiae that has been implicated in the activation of transcription by polymerase (Pol) II, in the termination of transcription by Pol I, and in the organization of nucleosomes. Studies of the transcriptional control of the REB1 gene have led us to identify three Reb1p binding sites in the 5' region of the its gene, termed A, B, and C, at positions -110, -80, and +30 with respect to transcription initiation. In vitro, Reb1p binds to the three sites with the relative affinity of A >/= C > B. Kinetic parameters suggest that when both A and C sites are present on the same DNA molecule, the C site may recruit Reb1p for the A site. In vivo the A and B sites each contribute to the transcription activity of REB1 in roughly additive fashion. Mutation of both A and B sites abolishes transcription. On the other hand, the C site is a negative element, reducing transcription by 40%. In cells overexpressing Reb1p, the C site reduces transcription by more than 80%. This effect can be transposed to another transcription unit, demonstrating that the effect of Reb1p binding at the C site does not depend on interaction with upstream Reb1p molecules. Relocation of the C site to a position 105 bp downstream of the transcription initiation site abolishes its effect, suggesting that it does not act as a conventional attenuator of transcription. We conclude that binding of Reb1p at the C site hinders formation of the initiation complex. This arrangement of Reb1p binding sites provides a positive and negative mechanism to autoregulate the expression of REB1. Such an arrangement could serve to dampen the inevitable fluctuation in Rep1p levels caused by the intermittent presence of its mRNA within an individual cell.
Mol Cell Biol 1998 Jul
PMID:Positive and negative autoregulation of REB1 transcription in Saccharomyces cerevisiae. 963 20

Genes of the Polycomb group (PcG) of Drosophila encode proteins necessary for the maintenance of transcriptional repression of homeotic genes. PcG proteins are thought to act by binding as multiprotein complexes to DNA through Polycomb group response elements (PREs); however, specific DNA binding has not been demonstrated for any of the PcG proteins. We have identified a sequence-specific DNA binding protein that interacts with a PRE from the Drosophila engrailed gene. This protein (PHO) is a homolog of the ubiquitous mammalian transcription factor Yin Yang-1 and is encoded by pleiohomeotic, a known member of the PcG. We propose that PHO acts to anchor PcG protein complexes to DNA.
Mol Cell 1998 Jun
PMID:The Drosophila Polycomb group gene pleiohomeotic encodes a DNA binding protein with homology to the transcription factor YY1. 965 90

Genetic processes require direct interactions between proteins bound at nonadjacent cis elements. Because duplex DNA is rigid, either the protein-protein interactions are strong enough to deform the double helix or some feature of the intervening DNA must encourage juxtaposition of separated sites. For example, bent DNA can bring together only certain precisely positioned cis elements with the same helical phase. Interposing a DNA segment that both bends and twists easily to create a universal joint would provide an even more general mechanism to promote the association of separated sites regardless of position. A cis element of the human c-myc gene, known to be melted in vivo, and its associated single-strand DNA binding protein were examined and found to comprise just such a protein-DNA hinge.
Mol Cell 1998 Apr
PMID:Unrestraining genetic processes with a protein-DNA hinge. 966 Sep 59

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