Gene 5 protein of bacteriophage fd: A dimer which interacts Co-operatively with DNA

Isolated gene 5 protein from bacteriophage fd-infected Escherichia coli has been shown by sedimentation equilibrium to exist primarily as a dimer under non-denaturing conditions. The dimer was stable under conditions of high ionic strength, extremes in pH, dilution to 0.075 mg/ml, and increased temperature. Gene 5 protein did not undergo the indefinite self-association observed with gene 32 protein.Three lines of evidence for co-operative binding of gene 5 protein to DNA were developed. First, the interaction between gene 5 protein and phage T4 DNA was examined using a nitrocellulose filter assay. Scatchard plots of the binding data indicated that the interaction was co-operative. Similar results were obtained with gene 32 protein. Second, the co-operative binding of both proteins to DNA was shown by the sensitivity of the protein-DNA interaction to increasing ionic strength at various ratios of protein to DNA. Finally, by using the cross-linking agent, dimethyl suberixmidate, oligomeric structures containing at least seven monomers were found when the DNA was less than saturated.The possibility that gene 5 protein dimers undergo indefinite self-association in the presence of oligonucleotides was examined by sedimentation equilibrium. With oligo[d(pT)₄], the protein dimer was complexed with this oligonucleotide but no self-association was observed. With oligo[d(pT)₈], gene 5 protein formed tetramers, but no significant indefinite association was noted. These results do not suggest a DNA-induced conformational change, which results in indefinite association. A model for the co-operative binding of gene 5 protein to DNA is presented.     

Nuclear Localization of the Saccharomyces cerevisiae HMG Protein NHP6A Occurs by a Ran-Independent Nonclassical Pathway

The Saccharomyces cerevisiae non-histone protein 6-A (NHP6A) is a member of the high-mobility group 1/2 protein family that bind and bend DNA of mixed sequence. NHP6A has only one high-mobility group 1/2 DNA binding domain and also requires a 16-amino-acid basic tail at its N-terminus for DNA binding. We show in this report that nuclear accumulation of NHP6A is strictly correlated with its DNA binding properties since only nonhistone protein 6 A–green fluorescent protein chimeras that were competent for DNA binding were localized to the nucleus. Despite the requirement for basic residues within the N-terminal segment for DNA binding and nuclear accumulation, this region does not appear to contain a nuclear localization signal. Moreover, NHP6A does not bind to the yeast nuclear localization signal receptor SRP1 and nuclear targeting of NHP6A does not require the function of the 14 different importins. Unlike histone H2B1 which contains a classical nuclear localization signal, entry of NHP6A into the nucleus was found to be independent of Ran as judged by coexpression of Ran GTPase mutants and was shown to occur at 0 °C after a 15-min induction. These unusual properties lead us to suggest that NHP6A entry into the nucleus proceeds by a nonclassical Ran-independent pathway.     

Physical studies of the interaction between the Escherichia coli DNA binding protein and nucleic acids.

The interaction of nucleic acid with the Escherichia coli DNA-binding protein has been studied by fluorescence emission spectroscopy and sedimentation velocity analysis. The protein binds to single-strand DNA with an apparent equilibrium dissociation constant of 2 X 10(-9). It binds to the homopolymers poly (dA) and poly (dT) slightly more tightly, but has a larger apparent equilibrium dissociation constant to poly (dC). The protein also binds tightly to ribohomopolymers and to tRNA, but not to duplex DNA. By the use of defined-length oligonucleotides, it has been shown that the protein binds to DNA in a highly cooperative manner. The extent of cooperativity is seen as the difference in binding between an isolated monomeric protein molecule bound to DNA and two or more molecules binding to contiguous sites.     

Live-cell imaging reveals multiple interactions between Epstein-Barr virus nuclear antigen 1 and cellular chromatin during interphase and mitosis

Epstein-Barr virus (EBV) establishes a life-long latent infection in humans. In proliferating latently infected cells, EBV genomes persist as multiple episomes that undergo one DNA replication event per cell cycle and remain attached to the mitotic chromosomes. EBV nuclear antigen 1 (EBNA-1) binding to the episome and cellular genome is essential to ensure proper episome replication and segregation. However, the nature and regulation of EBNA-1 interaction with chromatin has not been clearly elucidated. This activity has been suggested to involve EBNA-1 binding to DNA, duplex RNA, and/or proteins. EBNA-1 binding protein 2 (EBP2), a nucleolar protein, has been proposed to act as a docking protein for EBNA-1 on mitotic chromosomes. However, there is no direct evidence thus far for EBP2 being associated with EBNA-1 during mitosis. By combining video microscopy and Förster resonance energy transfer (FRET) microscopy, we demonstrate here for the first time that EBNA-1 and EBP2 interact in the nucleoplasm, as well as in the nucleoli during interphase. However, in strong contrast to the current proposed model, we were unable to observe any interaction between EBNA-1 and EBP2 on mitotic chromosomes. We also performed a yeast double-hybrid screening, followed by a FRET analysis, that led us to identify HMGB2 (high-mobility group box 2), a well-known chromatin component, as a new partner for EBNA-1 on chromatin during interphase and mitosis. Although the depletion of HMGB2 partly altered EBNA-1 association with chromatin in HeLa cells during interphase and mitosis, it did not significantly impact the maintenance of EBV episomes in Raji cells.     

Interactions of the basic N-terminal and the acidic C-terminal domains of the maize chromosomal HMGB1 protein

Maize HMGB1 is a typical member of the family of plant chromosomal HMGB proteins, which have a central high-mobility group (HMG)-box DNA-binding domain that is flanked by a basic N-terminal region and a highly acidic C-terminal domain. The basic N-terminal domain positively influences various DNA interactions of the protein, while the acidic C-terminal domain has the opposite effect. Using DNA-cellulose binding and electrophoretic mobility shift assays, we demonstrate that the N-terminal basic domain binds DNA by itself, consistent with its positive effects on the DNA interactions of HMGB1. To examine whether the negative effect of the acidic C-terminal domain is brought about by interactions with the basic part of HMGB1 (N-terminal region, HMG-box domain), intramolecular cross-linking in combination with formic acid cleavage of the protein was used. These experiments revealed that the acidic C-terminal domain interacts with the basic N-terminal domain. The intramolecular interaction between the two oppositely charged termini of the protein is enhanced when serine residues in the acidic tail of HMGB1 are phosphorylated by protein kinase CK2, which can explain the negative effect of the phosphorylation on certain DNA interactions. In line with that, covalent cross-linking of the two terminal domains resulted in a reduced affinity of HMGB1 for linear DNA. Comparable to the finding with maize HMGB1, the basic N-terminal and the acidic C-terminal domains of the Arabidopsis HMGB1 and HMGB4 proteins interact, indicating that these intramolecular interactions, which can modulate HMGB protein function, generally occur in plant HMGB proteins.     

DNA-binding properties of the recombinant high-mobility-group-like AT-hook-containing region from human BRG1 protein

The hBRG1 protein, a central ATPase of the human switching/sucrose non-fermenting (SWI/SNF) remodeling complex, has a catalytic ATPase domain, an AT-hook motif and a bromodomain. Bromodomains, found in many chromatin-associated proteins, recognize N-acetyl-lysine in histones and other proteins. The AT-hook motif, first described in the high-mobility group of non-histone chromosomal proteins HMGA1/2, is a DNA-binding motif. The AT-hook binds to the AT-rich DNA sequences in the minor groove of B-DNA in a non-sequence specific manner. AT-hook motifs have been identified in many other DNA-binding proteins. In this study we cloned and purified a fragment of hBRG1 encompassing the AT-hook region and the bromodomain. Nuclear magnetic resonance (NMR) and circular dichroism (CD) analyses show that the recombinant domains are structured. The functionality of subdomains was checked by assessing their interactions with N-acetylated peptides from histones and with DNA. Isothermal titration calorimetric (ITC) analysis demonstrates that the primary micromolar interaction is through the AT-hook motif. The AT-hook region binds to linear DNA by unwinding it. These properties resemble the characteristics of the HMGA1/2 proteins and their interaction with DNA.     

Does high-mobility-group non-histone protein HMG 1 interact specifically with histone H1 subfractions?

The interaction of the non-histone chromosomal protein HMG (high-mobility group) 1 with histone H1 subfractions was investigated by equilibrium sedimentation and n.m.r. sectroscopy. In contrast with a previous report [Smerdon & Isenberg (1976) Biochemistry 15, 4242--4247], it was found, by using equilibrium-sedimentation analysis, that protein HMG 1 binds to all three histone H1 subfractions CTL1, CTL2, and CTL3, arguing against there being a specific interaction between protein HMG 1 and only two of the subfractions, CTL1 and CTL2. Raising the ionic strength of the solutions prevents binding of protein HMG 1 to total histone H1 and the three subfractions, suggesting that the binding in vitro is simply a non-specific ionic interaction between acidic regions of the non-histone protein and the basic regions of the histone. Protein HMG 1 binds to histone H5 also, supporting this view. The above conclusions are supported by n.m.r. studies of protein HMG 1/histone H1 subfraction mixtures. When the two proteins were mixed, there was little perturbation of the n.m.r. spectra and there was no evidence for specific interaction of protein HMG 1 with any of the subfractions. It therefore remains an open question as to whether protein HMG 1 and histone H1 are complexed together in chromatin.     

DNA interaction with RNase A alters protein conformation

DNA-RNase H adducts were used for site specific cleavage of RNA and DNA-RNA duplexes, whereas nonspecific DNA interaction with ribonuclease A (RNase A) has been observed. The aim of this study was to examine the complexation of calf-thymus DNA with RNase A at physiological condition, using constant DNA concentration (12.5 mM) and various protein contents (1 microM to 270 microM). FTIR, UV-visible, and CD spectroscopic methods were used to analyse protein binding mode, the binding constant and the effects of nucleic acid-enzyme interaction on both DNA and protein conformations. Our structural analysis showed a strong RNase-PO2 binding and minor interaction with G-C bases with overall binding constant of K = 6.1 x 10(4) M(-1). The RNase-DNA interaction alters the protein secondary structure with a major reduction of the alpha-helix and increase of the beta-sheet and random structure, while DNA remains in the B-family structure.     

Cooperative recruitment of HMGB1 during V(D)J recombination through interactions with RAG1 and DNA

During V(D)J recombination, recombination activating gene (RAG)1 and RAG2 bind and cleave recombination signal sequences (RSSs), aided by the ubiquitous DNA-binding/-bending proteins high-mobility group box protein (HMGB)1 or HMGB2. HMGB1/2 play a critical, although poorly understood, role in vitro in the assembly of functional RAG–RSS complexes, into which HMGB1/2 stably incorporate. The mechanism of HMGB1/2 recruitment is unknown, although an interaction with RAG1 has been suggested. Here, we report data demonstrating only a weak HMGB1–RAG1 interaction in the absence of DNA in several assays, including fluorescence anisotropy experiments using a novel Alexa488-labeled HMGB1 protein. Addition of DNA to RAG1 and HMGB1 in fluorescence anisotropy experiments, however, results in a substantial increase in complex formation, indicating a synergistic binding effect. Pulldown experiments confirmed these results, as HMGB1 was recruited to a RAG1–DNA complex in a RAG1 concentration-dependent manner and, interestingly, without strict RSS sequence specificity. Our finding that HMGB1 binds more tightly to a RAG1–DNA complex over RAG1 or DNA alone provides an explanation for the stable integration of this typically transient architectural protein in the V(D)J recombinase complex throughout recombination. These findings also have implications for the order of events during RAG–DNA complex assembly and for the stabilization of sequence-specific and non-specific RAG1–DNA interactions.     

Interactions between N- and C-terminal domains of the Saccharomyces cerevisiae high-mobility group protein HMO1 are required for DNA bending

The Saccharomyces cerevisiae high-mobility group protein HMO1 is composed of two DNA-binding domains termed box A and box B, of which only box B is predicted to adopt a HMG fold, and a lysine-rich C-terminal extension. To assess the interaction between individual domains and their contribution to DNA binding, several HMO1 variants were analyzed. Using circular dichroism spectroscopy, thermal stability was measured. While the melting temperatures of HMO1-boxA and HMO1-boxB are 57.2 and 47.2 degrees C, respectively, HMO1-boxBC, containing box B and the entire C-terminal tail, melts at 46.1 degrees C, suggesting little interaction between box B and the tail. In contrast, full-length HMO1 exhibits a single melting transition at 47.9 degrees C, indicating that interaction between box A and either box B or the tail destabilizes this domain. As HMO1-boxAB, lacking only the lysine-rich C-terminal segment, exhibits two melting transitions at 46.0 and 63.3 degrees C, we conclude that the destabilization of the box A domain seen in full-length HMO1 is due primarily to its interaction with the lysine-rich tail. Determination of DNA substrate specificity using electrophoretic mobility shift assays shows unexpectedly that the lysine-rich tail does not increase DNA binding affinity but instead is required for DNA bending by full-length HMO1; HMO1-boxBC, lacking the box A domain, also fails to bend DNA. In contrast, both HMO1 and HMO1-boxAB, but not the individual HMG domains, exhibit preferred binding to constrained DNA minicircles. Taken together, our data suggest that interactions between box A and the C-terminal tail induce a conformation that is required for DNA bending.     

Efficient specific DNA binding by p53 requires both its central and C-terminal domains as revealed by studies with high-mobility group 1 protein

The nonhistone chromosomal protein high-mobility group 1 protein (HMG-1/HMGB1) can serve as an activator of p53 sequence-specific DNA binding (L. Jayaraman, N. C. Moorthy, K. G. Murthy, J. L. Manley, M. Bustin, and C. Prives, Genes Dev. 12:462-472, 1998). HMGB1 is capable of interacting with DNA in a non-sequence-specific manner and causes a significant bend in the DNA helix. Since p53 requires a significant bend in the target site, we examined whether DNA bending by HMGB1 may be involved in its enhancement of p53 sequence-specific binding. Accordingly, a 66-bp oligonucleonucleotide containing a p53 binding site was locked in a bent conformation by ligating its ends to form a microcircle. Indeed, p53 had a dramatically greater affinity for the microcircle than for the linear 66-bp DNA. Moreover, HMGB1 augmented binding to the linear DNA but not to the microcircle, suggesting that HMGB1 works by providing prebent DNA to p53. p53 contains a central core sequence-specific DNA binding region and a C-terminal region that recognizes various forms of DNA non-sequence specifically. The p53 C terminus has also been shown to serve as an autoinhibitor of core-DNA interactions. Remarkably, although the p53 C terminus inhibited p53 binding to the linear DNA, it was required for the increased affinity of p53 for the microcircle. Thus, depending on the DNA structure, the p53 C terminus can serve as a negative or a positive regulator of p53 binding to the same sequence and length of DNA. We propose that both DNA binding domains of p53 cooperate to recognize sequence and structure in genomic DNA and that HMGB1 can help to provide the optimal DNA structure for p53.     

DNA-binding properties of an adenovirus 289R E1A protein.

An adenovirus 2 289 amino acid (289R) E1A protein purified from Escherichia coli has been shown to interact with DNA by two independent methods. UV-crosslinking of complexes containing unmodified, uniformly 32P-labelled DNA and purified E1A protein induced efficient labelling of the protein with covalently attached oligonucleotides, indicating that the E1A protein itself contacts DNA. Discrete nucleoprotein species were also observed when E1A protein--DNA complexes were analysed by gel electrophoresis. Although the 289R E1A protein exhibited no significant binding to single-stranded DNA or to RNA, no evidence for its sequence-specific binding to double-stranded DNA was obtained with either assay. Identification of the sites of covalent attachment of 32P-labelled oligonucleotides by partial proteolysis of the crosslinked E1A protein indicated that the interaction of this protein with DNA is mediated via domain(s) in the C-terminal half of the protein. Such previously unrecognized DNA-binding activity is likely to contribute to the regulatory activities of this important adenoviral protein.     

Nonhistone chromosomal protein HMG 1 interactions with DNA. Fluorescence and thermal denaturation studies

The interaction of high mobility group protein 1 (HMG 1) isolated from chicken erythrocytes with DNA has been characterized using the intrinsic tryptophan fluorescence of the protein as a probe. It was found that the fluorescence is quenched approximately 30% upon binding to either single- or double-stranded DNA. Fluorescent titrations indicate that the physical site size for HMG 1 binding on native DNA is approximately 14 base pairs (or 14 bases for binding to single-stranded DNA). Binding to single-stranded poly(dA) is only slightly dependent on ionic strength, although the affinity for double-stranded DNA is strongly ionic strength-dependent and has an optimum at approximately 100-120 mM Na+. Above this range, binding to native DNA is virtually all electrostatic in nature. Although the affinity of HMG 1 for single-stranded DNA is higher than that for double-stranded DNA at the extremes of the ionic range studied, no clear evidence for a helix-destabilizing activity was obtained. At low ionic strength, the protein actually stabilized DNA against thermal denaturation, while at high ionic strength, HMG 1 appears to undergo denaturation below the Tm of the DNA. Studies of the environment of the tryptophan fluorophores using collisional quenchers iodide, cesium, and acrylamide suggest that the predominant fluorophore is relatively exposed but constrained in a rigid, positively charged environment.     

Decreased levels of soluble receptor for advanced glycation end products in patients with rheumatoid arthritis indicating deficient inflammatory control

The receptor for advanced glycation end products (RAGE) is a member of the immunoglobulin superfamily being expressed as a cell surface molecule and binding a variety of ligands. One of these ligands is high-mobility group box chromosomal protein 1, a potent proinflammatory cytokine, expression of which is increased in synovial tissue and in synovial fluid of rheumatoid arthritis (RA) patients. The interaction of high-mobility group box chromosomal protein 1 with cell-surface RAGE leads to an inflammatory response. In contrast, the presence of soluble RAGE (sRAGE) may abrogate cellular activation since the ligand is bound prior to interaction with the surface receptor.     

Characterization of RNA aptamer binding by the Wilms' tumor suppressor protein WT1

The interaction of the zinc finger protein WT1 with RNA aptamers has been investigated using a quantitative binding assay, and the results have been compared to those from a previous study of the DNA binding properties of this protein. A recombinant peptide containing the four zinc fingers of WT1 (WT1-ZFP) binds to representatives of three specific families of RNA aptamers with apparent dissociation constants ranging from 13.8 +/- 1.1 to 87.4 +/- 10.4 nM, somewhat higher than the dissociation constant of 4.12 +/- 0.4 nM for binding to DNA. An isoform that contains an insertion of three amino acids between the third and fourth zinc fingers (WT1[+KTS]-ZFP) also binds to these RNAs with slightly reduced affinity (the apparent dissociation constants ranging from 22.8 to 69.8 nM) but does not bind to DNA. The equilibrium binding of WT1-ZFP to the highest-affinity RNA molecule was compared to the equilibrium binding to a consensus DNA molecule as a function of temperature, pH, monovalent salt concentration, and divalent salt concentration. The interaction of WT1-ZFP with both nucleic acids is an entropy-driven process. Binding of WT1-ZFP to RNA has a pH optimum that is narrower than that observed for binding to DNA. Binding of WT1-ZFP to DNA is optimal at 5 mM MgCl(2), while the highest affinity for RNA was observed in the absence of MgCl(2). Binding of WT1 to both nucleic acid ligands is sensitive to increasing monovalent salt concentration, with a greater effect observed for DNA than for RNA. Point mutations in the zinc fingers associated with Denys-Drash syndrome have dramatically different effects on the interaction of WT1-ZFP with DNA, but a consistent and modest effect on the interaction with RNA. The role of RNA sequence and secondary structure in the binding of WT1-ZFP was probed by site-directed mutagenesis. Results indicate that a hairpin loop is a critical structural feature required for protein binding, and that some consensus nucleotides can be substituted provided proper base pairing of the stem of the hairpin loop is maintained.     

Condensation of vector DNA by the chromosomal protein HMG1 results in efficient transfection

The aim of this study was the search for a method of vector packaging using natural chromatin constituents. The interaction of the chromosomal non-histone protein HMG1 with a vector plasmid (pLTEneo) was studied by sedimentation analysis and electron microscopy at physiological salt concentration. At high protein input the complexes exist in a condensed, monodisperse form sedimenting with 80 S irrespective of the supercoiled or relaxed conformation of DNA. Saturation binding is already observed at much lower input ratios. Dilution of 80 S complexes results in decondensation of the complexes. In the decondensed complex form, HMG1 binds in a bead-like manner to specific DNA regions. Condensation by HMG1 is sufficient to introduce the vector into mammalian cells without the need for unphysiological additives. The transfection rates were similar to or even higher than those obtained by the calcium phosphate coprecipitation technique.     

High-mobility group A1 protein inhibits p53-mediated intrinsic apoptosis by interacting with Bcl-2 at mitochondria

The high-mobility group A (HMGA) proteins are a family of non-histone chromatin factors, encoded by the HMGA1 and HMGA2 genes. Several studies demonstrate that HMGA proteins have a critical role in neoplastic transformation, and their overexpression is mainly associated with a highly malignant phenotype, also representing a poor prognostic index. Even though a cytoplasmic localization of these proteins has been previously reported in some highly malignant neoplasias, a clear role for this localization has not been defined. Here, we first confirm the localization of the HMGA1 proteins in the cytoplasm of cancer cells, and then we report a novel mechanism through which HMGA1 inhibits p53-mitochondrial apoptosis by counteracting the binding of p53 to the anti-apoptotic factor Bcl-2. Indeed, we demonstrate a physical and functional interaction between HMGA1 and Bcl-2 proteins. This interaction occurs at mitochondria interfering with the ability of p53 protein to bind Bcl-2, thus counteracting p53-mediated mitochondrial apoptosis. This effect is associated with the inhibition of cytochrome c release and activation of caspases. Consistent with this mechanism, a strong correlation between HMGA1 cytoplasmic localization and a more aggressive histotype of thyroid, breast and colon carcinomas has been observed. Therefore, cytoplasmic localization of HMGA1 proteins in malignant tissues is a novel mechanism of inactivation of p53 apoptotic function.