Selective binding of tumor suppressor p53 protein to topologically constrained DNA: Modulation by intercalative drugs

Selective binding of the wild type tumor suppressor protein p53 to negatively and positively supercoiled (sc) DNA was studied using intercalative drugs chloroquine (CQ), ethidium bromide, acridine derivatives and doxorubicin as a modulators of the level of DNA supercoiling. The p53 was found to lose gradually its preferential binding to negatively scDNA with increasing concentrations of intercalators until the DNA negative superhelix turns were relaxed. Formation of positive superhelices (due to further increasing intercalator concentrations) rendered the circular duplex DNA to be preferentially bound by the p53 again. CQ at concentrations modulating the closed circular DNA topology did not prevent the p53 from recognizing a specific target sequence within topologically unconstrained linear DNA. Experiments with DNA topoisomer distributions differing in their superhelix densities revealed the p53 to bind selectively DNA molecules possessing higher number of negative or positive superturns. Possible modes of the p53 binding to the negatively or positively supercoiled DNA and tentative biological consequences are discussed.     

The Drosophila nuclear lamina protein YA binds to DNA and histone H2B with four domains

Dramatic changes occur in nuclear organization and function during the critical developmental transition from meiosis to mitosis. The Drosophila nuclear lamina protein YA binds to chromatin and is uniquely required for this transition. In this study, we dissected YA's binding to chromatin. We found that YA can bind to chromatin directly and specifically. It binds to DNA but not RNA, with a preference for double-stranded DNA (linear or supercoiled) over single-stranded DNA. It also binds to histone H2B. YA's binding to DNA and histone H2B is mediated by four domains distributed along the length of the YA molecule. A model for YA function at the end of Drosophila female meiosis is proposed.     

Topoisomerase IV bends and overtwists DNA upon binding

Escherichia coli topoisomerase IV (Topo IV) is an essential ATP-dependent enzyme that unlinks sister chromosomes during replication and efficiently removes positive but not negative supercoils. In this article, we investigate the binding properties of Topo IV onto DNA in the absence of ATP using a single molecule micromanipulation setup. We find that the enzyme binds cooperatively (Hill coefficient alpha approximately 4) with supercoiled DNA, suggesting that the Topo IV subunits assemble upon binding onto DNA. It interacts preferentially with (+) rather than (-) supercoiled DNA (Kd+=0.15 nM, Kd-=0.23 nM) and more than two orders-of-magnitude more weakly with relaxed DNA (Kd0 approximately 36 nM). Like gyrase but unlike the eukaryotic Topo II, Topo IV bends DNA with a radius 0= 6.4 nm and locally changes its twist and/or its writhe by 0.16 turn per bound complex. We estimate its free energy of binding and study the dynamics of interaction of Topo IV with DNA at the binding threshold. We find that the protein/DNA complex alternates between two states: a weakly bound state where it stays with probability p = 0.89 and a strongly bound state (with probability p = 0.11). The methodology introduced here to characterize the Topo IV/DNA complex is very general and could be used to study other DNA/protein complexes.     

StpA protein from Escherichia coli condenses supercoiled DNA in preference to linear DNA and protects it from digestion by DNase I and EcoKI

The nucleoid-associated protein, StpA, of Escherichia coli binds non-specifically to double-stranded DNA (dsDNA) and apparently forms bridges between adjacent segments of the DNA. Such a coating of protein on the DNA would be expected to hinder the action of nucleases. We demonstrate that StpA binding hinders dsDNA cleavage by both the non-specific endonuclease, DNase I, and by the site-specific type I restriction endonuclease, EcoKI. It requires approximately one StpA molecule per 250–300 bp of supercoiled DNA and approximately one StpA molecule per 60–100 bp on linear DNA for strong inhibition of the nucleases. These results support the role of StpA as a nucleoid-structuring protein which binds DNA segments together. The inhibition of EcoKI, which cleaves DNA at a site remote from its initial target sequence after extensive DNA translocation driven by ATP hydrolysis, suggests that these enzymes would be unable to function on chromosomal DNA even during times of DNA damage when potentially lethal, unmodified target sites occur on the chromosome. This supports a role for nucleoid-associated proteins in restriction alleviation during times of cell stress.     

Asymmetry of chromatin subunits probed with histone H1 in an H1-DNA complex

Treatment of nucleosomes with a low concentration of sodium dodecyl sulfate removed all proteins except histone H1 from DNA, thus confirming our previous observation on sheared chromatin. No redistribution of H1 occurred during this procedure for isolation of the H1-DNA complex. The H1-DNA complex was isolated from a nucleosome monomer, doubly labeled in its protein and DNA and fractionated according to the length of DNA, and then the distribution of H1 was analyzed quantitatively. The results indicated that the monomer consisted of two subspecies, one containing 160 base pairs of DNA and one molecule of H1, and the other containing 140 base pairs of DNA and no H1. Since no monomer with two molecules of H1 was found, it is concluded that the nucleosome core has a binding site for H1 on only one side, and thus that the nucleosome is not a dyad.     

Histone H1 inhibits eukaryotic DNA topoisomerase I.

Histone H1 inhibits the catalytic activity of topoisomerase I in vitro. The relaxation activity of the enzyme is partially inhibited at a molar ratio of one histone H1 molecule per 40 base pairs (bp) of DNA and completely inhibited at a molar ratio of one histone H1 molecule per 10 base pairs of DNA. Increasing the amount of enzyme at a constant histone H1 to DNA ratio antagonizes the inhibition. This indicates that topoisomerase I and histone H1 compete for binding sites on the substrate DNA molecules. Consistent with this we show on the sequence level that histone H1 inhibits the cleavage reaction of topoisomerase I on linear DNA fragments.     

Homologous pairing in duplex DNA regions and the formation of four-stranded paranemic joints promoted by RecA protein. Effects of gap length and negative superhelicity

RecA protein catalyzes homologous pairing of partially single-stranded duplex DNA and fully duplex DNA to form stable joint molecules. We constructed circular duplex DNA with various defined gap lengths and studied the pairing reaction between the gapped substrate with fully double-stranded DNA. The reaction required a stoichiometric amount of RecA protein, and the optimal reaction was achieved at a ratio of 1 RecA monomer per 4 base pairs. The length of the gap, ranging from 141 to 1158 nucleotides, had little effect on the efficiency of homologous pairing. By using a circular gapped duplex DNA prepared from the chimeric phage M13Gori1, we were able to show the formation of nonintertwined or paranemic joints in duplex regions between the gapped and fully duplex molecules. The formation of such paranemic joints occurred efficiently and included nearly all of the DNA in the reaction mixture. The reaction required negative superhelicity, and pairing was greatly reduced with linear or nicked circular DNA. We conclude that one functional role of the single-stranded gap is for facilitating the binding of RecA protein to the duplex region of the gapped DNA. Once the nucleoprotein filament is formed, homologous pairing between the gapped and fully duplex DNA can take place anywhere along the length of the nucleoprotein complex.     

Anthraquinones quinizarin and danthron unwind negatively supercoiled DNA and lengthen linear DNA

The intercalating drugs possess a planar aromatic chromophore unit by which they insert between DNA bases causing the distortion of classical B-DNA form. The planar tricyclic structure of anthraquinones belongs to the group of chromophore units and enables anthraquinones to bind to DNA by intercalating mode. The interactions of simple derivatives of anthraquinone, quinizarin (1,4-dihydroxyanthraquinone) and danthron (1,8-dihydroxyanthraquinone), with negatively supercoiled and linear DNA were investigated using a combination of the electrophoretic methods, fluorescence spectrophotometry and single molecule technique an atomic force microscopy. The detection of the topological change of negatively supercoiled plasmid DNA, unwinding of negatively supercoiled DNA, corresponding to appearance of DNA topoisomers with the low superhelicity and an increase of the contour length of linear DNA in the presence of quinizarin and danthron indicate the binding of both anthraquinones to DNA by intercalating mode.     

Single-strand DNA binding protein from rat liver: interactions with supercoiled DNA.

As shown by competition experiments, the single-strand DNA binding protein from normal rat liver (S25) interacts preferentially with supercoiled DNA compared to relaxed DNA duplexes. When followed both by sedimentation analysis and by nitrocellulose filter assay, the binding of S25 to SV40 supercoiled DNA (FI) appears to be non-cooperative. Saturation is reached at a protein to DNA weight ratio of about 2. The S25-DNA complexes prefixed with glutaraldehyde appear as beaded structures having an average of 14 to 16 beads per SV40 DNA molecules. Cross-linking of S25 bound to SV40 DNA by dimethyl suberimidate allows to detect oligomeric structures containing a maximum of twenty monomers of S25. When complexes are treated by glutaraldehyde, 10% of the genome become resistant against micrococcal nuclease. Moreover, S25 affects the DNA helical structure. Superhelical forms are generated by the association of S25 with SV40 DNA, in the presence of nicking-closing enzyme.     

The Zalpha domain from human ADAR1 binds to the Z-DNA conformer of many different sequences.

Z-DNA, the left-handed conformer of DNA, is stabilized by the negative supercoiling generated during the movement of an RNA polymerase through a gene. Recently, we have shown that the editing enzyme ADAR1 (double-stranded RNA adenosine deaminase, type 1) has two Z-DNA binding motifs, Zalpha and Zbeta, the function of which is currently unknown. Here we show that a peptide containing the Zalpha motif binds with high affinity to Z-DNA as a dimer, that the binding site is no larger than 6 bp and that the Zalpha domain can flip a range of sequences, including d(TA)3, into the Z-DNAconformation. Evidence is also presented to show that Zalpha and Zbeta interact to form a functional DNA binding site. Studies with atomic force microscopy reveal that binding of Zalpha to supercoiled plasmids is associated with relaxation of the plasmid. Pronounced kinking of DNA is observed, and appears to be induced by binding of Zalpha. The results reported here support a model where the Z-DNA binding motifs target ADAR1 to regions of negative supercoiling in actively transcribing genes. In this situation, binding by Zalpha would be dependent upon the local level of negative superhelicity rather than the presence of any particular sequence.     

Preferential Binding of Hot Spot Mutant p53 Proteins to Supercoiled DNA In Vitro and in Cells

Hot spot mutant p53 (mutp53) proteins exert oncogenic gain-of-function activities. Binding of mutp53 to DNA is assumed to be involved in mutp53-mediated repression or activation of several mutp53 target genes. To investigate the importance of DNA topology on mutp53-DNA recognition in vitro and in cells, we analyzed the interaction of seven hot spot mutp53 proteins with topologically different DNA substrates (supercoiled, linear and relaxed) containing and/or lacking mutp53 binding sites (mutp53BS) using a variety of electrophoresis and immunoprecipitation based techniques. All seven hot spot mutp53 proteins (R175H, G245S, R248W, R249S, R273C, R273H and R282W) were found to have retained the ability of wild-type p53 to preferentially bind circular DNA at native negative superhelix density, while linear or relaxed circular DNA was a poor substrate. The preference of mutp53 proteins for supercoiled DNA (supercoil-selective binding) was further substantiated by competition experiments with linear DNA or relaxed DNA in vitro and ex vivo. Using chromatin immunoprecipitation, the preferential binding of mutp53 to a sc mutp53BS was detected also in cells. Furthermore, we have shown by luciferase reporter assay that the DNA topology influences p53 regulation of BAX and MSP/MST1 promoters. Possible modes of mutp53 binding to topologically constrained DNA substrates and their biological consequences are discussed.     

The effect of supercoil and temperature on the recognition of palindromic and non-palindromic regions in phi X174 replicative form DNA by S1 and Bal31

The effect of supercoil and temperature on the topology of phi X174 replicative form (RF) DNA was studied using single-strand specific endonucleases S1 and Bal31 as probes for cruciform extrusion and other structural perturbations of the B-helix. Both enzymes were found to recognize specifically and reproducibly over 30 sites, most of which were cleaved by both enzymes independent of the superhelicity of the genome. A negative superhelical density exceeding 0.06 stabilized a transition in the DNA conformation that generated several new cleavage sites for Bal31. The underlying structures appeared to be only transiently stable and were lost from in vitro supercoiled DNA during brief incubation at 65 degrees C. They were generally absent from in vivo supercoiled RF DNA of equal superhelicity as a consequence of the extraction and storage procedure. Mapping of the cleavage sites suggested that they were preferentially located near the beginnings and ends of genes and that the structural basis for at least some of them was the extrusion of relatively small palindromes into the cruciform state. Insertion of a short synthetic palindromic sequence into the phi X174 genome generated a supercoil-dependent, temperature-sensitive secondary structure that was cleaved in the Bal31 but not the S1 reaction, further supporting the hypothesis that even small cruciforms with stem size of 7 or less base pairs may be transiently stable. Subjecting supercoiled RF DNA to the typical S1 reaction conditions induced a topological shift that diminished all but one of the supercoil-induced Bal31 recognition sites and promoted the formation of one major new site.     

Dynamics of DNA binding of replication initiation proteins during de novo formation of pre-replicative complexes in Xenopus egg extracts

We investigated the dynamics of DNA binding of replication initiation proteins during formation of the pre-replicative complex (pre-RC) on plasmids in Xenopus egg extracts. The pre-RC was efficiently formed on plasmids at 23 degrees C, with one or a few origin recognition complex (ORC) molecules and approximately 10-20 mini-chromosome maintenance 2 (MCM2) molecules loaded onto each plasmid. Although geminin inhibited MCM loading, MCM interacted weakly but stoichiometrically with the plasmid in an ORC-dependent manner, even in the presence of geminin (with approximately 10 MCM2 molecules per plasmid). Interestingly, DNA binding of ORC, CDC6, and CDT1 was significantly stabilized in the presence of geminin, under which conditions approximately 10-20 molecules each of ORC and CDC6 were bound. Moreover, a similarly stable ORC-CDC6-CDT1 complex rapidly formed on DNA at lower temperature (0 degrees C) without geminin, with approximately 10-20 molecules each of ORC and CDC6 bound to the plasmid, but almost no binding of MCM. However, upon shifting the temperature to 23 degrees C, most ORC, CDC6, and CDT1 molecules were displaced from the DNA, leaving about one ORC molecule on the plasmid, whereas approximately 10 MCM2 molecules were loaded onto each plasmid. Furthermore, it was possible to load MCM onto DNA when the isolated ORC-CDC6-CDT1-DNA complex was mixed with purified MCM proteins. These results suggest that an ORC-CDC6-CDT1 complex pre-formed on DNA is directly involved in MCM loading and imply that each DNA-bound ORC molecule loads only one or a few MCM2-7 complexes during metazoan pre-RC formation.