Interaction of the ADP-ribosylating enzyme from the hyperthermophilic archaeon S. solfataricus with DNA and ss-oligo deoxy ribonucleotides

The DNA-binding ability of the poly-ADPribose polymerase-like enzyme from the extremely thermophilic archaeon Sulfolobus solfataricus was determined in the presence of genomic DNA or single stranded oligodeoxyribonucleotides. The thermozyme protected homologous DNA against thermal denaturation by lowering the amount of melted DNA and increasing melting temperature. The archaeal protein induced structural changes of the nucleic acid by modifying the dichroic spectra towards a shape typical of condensing DNA. However, enzyme activity was slightly increased by DNA. Competition assays demonstrated that the protein interacted also with heterologous DNA. In order to characterize further the DNA binding properties of the archaeal enzyme, various ss-oligodeoxyribonucleotides of different base composition, lengths (12-mer to 24-mer) and structure (linear and circular) were used for fluorescence titration measurements. Intrinsic fluorescence of the archaeal protein due to tryptophan (excitation at 295 nm) was measured in the presence of each oligomer at 60 degrees C. Changes of tryptophan fluorescence were induced by all compounds in the same range of base number per enzyme molecule, but independently from the structural features of oligonucleotides, although the protein exhibited a slight preference for those adenine-rich and circular. The binding affinities were comparable for all oligomers, with intrinsic association constants of the same order of magnitude (K=10(6) M(-1)) in 0.01 M Na-phosphate buffer, pH 8.0, and accounted for a "non-specific" binding protein. Circular dichroism analysis showed that at 60 degrees C the native protein was better organized in a secondary structure than at 20 degrees C. Upon addition of oligonucleotides, enzyme structure was further stabilized and changed towards a beta-conformation. This effect was more marked with the circular oligomer. The analysed oligodeoxyribonucleotides slightly enhanced enzyme activity with the maximal increase of 50% as compared to the control. No activation was observed with the circular oligomer.     

Characterization of the 5' subtilisin (aprE) regulatory region from Bacillus subtilis

The poly(ADP-ribose) polymerase-like thermozyme purified from Sulfolobus solfataricus was characterised with respect to some physico-chemical properties. The archaeal protein exhibited a scarce electrophoretic mobility at both pH 2.9 and pH 7.5. Determination of the isoelectric point (pI=7.0-7.2) allowed us to understand the reason for the limited migration at pH 7.5, while amino acid composition analysis showed a moderate content of basic residues, which reduced mobility at pH 2.9. With respect to the charge, the archaeal enzyme behaved differently from the eukaryotic thermolabile poly(ADP-ribose) polymerase, described as a basic protein (pI=9.5). Well known inhibitors of the mesophilic polymerase like Zn(2+), nicotinamide and 3-aminobenzamide exerted a smaller effect on the enzyme from S. solfataricus, reducing the activity by at most 50%. Mg(2+) was a positive effector, although in a dose-dependent manner. It influenced the fluorescence spectrum of the archaeal protein, whereas NaCl had no effect.     

Mechanism of interaction between Ku protein and DNA

The mechanism of interaction between the Ku autoantigenic protein, a heterodimer of noncovalently linked 70,000- and 80,000-dalton subunits, and DNA was studied using immunoaffinity-purified Ku protein and a 300-base pair EcoRI fragment from HeLa cell DNA. In the nitrocellulose filter-binding assay, the Ku protein bound 32P-labeled double-stranded DNA, and much less efficiently single-stranded DNA. The binding of Ku to DNA was dependent on ionic strength and prevented by IgG from patient sera containing anti-Ku antibodies. In competitive assays, using unlabeled nucleic acid competitors, the DNA binding of Ku was not inhibited in the presence of yeast tRNA, synthetic copolymer of poly(A)-poly(dT), or circular plasmid pBR322 DNA, but was inhibited when the plasmid DNA was cleaved with appropriate restriction endonucleases. The inhibitory activities of cleaved plasmid DNA were independent of the configuration or nucleotide sequences at ends but proportional to the number of recognition sites of restriction enzymes used. Footprint analysis demonstrated that Ku protein protected both 3'- and 5'-terminal regions of double-stranded DNA from DNase I digestion. When Ku protein was fractionated electrophoretically, transferred to nitrocellulose filter, and probed with 32P-labeled DNA, only the 70,000-dalton subunit exhibited DNA binding. Thus, the Ku protein appears to recognize selectively ends of double-stranded DNA molecules. Possible functions of the Ku autoantigen in eukaryotic cells are discussed.     

The ADP-ribosylation of Sulfolobus solfataricus Sso7 modulates protein/DNA interactions in vitro

The 7 kDa Sso7 is a basic protein particularly abundant in Sulfolobus solfataricus and is involved in DNA assembly. This protein undergoes in vitro ADP-ribosylation by an endogenous poly(ADP-ribose) polymerase-like enzyme. The circular dichroism spectrum of purified ADP-ribosylated Sso7 shows that this modification stabilizes the prevalent protein β-conformation, as suggested by shifting of negative ellipticity minimum to 220 nm. Moreover, a short ADP-ribose chain (up to 6-mers) bound to Sso7 is able to reduce drastically the thermoprotective and DNA condensing ability of the protein, suggesting a possible regulatory role of ADP-ribosylation in sulfolobal DNA organization.     

Avian Retrovirus pp32 DNA-Binding Protein I. Recognition of Specific Sequences on Retrovirus DNA Terminal Repeats

The avian retrovirus pp32 protein possesses a DNA-nicking activity which prefers supercoiled DNA as substrate. We have investigated the binding of pp32 to avian retrovirus long terminal repeat (LTR) DNA present in both supercoiled and linear forms. The cloned viral DNA was derived from unintegrated Schmidt-Ruppin A (SRA) DNA. A subclone of the viral DNA in pBR322 (termed pPvuII-DG) contains some src sequences, tandem copies of LTR sequences, and partial gag sequences in the order src-U(3) U(5):U(3) U(5)-gag. Binding of pp32 to supercoiled pPvuII-DG DNA followed by digestion of this complex with a multicut restriction enzyme (28 fragments total) permitted pp32 to preferentially retain on nitrocellulose filters two viral DNA fragments containing only LTR DNA sequences. In addition, pp32 also preferentially retained four plasmid DNA fragments containing either potential promoters or Tn3 "left-end" inverted repeat sequences. Mapping of the pp32 binding sites on viral LTR DNA was accomplished by using the DNase I footprinting technique. The pp32 protein, but not the avian retrovirus alphabeta DNA polymerase, is able to form a unique protein-DNA complex with selected regions of either SRA or Prague A LTR DNAs. Partial DNase I digestion of a 275-base pair SRA DNA fragment complexed with pp32 gives upon electrophoresis in denaturing gels a unique ladder pattern, with regions of diminished DNase I susceptibility from 6 to 10 nucleotides in length, in comparison with control digests in the absence of protein. The binding of pp32 to this fragment also yields enhanced DNase I-susceptible sites that are spaced between the areas protected from DNase I digestion. The protected region of this unique complex was a stretch of 170 +/- 10 nucleotides that encompasses the presumed viral promoter site in U(3), which is adjacent to the src region, extends through U(5), and proceeds past the joint into U(3) for about 34 base pairs. No specific protection or DNase I enhancement by pp32 was observed in experiments with a 435-base pair SRA DNA fragment derived from a part of U(3) and the adjacent src region or a 55-base pair DNA fragment derived from another part of U(3). The DNA sequence of Prague A DNA at the fused LTRs differs from that of SRA DNA. The alteration in the sequence at the juncture of the LTRs prevented pp32 from forming a stable complex in this region of the LTR. Our results are relevant to two aspects of the interaction between pp32 and LTR DNA. First, the pp32 protein in the presence of selected viral DNA restriction fragments possibly forms a higher order oligomer analogous to Escherichia coli DNA gyrase-DNA complexes or eucaryotic nucleosome structures. Second, the specificity of the binding suggests a role for pp32 and the protected DNA sequences in the retrovirus life cycle. The preferred sequences to which pp32 binds include two adjacent 15-base pair inverted terminal repeats at the joint between U(5) and U(3) in SRA DNA. This region is involved in circularization of linear DNA and is perhaps the site that directs integration into cellular DNA.     

Carp liver DNase--isolation, further characterization and interaction with endogenous actin

Deoxyribonuclease I (DNase I)-like enzyme from the liver of the carp (Cyprinus carpio) was purified to homogeneity and further characterized. Ion exchange chromatography on DEAE-cellulose, molecular filtration on Sephacryl S-300 and Con A-Sepharose affinity chromatography were applied for enzyme isolation. Carp liver DNase, similarly to DNase I from bovine pancreas, was found to be an endonuclease that hydrolyses linear DNA from salmon sperm as well as circular DNA forms--plasmid and cosmid. The purified enzyme is a glycoprotein and shows microheterogeneity, as observed in DNase zymograms prepared after native and two-dimensional electrophoresis (2D-PAGE). The composition of sugar component of the enzyme was characterized. Special attention was focused on the ability of carp liver DNase to interact with carp liver actin. The carp liver enzyme was inhibited by endogenous actin. The estimated binding constant of carp liver DNase to carp liver actin was calculated to be 1.1 x 10(6) M(-1).     

De novo assembly of genuine replication forks on an immobilized circular plasmid in Xenopus egg extracts

We describe an improved model of DNA replication in Xenopus egg extracts, in which a circular plasmid immobilized on paramagnetic beads is used as a template. DNA synthesis occurred on either circular or linear plasmids coupled to the beads, but only DNA synthesis on the circular plasmid was inhibited by geminin and a CDK inhibitor, p21. DNA synthesis on the circular plasmid occurred after a time lag, during which nuclear formation was probably occurring. Although pre-replicative complexes (pre-RCs) were formed soon after mixing plasmids with egg extracts, binding of CDC45, RPA, Pol α, δ and , and PCNA to the circular plasmid was delayed, but still correlated with DNA synthesis. Moreover, p21 inhibited binding of these replication fork proteins to the circular plasmid. Therefore, the circular plasmid, but not the linear plasmid, assembles bona fide replication forks in egg extracts. We conclude that this improved replication system will be useful for studying the mechanism of formation of replication forks in eukaryotic DNA replication.     

DNA-binding properties of gene-5 protein encoded by bacteriophage M 13. 1. The kinetics of the dissociation of gene-5-protein.polynucleotide complexes upon addition of salt

The irreversible dissociation kinetics of complexes of M13-encoded gene-5 protein with the polynucleotides poly(dA) and M13 DNA was studied by means of stopped-flow experiments. A linear decay was found for all gene-5-protein.poly(dA) complexes and for the gene-5-protein.M13 DNA complexes for which the DNA lattice was completely saturated at the beginning of the dissociation experiments. Only at the end of the dissociation curve was a deviation from linearity observed. A single-exponential decay was found for the dissociation of gene-5-protein.M13 DNA complexes when the DNA was not completely saturated initially. These results could be interpreted by assuming that dissociation of bound protein is only possible from isolated binding sites, while during the dissociation, rearrangement of bound protein clusters takes place continuously, including the formation of newly isolated bound protein. This redistribution results from a translocation of the protein along the lattice, which, for the poly(dA) complex, is fast with respect to the dissociation step, but which is slow for the M13 DNA complex. During this process the equilibrium cluster distribution predicted by the theory of McGhee and Von Hippel is not maintained. The binding of gene-5 protein to poly(dA) or poly(dT) does not result in a broadening of the nucleotide resonances in the NMR spectra of these polynucleotides, as had been observed for E. coli DNA-binding protein and interpreted as an indication for a high rate of translocation of the protein on the polynucleotide. The absence of line broadening for gene-5-protein.polynucleotide complexes is caused by the high binding cooperativity. As a consequence the majority of the protein molecules are bound in a cluster which makes the concentration of isolated bound protein very low. This results in a decrease of the signal/noise ratio at higher degrees of binding, but does not lead to line broadening while fast translocation still occurs.     

Hoechst 33258--poly(dG-dC).poly(dG-dC) complexes of three types

It was found recently that Hoechst 33258, a dsDNA fluorescent dye used in cytological studies, is an efficient inhibitor of the interaction of TATA-box-binding protein with DNA, DNA topoisomerase I, and DNA helicases. In addition it proved to be a radioprotector. Biological activity of Hoechst 33258 may be associated with dsDNA complexes of not only monomeric, but also dimeric type. In this work, the Hoechst 33258 interaction with poly(dG-dC).poly(dG-dC) was studied using UV-vis and fluorescent spectroscopy, circular and flow-type linear dichroism. It was found that Hoechst 33258 formed with poly(dG-dC).poly(dG-dC) complexes of three types, namely, monomeric, dimeric, and, apparently, tetrameric, and their spectral properties were studied. Complexes of monomeric and dimeric types competed with distamycin A, a minor groove ligand, for binding to poly(dG-dC).poly(dG-dC). We proposed that Hoechst 33258 both monomers and dimers form complexes of the external type with poly(dG-dC).poly(dG-dC) from the side of the minor groove.     

Partial purification and properties of an exonuclease inhibitor induced by bacteriophage Mu-1.

From an induced lysogen of bacteriophage Mu-1, we partially purified a substance of high molecular weight that blocks the action of several exonucleases on double-stranded DNA. The presence of the inhibitor in cell-free extracts is dependent on induction of a Mu prophage. The Mu-related inhibitor acts by binding to double-stranded DNA rather than by interacting with the DNase. The inhibitor protects linear duplex DNA of Mu, P22, and phi X174am3 from exonucleolytic degradation by recBC DNase and lambda exonuclease. Single-stranded DNA, however, is not protected by the inhibitor from degradation by either recBC DNase or exonuclease I. The inhibitor preparation contains a protein that binds to linear duplex DNA, but not to circular duplex DNA; ends are required for binding to occur. Single-stranded DNA is not a substrate for the binding protein. These and other results suggest that the binding protein and the inhibitor are the same activity.     

Human 170 kDa and 180 kDa Topoisomerases II Bind Preferentially to Curved and Left-Handed Linear DNA

Abstract

The binding activities of the 170 kDa and the 180 kDa human topoisomerases II (topo IIa and topo IIβ) to linear DNA fragments with different degrees of curvature were characterized. In gel retardation experiments it was shown that both forms of the enzyme bind preferentially to a curved 287 bp fragment, forming a detectable stable complex. The affinity for straight DNA fragments of similar length is significantly lower. Both a commercially available topo IIa, isolated from placenta, and topo IIα and topo IIβ purified from nuclear extracts of the Namahva lymphoma tissue culture line gave similar results. The effects of double-stranded poly[d(A-T)], poly[d(G-C)], supercoiled plasmid DNA and linear Z-DNA on the topo II- complex with curved DNA were analyzed in competition experiments. The hierarchy of affinities of the 180 kDa topo IIβ for these DNAs has the order: linear left-handed DNA > supercoiled DNA ? curved DNA ? poly[d(A-T)] ? poly[d(G-C)]. The 170 kDa topo IIa binds with similar affinity to curved DNA and linear Z-DNA ? supercoiled DNA ? linear B- DNA The data imply that human topoisomerase II binding is more sensitive to DNA secondary structure than to DNA sequence per se. The ability of the enzyme to preferentially recognize a wide variety of sequences in unusual secondary structures suggests a mode of targeting the enzyme in vivo to regions of high negative supercoiling.     

Imaging DNA loops induced by restriction endonuclease EcoRII. A single amino acid substitution uncouples target recognition from cooperative DNA interaction and cleavage

EcoRII is a type IIE restriction endonuclease characterized by a highly cooperative reaction mechanism that depends on simultaneous binding of the dimeric enzyme molecule to two copies of its DNA recognition site. Transmission electron microscopy provided direct evidence that EcoRII mediates loop formation of linear DNA containing two EcoRII recognition sites. Specific DNA binding of EcoRII revealed a symmetrical DNase I footprint occupying 16-18 bases. Single amino acid replacement of Val(258) by Asn yielded a mutant enzyme that was unaffected in substrate affinity and DNase I footprinting properties, but exhibited a profound decrease in cooperative DNA binding and cleavage activity. Because the electrophoretic mobility of the mutant enzyme-DNA complexes was significantly higher than that of the wild-type, we investigated if mutant V258N binds as a monomer to the substrate DNA. Analysis of the molecular mass of mutant V258N showed a high percentage of protein monomers in solution. The dissociation constant of mutant V258N confirmed a 350-fold decrease of the enzyme dimerization capability. We conclude that Val(258) is located in a region of EcoRII involved in homodimerization. This is the first report of a specific amino acid replacement in a restriction endonuclease leading to the loss of dimerization and DNA cleavage while retaining specific DNA binding.     

Plasmid transformation of Streptococcus sanguis (Challis) occurs by circular and linear molecules

Summary Transformation of Streptococcus sanguis (Challis) by antibiotic resistance plasmids has shown that (a) competente developed with identical kinetics for chromosomal and plasmid DNA; (b) dependence of transformant yield on plasmid DNA concentration was second order; (c) open circular plasmid DNA transformed Challis, although at reduced frequency; (d) linearization of plasmid DNA by restriction enzymes cutting at unique sites inactivated the transforming capacity; (e) transforming activity was restored when linear plasmid molecules generated by different restriction enzymes were mixed; (f) restoration of transforming activity depended on the distance between the linearizing cuts, i.e. on the presence of sufficiently long overlapping homologous sequences; (g) when linear deletion mutants were mixed with linear parental plasmids the smaller plasmid was restored with significantly higher frequency.Based on these data, a model for plasmid transformation of Challis is proposed according to which circular plasmid is linearized during binding and uptake. One DNA strand enters the cell and restoration of circular plasmids inside the cell occurs by annealing of complementary single strands from two different donor molecules. Implications of this model for recombinant DNA experiments in streptococci are discussed.     

Molecular interactions between DNA, poly(ADP-ribose) polymerase, and histones

Molecular interactions between purified poly(ADP-ribose) polymerase, whole thymus histones, histone H1, rat fibroblast genomic DNA, and closed circular and linearized SV40 DNA were determined by the nitrocellulose filter binding technique. Binding of the polymerase protein or histones to DNA was augmented greatly when both the enzyme protein and histones were present simultaneously. The polymerase protein also associated with histones in the absence of DNA. The cooperative or promoted binding of histones and the enzyme to relaxed covalently closed circular SV40 DNA was greater than the binding to the linearized form. Binding of the polymerase to SV40 DNA fragments in the presence of increasing concentrations of NaCl indicated a preferential binding to two restriction fragments as compared to the others. Polymerase binding to covalently closed relaxed SV40 DNA resulted in the induction of superhelicity. The simultaneous influence of the polymerase and histones on DNA topology were more than additive. Topological constraints on DNA induced by poly(ADP-ribose) polymerase were abolished by auto ADP-ribosylation of the enzyme. Benzamide, by inhibiting poly(ADP-ribosylation), reestablished the effect of the polymerase protein on DNA topology. Polymerase binding to in vitro-assembled core particle-like nucleosomes was also demonstrated.     

Linear DNA low efficiency transfection by liposome can be improved by the use of cationic lipid as charge neutralizer

A plasmid expressing the beta-galactosidase enzyme was used to transfect Vero cells in order to evaluate the efficiency of a liposome-mediated transfection by circular and linear DNA. The results obtained showed a low rate of transfection by linear DNA:liposome complexes. To explore whether the structure of the complexes was interfering with the transfection, atomic force microscopy (AFM) was used. It has confirmed the difference between the linear and circular condensates: whereas the circular DNA:liposome complexes presented compact spherical or cylindrical structures of about 100-800 nm, the linear DNA showed pearl necklace-like structures, with pearls varying from 250 to 400 nm. On the basis of the theory proposed by Kuhn et al. (1999), low concentrations of cationic amphihile were used to neutralize or reverse the DNA charge in order to improve the transfection efficiency of the linear DNA. Using this method, we were able to obtain the expression of the transgene without an associated toxicity observed with the linear DNA liposome delivery.     

Orientation of the bases of single-stranded DNA and polynucleotides in complexes formed with the gene 32 protein of bacteriophage T4. A linear dichroism study

Linear dichroism measurements were performed in the wavelength region 250 to 350 nm on complexes between the single-stranded DNA binding protein of bacteriophage T4 (gp32) and single-stranded DNA and a variety of homopolynucleotides in compressed polyacrylamide gels. The complexes appeared to orient well, giving rise to linear dichroism spectra that showed contributions from both the protein aromatic residues and the bases of the polynucleotides. In most cases the protein contribution appeared to be very similar, and the linear dichroism of the bases could be explained by similar orientations of the bases for most of the complexes. Assuming a similar, regular structure for most of the polynucleotides in complex, only a limited set of combinations of tilt and twist angles can explain the linear dichroism spectra. These values of tilt and twist are close to (-40 degrees, 30 degrees), (-40 degrees, 150 degrees), (40 degrees, -30 degrees) or (40 degrees, -150 degrees), with an uncertainty in both angles of about 15 degrees. Although the linear dichroism results do not allow a choice between these possible orientations, the latter two combinations are not in agreement with earlier circular dichroism calculations. For the complexes formed with poly(rC) and poly(rA), the linear dichroism spectra could not be explained by the same base orientations. In these two cases also the protein contribution to the linear dichroism appeared to be different, indicating that for some aromatic residues the orientations are not the same as those in the other complexes. The different structures of these complexes are possibly related to the relatively low binding affinity of gp32 to poly(rC), and to a lesser extent to poly(rA).     

Application of an immunoprecipitation procedure to the study of SV40 tumor antigen interaction with mouse genomic DNA sequences.

Simian Virus 40 (SV40) large T antigen is a DNA binding protein with high affinity for segments of the viral genome. To find out whether T antigen also binds to sequences of genomic cellular DNA we mixed T antigen and SAU 3 A restricted mouse DNA under stringent DNA binding conditions. Resulting protein-DNA complexes were immunoprecipitated using T antigen specific monoclonal or polyclonal antibodies. The DNA fragments in the immunoprecipitates were cloned in plasmid vectors. Four plasmid clones were selected for a detailed investigation of the inserted mouse DNA fragments. Nucleotide sequencing and DNase I footprint experiments showed that T antigen binds to sites in these fragments consisting of two tandemly oriented G(A)AGGC pentamers separated by AT rich spacers of different lengths. The cellular binding sites are very similar in their architecture to the SV40-DNA binding site I. The isolated cellular DNA fragments with T antigen binding sites occur only once or a few times in the mouse genome. Our data help to further define the structure of T antigen's DNA binding sites. The genetic functions of the isolated cellular DNA elements are not known.     

Binding of netropsin to DNA in complexes with polypeptides containing repetitive lysine sequences

The interaction of the antibiotic netropsin with calf thymus DNA, T4 DNA and poly(dA-dT) . poly(dA-dT) in complexes with sequential polypeptides containing repetitive lysine sequences and histone H1 was investigated using circular dichroism spectroscopy and equilibrium dialysis. Both soluble DNA-polypeptide complexes and insoluble complexes showed binding of netropsin. The possibility of displacement of polypeptides from DNA binding sites by competition with netropsin molecules was eliminated by experiments using 14C-labelled polypeptides. From the analysis of CD titration behavior as well as from the results of equilibrium dialysis studies it follows that netropsin does not compete with polypeptides for DNA binding sites, which suggests that these two ligands occupy different sites. Various explanations for minor differences in the CD behavior of the bound netropsin in the saturation region are also discussed.