DNA supercoiling during ATP-dependent DNA translocation by the type I restriction enzyme EcoAI

Type I restriction enzymes cleave DNA at non-specific sites far from their recognition sequence as a consequence of ATP-dependent DNA translocation past the enzyme. During this reaction, the enzyme remains bound to the recognition sequence and translocates DNA towards itself simultaneously from both directions, generating DNA loops, which appear to be supercoiled when visualised by electron microscopy. To further investigate the mechanism of DNA translocation by type I restriction enzymes, we have probed the reaction intermediates with DNA topoisomerases. A DNA cleavage-deficient mutant of EcoAI, which has normal DNA translocation and ATPase activities, was used in these DNA supercoiling assays. In the presence of eubacterial DNA topoisomerase I, which specifically removes negative supercoils, the EcoAI mutant introduced positive supercoils into relaxed plasmid DNA substrate in a reaction dependent on ATP hydrolysis. The same DNA supercoiling activity followed by DNA cleavage was observed with the wild-type EcoAI endonuclease. Positive supercoils were not seen when eubacterial DNA topoisomerase I was replaced by eukaryotic DNA topoisomerase I, which removes both positive and negative supercoils. Furthermore, addition of eukaryotic DNA topoisomerase I to the product of the supercoiling reaction resulted in its rapid relaxation. These results are consistent with a model in which EcoAI translocation along the helical path of closed circular DNA duplex simultaneously generates positive supercoils ahead and negative supercoils behind the moving complex in the contracting and expanding DNA loops, respectively. In addition, we show that the highly positively supercoiled DNA generated by the EcoAI mutant is cleaved by EcoAI wild-type endonuclease much more slowly than relaxed DNA. This suggests that the topological changes in the DNA substrate associated with DNA translocation by type I restriction enzymes do not appear to be the trigger for DNA cleavage.     

Spontaneous DNA repair in human peripheral blood mononuclear cells

DNA molecules are constantly damaged during mitosis and by oxygen-free radicals produced by either cellular metabolism or by external factors. Populations at risk include patients with cancer-prone disease, patients under enhanced oxidative stress, and those treated with immunosuppressive/cytotoxic therapy. The DNA repair process is crucial in maintaining the genomal DNA integrity. The aim of this study was to evaluate spontaneous DNA repair capacity of peripheral blood mononuclear cells (PBMC) from normal blood donors. PBMC DNA repair ability represents DNA repair by other tissues as well. It is shown in the present study that in vitro incorporation of [3H]thymidine in non-stimulated PBMC expresses the ability of the cells to repair DNA damage. This method was validated by double-stranded DNA measurements. Both catalase and Fe2+ increased DNA repair, the former by preventing re-breakage of newly repaired DNA and the latter by introducing additional DNA damage, which enhanced DNA repair. Better understanding of DNA repair processes will enable to minimize DNA damage induced by oxidative stress.     

Electron microscopy visualization of DNA-protein complexes formed by Ku and DNA ligase IV

The repair of DNA double-stranded breaks (DSBs) is essential for cell viability and genome stability. Aberrant repair of DSBs has been linked with cancer predisposition and aging. During the repair of DSBs by non-homologous end joining (NHEJ), DNA ends are brought together, processed and then joined. In eukaryotes, this repair pathway is initiated by the binding of the ring-shaped Ku heterodimer and completed by DNA ligase IV. The DNA ligase IV complex, DNA ligase IV/XRRC4 in humans and Dnl4/Lif1 in yeast, is recruited to DNA ends in vitro and in vivo by an interaction with Ku and, in yeast, Dnl4/Lif1 stabilizes the binding of yKu to in vivo DSBs. Here we have analyzed the interactions of these functionally conserved eukaryotic NHEJ factors with DNA by electron microscopy. As expected, the ring-shaped Ku complex bound stably and specifically to DNA ends at physiological salt concentrations. At a ratio of 1 Ku molecule per DNA end, the majority of DNA ends were occupied by a single Ku complex with no significant formation of linear DNA multimers or circular loops. Both Dnl4/Lif1 and DNA ligase IV/XRCC4 formed complexes with Ku-bound DNA ends, resulting in intra- and intermolecular DNA end bridging, even with non-ligatable DNA ends. Together, these studies, which provide the first visualization of the conserved complex formed by Ku and DNA ligase IV at juxtaposed DNA ends by electron microscopy, suggest that the DNA ligase IV complex mediates end-bridging by engaging two Ku-bound DNA ends.     

Stimulation of mouse DNA primase-catalyzed oligoribonucleotide synthesis by mouse DNA helicase B.

Many prokaryotic and viral DNA helicases involved in DNA replication stimulate their cognate DNA primase activity. To assess the stimulation of DNA primase activity by mammalian DNA helicases, we analyzed the synthesis of oligoribonucleotides by mouse DNA polymerase alpha-primase complex on single-stranded circular M13 DNA in the presence of mouse DNA helicase B. DNA helicase B was purified by sequential chromatography through eight columns. When the purified DNA helicase B was applied to a Mono Q column, the stimulatory activity for DNA primase-catalyzed oligoribonucleotide synthesis and DNA helicase and DNA-dependent ATPase activities of DNA helicase B were co-eluted from the column. The synthesis of oligoribonucleotides 5-10 nt in length was markedly stimulated by DNA helicase B. The synthesis of longer species of oligoribonucleotides, which were synthesized at a low level in the absence of DNA helicase B, was inhibited by DNA helicase B. The stimulatory effect of DNA helicase B was marked at low template concentrations and little or no effect was observed at high concentrations. The mouse single-stranded DNA binding protein, replication protein A (RP-A), inhibited the primase activity of the DNA polymerase alpha-primase complex and DNA helicase B partially reversed the inhibition caused by RP-A.     

Supercoiling-dependent sequence specificity of mammalian DNA methyltransferase.

Negative supercoiling of substrate DNA dramatically alters the in vitro sequence specificity of mammalian DNA methyltransferase (DNA MeTase). This result suggests that in vivo site selection by DNA MeTase could be regulated by conformational information in the form of alternative secondary structures induced in DNA by local supercoiling or by the binding of specific nuclear proteins. DNA in the left-handed Z-form is shown not to be a substrate for mammalian DNA MeTase. The sensitivity of DNA MeTase to DNA structure may also make it useful as a probe for sequences which undergo supercoiling-dependent structural transitions in vitro.     

A method to increase the bioactivity of plasmid DNA by heat treatment

A method to increase the bioactivity of plasmid DNA by heat treatment has been developed. The structure of the heat treated plasmid DNA was investigated by electrophoresis assay and atomic force microscope (AFM) observation. Electrophoresis assay showed that the heat treated DNA consisted of three components: the supercoiled DNA (component I), the open circular DNA (component II) and the heat denatured DNA component. The bioactivity of the heat treated plasmid DNA was investigated by both DNA condensation experiments and gene transfection experiment with mammal cells. DNA condensation experiments showed that the heat denatured DNA component owned higher sensitivity to spermidine and polyethylenimine (PEI) than component I and component II DNA. Gene transfection experiment with PEI indicated that the heat treated DNA had higher gene transfection efficiency than untreated DNA. Our experiment not only shows an effective approach to increase the bioactivity of plasmid DNA but also leads a way to improve the bioactivity of DNA by physically modifying their structure.     

Purification and properties of spleen necrosis virus DNA polymerase.

DNA polymerase was purified to apparent electrophoretic homogeneity from virions of spleen necrosis virus (SNV). (SNV is a member of the reticuloendotheliosis group of avian ribodeoxyviruses). The SNV DNA polymerase appears to consist of a single polypeptide with a molecular weight of 68,000. The SNV DNA polymerase has a preference for Mn2+ for DNA synthesis with an RNA template and Mg2+ for DNA synthesis with a deoxyribohomopolymer template. At the optimum concentrations of divalent cation, the relative rates of DNA synthesis by SNV DNA polymerase with different template.primers were similar to the relative rates of DNA synthesis by an avian leukosis virus DNA polymerase, with the exception of a lower relative rate of DNA synthesis by SNV DNA polymerase with SNV RNA. However, in contrast to DNA synthesized by the avian leukosis virus DNA polymerase with a SNV RNA template, DNA synthesized by SNV DNA polymerase with an SNV RNA template did not hybridize to the SNV RNA. SNV DNA polymerase has RNase H activity which is antigenically distinct from the RNase H activity of avian leukosis-sarcoma virus DNA polymerase.     

DNA bending by charged peptides: electrophoretic and spectroscopic analyses

We are testing the idea that placement of fixed charges near one face of the DNA double helix can induce DNA bending by a purely electrostatic mechanism. If stretching forces between DNA phosphates are significant, fixed charges should induce DNA bending by asymmetrically modulating these forces. We have previously tested this hypothesis by adding charged residues to small bZIP DNA binding peptides and monitoring DNA bending using electrophoretic phasing assays. Our results were consistent with an electrostatic model of DNA bending in predicted directions. We now confirm these observations with fluorescence resonance energy transfer (FRET). Using a "U"-shaped DNA probe, we report that DNA bending by charged bZIP peptides is readily detected by FRET. We further show that charged bZIP peptides cause DNA bending rather than DNA twisting.     

Fate of Infecting Simian Virus 40-Deoxyribonucleic Acid in Nonpermissive Cells: Integration into Host Deoxyribonucleic Acid

Nonpermissive 3T3 cells were infected with purified superhelical simian virus 40 (SV40) deoxyribonucleic acid I (DNA I). One hour after infection, approximately 60% of the intracellular SV40 DNA was converted to relaxed forms. One day after infection, all intracellular SV40 DNA was present as slow-sedimenting material, and no SV40 DNA I was detectable. At 2 days after infection there appeared viral DNA sequences cosedimenting with cellular DNA during alkaline velocity centrifugation. Furthermore, by both alkaline equilibrium gradient centrifugation and by DNA-ribonucleic acid hybridization analysis, covalent linkage of viral DNA sequences to cellular DNA was demonstrated. Integration of SV40 DNA into cellular DNA did not appear to require DNA synthesis, although DNA synthesis followed by mitotic division of the cells enhanced the amount of viral DNA integrated. Based on data obtained by two different methods, it was calculated that 1,100 to 1,200 SV40 DNA equivalents must be integrated per cell by 48 hr after infection.     

Site-specific recognition of bacteriophage T4 DNA by T4 type II DNA topoisomerase and Escherichia coli DNA gyrase

The site specificity of bacteriophage T4-induced type II DNA topoisomerase action on double-stranded DNA has been explored by studying the sites where DNA cleavages are induced by the enzyme. Oxolinic acid addition increases the frequency at which phi X174 duplex DNA is cut by the enzyme by about 100-fold, to the point where nearly every topoisomerase molecule causes a double-stranded DNA cleavage event. The effect of oxolinic acid on the enzyme is very similar to its effect on another type II DNA topoisomerase, the Escherichia coli DNA gyrase. A filter-binding method was developed that allows efficient purification of topoisomerase-cleaved DNA fragments by selecting for the covalent attachment of this DNA to the enzyme. Using this method, T4 topoisomerase recognition of mutant cytosine-containing T4 DNA was found to be relatively nonspecific, whereas quite specific recognition sites were observed on native T4 DNA, which contains glucosylated hydroxymethylcytosine residues. The increased specificity of native T4 DNA recognition seems to be due entirely to the glucose modification. In contrast, E. coli DNA gyrase shows a high level of specificity for both the mutant cytosine-containing DNA and native T4 DNA, recognizing about five strong cleavage sites on both substrates. An unexpected feature of DNA recognition by the T4 topoisomerase is that the addition of the cofactor ATP strongly stimulates the topoisomerase-induced cleavage of native T4 DNA, but has only a slight effect on cleavage of cytosine-containing T4 DNA.     

Regulation of the genes for E. coli DNA gyrase: Homeostatic control of DNA supercoiling

DNA gyrase is the bacterial enzyme responsible for converting circular DNA to a negatively supercoiled form. We show that the synthesis of DNA gyrase is itself controlled by DNA supercoiling; synthesis is highest when the DNA template is relaxed. The rates of synthesis in vivo of both the A and B subunits of DNA gyase are increased up to 10-fold by treatments that block DNA gyrase activity and decrease the supercoiling of intracellular DNA. Similarly, efficient synthesis of both gyrase subunits in a cell-free S-30 extract depends on keeping the closed circular DNA template in a relaxed conformation. The results suggest that DNA supercoiling in E. coli is controlled by a homeostatic mechanism. Synthesis of the RecA protein and several other proteins is also increased by treatments that relax intracellular DNA.     

Initiation, elongation and pausing of in vitro DNA synthesis catalyzed by immunopurified yeast DNA primase: DNA polymerase complex.

Yeast DNA primase and DNA polymerase I can be purified by immunoaffinity chromatography as a multipeptide complex which can then be resolved into its functional components and further reassembled in vitro. Isolated DNA primase synthesizes oligonucleotides of a preferred length of 9-10 nucleotides and multiples thereof on a poly(dT) template. In vitro reconstitution of the DNA primase:DNA polymerase complex allows the synthesis of long DNA chains covalently linked to RNA initiators shorter than those synthesized by DNA primase alone. The SS (single-stranded) circular DNA of phage M13mp9 can also be replicated by the DNA primase:DNA polymerase complex. Priming by DNA primase occurs at multiple sites and the initiators are utilized by the DNA polymerase moiety of the complex, so that almost all the SS template is converted into duplex form. The rate of DNA synthesis catalyzed by isolated yeast DNA polymerase I on the M13mp9 template is not constant and is characterized by distinct pausing sites, which partly correlate with secondary structures on the template DNA. Thus, replication of M13mp9 SS DNA with the native primase:polymerase complex gives rise to a series of DNA chains with significantly uniform termini specified by the primase start sites and the polymerase stop sites.     

DNA unwinding by replication protein A is a property of the 70 kDa subunit and is facilitated by phosphorylation of the 32 kDa subunit.

Replication protein A (RP-A) is a heterotrimeric single-stranded DNA binding protein with important functions in DNA replication, DNA repair and DNA recombination. We have found that RP-A from calf thymus can unwind DNA in the absence of ATP and MgCl2, two essential cofactors for bona fide DNA helicases (Georgaki, A., Strack, B., Podust, V. and Hübscher, U. FEBS Lett. 308, 240-244, 1992). DNA unwinding by RP-A was found to be sensitive to MgCl2, ATP, heating and freezing/thawing. Escherichia coli single stranded DNA binding protein at concentrations that coat the single stranded regions had no influence on DNA unwinding by RP-A suggesting that RP-A binds fast and tightly to single-stranded DNA. DNA unwinding by RP-A did not show directionality. Experiments with monoclonal antibodies strongly suggested that the 70kDa subunit is responsible for DNA unwinding. Phosphorylation of the 32kDa subunit of RP-A by chicken cdc2 kinase facilitated DNA unwinding indicating that this posttranslational modification might be important for modulating this activity of RP-A. Finally, DNA unwinding of a primer recognition complex for DNA polymerase delta which is composed of proliferating cell nuclear antigen, replication factor C and ATP bound to a singly-primed M13DNA slightly inhibited DNA unwinding. An important role for DNA unwinding by RP-A in processes such as initiation of DNA replication, fork propagation, DNA repair and DNA recombination is discussed.     

Integrated State of Oncornavirus DNA in Normal Chicken Cells and in Cells Transformed by Avian Myeloblastosis Virus

The covalent linkage of oncornavirus-specific DNA to chicken DNA was investigated in normal chicken embryo fibroblasts (CEF) and in virus-producing leukemic cells transformed by avian myeloblastosis virus (AMV). The virus-specific sequences present in cellular DNA fractionated by different methods were detected by DNA-RNA hybridization by using 70S AMV RNA as a probe. In CEF and in leukemic cells, the viral DNA appeared to be present only in the nucleus. After cesium chloride-ethidium bromide density equilibrium sedimentation, the viral DNA was present as linear, double-stranded molecules not separable from linear chicken DNA. After extraction by the Hirt procedure, the viral DNA precipitated with the high-molecular-weight DNA. After alkaline sucrose velocity sedimentation, the viral DNA cosedimented with the high-molecular-weight cellular DNA. The results indicate that in both types of cells studied, the oncornavirus-specific DNA sequences were linked by alkali stable bonds to nuclear cellular DNA of high molecular weight and did not appear to be present in free form of any size.     

Rapid preparation of vector-free hybridization probes suitable for screening recombinant libraries

A procedure is described to rapidly prepare radioactively labeled DNA inserts from crude recombinant plasmid DNA preparations. These probes can subsequently be used to identify homologous nucleotide sequences in bacteria containing recombinant plasmids by colony hybridization. In a single procedure, crude recombinant plasmid DNA is both ³²P-labeled and fragmented by nick-translation in the presence of sufficient pancreatic DNase I to produce radioactive DNA of about 0.2–0.3-kb single-strand length. At this DNA fragment length the majority of the vector and insert sequences are on different DNA fragments. The insert DNA can then be separated from vector and contaminating Escherichia colt host chromosomal DNA by the following method. The DNA fragment population is first denatured and renatured under conditions such that the recombinant plasmid DNA reassociates but host DNA does not. The renatured plasmid DNA fragments are separated from the denatured host DNA by hydroxylapatite chromatography. The plasmid DNA fragments are then denatured and renatured with an excess of insert-free vector DNA. Conditions are chosen such that the insert DNA remains single-stranded while the vector DNA becomes double-stranded. The single-stranded insert DNA can be separated from the double-stranded vector DNA on hydroxylapatite and used directly for colony hybridization.     

Integration of Rous sarcoma virus DNA during transfection

We have investigated the organization and integration sites of Rous sarcoma virus (RSV) DNA in NIH 3T3 mouse cells transformed by transfection with unintegrated and integrated donor RSV DNAs. RSV DNAs of different cell lines transformed by unintegrated donor DNA were flanked by different cellular DNA sequences, indicating that RSV DNA integrates at multiple sites during transfection. The RSV genomes of cells transformed by transfection were colinear with unintegrated RSV DNA, except that deletions within the terminal repeat units of RSV DNA were detected in some cell lines. These results suggested that the terminal repeat sequences of RSV DNA did not necessarily provide a specific integration site for viral DNA during transfection. In addition, cell lines transformed by integrated RSV DNAs contained both the RSV genomes and flanking cellular sequences of the parental cell lines, indicating that integration of integrated viral DNA during transfection occurred by recombinational events within flanking cellular DNA sequences rather than at the terminal of viral DNA. Integration of RSV DNA during transfection thus appears to differ from integration of RSV DNA in virus-infected cells, where the terminal repeat units of viral DNA provide a highly specific integration site. Integration of donor DNA during transfection of NIH 3T3 cells instead appears to proceed by a pathway which is nonspecific for both donor and recipient DNA sequences.     

Eukaryotic DNA replication. Enzymes and proteins acting at the fork

A complex network of interacting proteins and enzymes is required for DNA replication. Much of our present understanding is derived from studies of the bacterium Escherichia coli and its bacteriophages T4 and T7. These results served as a guideline for the search and the purification of analogous proteins in eukaryotes. model systems for replication, such as the simian virus 40 DNA, lead the way. Generally, DNA replication follows a multistep enzymatic pathway. Separation of the double-helical DNA is performed by DNA helicases. Synthesis of the two daughter strands is conducted by two different DNA polymerases: the leading strand is replicated continuously by DNA polymerase delta and the lagging strand discontinuously in small pieces by DNA polymerase alpha. The latter is complexed to DNA primase, an enzyme in charge of frequent RNA primer syntheses on the lagging strand. Both DNA polymerases require several auxiliary proteins. They appear to make the DNA polymerases processive and to coordinate their functional tasks at the replication fork. 3'----5'-exonuclease, mostly part of the DNA polymerase delta polypeptide, can perform proof-reading by excising incorrectly base-paired nucleotides. The short DNA pieces of the lagging strand, called Okazaki fragments, are processed to a long DNA chain by the combined action of RNase H and 5'----3'-exonuclease, removing the RNA primers, DNA polymerase alpha or beta, filling the gap, and DNA ligase, sealing DNA pieces by phosphodiester bond formation. Torsional stress during DNA replication is released by DNA topoisomerases. In contrast to prokaryotes, DNA replication in eukaryotes not only has to create two identical daughter strands but also must conserve higher-order structures like chromatin.     

Persistence of DNA synthesis arrest sites in the presence of T4 DNA polymerase and T4 gene 32, 44, 45 and 62 DNA polymerase accessory proteins.

DNA synthesis by phage T4 DNA polymerase is arrested at specific sequences in single-stranded DNA templates. To determine whether or not T4 DNA polymerase accessory proteins 32, 44, 45 and 62 eliminated recognition of these arrest sites, unique primer-templates were constructed in which DNA synthesis began at a DNA primer located at different distances from palindromic and nonpalindromic arrest sites. Nucleotide positions that caused polymerase to pause or leave the template were identified by sequence analysis of 5'-end labeled nascent DNA chains. Stable hairpin structures at palindromic sequences were confirmed by acetylation of single-stranded sequences with bromoacetaldehyde. Our results confirmed that these T4 DNA polymerase accessory proteins stimulated T4 DNA polymerase activity and processivity on natural as well as homopolymer primer-templates. However, they did not alter recognition of DNA synthesis arrest sites by T4 DNA polymerase. Extensive DNA synthesis resulted from an increased rate of translocation and/or processivity to the same extent over all DNA sequences.     

Effect of DNA polymerase inhibitors on DNA repair in intact and permeable human fibroblasts: evidence that DNA polymerases delta and beta are involved in DNA repair synthesis induced by N-methyl-N'-nitro-N-nitrosoguanidine

The involvement of DNA polymerases alpha, beta, and delta in DNA repair synthesis induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was investigated in human fibroblasts (HF). The effects of anti-(DNA polymerase alpha) monoclonal antibody, (p-n-butylphenyl)deoxyguanosine triphosphate (BuPdGTP), dideoxythymidine triphosphate (ddTTP), and aphidicolin on MNNG-induced DNA repair synthesis were investigated to dissect the roles of the different DNA polymerases. A subcellular system (permeable cells), in which DNA repair synthesis and DNA replication were differentiated by CsCl gradient centrifugation of BrdUMP density-labeled DNA, was used to examine the effects of the polymerase inhibitors. Another approach investigated the effects of several of these inhibitors on MNNG-induced DNA repair synthesis in intact cells by measuring the amount of [3H]thymidine incorporated into repaired DNA as determined by autoradiography and quantitation with an automated video image analysis system. In permeable cells, MNNG-induced DNA repair synthesis was inhibited 56% by 50 micrograms of aphidicolin/mL, 6% by 10 microM BuPdGTP, 13% by anti-(DNA polymerase alpha) monoclonal antibodies, and 29% by ddTTP. In intact cells, MNNG-induced DNA repair synthesis was inhibited 57% by 50 micrograms of aphidicolin/mL and was not significantly inhibited by microinjecting anti-(DNA polymerase alpha) antibodies into HF nuclei. These results indicate that both DNA polymerases delta and beta are involved in repairing DNA damage caused by MNNG.     

ATR: a master conductor of cellular responses to DNA replication stress

The integrity of the genome is constantly challenged by intrinsic and extrinsic genotoxic stresses that damage DNA. The cellular responses to DNA damage are orchestrated by DNA damage signaling pathways, also known as DNA damage checkpoints. These signaling pathways play crucial roles in detecting DNA damage, regulating DNA repair and coordinating DNA repair with other cellular processes. In vertebrates, the ATM- and Rad3-related (ATR) kinase plays a key role in the response to a broad spectrum of DNA damage and DNA replication stress. Here, we will discuss the recent findings on how ATR is activated by DNA damage and how it protects the genome against interference with DNA replication.