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Query: EC:2.7.7.7 (DNA polymerase)
17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In the long unique region of the genome of herpes simplex virus type 1 (HSV-1), the genes for DNA polymerase and the major DNA binding protein are arranged in a head to head manner, with an origin of DNA replication (termed OriL) located between them. This paper reports an 8400 base pair DNA sequence containing both genes and the origin, obtained mostly by M13/dideoxy analysis of plasmid cloned fragments. Amino acid sequences of the two proteins were deduced. Homologues of both genes were detected in the genome sequence of the distantly related Epstein-Barr virus (EBV). Arrangement of these HSV-1 and EBV genes differs in genome location and in relative orientation. A part of HSV-1 DNA polymerase was found to be similar to a sequence in adenovirus 2 DNA polymerase, but the significance of this is unclear. Since a DNA sequence in the locality of OriL deletes on plasmid cloning, this region was analysed using virus DNA. A palindrome with 72-residue arms was found, which shows great similarity to the better characterized origin, OriS.
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PMID:DNA sequence of the region in the genome of herpes simplex virus type 1 containing the genes for DNA polymerase and the major DNA binding protein. 299 14

We have identified a protein that binds specifically to an origin of replication (oris) of the herpes simplex virus type 1 genome. The oris binding protein, detectable only in nuclear extracts of infected cells, shows the same time course of appearance as the herpesvirus-induced DNA polymerase and the DNA binding protein ICP8. The partially purified oris binding protein generates a DNase I "footprint" that spans 18- of the 90-base-pair minimal oris sequence. The oris binding protein may, therefore, be analogous to other origin-specific binding proteins that are required for the initiation of viral and chromosomal DNA replication.
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PMID:A DNA binding protein specific for an origin of replication of herpes simplex virus type 1. 301 24

Several laboratories have shown that transfected plasmid DNAs containing either of the two known origins of herpes simplex virus (HSV) DNA replication, oriS or oriL, are replicated in HSV-1-infected cells or in cells cotransfected with virion DNA. I have found that HSV-1 (KOS) DNA digested to completion with the restriction enzyme Xba I is as efficient as intact viral DNA in supporting the in vivo replication of cotransfected plasmids containing oriS. On the basis of this result, several of the Xba I restriction fragments of HSV-1 DNA were cloned into the plasmid vector pUC19, and combinations of cloned DNAs were tested for their ability to supply the trans-acting functions required for HSV origin-dependent replication. A combination of five cloned fragments of HSV-1 can supply all of the necessary functions: Xba I C (coordinates 0.074-0.294), Xba I F (coordinates 0.294-0.453), Xba I E (coordinates 0.453-0.641), Xba I D (coordinates 0.641-0.830), and EcoRI JK (coordinates 0.0-0.086; 0.830-0.865). Transient plasmid replication in this system is dependent on the presence of either oriS or oriL in cis. The plasmid containing Xba I F can be replaced by two smaller plasmids, one of which contains only the gene for the HSV-encoded DNA polymerase, and the other of which contains only the gene for the major DNA binding protein (ICP8). Thus, plasmid DNA replication in this system depends on two of the genes known from genetic studies to be essential for viral DNA replication in infected cells. This system defines a simple complementation assay for cloned fragments of HSV DNA that contain other genes involved in viral DNA replication and should lead to the rapid identification of all such genes.
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PMID:A method for identifying the viral genes required for herpesvirus DNA replication. 302 66

The herpes simplex virus type 2 (HSV-2)-induced deoxyuridine triphosphate nucleotidohydrolase (dUTPase) was purified approximately 600 +/- 43-fold using a combination of affinity, hydrophobic, absorption, and ion-exchange chromatography techniques. The only substrate for the dUTPase was dUTP with a Km of 3.6 +/- 1.1 microM. There was no apparent divalent cation requirement, but the HSV-2-induced dUTPase was inhibited by EDTA (0.1 mM) and this inhibition was reversed by either Co2+ (0.5 mM) or Mg2+ (0.5 mM). The HSV-2-induced dUTPase was distinguished from the HSV-1-induced and cellular dUTPases based upon differences in sensitivity to substrate inhibition, thermostability, and electrophoretic migration in nondenaturing polyacrylamide gels. Analysis of HSV-1 temperature-sensitive (ts) mutants demonstrated that ts A15 and ts K13 did not induce significant amounts of dUTPase activity at the permissive or nonpermissive temperatures. Mutants with defects in HSV-induced DNA polymerase or in the major DNA binding protein induced dUTPase at both temperatures. In contrast ts mutants defective in the alpha polypeptide VP175 (ICP4) did not induce normal levels of dUTPase at the nonpermissive temperature. The location of a gene encoding for the type specificity of the HSV induced dUTPase was mapped to the left 20% of the genome in Us in the region 0.060 to 0.100 or from 0.148 to 0.204.
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PMID:Characterization of a herpes simplex virus type 2 deoxyuridine triphosphate nucleotidohydrolase and mapping of a gene conferring type specificity for the enzyme. 302 79

Single-stranded DNA binding protein is a key component in growth of bacteriophage T7. In addition, DNA synthesis by the purified in vitro replication system is markedly stimulated when the DNA template is coated with Escherichia coli single-stranded DNA binding protein (SSB). In an attempt to understand the mechanism for this stimulation, we have studied the effect of E. coli SSB on DNA synthesis by the T7 DNA polymerase using a primed single-stranded M13 DNA template which serves as a model for T7 lagging strand DNA synthesis. Polyacrylamide gel analysis of the DNA product synthesized on this template in the absence of SSB indicated that the T7 DNA polymerase pauses at many specific sites, some stronger than others. By comparing the position of pausing with the DNA sequence of this region and by using a DNA template that contains an extremely stable hairpin structure, it was found that many, but not all, of these pause positions correspond to regions of potential secondary structure. The presence of SSB during synthesis resulted in a large reduction in the frequency of hesitations at many sites that correspond to these secondary structures. However, the facts that a large percentage of the pause sites remain unaffected even at saturating levels of SSB and that SSB stimulates synthesis on a singly primed poly(dA) template suggested that other mechanisms also contribute to the stimulation of DNA synthesis caused by SSB. Using a sucrose gradient analysis, we found that SSB increases the affinity of the polymerase for single-stranded DNA that this increased binding is only noticed when the polymerase concentration is limiting. The effect of this difference in polymerase affinity was clearly observed by a polyacrylamide gel analysis of the product DNA synthesized during a limited DNA synthesis reaction using conditions where only two nucleotides are added to the primer. Under these circumstances, where the presence of hairpin structures should not contribute to the stimulatory effect of SSB, we found that the extension of the primer is stimulated 4-fold if the DNA template is coated with SSB. Furthermore, SSB had no effect on this synthesis at large polymerase to template ratios.
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PMID:Mechanism of stimulation of T7 DNA polymerase by Escherichia coli single-stranded DNA binding protein (SSB). 305 1

In order to elucidate the role of in vivo interaction of single-strand DNA binding protein with DNA polymerase II isogenic strains of Escherichia coli were constructed combining the ssb+, ssb-1 alleles with DNA polymerases I or II mutations; their radiosensitivity and a level of UV-induced DNA degradation were studied. Received findings suggest a functional antagonism of SSB-proteins depending on intracellular conditions (from the balance of DNA and protein synthesis). The SSB-proteins provide the stability of the genome or, vice versa, perturb the stability of the genome, by degrading of DNA macromolecules.
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PMID:[The role of in vivo interaction of proteins SSB with DNA polymerase II]. 328 31

Factor D, a DNA binding protein that enhances the activities of diverse DNA polymerases with a common restricted set of templates, was initially characterized in mouse liver but has resisted extensive purification. In this paper, we report that a similar stimulatory activity can be obtained in highly purified form from nuclei of rabbit hepatocytes. The rabbit liver protein increases the rates at which several DNA polymerases copy sparsely primed natural DNA templates and primed synthetic poly(dT), but it has no effect on the rates of copying of activated DNA or of poly(dG), poly(dA), and poly(dC). Direct binding of the purified stimulatory protein to an oligomer that contains a (dT)16 base stretch is visualized by retardation of the nucleoprotein complex on nondenaturing electrophoretograms. In the presence of the enhancing factor, Michaelis constants, Km, of responsive polymerase for singly primed bacteriophage M13 DNA and for poly(dT), but not for poly(dA), are decreased. Product analysis of M13 DNA primer extension indicates that the rabbit factor augments the apparent processivity of DNA polymerase by decreasing the extent of enzyme pausing at a tract of four consecutive thymidine residues in the template. Gel filtration of the native stimulatory protein yields an apparent relative molecular size of 58 +/- 2 kilodaltons. Stimulatory activity is readily inactivated by heat or by trypsin digestion, but it is resistant to micrococcal nuclease, N-ethyl-maleimide, or calcium ions.
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PMID:Rabbit liver factor D, a poly(thymidine) template stimulatory protein of DNA polymerases: purification and characterization. 340 61

A soluble enzyme system has been prepared from a phage P4-infected Escherichia coli strain that supports the replication of exogenous, supercoiled P4 DNA. This DNA synthesis in vitro depends upon the four deoxyribonucleotides and ATP, but is enhanced about four- to fivefold by the presence of other ribonucleotides. E. coli DNA polymerase III holoenzyme, the E. coli single-strand DNA binding protein, and the partially purified P4 alpha gene product are required for replication in vitro. Rifamycin does not inhibit P4 replication in vitro. Since the P4 alpha gene codes for a rifamycin-resistant RNA polymerase (Barrett et al., 1983), and since P4 DNA replication is independent of the host primase (Bowden et al., 1975), we believe the alpha gene product is functioning as a P4-specific DNA primase.
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PMID:The replication of bacteriophage P4 DNA in vitro. Partial purification of the P4 alpha gene product. 387 88

Sera from patients suffering from autoimmune diseases were analyzed for the presence of antibodies that inhibit adenovirus DNA replication in vitro. DNA replication was studied in a reconstituted system containing purified viral proteins (DNA binding protein, DNA polymerase and the precursor to the terminal protein) and a crude nuclear extract from HeLa cells. About half the autoimmune sera analyzed inhibited DNA replication by more than 50% while only 2 out of 31 control sera showed strong inhibition. The inhibition was caused by the IgG fractions of the sera and was most frequently observed with sera from scleroderma patients. Several lines of evidence indicate that the inhibition is not due to anti-DNA antibodies. The mechanism of inhibition of two strongly inhibitory sera was further investigated. The IgG fractions from these sera blocked DNA chain elongation more than 80% but had no effect on the initiation step or the synthesis of the first 26 nucleotides. Using a dot blot assay and different incubation conditions, evidence was obtained that the inhibition is due to immunorecognition of a nuclear factor from HeLa cells. Two nuclear proteins are known to be required for adenovirus DNA replication, nuclear factors I and II. DNA replication in the presence of purified nuclear factor I instead of a crude nuclear extract was only slightly inhibited by the antisera. In agreement with this, immunorecognition of nuclear factor I could not be detected using a dot blot assay. Since nuclear factor II is not required in our assay system, these results suggest the existence of another nuclear component involved in adenovirus DNA replication which is neutralized by these antibodies.
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PMID:Inhibition of adenovirus DNA replication in vitro by autoimmune sera. 394 34

The E. coli DNA binding protein reduces the activity of the single-strand-specific nucleases associated with all three DNA polymerases known in E. coli. A slight excess of binding protein over that required to saturate the DNA template leads to total inhibition of activity of the 3' --> 5' nucleases associated with DNA polymerases I and III, but restores maximum activity of the DNA polymerase II-associated nuclease. The binding protein forms a specific complex with DNA polymerase II in the absence of DNA, and it is this complex that degrades a DNA.binding protein complex. Binding protein also facilitates the binding of DNA polymerase II to single-stranded DNA, whereas the binding to DNA of DNA polymerase I is inhibited. These data may explain the specificity with which the binding protein enhances the synthetic ability of DNA polymerase II.
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PMID:Properties of the Escherichia coli in DNA binding (unwinding) protein: interaction with DNA polymerase and DNA. 461 May 64

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