EC:5.99.1.2 - FACTA Search

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Query: EC:5.99.1.2 (topoisomerase)
9,166 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Vaccinia virus DNA topoisomerase I forms a 3'-phosphoryl intermediate with duplex DNAs containing the conserved binding/cleavage motif 5'CCCTT decreases. Covalently bound enzyme is capable of transferring the incised DNA strand to a heterologous DNA acceptor containing a 5'OH terminus. Both intramolecular and intermolecular religation reactions are catalyzed. Intramolecular strand transfer occurs to the noncleaved strand of the DNA duplex and results in formation of a hairpin loop. Intermolecular religation to an exogenous DNA strand is favored over hairpin formation and requires the potential for base pairing between the acceptor and the noncleaved strand of the donor complex. As few as 4 potential base pairs are sufficient to support intermolecular transfer. These results in vitro are consistent with the proposal that vaccinia topoisomerase can catalyze sequence-specific strand transfer during genetic recombination in vivo (Shuman, S. (1991) Proc. Natl. Acad. Sci. U.S.A. 88, 10104-10108.).
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PMID:DNA strand transfer reactions catalyzed by vaccinia topoisomerase I. 131 32

Analysis of vaccinia topoisomerase mutants that are impaired in DNA relaxation has allowed the identification of amino acid residues required for the transesterification step of catalysis. Missense mutations of wild-type residues Gly-132----Asp and Arg-223----Gln rendered the protein inert in formation of the covalent enzyme-DNA complex and hence completely inactive in DNA relaxation. Mutations of Thr-147----Ile and Gly-132----Ser caused severe defects in covalent adduct formation that correlated with the extent of inhibition of relaxation. None of these point mutations had an effect on noncovalent DNA binding sufficient to account for the defect in relaxation. Deletion of amino- or carboxyl-terminal portions of the polypeptide abrogated noncovalent DNA binding. Two distinct topoisomerase-DNA complexes were resolved by native gel electrophoresis. One complex, which was unique to those proteins competent in covalent adduct formation, contained topoisomerase bound to the 5'-portion of the incised DNA strand. The 3'-segment of the cleaved strand had dissociated spontaneously. This complex was isolated and shown to catalyze transfer of the covalently bound DNA to a heterologous acceptor oligonucleotide, thereby proving that the covalent adduct between protein and duplex DNA is a true intermediate in strand breakage and reunion. The role of the active site region of eukaryotic topoisomerase in determining sensitivity or resistance to camptothecin was examined by converting the active site region of the resistant vaccinia enzyme (SKRAY274) to that of the drug-sensitive yeast enzyme (SKINY). The SKINY mutation did not alter the resistance of the vaccinia enzyme to the cleavage-enhancing effects of camptothecin.
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PMID:Covalent and noncovalent DNA binding by mutants of vaccinia DNA topoisomerase I. 132 12

The ability of a eukaryotic DNA topoisomerase I to catalyze DNA rearrangements was examined in vitro using defined substrates and purified enzyme. Site-specific DNA strand cleavage by vaccinia topoisomerase I across from a nick generated double-strand breaks that could be religated to a heterologous blunt-ended duplex DNA regardless of the sequence of the acceptor molecule. Topoisomerase bound covalently at internal positions could religate the bound strand to an incoming acceptor provided that DNA molecule had sequence homology to the region 3' of the scissile bond. These end-joining reactions suggest two potential modes of topoisomerase-mediated recombination that differ in their requirements for DNA homology.
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PMID:Two classes of DNA end-joining reactions catalyzed by vaccinia topoisomerase I. 132 9

Purified vaccinia virus DNA topoisomerase I forms a cleavable complex with duplex DNA at a conserved sequence element 5'(C/T)CCTTdecreases in the incised DNA strand. DNase I footprint studies show that vaccinia topoisomerase protects the region around the site of covalent adduct formation from nuclease digestion. On the cleaved DNA strand, the protected region extends from +13 to -13 (+1 being the site of cleavage). On the noncleaved strand, the protected region extends from +13 to -9. Similar nuclease protection is observed for a mutant topoisomerase (containing a Tyr ---- Phe substitution at the active site amino acid 274) that is catalytically inert and does not form the covalent intermediate. Thus, vaccinia topoisomerase is a specific DNA binding protein independent of its competence in transesterification. By studying the cleavage of a series of 12-mer DNA duplexes in which the position of the CCCTTdecreases motif within the substrate is systematically phased, the "minimal" substrate for cleavage has been defined; cleavage requires six nucleotides upstream of the cleavage site and two nucleotides downstream of the site. An analysis of the cleavage of oligomer substrates mutated singly in the CCCTT sequence reveals a hierarchy of mutational effects based on position within the pentamer motif and the nature of the sequence alteration.
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PMID:Site-specific interaction of vaccinia virus topoisomerase I with duplex DNA. Minimal DNA substrate for strand cleavage in vitro. 168 12

Specialized type I topoisomerases catalyze DNA strand transfer during site-specific recombination in prokaryotes and fungi. As a rule, the site specificity of these systems is determined by the DNA binding and cleavage preference of the topoisomerase per se. The Mr 32,000 topoisomerase I encoded by vaccinia virus (a member of the eukaryotic family of "general" type I enzymes) is also selective in its interaction with DNA; binding and cleavage occur in vitro at a pentameric motif 5'-(C or T)CCTT in duplex DNA. Expression of vaccinia virus DNA topoisomerase I in a lambda lysogen of Escherichia coli promotes int-independent excisive recombination of the prophage. To address whether the topoisomerase directly catalyzes DNA strand transfer in vivo, the recombination junctions of plaque-purified progeny phage were cloned and sequenced. In five of six distinct excision events examined, a topoisomerase cleavage sequence is present in one strand of the DNA duplex of both recombining partners. Recombination entails no duplication, insertion, or deletion of nucleotides at the crossover points, consistent with excision via conservative strand exchange at sites of topoisomerase cleavage. Three of these five recombination events are distinguished by the presence of direct repeats at the parental half-sites that extend beyond the pentameric cleavage motif, suggesting that sequence homology may facilitate excision. The data are consistent with a model in which vaccinia topoisomerase catalyzes reciprocal strand transfer, leading to the formation of a nonmigrating Holliday junction, the resolution of which can lead to excisive recombination.
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PMID:Recombination mediated by vaccinia virus DNA topoisomerase I in Escherichia coli is sequence specific. 165 96

Cleavage of linear duplex DNA by purified vaccinia virus DNA topoisomerase I occurs at a conserved sequence element (5'-C/T)CCTT decreases) in the incised DNA strand. Oligonucleotides spanning the high affinity cleavage site CCCTT at nucleotide 2457 in pUC19 DNA are cleaved efficiently in vitro, but only when hybridized to a complementary DNA molecule. As few as 6 nucleotides proximal to the cleavage site and 6 nucleotides downstream of the site are sufficient to support exclusive cleavage at the high affinity site (position +1). Single nucleotide substitutions within the consensus pentamer have deleterious effects on the equilibria of the topoisomerase binding and DNA cleavage reactions. The effects of base mismatch within the pentamer are more dramatic than are the effects of mutations that preserve base complementarity. Competition experiments indicate that topoisomerase binds preferentially to DNA sites containing the wild-type pentamer element. Single-stranded DNA containing the sequence CCCTT in the cleaved stand is a more effective competitor than is single-stranded DNA containing the complementary sequence in the noncleaved strand.
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PMID:Site-specific DNA cleavage by vaccinia virus DNA topoisomerase I. Role of nucleotide sequence and DNA secondary structure. 184 64

The Shope fibroma virus (SFV) DNA topoisomerase gene has been identified and mapped to the BamHI D fragment near the midpoint of the genome. The DNA sequence of the SFV BamHI S fragment together with the contiguous BamHI-ClaI subfragment of BamHI D which encompasses the topoisomerase gene and two flanking genes has been determined and analyzed. Both the SFV DNA topoisomerase and the two flanking genes are closely related in terms of sequence and spatial organization to the homologous sequences from the midpoint of the vaccinia virus genome, indicating that these proteins are conserved not only in their sequence but also by position within the poxvirus genome. To confirm the assignment of the SFV gene, the putative SFV DNA topoisomerase has been expressed as an active fusion protein in Escherichia coli and this system should be useful in the analysis of topoisomerase function following the introduction of targeted mutations into the topoisomerase gene. The results of this work shed further light on the evolutionary relationship of the different poxvirus genera and indicate that central unique regions of the poxvirus genomes contain many of the essential viral genes and are thus highly conserved.
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PMID:Identification and DNA sequence of the Shope fibroma virus DNA topoisomerase gene. 216 Nov 44

We have developed a simple, effective genetic screen for mutant alleles of eukaryotic DNA topoisomerase I that manifest severely depressed or complete loss of enzymatic function. The screen is based on the extreme toxicity of vaccinia topoisomerase expression in the Escherichia coli lysogen strain BL21(DE3) and is notable for its ease in distinguishing nonsense mutations (that result in truncated proteins) from missense mutations. The power of the method is evinced by our observation that 100% of the candidate alleles identified in the screen were ultimately found to have single-base changes at the DNA level that result in amino acid substitutions at the protein level. By mutagenizing plasmid DNA in vitro with hydroxylamine and applying this phenotypic screen, we have isolated five distinct single amino acid substitution mutants, each of which shows a biochemical phenotype, that is, greater than or equal to 90% reduction in specific DNA relaxing activity of the mutant protein relative to wild type. The amino acids thus implicated in topoisomerase function have identical or related counterparts at homologous positions in the topoisomerases from yeast and man. The same genetic screen has been applied to the selection of temperature-sensitive alleles of the vaccinia topoisomerase, leading to the isolation of two additional single-hit mutant alleles that display a temperature-sensitive growth phenotype in E. coli BL21(DE3). By broadening our mutagenesis procedures, we expect to generate a comprehensive map of vaccinia topoisomerase function and primary protein structure that should have direct application to eukaryotic cellular enzymes. Our methodology should be applicable to the selection of missense and conditional mutant alleles in other genes whose expression in bacteria is toxic.
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PMID:Phenotypic selection and characterization of mutant alleles of a eukaryotic DNA topoisomerase I. 216 40

Cleavage of a defined linear duplex DNA by vaccinia virus DNA topoisomerase I was found to occur nonrandomly and infrequently. Approximately 12 sites of strand scission were detected within the 5372 nucleotides of pUC19 DNA. These sites could be classified as having higher or lower affinity for topoisomerase based on the following criteria. Higher affinity sites were cleaved at low enzyme concentration, were less sensitive to competition, and were most refractory to religation promoted by salt, divalent cations, and elevated temperature. Cleavage at lower affinity sites required higher enzyme concentration and was more sensitive to competition and induced religation. Cleavage site selection correlated with a pentameric sequence motif (C/T)CCTT immediately preceding the site of strand scission. Noncovalent DNA binding by topoisomerase predominated over covalent adduct formation, as revealed by nitrocellulose filter-binding studies. The noncovalent binding affinity of vaccinia topoisomerase for particular subsegments of pUC19 DNA correlated with the strength and/or the number of DNA cleavage sites contained therein. Thus, cleavage site selection is likely to be dictated by specific noncovalent DNA-protein interactions. This was supported by the demonstration that a mutant vaccinia topoisomerase (containing a Tyr----Phe substitution at the active site) that was catalytically inert and did not form the covalent intermediate, nevertheless bound DNA with similar affinity and site selectivity as the wild-type enzyme. Noncovalent binding is therefore independent of competence in transesterification. It is construed that the vaccinia topoisomerase is considerably more stringent in its cleavage and binding specificity for duplex DNA than are the cellular type I enzymes.
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PMID:Specific DNA cleavage and binding by vaccinia virus DNA topoisomerase I. 217 Mar 98

Vaccinia virus encodes a type I DNA topoisomerase whose function in virus replication is not known. To determine whether topoisomerase is required for growth of vaccinia in cell culture, we attempted to isolate null mutations in the topoisomerase gene through insertional mutagenesis. Plasmids containing mutant topoisomerase alleles were constructed by intragenic insertion of the Escherichia coli gpt gene. Recombinant viruses containing the gpt insertion were isolated by selection for growth in the presence of mycophenolic acid. Analysis of the genome structures of drug-resistant viruses revealed that in every case (n = 22) both the wild-type and the gpt-inserted allele were present in viral DNA. We interpret the retention of the wild-type allele as indicative of the essential nature of the topoisomerase gene for vaccinia virus growth.
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PMID:Insertional mutagenesis of the vaccinia virus gene encoding a type I DNA topoisomerase: evidence that the gene is essential for virus growth. 254 48

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