EC:5.99.1.3 - FACTA Search

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Query: EC:5.99.1.3 (topoisomerase)
9,911 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transcription of the Bombyx mori fibroin gene in a posterior silk gland extract can be separated into three functional steps on the basis of sensitivity to Sarkosyl: 1) formation of an initiation complex, which is blocked by 0.025% Sarkosyl; 2) conversion of the initiation complex to an elongation complex, a step sensitive to 0.05% Sarkosyl; 3) the subsequent elongation of RNA chain which occurs in the presence of 0.05% Sarkosyl. Whereas the last two steps are rapid and unaffected by template topology, the first step is slow and affected by DNA conformation. In the posterior silk gland extract, closed circular DNA forms a superhelical state and supports more rapid assembly of the initiation complex than linear DNA does. Both DNA supercoiling and rapid assembly of the initiation complex require ATP and are abolished by the addition of a topoisomerase II inhibitor VP16. These results suggest that DNA supercoiling enhances the fibroin gene transcription by facilitating formation of the initiation complex.
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PMID:DNA supercoiling facilitates formation of the transcription initiation complex on the fibroin gene promoter. 245 21

A mitochondrial type II DNA topoisomerase (topoIImt) has been purified to near homogeneity from the trypanosomatid Crithidia fasciculata. A rapid purification procedure has been developed based on the affinity of the enzyme for novobiocin, a competitive inhibitor of the ATP-binding moiety of type II topoisomerases. The purified enzyme is capable of ATP-dependent catenation and decatenation of kinetoplast DNA networks as well as catalyzing the relaxation of supercoiled DNA. topoIImt exists as a dimer of a 132-kDa polypeptide. Immunoblots of whole cell lysates show a single predominant band that comigrates with the 132-kDa polypeptide, indicating that the 264-kDa homodimer represents the intact form of the enzyme. Localization of the enzyme within the single mitochondrion of C. fasciculata (Melendy, T., Sheline, C., and Ray, D. S. (1988) Cell, in press) suggests an important role for topoIImt in kinetoplast DNA replication.
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PMID:Novobiocin affinity purification of a mitochondrial type II topoisomerase from the trypanosomatid Crithidia fasciculata. 253 75

The role of topoisomerase enzymes in the response of HeLa S3 cells to ionizing radiation was investigated. Exposure of cells to 100 Gy of X-radiation had no detectable effect either on the total cellular topoisomerase activity as measured by the relaxation of supercoiled plasmid DNA by cell sonicates or on the total cellular topoisomerase II activity as measured by plasmid DNA catenation. Total topoisomerase II activity remained constant for up to 90 min after cell irradiation. The effect of 2 drugs (caffeine and novobiocin) which inhibit topoisomerase II activity on the HeLa cell response to radiation was determined. Both drugs were found to inhibit topoisomerase II in vitro and to inhibit the recovery of nucleoid sedimentation in irradiated cells in vivo to the same extent. Topoisomerase II was inhibited by 50% by exposure to 10 mM caffeine and 0.79 mM novobiocin. At low concentrations neither drug affected the induction frequency, nor the rejoining rate, of DNA double-strand breaks. Caffeine (5 mM) inhibited the short-term recovery of cells from radiation while novobiocin (0.79 mM) had no detectable effect on the capacity of cells to recover from radiation exposure. The results indicate that topoisomerase II is not required for DNA double-strand break rejoining though it could be required for the recovery of DNA coiling in the irradiated cell. If topoisomerase II is involved at all in cell recovery from irradiation, this role does not apparently involve an ATP-dependent enzyme activity.
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PMID:Topoisomerase activity in irradiated mammalian cells. 253 62

DNA topoisomerase I (Topo I) can exist in several different molecular weight forms in human leukemic cells. The Mr 98,000 form of Topo I was inhibited by several nucleoside triphosphates and their analogues at a 500 microM concentration in the order: dideoxy-GTP greater than 2-bromo-dATP greater than dideoxy-ATP greater than dideoxy-CTP greater than 2-fluoro-dATP greater than 2-chloro-dATP. The same concentration of these nucleoside triphosphates also inhibited the Mr 32,000 and the Mr 35,000 Topo I forms in the order: 2-bromo-dATP greater than dideoxy-GTP greater than 2-fluoro-dATP greater than dideoxy-ATP; however, dideoxy-CTP and 2-chloro-dATP did not inhibit these forms. ATP inhibited both the large and the small molecular weight forms of Topo I at a concentration of 8 mM. DNA topoisomerase II (Topo II) isolated from human leukemic cells requires ATP for its activity. Of the nucleoside triphosphates examined, only dATP could substitute for ATP. In the presence of 500 microM ATP, equimolar concentrations of 2-bromo-dATP, dideoxy-ATP, 2-chloro-dATP, 2-fluoro-dATP, and dideoxy-GTP nucleotide analogues inhibited the unknotting activity of the Topo II enzyme. When the nucleotide analogue concentration was decreased to 250 microM, only 2-bromo-dATP still had a significant inhibitory effect on Topo II. With the exception of 2-bromo-dATP, the analogues studied appeared to inhibit the nicking step of both the Topo I and Topo II enzyme activity. These results differ from previously described mechanisms of inhibition by camptothecin of Topo I and etoposide of Topo II. These enzymatic studies suggest the inhibition of Topo I and Topo II activities could contribute to the cytotoxicity of the respective nucleoside analogues in cell culture, particularly when high concentrations of these nucleoside analogues accumulate as triphosphates inside the cells.
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PMID:Interaction of several nucleoside triphosphate analogues and 10-hydroxycamptothecin with human DNA topoisomerases. 253 24

Circular plasmid DNA was efficiently converted into huge catenated intranuclear networks by incubation with isolated nuclei in the presence of ATP. The network production is abolished by omission of ATP, strongly inhibited by etoposide (VP-16), but only slightly inhibited by antibody to topoisomerase I, indicating that the major enzyme responsible for catenation is DNA topoisomerase II. Under optimal conditions, a single nucleus incorporates about 4.2 x 10(4) DNA rings into its networks. Under the light microscope, networks retrieved from nuclei appear like spheres of various sizes. Sedimentation analysis showed that most of the networks are composed of thousands of catenated rings, which was confirmed by electron microscopy. Data from experiments that caused partial disruption of the networks were submitted to analysis based on probable models of catenane structure. The results suggest that the predominant pattern is a linear alignment of catenated rings. Similar networks are formed when the nuclear scaffold is incubated with circular DNA in the presence of nuclear extract containing topoisomerase II. Titration experiments showed that the scaffold binds a stoichiometric amount of the substrate and that a critical level of DNA is required for network formation. The results are consistent with the idea that DNA-binding sites are fixed on the scaffold and mediate catenation of bound DNA circles by holding them in close proximity to each other. We propose that catenation by the nuclear scaffold also occurs in intact nuclei, suggesting additional roles for the scaffold in vivo.
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PMID:Incorporation of exogenous circular DNA into large catenated networks in isolated nuclei. Evidence for involvement of the nuclear scaffold. 254 Jan 99

DNA topoisomerases are complex and unique enzymes which alter the topological state of DNA without changing its chemical structure. Between the type I and II enzymes, topoisomerases carry out a multitude of reactions, including DNA binding, site specific DNA cleavage/religation, relaxation, catenation/decatenation, and knotting/unknotting of nucleic acid substrates, DNA strand transfer, and ATP hydrolysis. In vivo, topoisomerases are involved in many aspects of nucleic acid metabolism and play critical roles in maintaining chromosome and nuclear structure. Finally, these enzymes are of clinical relevance, as they appear to be the primary cellular targets for many varied classes of antineoplastic agents. Considering the importance of the topoisomerases, it is distressing that we know so little about their enzymatic mechanisms. Many major questions remain. Just a few include, "How do topoisomerases recognize their nucleic acid interaction sites?"; "What amino acid residues comprise the enzymes' active sites?"; "What are the conformational changes that accompany DNA strand passage?"; "How does phosphorylation stimulate enzyme activity?"; "How does topoisomerase function when it is part of an immobilized structure such as the nuclear matrix or the mitotic chromosome scaffold?"; and "How do antineoplastic agents interact with their topoisomerase targets and stabilize covalent enzyme.DNA cleavage products?" Clearly, before the physiological functions of the topoisomerases can be fully described, these and similar issues will have to be addressed. Hopefully, the next several years will produce answers for at least some of these important questions.
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PMID:Biochemical basis for the interactions of type I and type II topoisomerases with DNA. 254 Apr 96

Merbarone has previously been shown to have antitumor activity of unknown mechanism in P388 and L1210 tumor models (A. D. Brewer et al., Biochem. Pharmacol., 34:2047-2050, 1985) and is currently undergoing Phase I clinical trials. Here we report that merbarone is an inhibitor of topoisomerase II. Merbarone inhibited purified mammalian topoisomerase II with a 50% inhibitory concentration of 20 microM, as assessed by ATP-dependent unknotting of P4 phage DNA or relaxation of supercoiled pBR322 plasmid. In contrast to the type II enzyme, inhibition of catalytic activity of topoisomerase I required about 10-fold higher concentrations of merbarone, with a 50% inhibitory concentration of approximately 200 microM. Unlike epipodophyllotoxin analogues and certain DNA intercalative agents which stabilize the topoisomerase II-DNA "cleavable complex," merbarone did not cause detectable topoisomerase II-induced DNA cleavage. Furthermore, merbarone inhibited the production by amsacrine or teniposide of topoisomerase II-associated DNA strand breaks; under identical conditions novobiocin did not decrease these breaks, setting merbarone apart from a novobiocin-like class of topoisomerase II inhibitor. In L1210 cells, merbarone produced only small numbers of protein-associated DNA strand breaks, and only at very high concentrations. Merbarone reduced in a concentration-dependent manner the number of amsacrine- or teniposide-stimulated protein-associated DNA strand breaks in L1210 cells or their isolated nuclei. The data suggest that merbarone represents a novel type of topoisomerase II inhibitor.
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PMID:In vitro and intracellular inhibition of topoisomerase II by the antitumor agent merbarone. 254 Sep 3

Nuclear extracts of 3T6 mouse cells were able to assemble in vitro minichromosomes which displayed a 150-bp periodicity. Activities of both DNA topoisomerases I and II were detected in these extracts. When a supercoiled pUC DNA was added, it was first relaxed in less than 3 min, then slowly supercoiled again in 1-4 h. Both reactions occurred either in the absence or the presence of added Mg2+ and/or ATP, they were not blocked by DNA topoisomerase II inhibitors and they were inhibited by an antiserum against DNA topoisomerase I and by camptothecin. These findings led us to propose that, under our in vitro assay conditions, chromatin assembly is mainly carried out by a DNA topoisomerase I.
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PMID:Requirement of DNA topoisomerases for in vitro chromatin assembly by 3T6 mouse cell extracts. 254 Sep 77

We have isolated DNA polymerases and topoisomerases from two thermoacidophilic archaebacteria: Sulfolobus acidocaldarius and Thermoplasma acidophilum. The DNA polymerases are composed of a single polypeptide with molecular masses of 100 and 85 kDa, respectively. Antibodies against Sulfolobus DNA polymerase did not cross react with Thermoplasma DNA polymerase. Whereas the major DNA topoisomerase activity in S. acidocaldarius is an ATP-dependent type I DNA topoisomerase with a reverse gyrase activity, the major DNA topoisomerase activity in T. acidophilum is a ATP-independent relaxing activity. Both enzymes resemble more the eubacterial than the eukaryotic type I DNA topoisomerase. We have found that small plasmids from halobacteria are negatively supercoiled and that DNA topoisomerase II inhibitors modify their topology. This suggests the existence of an archaebacterial type II DNA topoisomerase related to its eubacterial and eukaryotic counterparts. As in eubacteria, novobiocin induces positive supercoiling of halobacterial plasmids, indicating the absence of a eukaryotic-like type I DNA topoisomerase that relaxes positive superturns.
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PMID:Studies on DNA polymerases and topoisomerases in archaebacteria. 254 77

Incubation of topologically relaxed plasmid DNA with simian virus 40 (SV40) large tumor antigen (T antigen), ATP, and eubacterial DNA topoisomerase I resulted in the formation of highly positively supercoiled DNA. Eukaryotic DNA topoisomerase I could not substitute for eubacterial DNA topoisomerase 1 in this reaction. Furthermore, the addition of eukaryotic topoisomerase I to a preincubated reaction mixture containing both T antigen and eubacterial topoisomerase I caused rapid relaxation of the positively supercoiled DNA. These results suggest that SV40 T antigen can introduce topoisomerase-relaxable supercoils into DNA in a reaction coupled to ATP hydrolysis. We interpret the observed T antigen supercoiling reaction in terms of a recently proposed twin-supercoiled-domain model that describes the mechanics of DNA helix-tracking processes. According to this model positive and negative supercoils are generated ahead of and behind the moving SV40 T antigen, respectively. The preferential relaxation of negative supercoils by eubacterial DNA topoisomerase I explains the accumulation of positive supercoils in the DNA template. The supercoiling assay using DNA conformation-specific eubacterial DNA topoisomerase I may be of general use for the detection of ATP-dependent DNA helix-tracking proteins.
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PMID:Template supercoiling during ATP-dependent DNA helix tracking: studies with simian virus 40 large tumor antigen. 254 99

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