EC:2.7.7.7 - FACTA Search

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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)

DNA polymerase I has been purified to greater than 90% homogeneity from a strain of Escherichia coli K12 that bears the temperature-sensitive DNA polymerase I mutatation, polA12. The mutant enzyme has a reduced electrophoretic mobility and sedimentation rate. It is abnormally thermolabile and is rapidly inactivated at low salt concentrations. Its polymerase and 5' leads to 3' exonuclease activities are not grossly defective at 30 degrees, yet its capacity to promote the concerted 5' leads to 3' polymerization and the 5' leads to 3' exonucleolytic hydrolysis of nucleotides at a nick ("nick translation") is decreased 10-fold. These effects are probably the result of a significant alteration in the tertiary structure of the enzyme.
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PMID:Biochemical characterization of mutant forms of DNA polymerase I from Escherichia coli. I. The polA12 mutation. 0 70

1. Acridine Orange inhibits growth of Escherichia coli K12 when incubated at pH 7.9, but not at pH 7.4.2. At a non-permissive temperature for DNA polymerase I, Acridine Orange inhibits growth of a temperature-sensitive strain and also increases the rate of elimination of the F'-Lac plasmid. 3. DNA isolated from cells treated with Acridine Orange under conditions that inhibit growth contains material of low molecular weight, which is absent from DNA isolated from cells treated under conditions in which growth is not impaired. 4. Cells incubated with Acridine Orange at both pH 7.4 and 7.9 suffer degradation of DNA, as shown by loss of labelled DNA from the acid-insoluble fraction, which is not observed with untreated cells at either pH. 5. The results suggest that elimination of the F'-Lac plasmid by Acridine Orange requires inactivation of repair processes.
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PMID:The effects of acridine orange on deoxyribonucleic acid in Escherichia coli. 2 67

Inhibition of DNA polymerase from oncorna viruses by a new class of macromolecular inhibitors is reported. The macromolecule, designated as mercaptopolycytidylic acid (MPC), is a chemically modified polycytidylic acid containing 5-SH cytidylic bases in the polymerase. Partially thiolated polycytidylic acids (MPC I-III, containing 1.7%, 3.5%, and 8.6% 5-mercaptocytidylate units, respectively) inhibited the DNA-polymerase of Friend leukemia virus (FVL) in the endogenic reaction as well as in the presence of poly rA-(dT)14 or poly (dA-dT) templates; the inhibitory activities were directly related to the percent of tholation. In a bacterial DNA polymerase (E coli-K12 with denatured calf thymus DNA as template) MPCI-III showed no activity. Biological experiments showed that MPC III inhibits the leukemogenic potential of cell-free spleen extracts from FVL-infected mice to about 60%, measured on the basis of spleen weight. The enzymatic and animal experiments have led us to carry out preliminary clinical trials in some cases of Children leukemia. These cases, resistent to the known therapeutic regimes (combination chemotherapy), responded well when treated with MPC along, or in combination with poly I. The experiments indicate that the development of modified polynucleotids with structural similarities to functional templates may be of potential use in the future chemotherapy of leukemia.
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PMID:[Inhibition of viral reverse transcriptase and leukemogenesis by modified nucleic acids (author's transl)]. 4 86

Evidence from various sources in the literature suggests that, in connection with DNA, ATP dephosphorylation can be used to provide energy for mechanical effects. Starting from this concept we have studied a novel DNA-dependent ATPase purified to 90% homogeneity from Escherichia coli. The enzyme has a peptide weight near 180 000 and, in high salt, is a monomeric, probably highly anisometric molecule. In salt-free buffer, where the ATPase activity is highest, the enzyme forms aggregates. ATP is the preferred substrate (Km 0.27 mM) and dephosphorylated at the gamma-position at a maximal rate near 10(4) molecules per enzyme monomer per min at 35 degrees C. A requirement for divalent cation is best satisfied by Mg2+ or Ca2+ and the requirement for DNA best by the single-stranded, circular DNA of phages phiX174 (Km 62 nM nucleotide) and fd indicating that the enzyme recognizes internal DNA regions. When saturated with E. coli DNA unwinding protein phiX DNA is not accepted but, once in contact with the DNA, the enzyme is little inhibited by unwinding protein. Apparently the unwinding protein interferes preferentially with the recognition of DNA. The enzyme does not detectably cleave DNA, and for this and genetic reasons is not identical with the recBC ATPase or the K12 restriction ATPase of the extracted cells. The enzyme is probably not identical either with the dnaB-product-associated ATPase or the ATPase activity found in DNA polymerase III holoenzyme under appropriate conditions, and it is certainly not identical with a DNA-dependent ATPase of molecular weight 69 000 from E. coli which has recently been purified. Attempts to ascribe the enzyme to other genes, including recA, lex and rep, have failed.
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PMID:Enzymic unwinding of DNA. 1. Purification and characterization of a DNA-dependent ATPase from Escherichia coli. 13 22

The induction of prophage lambda by ultraviolet light has been measured in E. coli K12 lysogenic cells deficient in DNA polymerase I. The efficiency of the induction process was greater in polA1 polC(dnaE) double mutants incubated at the temperature that blocks DNA replication than in polA+ polC single mutants. Similarly, the polA1 mutation sensitized tif-promoted lysogenic induction in a polA1 tif strain at 42 degrees. In strains bearing the polA12 mutation, which growth normally at 30 degrees, induction of the prophage occurred after the shift to 42 degrees. It is concluded that dissapearance of the DNA polymerase I activity leads to changes in DNA replication that are able, per se, trigger the prophage induction process.
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PMID:Prophage induction in Escherichia coli K12 cells deficient in DNA polymerase I. 33 8

Toluene treated cells have been used to study the processes of DNA synthesis and DNA degradation in ultra-violet irradiated Escherichia coli K12. Synthesis and degradation are both shown to occur extensively if polynucleotide ligase is inhibited, and to occur to a much lesser extent if ligase activity is optimal. Extensive UV-induced DNA synthesis in toluene-treated cells requires ATP for the initial incision step, and DNA polymerase I. Extensive degradation also depends on the early ATP-dependent incision step, and the subsequent degradation shows a partial requirement for ATP. Curtailment of degradation by ligase requires DNA polymerase activity, but is not dependent upon DNA polymerase I. Apparently this process can be carried out with equal facility by either DNA polymerase II or polymerase III. These observations suggest that extensive DNA polymerase I-dependent repair synthesis and extensive DNA degradation are facets of two divergent pathways of excision repair, both of which depend upon the early uvrABC determined ATP-dependent incision step.
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PMID:DNA synthesis and degradation in UV-irradiated toluene treated cells of E. coli K12: the role of polynucleotide ligase. 34 Sep 17

DNA polymerase I produced by infection of Escherichia coli K12 with the specialized transducing phage lambdapolA has been purified by a simplified procedure and shown to be identical with the enzyme produced by uninfected E. coli in all aspects which have been examined. The abundance of the enzyme in infected cells and the ease with which it may be purified will simplify the study of the enzyme's physical and chemical characteristics. In addition, the enzyme is now much more readily available for use as an analytical tool in nucleic acid sequence and structure studies.
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PMID:A rapid procedure for isolation of large quantities of Escherichia coli DNA polymerase I utilizing a lambdapolA transducing phage. 37 87

Synthesis of DNA complementary to the transferred strand of an IncI alpha plasmid has been shown previously to require DNA polymerase III. The possible involvement of the two defined priming proteins of Escherichia coli K12, RNA polymerase and primase, in initiating this conjugal DNA synthesis had been examined. Primase was inactivated using temperature-sensitive dnaG3 mutants and RNA polymerase was inhibited using rifampicin. When these two proteins were simultaneously inactivated in both parental strains, the average recipient synthesised at least one single-stranded equivalent of R144drd-3 before the rifampicin-treated donors lost the ability to transmit DNA. It is proposed that the product of a plasmid transfer gene is responsible for initiating this DNA synthesis in recipients. The results imply that this protein is supplied by the donors.
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PMID:A novel priming system for conjugal synthesis of an IncI alpha plasmid in recipients. 39 29

The effects of eight different polA alleles on the replication of six different non-transferring enterobacterial plasmids have been tested. Using phage P1CM transduction, different allelic polA mutations were introduced into E. coli K12 strains carrying one of several antibiotic resistance plasmids. Plasmid stability in the transductants was examined by testing clones for drug resistance after growth under various conditions. From the results, the R factors may be divided into three different classes. One plasmid is only affected by PolA conditions which inhibit host cell growth, 3 plasmids (from the same compatibility group) are unstable under conditions in which the cells are severely deficient in DNA polymerase I and two other plasmids (compatible with each other and with the other 4) are immediately lost from such transductants and are unstable in a number of others. Furthermore, the plasmids which are most dependent on DNA polymerase I have been shown to replicate in the presence of chloramphenicol and therefore typigy a class of plasmids which includes bacteriocinogenic factors such as ColE1 and CloDF13, resistance determinant RSF1030 and the E. coli 15 minicircular plasmid.
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PMID:Effects of different alleles of the E. coli K12 pol A gene on the replication of non-transferring plasmids. 76 63

DNA polymerase I has been purified to homogeneity from an Escherichia coli K12 strain bearing the temperature-sensitive conditionally lethal mutation, polAex1. The purified enzyme shows no defect in its polymerase or 3' leads to 5'-exonuclease activities; however, its 5' leads to 3'-exonuclease activity is abnormally low at both 30 degrees and 43 degrees. Although the mutant enzyme is able to catalyze the coordinated 5' leads to 3' polymerization and 5' leads to 3' exonucleolytic hydrolysis of nucleotides at a nick in duplex DNA ("nick translation") at a measurable rate at 30 degrees, this reaction is undetectable at 43 degrees. This defect is very likely responsible for the retarded joining of nascent DNA fragments and the consequent loss of viability that occur in the mutant at this temperature.
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PMID:Biochemical characterization of mutant forms of DNA polymerase I from Escherichia coli. II. The polAex1 mutation. 77 79

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