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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An Indian muntjac cell line, SVM, is unusually sensitive to cell killing induced by a range of alkylating agents. Cells transfected with the Escherichia coli ada gene or human genomic DNA have allowed the response of SVM to alkylating agents to be dissociated into two distinct components. Thus, in SVM, which expresses very low levels of alkyltransferase (AT), O6-alkylguanine appears to be the major cytotoxic, clastogenic, and recombinogenic lesion following exposure to agents such as methylnitrosourea (MNU). However, SVM is also very sensitive to agents such as dimethylsulfate (DMS), which produce only very low levels of O6-methylguanine damage. Sensitivity to DMS resides in an inability to complete base excision repair, with the appearance of persistent single-strand DNA breaks (SSBs), and does not appear to involve defects in glycosylase, apurinic/apyrimidinic endonuclease, or DNA ligase activities. Another, possibly related, phenotypic trait in SVM is its limited ability to ligate transfected linear plasmid DNA. Transfectants of SVM, harboring human DNA sequences, show a significant correction of DMS-induced cytotoxicity and clastogenicity and a reduction in the levels of DMS-induced DNA SSBs. The DMS-resistant transfectants have an increased ability to ligate linear plasmid DNA, and also express AT, making these lines resistant to alkylating agents such as MNU. These results suggest that cells possess a mechanism that regulates AT expression, plasmid break-joining ability, and certain aspects of base excision repair. Transfectants of SVM containing human DNA provide a means to isolate genes involved in a coordinate response to alkylation damage.
Somat Cell Mol Genet 1992 Nov
PMID:Characterisation and correction of a mammalian cell mutant defective in late step of base excision repair. 128 51

The incorporation of 6-thioguanine (S6G) in place of guanine proceeds readily in DNA synthesis reactions catalyzed by mammalian and bacterial polymerases. This report summarizes the consequences of such incorporation studied to date. S6G was incorporated into one strand of a defined M13mp18 phage sequence in a (+)reaction catalyzed by the Klenow fragment of Escherichia coli DNA polymerase I. After denaturation of the newly synthesized strand (containing S6G) and annealing with a reverse (-) 32P-labeled primer, polymerization catalyzed by the Klenow enzyme as well as by human DNA polymerases alpha, gamma, and delta was slowed considerably, compared with that across the corresponding guanine-containing template. To evaluate S6G-containing DNA as a substrate for DNA ligases, two oligodeoxynucleotides (19- and 20-mers) antisense to a 40-mer were synthesized so that the 40-mer coded for guanine at the 3' terminus of the 19-mer. After annealing of the synthetic oligonucleotides to form a duplex DNA containing a one-nucleotide gap (opposite cytosine in the 40-mer), the 19-mer was extended with 2'-deoxythioguanosine 5'-triphosphate using DNA polymerase, forming a nicked duplex DNA. The abilities of T4 DNA ligase and HeLa and calf thymus DNA ligase I to join the 5'-phosphate with the 3'-S6G-OH were severely inhibited, compared with the 3'-guanine-extended control. This finding suggests that incorporation of S6G at the 3' terminus of Okazaki fragments would inhibit lagging strand DNA synthesis. In other experiments, cleavage of S6G-containing DNA by some but not all restriction endonucleases progressed poorly, compared with the control guanine-containing DNA, independently of the location of S6G at recognition or cleavage sites, as previously observed by Iwaniec et al. [Mol. Pharmacol. 39:299-306 (1991)] with a different spectrum of enzymes. These findings indicate altered DNA-protein interactions due to S6G incorporation. The poor template function of S6G-containing DNA is consistent with the known delayed cytotoxicity and DNA damage previously reported to occur in S6G-treated cells.
Mol Pharmacol 1992 Nov
PMID:Consequences of 6-thioguanine incorporation into DNA on polymerase, ligase, and endonuclease reactions. 133 62

We isolated a mutant mammalian cell line lacking activity for the DNA repair enzyme 5-hydroxymethyluracil-DNA glycosylase (HmUra-DNA glycosylase). The mutant was isolated through its resistance to the thymidine analog 5-hydroxymethyl-2'-deoxyuridine (HmdUrd). The mutant incorporates HmdUrd into DNA to the same extent as the parent line but, lacking the repair enzyme, does not remove it. The phenotype of the mutant demonstrates that the toxicity of HmdUrd does not result from substitution of thymine in DNA by HmUra but rather from the removal via base excision of large numbers of HmUra residues in DNA. This finding elucidates a novel mechanism of toxicity for a xenobiotic nucleoside. Furthermore, the isolation of this line supports our hypothesis that the enzymatic repairability of HmUra derives not from its formation opposite adenine via the oxidation of thymine, but rather from its formation opposite guanine as a product of the oxidation and subsequent deamination of 5-methylcytosine.
Mol Cell Biol 1992 Dec
PMID:A mammalian cell line deficient in activity of the DNA repair enzyme 5-hydroxymethyluracil-DNA glycosylase is resistant to the toxic effects of the thymidine analog 5-hydroxymethyl-2'-deoxyuridine. 144 84

In this study we present the characterization of the temperature-sensitive mutant allele cdc9-1 encoding DNA ligase, of Saccharomyces cerevisiae strain A364A by DNA sequencing. Comparison with the published wild-type sequence from strain SK1 revealed 13 nucleotide exchanges between these two sequences, which are derived from non-isogenic genetic backgrounds. Only four of these changes, distributed over the whole coding region, lead to amino acid exchanges in the protein chain. Our analysis of the sequence of the wild-type CDC9 allele from strain A364A revealed differences from the isogenic cdc9-1 allele in only two nucleotides: one silent change and one leading to a single amino acid exchange. The latter is therefore responsible for the temperature-sensitive phenotype. A mosaic protein, in which a region carrying this amino acid exchange has been inserted in place of the corresponding part of CDC9 from the non-isogenic strain SK1, is not temperature sensitive. The exchange of a longer stretch of DNA leading to atteration of three amino acids of the protein compared with the original sequence of SK1 is required to obtain a temperature-sensitive DNA ligase in this strain, while in strain A364A a single amino acid change is sufficient for expression of a temperature-sensitive protein.
Mol Gen Genet 1992 Mar
PMID:Temperature sensitivity of the cdc9-1 allele of Saccharomyces cerevisiae DNA ligase is dependent on specific combinations of amino acids in the primary structure of the expressed protein. 155 39

DNA polymerase beta (beta-pol) and its mRNA are maintained at constitutive levels during the cell cycle and during stages of cell growth in culture. To study biological consequences of variations in the level of this DNA repair enzyme and/or its mRNA, we prepared expression vectors in which cDNA for human beta-pol is inserted under the control of a metallothionein promoter (pMT) in the sense and antisense orientation, respectively, and these vectors then were used for stable transformation of mouse 3T3 cells. Vectors also contained the mouse DHFR gene, such that culture of transformants in medium with increasing concentrations of methotrexate resulted in amplification of inserted DNA. The levels of sense and antisense transcripts are strongly increased by culture of transformants in medium with 65 microM Zn2+, although some expression is detected even without Zn2+ induction. After five days of induction, the beta-pol level was about threefold higher in sense cells and about 10-fold lower in antisense cells than in parallel cultures without induction. The antisense line has a threefold increased cell doubling time in the presence of 65 microM Zn2+ compared with the absence of Zn2+. Zn2+ (65 microM) induction for the sense line results in normal growth for the first three days and, thereafter, a complete cessation of growth. Yet, these blocked cells remain fully viable. The results indicate that sudden deregulation of beta-pol expression alters cell growth in mouse 3T3 cells.
Somat Cell Mol Genet 1990 Jul
PMID:Deregulation of DNA polymerase beta by sense and antisense RNA expression in mouse 3T3 cells alters cell growth. 169 88

The yeast 2 microns plasmid is found in the nucleus of almost all Saccharomyces cerevisiae strains. Its replication is very similar to that of chromosomal DNA. Although the plasmid does not encode essential genes it is stably maintained in the yeast population and exhibits only a small, though detectable, loss rate. This stability is achieved by a plasmid-encoded copy-number control system which ensures constant plasmid levels. For the investigation of 2 microns replication, a yeast strain that is absolutely dependent on this plasmid was constructed. This was achieved by disruption of the chromosomal CDC9 gene, coding for DNA ligase and providing this essential gene on a 2 microns-derived plasmid. This plasmid is absolutely stable under all growth conditions tested. Using the temperature-sensitive mutant allele cdc9-1 we have developed an artificial control system which allows one to change the copy number of 2 microns-derived plasmids solely by changing the incubation temperature.
Mol Microbiol 1991 Jun
PMID:A new system for amplifying 2 microns plasmid copy number in Saccharomyces cerevisiae. 178 2

DNA break processing is compared in the Indian muntjac cell lines, SVM and DM. The initial frequencies and resealing of X-ray generated single- and double-strand breaks are similar in the two cell lines. Inhibiting the repair of UV damage leads to greater double-strand breakage in SVM than in DM, and some of these breaks are not repaired; however, repair-associated single-strand breakage and resealing are normal. Dimethylsulfate also induces excess double-strand breakage in SVM, and these breaks are irreparable. Restricted plasmids are reconstituted correctly in SVM at approximately 30% of the frequency observed in DM. Thus SVM has a reduced capacity to repair certain types of double-strand break. This defect is not due to a DNA ligase deficiency. We conclude that DNA double-strand breaks are repaired by a variety of pathways within mammalian cells and that the structure of the break or its mode of formation determines its subsequent fate.
Somat Cell Mol Genet 1990 Sep
PMID:Multiple pathways of DNA double-strand break processing in a mutant Indian muntjac cell line. 217 53

In this review the results of the interaction of the active dyes used in the USSR textile industry with microbial enzymes and blood serum proteins are discussed. The complexity of dye/protein interaction and the dependence of this interaction on different factors is demonstrated. Some practical aspects of the use of dye containing sorbents are presented and discussed. Their suitability for RNA ligase and DNA ligase, acetate kinase, alcohol dehydrogenase, lactate dehydrogenase and glucose-6-phosphate dehydrogenase purification and blood serum protein fractionation is demonstrated.
J Mol Recognit 1990 Jun
PMID:Investigation of dye/protein interaction and its application to enzyme purification. 222 63

The tendency for relatively short (less than 500 base-pair) DNA molecules to circularize in the presence of DNA ligase is a sensitive function of both the lateral and torsional flexibilities of the molecules being studied. This tendency is reflected in a quantity known as the j-factor, which is determined experimentally by measuring the relative rates of circle and linear dimer formation at a specified concentration of linear monomer. Shimada & Yamakawa have provided an analytical representation of j that takes account of DNA molecules whose ends are not torsionally aligned. Their approach, however, assumes that contributions from helix writhe are small. Using a Monte Carlo approach for the determination of j, thereby avoiding any assumptions regarding writhe, we demonstrate that the computed, torsion angle-averaged quantity, [j], is exactly reproduced by the corresponding Shimada & Yamakawa quantity for all lengths examined. However, for DNA molecules having lengths that are substantially greater than the persistence length, P, the analysis of experimental ring-closure data using j (Shimada & Yamakawa) may lead to underestimates for the torsional elastic constant C. We demonstrate that no single set of values for P, C and the helical repeat (hR) can produce a reasonable fit of the computed j curve to the experimental values of Shore et al. This observation suggests that P, C and/or hR vary within the set of DNA molecules studied by those authors. The current computational analysis considers the effects on j of single or multiple bends in the helix axis. For single, centrally located bends, the shift in the distribution of end-to-end separations to smaller values is nearly offset by the less favorable polar alignment of the ends of the chain; the net effect being a modest change in j that is not a monotonic function of the bend angle. In contrast, polar alignment, and hence j, can be enhanced dramatically for molecules containing multiple, phased bends. However, for studies of the distribution of circle sizes formed from ligation of bend-containing DNA oligomers, the DNA lengths giving rise to maximal j values are smaller than predicted on the basis of the number of bends and the per-bend angle. This last result suggests that such studies may yield apparent bend angles that are too large.
J Mol Biol 1990 Mar 20
PMID:Application of the method of phage T4 DNA ligase-catalyzed ring-closure to the study of DNA structure. I. Computational analysis. 231 3

We made use of enhancement of fluorescence anisotropy of protein upon DNA binding to analyze interactions between Ada protein and DNA. Ada protein is a DNA repair enzyme that also acts as a transcription regulator. The isotropic fluorescence was not significantly affected upon interaction with DNA and could not be used as a signal for detection of the binding. The anisotropy did became larger because the binding to DNA reduces diffusion of the protein. The change was reproducible and independent of protein concentration and also independent of the degree of saturation of DNA with the protein when DNA was large; these values can readily be converted to the proportion of the complexed protein. The binding parameters were then determined by direct comparison between experimental and theoretical variations of anisotropy, with increasing concentrations of DNA. The theoretical variations were computed by considering the overlap of potential binding sites on the DNA lattice [McGhee & von Hippel (1974) J. Mol. Biol. 86, 469-489]. Binding does not seem to occur in a cooperative manner. The number of base pairs covered by a protein monomer was 7 +/- 1; this number is independent of the salt concentration. The equilibrium association constant decreased from 4 X 10(7) to 3 X 10(5) M-1 for an increase of NaCl concentration from 0.1 to 0.2 M, thereby indicating the possible involvement of ionic interactions between phosphate groups of DNA and the protein.
 ...
PMID:Interaction of Ada protein with DNA examined by fluorescence anisotropy of the protein. 235 46


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