Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.4.2.7 (adenine phosphoribosyltransferase)
 692 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have examined the clonal variation in rates of amino acid transport, protein synthesis, protein degradation, growth and proliferation for CHO cells with mutations in the purine and pyrimidine salvage pathways. First we compared three clonal cell lines, each with a different mutation, with the heterozygous parental line AT3-2. Overall, the correlation between rates of protein turnover, growth and proliferation was excellent. The slower growth and proliferation of one mutant, AB3 (TK-, APRT-), is explained by a low intrinsic rate of protein synthesis coupled with a smaller response in rates of amino acid transport, protein synthesis and protein degradation to insulin, serum and dexamethasone. Secondly, we compared seven aza-adenine-resistant and 14 thioguanine-resistant mutants of AT3-2 and found significant differences in control and insulin-stimulated rates of protein turnover both within and between mutant populations. A significant difference between the populations was unexpected because each individual cell line was cloned from a spontaneous pre-existing mutation in AT3-2, and each population should have the same average rate. Remarkably, all 24 mutants had lower rates of protein synthesis than AT3-2. We cannot explain the data solely in terms of mutations in the salvage pathways. Rather, we propose that the mutant survivors have randomly down-regulated the intrinsically fixed growth factor-regulated pathways of protein turnover, resulting in a broad spectrum of lower metabolic rates.
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PMID:Protein turnover, growth and proliferation in CHO cells. Variation within and between mutant classes for salvage pathway enzymes. 154 Jan 46

The initiation of carcinogenesis by carcinogens such as 7r,8t-dihydroxy-9,10t-oxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE-I) is thought to involve the formation of DNA adducts. However, the diastereomeric diol epoxide, 7r,8t-dihydroxy-9,10c-oxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE-II), also forms DNA adducts but is inactive in standard carcinogenesis models. We have measured the formation and loss of DNA adducts derived from BPDE-II in a DNA-repair-proficient line of Chinese hamster ovary (CHO) cells, AT3-2, and in two derived mutant cell lines, UVL-1 and UVL-10, which are unable to repair bulky DNA adducts. BPDE-II adducts were lost from cellular DNA in AT3-2 cells with a half-life of 13.8 h; this was about twice the rate found for BPDE-I adducts. BPDE-II adducts were also lost from DNA in UVL-1 and UVL-10 cells, but at a much slower rate. When purified DNA was modified in vitro with BPDE-II and then held at 37 degrees C, DNA adducts were removed at a rate identical to that seen in UVL-1 and UVL-10 cells, suggesting that the loss in these cells was not due to enzymatic DNA-repair processes but to chemical lability of the adducts. Mutant frequencies at the APRT and HPRT loci were measured at BPDE-II doses that resulted in greater than 20% survival, and were found to increase linearly with dose. In the DNA-repair-deficient cells, the HPRT locus was moderately hypermutable compared with AT3-2 cells (about 5-fold); the APRT locus was extremely hypermutable, giving about 25-fold higher mutant fractions in UVL-1 and UVL-10 than in AT3-2 cells at equal initial levels of binding. When we compared the mutational efficiency of BPDE-II at both loci in AT3-2 cells (the mutant frequency in mutants/10(6) survivors at a dose that resulted in one adduct per 10(6) base pairs) with our previous studies of BPDE-1, we found that BPDE-II was 4-5 times less efficient as a mutagen than BPDE-I. This difference in mutational efficiency could be explained in part by the increased rate of loss of BPDE-II adducts from the cellular DNA, part of which was due to an increased rate of enzymatic removal of these lesions compared with the removal of BPDE-I adducts.
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PMID:Differences in the rate of DNA adduct removal and the efficiency of mutagenesis for two benzo[a]pyrene diol epoxides in CHO cells. 172 82

Reports describing short (less than 20 bp) gene deletions causing human genetic disease were collated in order to study underlying causative mechanisms. Deletion breakpoint junction regions were found to be non-random both at the nucleotide and dinucleotide sequence levels, an observation consistent with an endogenous sequence-directed mechanism of mutagenesis. Direct repeats of between 2bp and 8bp were found in the immediate vicinity of all but one of the 60 deletions analysed. Direct repeats are a feature of a number of recombination, replication or repair-based models of deletion mutagenesis and the possible contribution of each to the spectrum of mutations examined was assessed. The influence of parameters such as repeat length and length of DNA between repeats was studied in relation to the frequency, location and extent of these deletions. Findings were broadly consistent with a slipped mispairing model but the predicted deletion of one whole repeat copy was found only rarely. A modified version of the slipped mispairing hypothesis was therefore proposed and was shown to possess considerable explanatory value for approximately 25% of deletions examined. Whereas the frequency of inverted repeats in the vicinity of gene deletions was not significantly elevated, these elements may nevertheless promote instability by facilitating the formation of secondary structure intermediates. A significant excess of symmetrical sequence elements was however found at sites of single base deletions. A new model to explain the involvement of symmetric elements in frameshift mutagenesis was devised, which successfully accounted for a majority of the single base deletions examined. In general, the loss of one or a few base pairs of DNA was found to be more compatible with a replication-based model of mutagenesis than with a recombination or repair hypothesis. Seven hitherto unrecognized hotspots for deletion were noted in five genes (AT3, F8, HBA, HBB and HPRT). Considerable sequence homology was found between these different sites, and a consensus sequence (TGA/GA/GG/TA/C) was drawn up. Sequences fitting this consensus (i) were noted in the immediate vicinity of 41% of the other (sporadic) gene deletions, (ii) were found frequently at sites of spontaneous deletion in the hamster APRT gene, (iii) were found to be associated with many larger human gene deletions/translocations, (iv) act as arrest sites for human polymerase alpha during DNA replication and (v) have been shown by in vitro studies of human polymerase alpha to be especially prone to frameshift mutation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Gene deletions causing human genetic disease: mechanisms of mutagenesis and the role of the local DNA sequence environment. 201 84

The CHO-AT3-2 Chinese hamster ovary cell line is functionally hemizygous for the adenine phosphoribosyltransferase (APRT; EC 2.4.2.7) locus. Class 1 APRT +/- heterozygotes, such as CHO-AT3-2, can be isolated at high spontaneous frequencies from wild-type CHO cell populations. Simon et al. [Simon, A. E., Taylor, M. W., Bradley, W. E. C. & Thompson, L. (1982) Mol. Cell. Biol. 2, 1126-1133] have proposed that a high-frequency event that inactivates one APRT allele might be responsible for both the spontaneous generation of class 1 APRT +/- heterozygotes and the high-frequency occurrence of APRT- mutants in class 2 APRT +/- heterozygote populations. This event appears to occur at only one of the two APRT alleles. To investigate the nature of this high-frequency event, and to determine the genetic basis for functional hemizygosity of the APRT locus in CHO-AT3-2 cells, we have mapped the APRT locus by using CHO-AT3-2-mouse somatic cell hybrids. Our data confirm that CHO-AT3-2 cells have a single functional APRT allele, which is located on the Z7 chromosome. Karyotypic analysis of CHO-AT3-2 revealed an interstitial deletion on the long arm of the Z4 chromosome, in the very region where the other APRT allele should be located. To determine whether the Z4q interstitial deletion had resulted in physical loss of the APRT gene, DNA from CHO-AT3-2-mouse cell hybrids that had either lost or retained the Z4q- chromosome was analyzed for the presence of CHO APRT coding sequences. Our data suggest that allele-specific high-frequency structural gene deletion events involving the long arm of chromosome Z4 are responsible for the spontaneous generation of functional hemizygosity at the APRT locus in CHO cells.
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PMID:High-frequency structural gene deletion as the basis for functional hemizygosity of the adenine phosphoribosyltransferase locus in Chinese hamster ovary cells. 631 Jun 7

As a first step in the development of a multiple-marker, mammalian cell mutagenesis assay system, we have isolated a Chinese hamster ovary (CHO) cell line that is heterozygous for both the adenine phosphoribosyltransferase (aprt) and thymidine kinase (tk) loci. Presumptive aprt+/- heterozygotes with intermediate levels of APRT activity were selected from unmutagenized CHO cell populations on the basis of resistance to low concentrations of the adenine analog, 8-azaadenine. a functional aprt+/ heterozygote with approximately 50% wild-type APRT activity was subsequently used to derive sublines that were also heterozygous for the tk locus. Biochemical and genetic characterization of one such subline, CHO-AT3-2, indicated that it was indeed heterozygous at both the aprt and tk loci. CHO-AT3-2 cells permitted single-step selection of mutants resistant for 8-azaadenine or 5-fluorodeoxyuridine, allowing quantitation and direct comparison of mutation induction at the autosomal aprt or tk loci, as well as in the gene involved in ouabain resistance or at the X-linked, hypoxanthine--guanine phosphoribosyltransferase (hgprt) locus. Significant dose-dependent increases in mutation frequency were observed for all 4 genetic markers after treatment of CHO-AT3-2 cells with ethyl methanesulfonate.
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PMID:Mutagenicity testing in mammalian cells. I. Derivation of a Chinese hamster ovary cell line heterozygous for the adenine phosphoribosyltransferase and thymidine kinase loci. 644 63

Using Uvr proteins we have quantified benzo(a)pyrene diol epoxide (BPDE)-DNA adduct formation and repair at the dihydrofolate reductase (DHFR) and adenine phosphoribosyltransferase (APRT) genes in two Chinese hamster ovary cell lines: B-11 cells, which are 50-fold amplified for DHFR, and AT3-2 cells, which are diploid for DHFR. We have found that: 1) BPDE-DNA adduct formation in different regions of the DHFR gene is proportional to the concentration of BPDE. 2) There is no significant difference in the repair of BPDE-DNA adducts between the coding and noncoding regions in either amplified or nonamplified DHFR gene domains. 3) Repair in the nonamplified DHFR gene is more efficient (30-40%) than in the amplified DHFR genes. 4) There are no significant differences of repair in the transcribed or nontranscribed strands of the DHFR gene. 5) BPDE-DNA adduct formation and repair in the APRT gene in B-11 and AT3-2 cells are the same. These results contrast those for the repair of cyclobutane pyrimidine dimers, which occurs preferentially in the transcribed strand of the DHFR gene and in which gene amplification appears to play no role.
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PMID:Repair of benzo(a)pyrene diol epoxide- and UV-induced DNA damage in dihydrofolate reductase and adenine phosphoribosyltransferase genes of CHO cells. 817 87