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Query: EC:1.5.1.3 (
dihydrofolate reductase
)
5,819
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have measured the removal of UV-induced pyrimidine dimers from DNA fragments of the adenosine deaminase (ADA) and
dihydrofolate reductase
(
DHFR
) genes in primary normal human and
xeroderma pigmentosum
complementation group C (XP-C) cells. Using strand-specific probes, we show that in normal cells, preferential repair of the 5' part of the ADA gene is due to the rapid and efficient repair of the transcribed strand. Within 8 h after irradiation with UV at 10 J m-2, 70% of the pyrimidine dimers in this strand are removed. The nontranscribed strand is repaired at a much slower rate, with 30% dimers removed after 8 h. Repair of the transcribed strand in XP-C cells occurs at a rate indistinguishable from that in normal cells, but the nontranscribed strand is not repaired significantly in these cells. Similar results were obtained for the
DHFR
gene. In the 3' part of the ADA gene, however, both normal and XP-C cells perform fast and efficient repair of either strand, which is likely to be caused by the presence of transcription units on both strands. The factor defective in XP-C cells is apparently involved in the processing of DNA damage in inactive parts of the genome, including nontranscribed strands of active genes. These findings have important implications for the understanding of the mechanism of UV-induced excision repair and mutagenesis in mammalian cells.
...
PMID:Xeroderma pigmentosum complementation group C cells remove pyrimidine dimers selectively from the transcribed strand of active genes. 164 89
We have measured removal of pyrimidine dimers in defined DNA sequences in confluent and actively growing normal human and
xeroderma pigmentosum
complementation group C (XP-C) fibroblasts exposed to 10 J/m2 UV-irradiation. In normal fibroblasts 45% and 90% of the dimers are removed from the transcriptionally active adenosine deaminase (ADA) gene within 4 and 24 hours after irradiation respectively. Equal repair efficiencies are found in fragments located entirely within the transcription unit or partly in the 3' flanking region of the ADA gene. The rate and extent of dimer removal from the
dihydrofolate reductase
(
DHFR
) gene is very similar to that of the ADA gene. Repair of the transcriptionally inactive 754 locus is less efficient: 18% and 52% of the dimers are removed within 4 and 24 hours respectively. In spite of the limited overall repair capacity, confluent XP-C fibroblasts efficiently remove dimers from the ADA and
DHFR
genes: about 90% and 50% within 24 hours respectively. The 3' end of the ADA gene is repaired as efficiently as in normal human fibroblasts, but less efficient repair occurs in DNA fragments located in the
DHFR
gene and at the 5' end of the ADA gene. Repair of the inactive 754 locus does not exceed the very slow rate of dimer removal from the genome overall. Confluent and actively growing XP-C cells show similar efficiencies of repair of the ADA,
DHFR
and 754 genes. Our findings suggest the existence of two independently operating pathways directed towards repair of pyrimidine dimers in either active or inactive chromatin. XP-C cells have lost the capacity to repair inactive chromatin, but are still able to repair active chromatin.
...
PMID:The residual repair capacity of xeroderma pigmentosum complementation group C fibroblasts is highly specific for transcriptionally active DNA. 230 42
The limited DNA-excision repair in UV-irradiated nondividing fibroblasts from
xeroderma pigmentosum
complementation group C (XP-C) occurs in localized chromatin regions generating large DNA segments (at least 30-70 kb) free of pyrimidine dimers. A genomic fraction enriched for this DNA was isolated on the basis of the larger size of the repaired fragments after UV-endonuclease treatment and screened for specific genes. It contains more copies per microgram DNA of two transcriptionally active genes, beta-actin and
dihydrofolate reductase
, compared to the remaining DNA but an equal number of copies per microgram DNA of an inactive locus termed 754. We confirmed that the active genes were preferentially repaired by measuring the removal of pyrimidine dimers from specific genomic restriction fragments comprising these sequences. These results mean that a unique set of relatively large chromatin domains are repaired in nondividing XP-C cells, even though most of the DNA remains unrepaired. The repaired domains may be those containing the active genes. This specific repair may account for the relatively high UV-resistance of the nondividing cells. In normal cells, a very rapid repair of a restriction fragment containing the beta-actin gene and slow repair of the 754-containing fragment was detected indicating that a similar domain-oriented repair process also exists in these cells. These results are consistent with the previously discovered rapid repair of active genes compared to bulk DNA. Separate damage-recognition systems may exist in human cells for chromatin domains that contain transcribed regions and those that contain no transcribed regions. The latter system may be deficient in XP-C.
...
PMID:Selective repair of specific chromatin domains in UV-irradiated cells from xeroderma pigmentosum complementation group C. 234 4
DNA repair in man can be described in general terms, but details are still obscure. Excision repair of base damage has a general similarity to the mechanism of the bacterial uvr ABC exonuclease, but the individual roles of at least 15 genes that regulate mammalian excision repair are as yet unknown. The differential repair of specific regions of DNA and of specific genes is highlighted by the clustered mode of repair characteristic of
xeroderma pigmentosum
group C and by the rapid repair of the
dihydrofolate reductase
gene. Cloning of genes that specify repair in man is proceeding slowly, in part, because of confusion by genes that produce only partial correction or nonspecific changes in sensitivity and by phenotypic reversion. In human cells, DNA damage-inducible genes are recognized that may overlap the spectra of other stress-induced proteins, but the relationship of these to any error-prone or recA-like system is unknown and unlikely. Four diseases,
xeroderma pigmentosum
, ataxia telangiectasia, Cockayne syndrome, and Fanconi anemia, have well-documented and significantly increased sensitivities to DNA-damaging agents, and each has recognizable though complex abnormalities in processing DNA damage. In addition, a wide variety of diseases and cellular processes have been ascribed to an association with DNA damage and repair, but the accuracy and significance of these associations are hard to identify.
...
PMID:DNA repair in man. 265 41
DNA methylation was examined in
xeroderma pigmentosum
(XP) cells. The amount of 5-methylcytosine (mC) in DNA from XP cells was about 70% of that in DNA from normal controls. Southern hybridization analysis showed that the HLA-DR alpha gene in XP lymphocyte B cells was differently methylated from normals, but its expression was apparently unaffected. The methylation of
dihydrofolate reductase
, a housekeeping gene, was the same as in controls. The revertants to UV resistance from XP fibroblasts recovered a methylation level close to that of normal cells. Results suggested that XP DNA was undermethylated non-randomly, and that DNA methylation might be associated with DNA repair function.
...
PMID:DNA methylation in xeroderma pigmentosum. 291 67
The survival of UV-irradiated mammalian cells is not necessarily correlated with their overall capacity to carry out DNA repair. Human cells typically remove 80% of the pyrimidine dimers produced by a UV dose of 5 J/m2 within 24 hr. In contrast, a Chinese hamster ovary (CHO) cell line survives UV irradiation equally well while removing only 15% of the dimers. Using a newly developed technique to measure dimer frequencies in single-copy specific sequences, we find that the CHO cells remove 70% of the dimers from the essential
dihydrofolate reductase
(
DHFR
) gene but only 20% from sequences located 30 kilobases or more upstream from the 5' end of the gene in a 24-hr period. Repair-deficient human cells from
xeroderma pigmentosum
complementation group C (XPC) are similar to the CHO cells in overall repair levels, but they are extremely sensitive to killing by UV irradiation. In the XPC cells, we find little or no repair in the
DHFR
gene; in contrast, in normal human fibroblasts and epidermal keratinocytes, greater than 80% of the dimers induced in the gene by 20 J/m2 are removed in 24 hr. Since the CHO and normal human cells exhibit similar UV resistance, much higher than that of XPC cells, our findings suggest a correlation between efficient repair of essential genes and resistance to DNA-damaging agents such as UV light.
...
PMID:Survival of UV-irradiated mammalian cells correlates with efficient DNA repair in an essential gene. 345 59
Previous studies have demonstrated transcription-coupled DNA repair in mammalian genes transcribed by RNA polymerase II but not in ribosomal RNA genes (rDNA), which are transcribed by RNA polymerase I. The removal of UV-induced cyclobutane pyrimidine dimers (CPD) from rDNA in repair-proficient human cells has been shown to be slow but detectable and apparently not coupled to transcription. We studied the induction and removal of CPD from rDNA in cultured cells from two repair-deficient human disorders. Primary
xeroderma pigmentosum
complementation group C (XP-C) cells, whether proliferating or nondividing, removed no CPD from either rDNA strand in 24 h post-UV, a result which supports earlier conclusions that XP-C cells lack the general, transcription-independent pathway of nucleotide excision repair. We also observed lower than normal repair of rDNA in Cockayne's syndrome (CS) cells from complementation groups A and B. In agreement with previous findings, the repair of both strands of the RNA polymerase II-transcribed
dihydrofolate reductase
gene was also deficient relative to that of normal cells. This strongly suggests that the defect in CS cells is not limited to a deficiency in a transcription-repair coupling factor. Rather, the defect may interfere with the ability of repair proteins to gain access to all expressed genes.
...
PMID:Repair in ribosomal RNA genes is deficient in xeroderma pigmentosum group C and in Cockayne's syndrome cells. 751 88
We have studied the effect of caffeine on gene- and strand-specific DNA repair after exposure of Chinese hamster ovary cells and human
xeroderma pigmentosum
complementation group C (XPC) cells to ultraviolet irradiation (UV). In hamster cells, caffeine inhibited the repair of cyclobutane dimers (CPDs) in the
dihydrofolate reductase
(
DHFR
) gene by up to 66% after 8 h of repair incubation. This effect was dose-dependent, with more inhibition at 10 than at 1.5 mM caffeine. The inhibition was due to decreased repair in the transcribed strand of the hamster
DHFR
gene. This decrease in repair of CPDs in the
DHFR
gene correlated with an enhancement of UV-induced cell killing by caffeine. DNA repair was also measured in the overall genome by repair-replication analysis. In hamster cells, caffeine caused a modest enhancement of repair. Caffeine did not produce a significant effect on cell cycle progression up to 8 h after UV irradiation, but it caused a distinct block in early S phase during the 24 h post-irradiation period. In XPC cells, 10 mM caffeine inhibited the removal of CPDs from the transcribed strand of the
DHFR
gene by 92%. The removal of all photoproducts from the overall genome was inhibited by 26% in these cells. Since the residual repair in XPC cells is thought to occur in active genomic regions, we propose that caffeine preferentially inhibits gene-specific repair.
...
PMID:Caffeine inhibits gene-specific repair of UV-induced DNA damage in hamster cells and in human xeroderma pigmentosum group C cells. 776 78
We have measured the gene-specific and strand-specific DNA repair of UV-induced cyclobutane pyrimidine dimers in the p53 tumor suppressor gene in a normal, repair-proficient human fibroblast strain and in fibroblasts from a patient with the repair deficient disorder
xeroderma pigmentosum
, complementation
xeroderma pigmentosum
group C (XP-C). In both cell strains, repair was measured in the p53 gene and in its individual DNA strands. For comparison, the repair also was measured in other genomic regions in these human fibroblast strains, including the housekeeping gene
dihydrofolate reductase
, and two inactive genomic regions, the delta globin gene, and the 754 locus of the X chromosome. In both cell strains, we find that the p53 gene is repaired faster than the
dihydrofolate reductase
gene and much more efficiently than the inactive genomic regions. Selective repair of the transcribed DNA strand of p53 is observed in both human cell strains; the strand bias of repair is particularly distinct in XP-C. Mutations specific to the nontranscribed strand may occur due to replication errors at the sites of unrepaired DNA damage. Therefore, our results predict that the majority of mutations in skin cancers, especially those from patients with XP-C, would occur on the nontranscribed strand of the p53 gene. Indeed, Dumasz et al. (Proc. Natl. Acad. Sci. USA, in press, 1993) report such a strand bias of p53 mutation in skin cancers from XP-C patients.
...
PMID:DNA strand bias in the repair of the p53 gene in normal human and xeroderma pigmentosum group C fibroblasts. 822 75
A UV-resistant revertant (XP129) of a
xeroderma pigmentosum
group A cell line has been reported to be totally deficient in repair of cyclobutane pyrimidine dimers (CPDs) but proficient in repair of 6-4 photoproducts. This finding has been interpreted to mean that CPDs play no role in cell killing by UV. We have analyzed the fine structure of repair of CPDs in the
dihydrofolate reductase
gene in the revertant. In this essential, active gene, we observe that repair of the transcribed strand is as efficient as that in normal, repair-proficient human cells, but repair of the nontranscribed strand is not. Within 4 h after UV at 7.5 J/m2, over 50% of the CPDs were removed, and by 8 h, 80% of the CPDs were removed. In contrast, there was essentially no removal from the nontranscribed strand even by 24 h. Our results demonstrate that overall repair measurements can be misleading, and they support the hypothesis that removal of CPDs from the transcribed strands of expressed genes is essential for UV resistance.
...
PMID:Increased UV resistance of a xeroderma pigmentosum revertant cell line is correlated with selective repair of the transcribed strand of an expressed gene. 842 16
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