Strand-selective repair of DNA damage in the yeast GAL7 gene requires RNA polymerase II

The Efficiency of Global Genome-Nucleotide Excision Repair is Linked to the Fraction of Open rRNA Gene Chromatin, in Yeast

The yeast rDNA locus is a suitable model to study nucleotide excision repair (NER) in chromatin. A portion of rRNA genes is transcribed and largely depleted of nucleosomes, the remaining genes are not transcribed and folded in nucleosomes. In G1-arrested cells, most rRNA genes do not have nucleosomes. TC-NER removes UV-induced DNA lesions from the transcribed strand of active genes. GG-NER is less efficient and removes DNA lesions from the nontranscribed strand of active genes and from the inactive genome. Different from mammalian cells, in yeast, the rRNA gene-transcribed strand is repaired by RNA polymerase-I-dependent TC-NER. The opposite nontranscribed strand is repaired faster than both strands of inactive rRNA genes. In log-phase cells, RNA polymerase-I are dislodged from the damaged transcribed strand and partially replaced by nucleosomes. Contrary to log-phase cells, in G1-phase cells few, if any, histones are deposited on the open rRNA genes during NER. In this study, we compared GG-NER efficiency in the rRNA gene coding region: without nucleosomes, partially loaded or wholly loaded with nucleosomes. The results indicate that in log-phase cells histones obstruct GG-NER, whereas in G1-phase cells GG-NER is as efficient as TC-NER.

Distinct associations of the Saccharomyces cerevisiae Rad9 protein link Mac1-regulated transcription to DNA repair

While it is known that ScRad9 DNA damage checkpoint protein is recruited to damaged DNA by recognizing specific histone modifications, here we report a different way of Rad9 recruitment on chromatin under non DNA damaging conditions. We found Rad9 to bind directly with the copper-modulated transcriptional activator Mac1, suppressing both its DNA binding and transactivation functions. Rad9 was recruited to active Mac1-target promoters (CTR1, FRE1) and along CTR1 coding region following the association pattern of RNA polymerase (Pol) II. Hir1 histone chaperone also interacted directly with Rad9 and was partly required for its localization throughout CTR1 gene. Moreover, Mac1-dependent transcriptional initiation was necessary and sufficient for Rad9 recruitment to the heterologous ACT1 coding region. In addition to Rad9, Rad53 kinase also localized to CTR1 coding region in a Rad9-dependent manner. Our data provide an example of a yeast DNA-binding transcriptional activator that interacts directly with a DNA damage checkpoint protein in vivo and is functionally restrained by this protein, suggesting a new role for Rad9 in connecting factors of the transcription machinery with the DNA repair pathway under unchallenged conditions.

RNA Polymerase-I-Dependent Transcription-coupled Nucleotide Excision Repair of UV-Induced DNA Lesions at Transcription Termination Sites, in Saccharomyces cerevisiae

If not repaired, ultraviolet light-induced DNA damage can lead to genome instability. Nucleotide excision repair (NER) of UV photoproducts is generally fast in the coding region of genes, where RNA polymerase-II (RNAP2) arrest at damage sites and trigger transcription-coupled NER (TC-NER). In Saccharomyces cerevisiae, there is RNA polymerase-I (RNAP1)-dependent TC-NER, but this process remains elusive. Therefore, we wished to characterize TC-NER efficiency in different regions of the rDNA locus: where RNAP1 are present at high density and start transcription elongation, where the elongation rate is slow, and in the transcription terminator where RNAP1 pause, accumulate and then are released. The Rpa12 subunit of RNAP1 and the Nsi1 protein participate in transcription termination, and NER efficiency was compared between wild type and cells lacking Rpa12 or Nsi1. The presence of RNAP1 was determined by chromatin endogenous cleavage and chromatin immunoprecipitation, and repair was followed at nucleotide precision with an assay that is based on the blockage of Taq polymerase by UV photoproducts. We describe that TC-NER, which is modulated by the RNAP1 level and elongation rate, ends at the 35S rRNA gene transcription termination site.

Transcription arrest at DNA damage sites

Transcription arrest by RNA polymerase II at a DNA damage site on the transcribed strand is considered an essential step in initiation of transcription-coupled repair (TCR), a specialized repair pathway, which specifically removes lesions from transcribed strands of expressed genes. To understand how initiation of TCR occurs, it is necessary to characterize the properties of the transcription complex when it encounters a lesion in its path. The analysis of different types of arrested complexes should help us understand how an arrested RNA polymerase may signal the repair proteins to initiate a repair event. This article will review the recent literature describing how the presence of DNA damage along the DNA affects transcription elongation by RNA polymerase II and its implications for the initial steps of TCR.

Characterization of ERCC3 mutations in the Chinese hamster ovary 27-1, UV24 and MMC-2 cell lines

Mutation of the XPB gene in humans gives rise to the distinct, autosomal recessive disorder, with a striking clinical heterogeneity: xeroderma pigmentosum associated with Cockayne's syndrome and trichothiodystrophy. XPB is a subunit of a multifunctional RNA polymerase II general initiation factor TFIIH and codes for 3'-->5' DNA helicase essential for both nucleotide excision repair (NER) and transcription. Since XPB defective human disease is extremely rare, Chinese hamster ovary (CHO) mutant cell lines belonging to the 3rd rodent complementation group (the hamster ERCC3 gene is the homologue of the human XPB gene) are a unique resource for analyzing structure-function relationships in the ERCC3/XPB protein. We have amplified, cloned and sequenced the ERCC3 genes from wild type and 27-1, UV24 and MMC-2 CHO mutant cell lines and identified the sites of the respective mutations. 27-1 mutant has an A1075G transition (K359E) located at the very beginning of the Ia helicase domain which causes deficiency in open complex formation and in 3', 5' and dual incisions during NER. UV24 cell line has two mutations. First, it is a T1144C transition (S382P) located behind the Ia helicase domain in a region responsible for ERCC3 binding to XPG, p62 and p44. Second mutation is identical with a mutation in MMC-2 mutant. It is a C2215T transition (Q739STOP) causing the truncation of the C-terminus of the protein, responsible for the 5' incision, by 44 amino acids. All mutant cell lines are unable to recover RNA synthesis after 10Jm(-2) UV, suggesting a defect in transcription-coupled repair. Their limited global NER capacity measured by a single-cell gel electrophoresis assay (0.25Jm(-2)) varies from 6% to 11%.

UV-induced de novo protein synthesis enhances nucleotide excision repair efficiency in a transcription-dependent manner in S. cerevisiae

DNA damage results in the up-regulation of several genes involved in different cellular physiological processes, such as the nucleotide excision repair (NER) mechanism that copes with a broad range of DNA alterations, including the carcinogenic ultraviolet (UV) light-induced pyrimidine dimers (PDs). There are two NER sub-pathways: transcription coupled repair (TCR) that is specific for the transcribed strands (TS) of active genes and global genomic repair (GGR) that repairs non-transcribed DNA sequences (NTD) and the non-transcribed strands (NTS) of expressed genes. To elucidate the role of UV-dependent de novo protein synthesis in nucleotide excision repair in the budding yeast, we investigated the effect of the protein synthesis inhibitor, cycloheximide, on the removal of PDs. Log phase as well as G(1)-synchronized cells were treated with the drug shortly before UV irradiation and immediately thereafter, and the repair of damaged DNA was assessed with the high resolution primer extension technique. The results show that in both cellular conditions, the inhibition of UV-dependent de novo protein synthesis by cycloheximide impairs the excision repair of the transcriptionally active GAL10 and URA3 genes, with a greater effect on the non-transcribed strands. This indicates that UV-mediated de novo protein synthesis is required for efficient nucleotide excision repair, but not for the preferential repair of the TSs. On the other hand, cycloheximide did not affect the repair of either strand of the repressed GAL10 gene or the non-transcribed promoter region of the URA3 gene, showing that UV-induced de novo protein synthesis is not required for PD removal from transcriptionally inactive DNA sequences. Together, these data show that despite the fact that NTD and NTSs are normally repaired by the GGR sub-pathway, their requirement for UV-dependent de novo protein synthesis is different, which may suggest a difference in the processing of UV lesions in these non-transcribed sequences of the genome.

In UV-irradiated Saccharomyces cerevisiae, overexpression of Swi2/Snf2 family member Rad26 increases transcription-coupled repair and repair of the non-transcribed strand

Nucleotide excision repair (NER) in eukaryotes is a pathway conserved from yeast to humans that removes many bulky chemical adducts and UV-induced photoproducts from DNA in a relatively error-free manner. In addition to the recognition and excision of DNA damage throughout the genome (GGR), there exists a mechanism, transcription-coupled nucleotide excision repair (TCR), for recognizing some types of DNA damage in the transcribed strand of genes in Escherichia coli, yeast and mammalian cells. An obstacle in the repair of the transcribed strand of active genes is the RNA polymerase complex stalled at sites of DNA damage. The stalled RNA polymerase complex may then mediate recruitment of repair proteins to damage in the transcribed strand. Proteins enabling TCR are the Cockayne syndrome B (CSB) protein in humans and its yeast homologue Rad26. Both CSB and Rad26 belong to the Swi2/Snf2 family of DNA-dependent ATPases, which change DNA accessibility to proteins by altering chromatin structure. To address how Rad26 functions in yeast repair, we used the genetic approach of overexpressing Rad26 and examined phenotypic changes, i.e. changes in NER. We found that repair of both the transcribed and the non-transcribed strands is increased. In addition, overexpression of Rad26 partially bypasses the requirement for Rad7 in GGR, specifically in the repair of non-transcribed sequences. As TCR takes place in very localized regions of DNA (i.e. within genes) in wild-type cells, we propose that overexpression of recombinant Rad26 increases accessibility of the damaged DNA in chromatin for interaction with repair proteins.

Dissecting transcription-coupled and global genomic repair in the chromatin of yeast GAL1-10 genes

Transcription-coupled repair (TCR) and global genomic repair (GGR) of UV-induced cyclobutane pyrimidine dimers were investigated in the yeast GAL1-10 genes. Both Rpb9- and Rad26-mediated TCR are confined to the transcribed strands, initiating at upstream sites approximately 100 nucleotides from the upstream activating sequence shared by the two genes. However, TCR initiation sites do not correlate with either transcription start sites or TATA boxes. Rad16-mediated GGR tightly correlates with nucleosome positioning when the genes are repressed and are slow in the nucleosome core and fast in linker DNA. Induction of transcription enhanced GGR in nucleosome core DNA, especially in the nucleosomes around and upstream of the transcription start sites. Furthermore, when the genes were induced, GGR was slower in the transcribed regions than in the upstream regions. Finally, simultaneous deletion of RAD16, RAD26, and RPB9 resulted in no detectable repair in all sites along the region analyzed. Our results suggest that (a). TCR may be initiated by a transcription activator, presumably through the loading of RNA polymerase II, rather than by transcription initiation or elongation per se; (b). TCR and nucleosome disruption-enhanced GGR are the major causes of rapid repair in regions around and upstream of transcription start sites; (c). transcription machinery may hinder access of NER factors to a DNA lesion in the absence of a transcription-repair coupling factor; and (d). other than GGR mediated by Rad16 and TCR mediated by Rad26 and Rpb9, no other nucleotide excision repair pathway exists in these RNA polymerase II-transcribed genes.

Transcription arrest at a lesion in the transcribed DNA strand in vitro is not affected by a nearby lesion in the opposite strand

Cis-syn cyclobutane pyrimidine dimers (CPDs) are the most frequently formed lesions in UV-irradiated DNA. CPDs are repaired by the nucleotide excision repair pathway. Additionally, they are subject to transcription-coupled DNA repair. In the general model for transcription-coupled DNA repair, an RNA polymerase arrested at a lesion on the transcribed DNA strand facilitates repair by recruiting the repair machinery to the site of the lesion. Consistent with this model, transcription experiments in vitro have shown that CPDs in the transcribed DNA strand interfere with the translocation of prokaryotic and eukaryotic RNA polymerases. Here, we study the behavior of RNA polymerase when transcribing a template that contains two closely spaced lesions, one on each DNA strand. Similar DNA templates containing no CPD, or a single CPD on either the transcribed or the nontranscribed strand were used as controls. Using an in vitro transcription system with purified T7 RNA polymerase (T7 RNAP) or rat liver RNAP II, we characterized transcript length and efficiency of transcription in vitro. We also tested the sensitivity of the arrested RNAP II-DNA-RNA ternary complex, at a CPD in the transcribed strand, to transcription factor TFIIS. The presence of a nearby CPD in the nontranscribed strand did not affect the behavior of either RNA polymerase nor did it affect the reverse translocation ability of the RNAP II-arrested complex. Our results additionally indicate that the sequence context of a CPD affects the efficiency of T7 RNAP arrest more significantly than that of RNAP II.

Yeast and Human RNA polymerase II elongation complexes: evidence for functional differences and postinitiation recruitment of factors

Immobilized DNA templates, glycerol gradient centrifugation, and native gel analysis were utilized to isolate and compare functional RNA polymerase II (RNAPII) elongation complexes from Saccharomyces cerevisiae and human cell nuclear extracts. Yeast elongation complexes blocked by incorporation of 3'-O-methyl-GTP into the nascent transcript exhibited a sedimentation coefficient of 35S, were less tightly associated to the template than their human counterparts, and displayed no detectable 3'-5' exonuclease activity on the associated transcript. In contrast, blocked human elongation complexes were more tightly bound to the template, and multiple forms were identified, with the largest exhibiting a sedimentation coefficient of 60S. Analysis of the associated transcripts revealed that a subset of the human elongation complexes exhibited strong 3'-5' exonuclease activity. Although isolated human preinitiation complexes were competent for efficient transcription, their ability to generate 60S elongation complexes was strikingly impaired. These findings demonstrate functional and size differences between S. cerevisiae and human RNAPII elongation complexes and support the view that the formation of mature elongation complexes involves recruitment of nuclear factors after the initiation of transcription.

RNA polymerase II large subunit is cleaved by caspases during DNA damage-induced apoptosis

UV radiation induces DNA lesions that are repaired by the nucleotide excision repair (NER) pathway. Cells that are NER deficient such as those derived from xeroderma pigmentosum (XP) patients are susceptible to apoptosis after 10J/m(2) UV radiation, a dose largely survivable by repair proficient cells. Herein, we report that RNA polymerase II large subunit (RNAP II-LS) undergoes caspase-mediated cleavage, yielding a 140kDa C-terminal fragment in XP lymphoblasts but not NER proficient lymphoblasts after 10J/m(2) UV irradiation. Cleavage could also be induced by cisplatin or oxaliplatin, but not transplatin, an isomer of cisplatin that does not induce DNA adducts. The cleavage of RNAP II-LS was blocked by a panel of caspase inhibitors but not by proteasomal inhibitors or inhibitors of other proteases. In vitro cleavage with caspase 8 yielded the same 140kDa RNAP II-LS fragment observed in vivo. Using site-directed mutagenesis, the RNAP II-LS cleavage site was localized to an LETD sequence ending at residue 1339, which is near its C-terminal domain.

Ultraviolet-sensitive syndrome cells are defective in transcription-coupled repair of cyclobutane pyrimidine dimers

Patients with ultraviolet-sensitive syndrome (UV(S)S) are sensitive to sunlight, but present neither developmental nor neurological deficiencies. Complementation studies with hereditary DNA repair syndromes show that UV(S)S is distinct from all known xeroderma pigmentosum (XP) and Cockayne syndrome (CS) groups. UV(S)S cells exhibit some characteristics typical of CS, including normal global genomic (GGR) repair of UV-photoproducts, poor clonal survival and defective recovery of RNA synthesis after UV exposure. Those observations have led us to suggest that UV(S)S cells, like those from CS, are defective in transcription-coupled repair (TCR) of cyclobutane pyrimidine dimers (CPD). We have now examined the repair of CPD in the transcribed and non-transcribed strands of the active dihydrofolate reductase (DHFR) and p53 genes, and of the silent alpha-fetoprotein (AFP) and mid-size neurofilament (NF-M) genes in normal human cells and in cells belonging to UV(S)S and CS complementation group B. Our results provide compelling evidence that the UV(S)S gene is essential for TCR of CPD and probably other bulky DNA lesions. As a possible distinction between UV(S)S and CS patients, we postulate that the UV(S)S gene may not be required for TCR of oxidative lesions. We have also found that repair of CPD in either DNA strand of the genomic fragments examined, occurs at a slower rate in TCR-deficient cells than in the non-transcribed strands in normal cells; we suggest that in the absence of TCR, global repair complexes have hindered access to lesions in genomic regions that extend beyond individual transcription units.

Strand bias in targeted gene repair is influenced by transcriptional activity

Modified single-stranded DNA oligonucleotides can direct nucleotide exchange in Saccharomyces cerevisiae. Point and frameshift mutations are corrected in a reaction catalyzed by cellular enzymes involved in various DNA repair processes. The present model centers on the annealing of the vector to one strand of the helix, followed by the correction of the designated base. The choice of which strand to target is a reaction parameter that can be controlled, so here we investigate the properties of strand bias in targeted gene repair. An in vivo system has been established in which a plasmid containing an actively transcribed, but mutated, hygromycin-enhanced green fluorescent protein fusion gene is targeted for repair and upon conversion will confer hygromycin resistance on the cell. Overall transcriptional activity has a positive influence on the reaction, elevating the frequency. If the targeting vector is synthesized so that it directs nucleotide repair on the nontranscribed strand, the level of gene repair is higher than if the template strand is targeted. We provide data showing that the targeting vector can be displaced from the template strand by an active T7 phage RNA polymerase. The strand bias is not influenced by which strand serves as the leading or lagging strand during DNA synthesis. These results may provide an explanation for the enhancement of gene repair observed when the non-template strand is targeted.

Can DNA repair cause enhanced cell killing following treatment with ionizing radiation?

Production of DNA damage is the basis of cancer treatments, such as chemotherapy and radiotherapy. The limitation of the treatment dose tends to be how well the normal cells within the body can tolerate the therapy. Although it is possible, to some extent, to localize the treatment area during radiotherapy by targeting the beam of ionizing radiation, chemotherapy usually involves a whole body treatment. In order to improve the effectiveness of treatments, it is important to understand how cells repair the DNA damage. This review will attempt to explain how DNA repair, which would be expected to always enhance cell survival, actually may result in increased cell killing following certain types of cancer treatments, such as ionizing radiation and bleomycin sulfate. Work is underway in many laboratories to unravel how the repair systems handle specific types of DNA damage. Such information will pave the way in designing adjuvant therapies that alter a tumor cell's DNA repair capacity and increase tumor cell killing.

Effect of thymine glycol on transcription elongation by T7 RNA polymerase and mammalian RNA polymerase II

Thymine glycols are formed in DNA by exposure to ionizing radiation or oxidative stress. Although these lesions are repaired by the base excision repair pathway, they have been shown also to be subject to transcription-coupled repair. A current model for transcription-coupled repair proposes that RNA polymerase II arrested at a DNA lesion provides a signal for recruitment of the repair enzymes to the lesion site. Here we report the effect of thymine glycol on transcription elongation by T7 RNA polymerase and RNA polymerase II from rat liver. DNA substrates containing a single thymine glycol located either in the transcribed or nontranscribed strand were used to carry out in vitro transcription. We found that thymine glycol in the transcribed strand blocked transcription elongation by T7 RNA polymerase approximately 50% of the time but did not block RNA polymerase II. Thymine glycol in the nontranscribed strand did not affect transcription by either polymerase. These results suggest that arrest of RNA polymerase elongation by thymine glycol is not necessary for transcription-coupled repair of this lesion. Additional factors that recognize and bind thymine glycol in DNA may be required to ensure RNA polymerase arrest and the initiation of transcription-coupled repair in vivo.

The defect in transcription-coupled repair displayed by a Saccharomyces cerevisiae rad26 mutant is dependent on carbon source and is not associated with a lack of transcription

Nucleotide excision repair (NER) is an evolutionarily conserved pathway that removes DNA damage induced by ultraviolet irradiation and various chemical agents that cause bulky adducts. Two subpathways within NER remove damage from the genome overall or the transcribed strands of transcribing genes (TCR). TCR is a faster repair process than overall genomic repair and has been thought to require the RAD26 gene in Saccharomyces cerevisiae. Rad26 is a member of the SWI/SNF family of proteins that either disrupt chromatin or facilitate interactions between the RNA Pol II and transcription activators. SWI/SNF proteins are required for the expression or repression of a diverse set of genes, many of which are differentially transcribed in response to particular carbon sources. The remodeling of chromatin by Rad26 could affect transcription and/or TCR following formation of DNA damage and other stress-inducing conditions. We speculate that another factor(s) can substitute for Rad26 under particular growth conditions. We therefore measured the level of repair and transcription in two different carbon sources and found that the defect in the rad26 mutant for TCR was dependent on the type of carbon source. Furthermore, TCR did not correlate with transcription rate, suggesting that disruption of RAD26 leads to a specific defect in DNA repair and not transcription.

RAD9, RAD24, RAD16 and RAD26 are required for the inducible nucleotide excision repair of UV-induced cyclobutane pyrimidine dimers from the transcribed and non-transcribed regions of the Saccharomyces cerevisiae MFA2 gene

In this study, the effect of a prior UV irradiation on the removal of cyclobutane pyrimidine dimers (CPDs) from the transcribed strand (TS) and non-transcribed strand (NTS) of the MFA2 gene in haploid Saccharomyces cerevisiae (S. cerevisiae) cells was investigated. In NER competent cells, the pre-irradiation with a dose of 20J/m2 enhances the removal of CPDs induced by a second UV dose of 100J/m2 in the TS and the NTS of MFA2 gene except for the CPDs in the region +258 to +298 in the NTS, where the enhanced repair was absent. No inducible repair was observed in rad9, rad24, rad16 and rad26 cells, indicating two checkpoint genes RAD9 and RAD24, the global repair gene RAD16 and the transcription coupled repair gene RAD26 are essential for inducible NER.

Disruption of the Cockayne syndrome B gene impairs spontaneous tumorigenesis in cancer-predisposed Ink4a/ARF knockout mice

Cells isolated from individuals with Cockayne syndrome (CS) have a defect in transcription-coupled DNA repair, which rapidly corrects certain DNA lesions located on the transcribed strand of active genes. Despite this DNA repair defect, individuals with CS group A (CSA) or group B (CSB) do not exhibit an increased spontaneous or UV-induced cancer rate. In order to investigate the effect of CSB deficiency on spontaneous carcinogenesis, we crossed CSB(-/-) mice with cancer-prone mice lacking the p16(Ink4a)/p19(ARF) tumor suppressor locus. CSB(-/-) mice are sensitive to UV-induced skin cancer but show no increased rate of spontaneous cancer. CSB(-/-) Ink4a/ARF(-/-) mice developed 60% fewer tumors than Ink4a/ARF(-/-) animals and demonstrated a longer tumor-free latency time (260 versus 150 days). Moreover, CSB(-/-) Ink4a/ARF(-/-) mouse embryo fibroblasts (MEFs) exhibited a lower colony formation rate after low-density seeding, a lower rate of H-Ras-induced transformation, slower proliferation, and a lower mRNA synthesis rate than Ink4a/ARF(-/-) MEFs. CSB(-/-) Ink4a/ARF(-/-) MEFs were also more sensitive to UV-induced p53 induction and UV-induced apoptosis than were Ink4a/ARF(-/-) MEFs. In order to investigate whether the apparent antineoplastic effect of CSB gene disruption was caused by sensitization to genotoxin-induced (p53-mediated) apoptosis or by p53-independent sequelae, we also generated p53(-/-) and CSB(-/-) p53(-/-) MEFs. The CSB(-/-) p53(-/-) MEFs demonstrated lower colony formation efficiency, a lower proliferation rate, a lower mRNA synthesis rate, and a higher rate of UV-induced cell death than p53(-/-) MEFs. Collectively, these results indicate that the antineoplastic effect of CSB gene disruption is at least partially p53 independent; it may result from impaired transcription or from apoptosis secondary to environmental or endogenous DNA damage.

Controlling the efficiency of excision repair

The early studies are recounted, that led to the discovery of the ubiquitous process of DNA excision repair, followed by a review of the pathways of transcription-coupled repair (TCR) and global genomic nucleotide excision repair (GGR). Repair replication of damaged DNA in UV-irradiated bacteria was discovered through the use of 5-bromouracil to density-label newly synthesized DNA. This assay was then used in human cells to validate the phenomenon of unscheduled DNA synthesis as a measure of excision repair and to elucidate the first example of a DNA repair disorder, xeroderma pigmentosum. Features of the TCR pathway (that is defective in Cockayne syndrome (CS)) include the possibility of "gratuitous TCR" at transcription pause sites in undamaged DNA. The GGR pathway is shown to be controlled through the SOS stress response in E. coli and through the activated product of the p53 tumor suppressor gene in human cells. These regulatory systems particularly affect the efficiency of repair of the predominant UV-induced photoproduct, the cyclobutane pyrimidine dimer, as well as that of chemical carcinogen adducts, such as benzo(a)pyrene diol-epoxide. Rodent cells (typically lacking the p53-controlled GGR pathway) and tumor virus infected human cells (in which p53 function is abrogated) are unable to carry out efficient GGR of some lesions. Therefore, caution should be exercised in the interpretation of results from such systems for risk assessment in genetic toxicology. Many problems in excision repair remain to be solved, including the mechanism of scanning the DNA for lesions and the subcellular localization of the repair factories. Also there are persisting questions regarding the multiple options of repair, recombination, and translesion synthesis when replication forks encounter lesions in the template DNA. That is where the field of DNA excision repair began four decades ago with studies on the recovery of DNA synthesis in UV-irradiated bacteria.

Measurement of oxidative DNA damage and repair in specific DNA sequences

We describe two methods that were developed in our laboratory to measure the production and repair of oxidative DNA damage in specific DNA sequences. Both of these methods rely on the use of monoclonal antibodies against modified nucleotides to separate DNA sequences that contain damage from those in which repair has occurred. In one case, the modified base is bromodeoxyuridine, which is inserted into the DNA during the repair synthesis step of excision repair. An antibody against this modified base is used to detect the production of the bromodeoxyuridine in the repair patch. This approach allows for the measurement of repair of any DNA lesion whose removal is accompanied by the production of a DNA repair patch. In the other case, the modified base is thymine glycol, an oxidized base that is produced by hydrogen peroxide and ionizing radiation. Using a monoclonal antibody that recognizes this altered base, detection of the production and repair of a specific base damage in a DNA sequence can be accomplished. These approaches are used in our laboratory to examine the transcription-coupled repair of oxidative DNA damage in both yeast and mammalian cells.

Growth retardation, DNA repair defects, and lack of spermatogenesis in BRCA1-deficient mice

BRCA1 is a nuclear phosphoprotein expressed in a broad spectrum of tissues during cell division. The inheritance of a mutant BRCA1 allele dramatically increases a woman's lifetime risk for developing both breast and ovarian cancers. A number of mouse lines carrying mutations in the Brca1 gene have been generated, and mice homozygous for these mutations generally die before day 10 of embryonic development. We report here the survival of a small number of mice homozygous for mutations in both the p53 and Brca1 genes. The survival of these mice is likely due to additional unknown mutations or epigenetic effects. Analysis of the Brca1(-/-) p53(-/-) animals indicates that BRCA1 is not required for the development of most organ systems. However, these mice are growth retarded, males are infertile due to meiotic failure, and the mammary gland of the female mouse is underdeveloped. Growth deficiency due to loss of BRCA1 was more thoroughly examined in an analysis of primary fibroblast lines obtained from these animals. Like p53(-/-) fibroblasts, Brca1(-/-) p53(-/-) cells proliferate more rapidly than wild-type cells; however, a high level of cellular death in these cultures results in reduced overall growth rates in comparison to p53(-/-) fibroblasts. Brca1(-/-) p53(-/-) fibroblasts are also defective in transcription-coupled repair and display increased sensitivity to DNA-damaging agents. We show, however, that after continued culture, and perhaps accelerated by the loss of BRCA1 repair functions, populations of Brca1(-/-) p53(-/-) fibroblasts with increased growth rates can be isolated. The increased survival of BRCA1-deficient fibroblasts in the absence of p53, and with the subsequent accumulation of additional growth-promoting changes, may mimic the events that occur during malignant transformation of BRCA1-deficient epithelia.

Characterization of the rhp7(+) and rhp16(+) genes in Schizosaccharomyces pombe

The global genome repair (GGR) subpathway of nucleotide excision repair (NER) is capable of removing lesions throughout the genome. In Saccharomyces cerevisiae the RAD7 and RAD16 genes are essential for GGR. Here we identify rhp7 (+), the RAD7 homolog in Schizosaccharomyces pombe. Surprisingly, rhp7 (+)and the previously cloned rhp16 (+)are located very close together and are transcribed in opposite directions. Upon UV irradiation both genes are induced, reaching a maximum level after 45-60 min. These observations suggest that the genes are co-regulated. Schizo-saccharomyces pombe rhp7 or rhp16 deficient cells are, in contrast to S.cerevisiae rad7 and rad16 mutants, not sensitive to UV irradiation. In S.pombe an alternative repair mechanism, UV damage repair (UVDR), is capable of efficiently removing photolesions from DNA. In the absence of this UVDR pathway both rhp7 and rhp16 deficient cells display an enhanced UV sensitivity. Epistatic analyses show that rhp7 (+)and rhp16 (+)are only involved in NER. Repair analyses at nucleotide resolution demonstrate that both Rhp7 and Rhp16, probably acting in a complex, are essential for GGR in S.pombe.

Structural characterization of RNA polymerase II complexes arrested by a cyclobutane pyrimidine dimer in the transcribed strand of template DNA

We have characterized the properties of immunopurified transcription complexes arrested at a specifically located cyclobutane pyrimidine dimer (CPD) using enzymatic probes and an in vitro transcription system with purified RNA polymerase II (RNAP II) and initiation factors. To help understand how RNAP II distinguishes between a natural impediment and a lesion in the DNA to initiate a repair event, we have compared the conformation of RNAP II complexes arrested at a CPD with complexes arrested at a naturally occurring elongation impediment. The footprint of RNAP II arrested at a CPD, using exonuclease III and T4 DNA polymerase's 3'-->5' exonuclease, covers approximately 35 base pairs and is asymmetrically located around the dimer. A similar footprint is observed when RNAP II is arrested at the human histone H3.3 arrest site. Addition of elongation factor SII to RNAP II arrested at a CPD produced shortened transcripts of discrete lengths up to 25 nucleotides shorter than those seen without SII. After addition of photolyase and exposure to visible light, some of the transcripts could be reelongated beyond the dimer, suggesting that SII-mediated transcript cleavage accompanied significant RNAP II backup, thereby providing access of the repair enzyme to the arresting CPD.

Intracistronic transcription termination in polysialyltransferase gene (siaD ) affects phase variation in Neisseria meningitidis

Expression of serogroup B meningococcal capsular polysaccharide is subject to frequent phase variation. A reversible +1/-1 frameshift mutation within a poly(dC) repeat altering the reading frame of the polysialyltransferase gene (siaD ), thereby causing premature arrest of translation, is responsible for loss of capsule expression. After analysis of transcription of the siaD gene from an encapsulated strain and from two unencapsulated derivatives, we have found that the siaD mRNA in the unencapsulated strains is reduced in size as a result of premature transcription termination at a cryptic Rho-dependent site within the proximal region of the siaD cistron. Termination is sensitive to bicyclomycin, a natural inhibitor of Rho activity. Bicyclomycin decreased the rates of capsule re-expression (off-on) without affecting the rates of loss of capsule expression (on-off). This finding suggested the existence of a novel mechanism linking transcription elongation termination and mutation frequency. A genetic system was therefore developed to measure phase variation of siaD-ermC' gene fusions in wild type and Rho-defective Escherichia coli strains. These studies demonstrated that in the Rho-defective E. coli strain readthrough transcription of the mutated siaD gene caused a fourfold lower off-on phase variation rate than in the congenic Rho+ strain. Analysis of phase variation of siaD-ermC' gene fusions in a DNA mismatch-defective E. coli strain suggests that the effect of transcription on mutation rates required a functional mismatch repair system.

Base excision repair of N-methylpurines in a yeast minichromosome. Effects of transcription, dna sequence, and nucleosome positioning

Base excision repair of dimethyl sulfate induced N-methylpurines (NMPs) was measured in a yeast minichromosome that has a galactose-inducible GAL1:URA3 fusion gene, a constitutively expressed HIS3 gene, and varied regions of chromatin structure. Removal rates of NMPs varied dramatically (>20-fold) at different sites along three selected fragments encompassing a total length of 1775 base pairs. Repair of NMPs was not coupled to transcription, because the transcribed strands of HIS3 and induced GAL1:URA3 were not repaired faster than the nontranscribed strands. However, the repair rate of NMPs was significantly affected by the nearest neighbor nucleotides. Slow repair occurred at NMPs between purines, especially guanines, whereas fast repair occurred at NMPs between pyrimidines. NMPs between a purine and pyrimidine were repaired at moderate rates. Moreover, a rough correlation between nucleosome positions and repair rates exists in some but not all regions that were analyzed.

Spontaneous and photosensitiser-induced DNA single-strand breaks and formamidopyrimidine-DNA glycosylase sensitive sites at nucleotide resolutionin the nuclear and mitochondrial DNA of Saccharomyces cerevisiae

A system is described for mapping oxidative DNA damage (sites sensitive to formamidopyrimidine-DNA glycosylase and single-strand breaks) at nucleotide resolution in the nuclear and mitochondrial DNA of Saccharomyces cerevisiae. Our 3' end labelling method is sensitive and was first developed using the well-studied inducer of oxidative DNA damage, methylene blue (MB) plus light. We treated yeast DNA in vitro with this so as to maximise levels of damage for assay development. Unfortunately, MB does not remain in yeast cells and yeast DNA repair mutants sensitive to active oxygen species are not sensitive to this agent, thus for in vivo experiments we turned to a polycyclic aromatic, RO 19-8022 (RO). This resulted in oxidative DNA damage when light was applied to yeast cells in its presence. The spectra of enzyme-sensitive sites and single-strand breaks induced by MB in vitro or by RO plus light in vivo or in vitro were examined in two yeast reporter genes: the nuclear MFA2 and the mitochondrial OLI1. The experiments revealed that most of the enzyme-sensitive sites and single-strand breaks induced by MB or RO plus light are at the same positions in these sequences, and that these are guanines.

Effect of DNA lesions on transcription elongation

Some types of damage to cellular DNA have been shown to interfere with the essential transactions of replication and transcription. Not only may the translocation of the polymerase be arrested at the site of the lesion but the bound protein may encumber recognition of the lesion by repair enzymes. In the case of transcription a subpathway of excision repair, termed transcription-coupled repair (TCR) has been shown to operate on lesions in the transcribed strands of expressed genes in bacteria, yeast, mammalian cells and a number of other organisms. Certain genes in mammalian cells (e.g., CSA and CSB) have been uniquely implicated in TCR while others (e.g., XPC-HR23 and XPE) have been shown to operate in the global genomic pathway of nucleotide excision repair, but not in TCR. In order to understand the mechanism of TCR it is important to learn how an RNA polymerase elongation complex interacts with a damaged DNA template. That relationship is explored for different lesions and different RNA polymerase systems in this article.

RNA polymerase II transcription suppresses nucleosomal modulation of UV-induced (6-4) photoproduct and cyclobutane pyrimidine dimer repair in yeast

The nucleotide excision repair (NER) pathway is able to remove a wide variety of structurally unrelated lesions from DNA. NER operates throughout the genome, but the efficiencies of lesion removal are not the same for different genomic regions. Even within a single gene or DNA strand repair rates vary, and this intragenic heterogeneity is of considerable interest with respect to the mutagenic potential of carcinogens. In this study, we have analyzed the removal of the two major types of genotoxic DNA adducts induced by UV light, i.e., the pyrimidine (6-4)-pyrimidone photoproduct (6-4PP) and the cyclobutane pyrimidine dimer (CPD), from the Saccharomyces cerevisiae URA3 gene at nucleotide resolution. In contrast to the fast and uniform removal of CPDs from the transcribed strand, removal of lesions from the nontranscribed strand is generally less efficient and is modulated by the chromatin environment of the damage. Removal of 6-4PPs from nontranscribed sequences is also profoundly influenced by positioned nucleosomes, but this type of lesion is repaired at a much higher rate. Still, the transcribed strand is repaired preferentially, indicating that, as in the removal of CPDs, transcription-coupled repair predominates in the removal of 6-4PPs from transcribed DNA. The hypothesis that transcription machinery operates as the rate-determining damage recognition entity in transcription-coupled repair is supported by the observation that this pathway removes both types of UV photoproducts at equal rates without being profoundly influenced by the sequence or chromatin context.

UV-enhanced reactivation of a UV-damaged reporter gene suggests transcription-coupled repair is UV-inducible in human cells

The genetic disorders xeroderma pigmentosum (XP) and Cockayne syndrome (CS) exhibit deficiencies in the repair of UV-induced DNA damage. CS fibroblasts retain proficient nucleotide excision repair (NER) of inactive (or bulk) DNA, but are deficient in the transcription-coupled repair (TCR) of active genes. In contrast, XP complementation group C (XP-C) fibroblasts retain proficient TCR, but are deficient in bulk DNA repair. The remaining NER-deficient XP groups exhibit deficiencies in both repair pathways. Ad5HCMVsp1lacZ is a recombinant adenovirus vector that is unable to replicate in human fibroblasts, but can efficiently infect and express the beta-galactosidase reporter gene in these cells. We have examined the host cell reactivation (HCR) of beta-galactosidase activity for UV-irradiated Ad5HCMVsp1lacZ in non-irradiated and UV-irradiated normal, XP-B, XP-C, XP-D, XP-F, XP-G, CS-A and CS-B fibroblasts. HCR of beta-galactosidase activity for UV-irradiated Ad5HCMVsp1lacZ was reduced in non-irradiated cells from each of the repair-deficient groups examined (including XP-C) relative to that in non-irradiated normal cells. Prior irradiation of cells with low UV fluences resulted in an enhancement of HCR for normal and XP-C strains, but not for the remaining XP and CS strains. HCR of the UV-damaged reporter gene in UV-irradiated XP and CS strains was similar to measurements of TCR reported previously for these cells. These results suggest that UV treatment results in an induced repair of UV-damaged DNA in the transcribed strand of an active gene in XP-C and normal cells through an enhancement of TCR or a mechanism which involves the TCR pathway.

BRCA1 required for transcription-coupled repair of oxidative DNA damage

The breast and ovarian cancer susceptibility gene BRCA1 encodes a zinc finger protein of unknown function. Association of the BRCA1 protein with the DNA repair protein Rad51 and changes in the phosphorylation and cellular localization of the protein after exposure to DNA-damaging agents are consistent with a role for BRCA1 in DNA repair. Here, it is shown that mouse embryonic stem cells deficient in BRCA1 are defective in the ability to carry out transcription-coupled repair of oxidative DNA damage, and are hypersensitive to ionizing radiation and hydrogen peroxide. These results suggest that BRCA1 participates, directly or indirectly, in transcription-coupled repair of oxidative DNA damage.

Mutants with changes in different domains of yeast replication protein A exhibit differences in repairing the control region, the transcribed strand and the non-transcribed strand of the Saccharomyces cerevisiae MFA2 gene

We have analysed the removal of UV-induced cyclobutane pyrimidine dimers (CPDs) at nucleotide resolution from the MFA2 gene of wild-type Saccharomyces cerevisiae and in strains harbouring mutations in one of the yeast replication protein A (RPA) genes, RFA1. This gene codes for the 70 kDa subunit of RPA and it has previously been shown to have a role in nucleotide excision repair. Here two RFA1 mutants were examined: rfa1-M2 which is mutated in the protein interaction domain and rfa1-M4 which is mutated in the DNA-binding domain. A distinct difference in the removal of CPDs from the MFA2 sequence of these two mutants was observed. Compared to the parental strain, there was no defect in CPD removal in the rfa1-M2 mutant. Contrarily, the rfa1-M4 mutant was totally defective in the global repair of CPDs from the non-transcribed strand and the non-transcribed portions of the strand containing the transcribed sequence, yet it was able to perform reduced transcription coupled repair of the transcribed strand. These results indicate that the role of the DNA-binding domain of RPA is different for global repair versus transcription coupled nucleotide excision repair.

Increased transcription decreases the spontaneous mutation rate at the thymidine kinase locus in human cells

Transcription increases DNA repair efficiency and modulates the distribution of certain types of DNA damage. Furthermore, increased transcription level stimulates spontaneous mutation rate in yeast. We explored whether transcription level affects spontaneous mutation rate in human cells. We first developed two thymidine kinase (tk) inducible human cell lines using the Gal4-Estrogen receptor system. In our TK6i-G3 and G9 tk heterozygous cell lines, the active tk allele is linked to an inducible promoter element. Tk mRNA is induced following treatment with estrogen. Spontaneous mutation rate was significantly decreased in human cell lines after induction in contrast to the report in yeast. Thus, humans may have evolved different or additional mechanisms to deal with transcription related spontaneous mutagenesis.

Nucleotide sequence context effect of a cyclobutane pyrimidine dimer upon RNA polymerase II transcription

We have studied the role of sequence context upon RNA polymerase II arrest by a cyclobutane pyrimidine dimer using an in vitro transcription system consisting of templates containing a specifically located cyclobutane pyrimidine dimer (CPD) and purified RNA polymerase II (RNAP II) and initiation factors. We selected a model sequence containing a well characterized site for RNAP II arrest in vitro, the human histone H3.3 gene arrest site. The 13-base pair core of the arrest sequence contains two runs of T in the nontranscribed strand that impose a bend in the DNA. We hypothesized that arrest of RNAP II might be affected by the presence of a CPD, based upon the observation that a CPD located at the center of a dA6.dT6 tract eliminates bending (Wang, C.-I., and Taylor, J.-S. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 9072-9076). We examined the normal H3.3 sequence and a mutant sequence containing a T --> G transversion, which reduces bending and efficiency of arrest. We show that a CPD in the transcribed strand at either of two locations in the arrest site is a potent block to transcription. However, a CPD in the nontranscribed strand only transiently pauses RNAP II. The CPD in concert with a mutation in the arrest site can reduce the extent of bending of the DNA and improve readthrough efficiency. These results demonstrate the potential importance of sequence context for the effect of CPDs within transcribed sequences.

Recovery of RNA polymerase II synthesis following DNA damage in mutants of Saccharomyces cerevisiae defective in nucleotide excision repair

We have measured the kinetics of the recovery of mRNA synthesis in the inducible GAL10 and RNR3 genes after exposure of yeast cells to ultraviolet (UV) radiation. Such recovery is abolished in mutant strains defective in nucleotide excision repair (NER) of DNA, including a rad23 mutant. Mutants defective in the RAD7 or RAD16 genes, which are required for the repair of the non-transcribed strand but not the transcribed strand of transcriptionally active genes, show slightly faster recovery of RNA synthesis than wild-type strains. A strain deleted of the RAD26 gene, which is known to be required for strand-specific NER in yeast, manifested delayed recovery of mRNA synthesis, whereas a rad28 mutant, which does not show defective strand-specific repair, showed normal kinetics of recovery. Measurement of the recovery of expression of selected individual yeast genes by Northern analysis following exposure of cells to UV radiation apparently correlates directly with the capacity of cells for strand-specific NER.

Incomplete complementation of the DNA repair defect in cockayne syndrome cells by the denV gene from bacteriophage T4 suggests a deficiency in base excision repair

Endonuclease V (denV) from bacteriophage T4 has been examined for its ability to complement the repair defect in Cockayne syndrome (CS) cells of complementation groups A and B. CS is an autosomal recessive disorder characterized by hypersensitivity to UV light and a defect in the preferential repair of UV-induced lesions in transcriptionally active DNA by the nucleotide excision repair (NER) pathway. The denV gene was introduced into non-transformed normal and CS fibroblasts transiently via a recombinant adenovirus (Ad) vector and into SV40-transformed normal and CS cells via a retroviral vector. Expression of denV in CS-A cells resulted in partial correction of the UV-sensitive phenotype in assays of gene-specific repair and cell viability, while correction of CS-B cells by expression of denV in the same assays was minimal or non-existent. In contrast, denV expression led to enhanced host cell reactivation (HCR) of viral DNA synthesis in both CS complementation groups to near normal levels. DenV is a glycosylase which is specific for cyclobutane-pyrimidine dimers (CPDs) but does not recognize other UV-induced lesions. Previous work has indicated that CS cells can efficiently repair all non-CPD UV-induced transcription blocking lesions (S.F. Barrett et al.. Mutation Res. 255 (1991) 281-291 [1]) and that denV incised lesions are believed to be processed via the base excision repair (BER) pathway. The inability of denV to complement the NER defect in CS cells to normal levels implies an impaired ability to process denV incised lesions by the BER pathway, and suggests a role for the CS genes, particularly the CS-B gene, in BER.

RNA polymerase II transcription inhibits DNA repair by photolyase in the transcribed strand of active yeast genes

Yeast uses nucleotide excision repair (NER) and photolyase (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs) generated by ultraviolet light. In active genes, NER preferentially repairs the transcribed strand (TS). In contrast, we recently showed that photolyase preferentially repairs the non-transcribed strands (NTS) of the URA3 and HIS3 genes in minichromosomes. To test whether photoreactivation depends on transcription, repair of CPDs was investigated in the transcriptionally regulated GAL10 gene in a yeast strain deficient in NER [AMY3 (rad1Delta)]. In the active gene (cells grown in galactose), photoreactivation was fast in the NTS and slow in the TS demonstrating preferential repair of the NTS. In the inactive gene (cells grown in glucose), both strands were repaired at similar rates. This suggests that RNA polymerases II blocked at CPDs inhibit accessibility of CPDs to photolyase. In a strain in which both pathways are operational [W303-1a (RAD1)], no strand bias was observed either in the active or inactive gene, demonstrating that photoreactivation of the NTS compensates preferential repair of the TS by NER. Moreover, repair of the NTS was more quickly in the active gene than in the repressed gene indicating that transcription dependent disruption of chromatin facilitates repair of an active gene.

Solution structure of a duplex DNA with an abasic site in a dA tract

The presence of dA tracts in DNA can lead to stable curvature of the DNA, and this curvature can be important in gene regulation, DNA packaging, and other processes. Since damage to DNA may eliminate this stable curvature, the solution state structure of the duplex of d(CGCAAAAATGCG) paired with d(CGCATTDTTCCG), with D indicating an abasic site, has been determined. The undamaged DNA bends into the major groove both in solution and in the crystal state. The presence of the abasic site in the dA tract region induces changes in the DNA structure up to four base pairs away from the damaged site. The structure of the DNA is dependent on whether the abasic site is in the alpha or beta hemiacetal form. These consequences are quite different from the more localized effects that have been observed for "normal" DNAs containing abasic sites. Thus, there appears to be a strong sequence dependence of the structural effects of abasic sites just as there is for undamaged DNA. Furthermore, these results indicate that the presence of an abasic site can alter DNA bending and hence is likely to have significant long range effects on gene regulation and other properties that are dependent on the stable curvature of DNA.

Repair of oxidative damage in nuclear DNA sequences with different transcriptional activities

This study was designed to investigate the repair of oxidative damage in nuclear DNA sequences with different transcriptional activities. Chinese hamster ovary (CHO) cells were treated with the oxygen radical generator hypoxanthine/xanthine oxidase (Hyp/XO). Damage and repair were evaluated in 14-kb restriction fragments containing either the DHFR gene, a 3'-non-transcribed flanking region, or the c-fos gene using a quantitative Southern blot technique. Damage to the sugar-phosphate backbone and abasic sites were detected by measuring their lability in alkali conditions. Lesions in DNA bases were identified using the bacterial repair enzyme endonuclease III, which predominantly recognizes damage to thymines and cytosines, and formamidopyrimidine-DNA glycosylase, which recognizes 8-oxoguanine and purines with fractured imidazole rings. The results showed that similar amounts of all types of oxidative damage were produced in both the transcribed and non-transcribed sequences following a 1-h exposure to the radical generator. Repair in all sequences was rapid, with approximately 60% removal of lesions observed by 1 h. Therefore, within these sequences, the repair of oxidative lesions is much faster than that of other types of damage, such as those induced by alkylating toxins and UV irradiation, and the repair is not affected appreciably by transcriptional status.

Transitions in the coupling of transcription and nucleotide excision repair within RNA polymerase II-transcribed genes of Saccharomyces cerevisiae

The molecular mechanism of transcription-coupled nucleotide excision repair in eukaryotes is poorly understood. The identification of the dual role of basal transcription factor TFIIH in DNA repair and transcription provided a plausible link between both processes. However, TFIIH is not part of the elongating transcription complex, suggesting that additional components are required to recruit TFIIH when RNA polymerase II (RNAPII) stalls at the site of DNA damage. Previously, we have shown that the yeast Rad26 protein is involved in transcription-coupled DNA repair. This paper describes the differential contribution of the Rad26 protein to efficient removal of UV-induced cyclobutane pyrimidine dimers (CPDs) from transcribed DNA. Two distinct regions within the transcribed strand of RNAPII-transcribed genes are identified that differ in their requirement for the RAD26 gene product. Using high-resolution repair analysis, we determined the in vivo repair kinetics of cyclobutane pyrimidine dimers positioned around the transcription initiation site of RNAPII-transcribed genes RPB2 and URA3. Although transcription-coupled repair is severely reduced in rad26 mutants, lesions positioned in a small region immediately downstream of transcription initiation are efficiently removed in the absence of Rad26. The observed transition in repair characteristics is abrupt and in excellent agreement with the region where TFIIH dissociates from RNAPII in vitro, strongly suggesting an inverse correlation between TFIIH association and Rad26 requirement. These data suggest that a transcription repair coupling factor (Rad26/CSB) is required for efficient repair only during the elongating stages of RNAPII transcription.

Excision repair at the level of the nucleotide in the Saccharomyces cerevisiae MFA2 gene: mapping of where enhanced repair in the transcribed strand begins or ends and identification of only a partial rad16 requisite for repairing upstream control sequences

We wished to determine where transcription enhanced nucleotide excision repair begins and ends for a Saccharomyces cerevisiae gene transcribed by RNA polymerase II, and to examine the role of the RAD16 gene in repairing upstream, non-transcribed control sequences of such a gene. To do so, we developed a method to study the repair of UV induced cyclobutane pyrimidine dimers (CPDs) at the level of the nucleotide in the control and coding sequences of the MFA2 gene. This gene is active in haploid a mating type cells but inactive in alpha cells: its regulation is mediated by changes in chromatin structure. DNA from UV irradiated cells was cut with a CPD-specific endonuclease, restricted and selected strands of the MFA2 gene separated from genomic DNA prior to end-labelling and resolution on a sequencing gel. We confirmed repair trends seen using Southern blotting to examine kilobase size fragments, but were additionally able to elucidate subtle differences in repairing portions of the transcribed strand (TS) of MFA2. Enhanced repair of the TS when the gene is active, began well before the start of transcription. Clearly, enhanced repair in this region cannot be due to mRNA synthesis. The repair of CPDs is even further enhanced in the transcribed portion of the TS, and returns to a basal level after the termination of transcription. The approach also revealed that RAD16 has a role in the repair of the TS when MFA2 is active. Removal of CPDs from the TS control region was impaired but not totally defective in a rad16 a mutant. Repair from the TS coding sequence also has a Rad16 component, but a lesser one than for the upstream control sequences, and this was more marked for the sequences towards the end of the transcribed region. The system developed permits further dissection of the relationships between DNA repair, chromatin structure and transcription at the MFA2 locus.

Defective transcription-coupled repair of oxidative base damage in Cockayne syndrome patients from XP group G

In normal human cells, damage due to ultraviolet light is preferentially removed from active genes by nucleotide excision repair (NER) in a transcription-coupled repair (TCR) process that requires the gene products defective in Cockayne syndrome (CS). Oxidative damage, including thymine glycols, is shown to be removed by TCR in cells from normal individuals and from xeroderma pigmentosum (XP)-A, XP-F, and XP-G patients who have NER defects but not from XP-G patients who have severe CS. Thus, TCR of oxidative damage requires an XPG function distinct from its NER endonuclease activity. These results raise the possibility that defective TCR of oxidative damage contributes to the developmental defects associated with CS.