Transcript cleavage by RNA polymerase II arrested by a cyclobutane pyrimidine dimer in the DNA template

TATA-binding protein promotes the selective formation of UV-induced (6-4)-photoproducts and modulates DNA repair in the TATA box

DNA-damage formation and repair are coupled to the structure and accessibility of DNA in chromatin. DNA damage may compromise protein binding, thereby affecting function. We have studied the effect of TATA-binding protein (TBP) on damage formation by ultraviolet light and on DNA repair by photolyase and nucleotide excision repair in yeast and in vitro. In vivo, selective and enhanced formation of (6-4)-photoproducts (6-4PPs) was found within the TATA boxes of the active SNR6 and GAL10 genes, engaged in transcription initiation by RNA polymerase III and RNA polymerase II, respectively. Cyclobutane pyrimidine dimers (CPDs) were generated at the edge and outside of the TATA boxes, and in the inactive promoters. The same selective and enhanced 6-4PP formation was observed in a TBP-TATA complex in vitro at sites where crystal structures revealed bent DNA. We conclude that similar DNA distortions occur in vivo when TBP is part of the initiation complexes. Repair analysis by photolyase revealed inhibition of CPD repair at the edge of the TATA box in the active SNR6 promoter in vitro, but not in the GAL10 TATA box or in the inactive SNR6 promoter. Nucleotide excision repair was not inhibited, but preferentially repaired the 6-4PPs. We conclude that TBP can remain bound to damaged promoters and that nucleotide excision repair is the predominant pathway to remove UV damage in active TATA boxes.

Transcription factor IIH: a key player in the cellular response to DNA damage

TFIIH (transcription factor IIH) is a multiprotein complex consisting of nine subunits initially characterized as a basal transcription factor required for initiation of protein-coding RNA synthesis. TFIIH was the first transcription factor shown to harbor several enzymatic activities, likely indicative of functional complexity. This intricacy was further emphasized with the cloning of the genes encoding the different subunits which disclosed direct connections between transcription, DNA repair and cell cycle regulation. In this review, we emphasize those functions of TFIIH involved in DNA repair, as well as their relationship to TFIIH's roles in transcription, cell cycle control and apoptosis. These connections may prove to be essential for the cellular response to DNA damage.

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.

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.

Factors regulating the transcriptional elongation activity of RNA polymerase II

The synthesis of mature and functional messenger RNA by eukaryotic RNA polymerase II (Pol II) is a complex, multistage process requiring the cooperative action of many cellular proteins. This process, referred to collectively as the transcription cycle, proceeds via five stages: preinitiation, initiation, promoter clearance, elongation, and termination. During the past few years, fundamental studies of the elongation stage of transcription have demonstrated the existence of several families of Pol II elongation factors governing the activity of Pol II. It is now clear that the elongation stage of transcription is a critical stage for the regulation of gene expression. In fact, two of these elongation factors, ELL and elongin, have been implicated in human cancer. This article will review the proteins involved in the regulation of the elongation stage of transcription by Pol II, describing the recent experimental findings that have propelled vigorous research on the properties and function of the elongating RNA polymerase II. --Shilatifard, A. Factors regulating the transcriptional elongation activity of RNA polymerase II.

Evasion of UVC-induced apoptosis by photorepair of cyclobutane pyrimidine dimers

Cyclobutyl pyrimidine dimer (CPD) photolyase is known to reverse pyrimidine dimers specifically under illumination with visible light. OCP13, a Medaka cell line showing a high level expression of the gene for CPD photolyase, completely reversed pyrimidine dimers induced by 20 J/m2 UVC by 1 h of photorepair. When OCP13 cells were irradiated with 20 J/m2 UVC, morphological changes such as shrinkage of cells, distorted nuclear shape, and decrease in the number of nucleoli appeared 2 to 4 h after UVC irradiation. Thereafter, the irradiated cells began to detach from the substratum, and DNA ladders were observed in the DNA extracted from detached cells. Thus, these changes in cells after UVC exposure were used to characterize the progression of UV-induced apoptosis in OCP13 cells. Although formation of DNA ladders and cell detachment were blocked by cycloheximide treatment prior to UVC exposure, the morphological changes were not. With photorepair treatment, even after the morphological changes appeared cells were still able to restore their normal morphological features and remained attached. On the other hand, the cell-cycle progression in UVC-irradiated cells was arrested even after photorepair of pyrimidine dimers. Thus, photorepair can rescue cells from UV-induced apoptosis, although DNA damage other than that of pyrimidine dimers, as well as additional non-DNA damage, possibly remained, and DNA replication was left inhibited. Among the various kinds of damage induced by UVC irradiation, the presence of pyrimidine dimers is proposed to be the major trigger for UVC-induced apoptosis.

The ability of a variety of polymerases to synthesize past site-specific cis-syn, trans-syn-II, (6-4), and Dewar photoproducts of thymidylyl-(3'-->5')-thymidine

The role of photoproduct structure, 3' --> 5' exonuclease activity, and processivity on polynucleotide synthesis past photoproducts of thymidylyl-(3' --> 5')-thymidine was investigated. Both Moloney murine leukemia virus reverse transcriptase and 3' --> 5' exonuclease-deficient (exo-) Vent polymerase were blocked by all photoproducts, whereas Taq polymerase could slowly bypass the cis-syn dimer. T7 RNA polymerase was able to bypass all the photoproducts in the order cis-syn > Dewar > (6-4) > trans-syn-II. Klenow fragment could not bypass any of the photoproducts, but an exo- mutant could bypass the cis-syn dimer to a greater extent than the others. Likewise T7 DNA polymerase, composed of the T7 gene 5 protein and Escherichia coli thioredoxin, was blocked by all the photoproducts, but the exo- mutant Sequenase 2.0 was able to bypass them all in the order cis-syn > Dewar > trans-syn-II > (6-4). No bypass occurred with an exo- gene 5 protein in the absence of the thioredoxin processivity factor. Bypass of the cis-syn and trans-syn-II products by Sequenase 2.0 was essentially non-mutagenic, whereas about 20% dTMP was inserted opposite the 5'-T of the Dewar photoproduct. A mechanism involving a transient abasic site is proposed to account for the preferential incorporation of dAMP opposite the 3'-T of the photoproducts.

Effects of nonbulky DNA base damages on Escherichia coli RNA polymerase-mediated elongation and promoter clearance

DNA base damage products either formed spontaneously or as a result of exposure to various genotoxic agents were examined for their effects on Escherichia coli RNA polymerase-mediated transcription in vitro. Uracil, O6-methylguanine (O6-meG), and 8-oxoguanine (8-oxoG) were placed at specific sites downstream from the transcriptional start site on the transcribed strand of a duplex template under the control of the strong tac promoter. In vitro, single-round transcription experiments carried out with purified E. coli RNA polymerase revealed efficient bypass at the three lesions examined and subsequent generation of full-length runoff transcripts. Transcript sequence analysis revealed that E. coli RNA polymerase inserted primarily adenine into the transcript opposite to uracil, uracil opposite to O6-meG, and either adenine or cytosine opposite to 8-oxoG. Thus, a uracil in the DNA template resulted in a G-to-A transition mutation in the lesion bypass product whereas O6-meG produced a C-to-U transition mutation and 8-oxoG generated either the correct transcriptional product or a C-to-A transversion mutation. When 8-oxoG was placed within close proximity to the transcriptional start site (within the region required for effective promoter clearance), a reduced of full-length, runoff transcript was observed, indicative of lower promoter clearance. Taken together, these results demonstrate that the DNA base damages studied here may exert significant in vivo effects on gene expression and DNA repair with respect to the production of mutant proteins (transcriptional mutagenesis), or decreased levels of expressed proteins.

Escherichia coli RNA and DNA polymerase bypass of dihydrouracil: mutagenic potential via transcription and replication

Dihydrouracil (DHU) is a DNA base damage product produced in significant amounts by ionizing radiation damage to cytosine under anoxic conditions. DHU represents a model for pyrimidine base damage (ring saturation products) of the type recognized and repaired by Escherichia coli endonuclease III and its homologs in other species. We have built this lesion into synthetic oligonucleotides, with DHU placed at a single location downstream from an E.coli RNA polymerase promoter. This construct was used to determine the effect of DHU when encountered on a DNA template strand by either E.coli RNA or DNA polymerase (Klenow fragment). Single round transcription experiments or primer extension-type replication experiments were conducted in order to make a direct comparison between RNA and DNA polymerases with DHU placed within the same sequence context. Both DNA and RNA polymerase efficiently bypass DHU and insert adenine opposite this lesion. These results suggest that DHU is mutagenic with respect to both replication and transcription and have implications for DNA repair as well the routes leading to generation of mutant proteins in dividing and non-dividing cells.

Ultraviolet radiation-induced ubiquitination and proteasomal degradation of the large subunit of RNA polymerase II. Implications for transcription-coupled DNA repair

We have shown previously that UV radiation and other DNA-damaging agents induce the ubiquitination of a portion of the RNA polymerase II large subunit (Pol II LS). In the present study UV irradiation of repair-competent fibroblasts induced a transient reduction of the Pol II LS level; new protein synthesis restored Pol II LS to the base-line level within 16-24 h. In repair-deficient xeroderma pigmentosum cells, UV radiation-induced ubiquitination of Pol II LS was followed by a sustained reduction of Pol II LS level. In both normal and xeroderma pigmentosum cells, the ubiquitinated Pol II LS had a hyperphosphorylated COOH-terminal domain (CTD), which is characteristic of elongating Pol II. The portion of Pol II LS whose steady-state level diminished most quickly had a relatively hypophosphorylated CTD. The ubiquitinated residues did not map to the CTD. Importantly, UV-induced reduction of Pol II LS level in repair-competent or -deficient cells was inhibited by the proteasome inhibitors lactacystin or MG132. These data demonstrate that UV-induced ubiquitination of Pol II LS is followed by its degradation in the proteasome. These results suggest, contrary to a current model of transcription-coupled DNA repair, that elongating Pol II complexes which arrest at intragenic DNA lesions may be aborted rather than resuming elongation after repair takes place.

Nucleotide excision repair and photolyase preferentially repair the nontranscribed strand of RNA polymerase III-transcribed genes in Saccharomyces cerevisiae

A high-resolution primer extension technique was used to study the relationships between repair, transcription, and mutagenesis in RNA polymerase III transcribed genes in Saccharomyces cerevisiae. The in vivo repair of UV-induced DNA damage by nucleotide excision repair (NER) and by photoreactivation is shown to be preferential for the nontranscribed strand (NTS) of the SNR6 gene. This is in contrast to RNA polymerase II genes in which the NER is preferential for the transcribed strand (TS). The repair-strand bias observed in SNR6 was abolished by inactivation of transcription in a snr6Delta2 mutant, showing a contribution of RNA polymerase III transcription in this phenomenon. The same strand bias for NER (slow in TS, fast in NTS) was discovered in the SUP4 gene, but only outside of the intragenic promoter element (box A). Unexpectedly, the repair in the transcribed box A was similar on both strands. The strand specificity as well as the repair heterogeneity determined in the transcribed strand of the SUP4 gene, correlate well with the previously reported site- and strand-specific mutagenesis in this gene. These findings present a novel view regarding the relationships between DNA repair, mutagenesis, and transcription.

Cisplatin- and UV-damaged DNA lure the basal transcription factor TFIID/TBP

A connection between transcription and DNA repair was demonstrated previously through the characterization of TFIIH. Using filter binding as well as in vitro transcription challenge competition assays, we now show that the promoter recognition factor TATA box-binding protein (TBP)/TFIID binds selectively to and is sequestered by cisplatin- or UV-damaged DNA, either alone or in the context of a larger protein complex including TFIIH. Computer-assisted 3D structural analysis reveals a remarkable similarity between the structure of the TATA box as found in its TBP complex and that of either platinated or UV-damaged oligonucleotides. Thus, cisplatin-treated or UV-irradiated DNA could be used as a competing binding site which may lure TBP/TFIID away from its normal promoter sequence, partially explaining the phenomenon of DNA damage-induced inhibition of RNA synthesis. Consistent with an involvement of damaged DNA-specific binding of TBP in inhibiting transcription, we find that microinjection of additional TBP in living human fibroblasts alleviates the reduction in RNA synthesis after UV irradiation. Future anticancer drugs could be designed with the consideration of lesion recognition by TBP and their ability to reduce transcription.

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.

Processing of topoisomerase I cleavable complexes into DNA damage by transcription

Topoisomerase I (TOP1)-mediated DNA damage induced by camptothecin (CPT) in the presence of active transcription has been studied using purified calf thymus TOP1 and T7 RNA polymerase. CPT-stabilized TOP1 cleavable complexes located on the template strand within the transcribed region were found to be converted into irreversible strand breaks by the elongating RNA polymerase. By contrast, CPT-stabilized TOP1 cleavable complexes located on the non-template strand within the transcribed region was unaffected by the elongating RNA polymerase. Previous studies have demonstrated that the elongating T7 RNA polymerase is arrested by TOP1 cleavable complexes located on the template but not the non-template strand [Bendixen et al ., (1990) Biochemistry , 29, 5613-5619]. Together, these results suggest a model in which collision between the TOP1-cleavable complexes located on the template strand and the elongating RNA polymerase results in transcription arrest and conversion of TOP1 cleavable complexes into 'irreversible' strand breaks. The implication of the transcription collision model in DNA damage and repair, as well as cell killing, is discussed.

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.

Cockayne syndrome group B protein enhances elongation by RNA polymerase II

Cockayne syndrome (CS) is characterized by impaired physical and mental development. Two complementation groups, CSA and CSB, have been identified. Here we report that the CSB gene product enhances elongation by RNA polymerase II. CSB stimulated the rate of elongation on an undamaged template by a factor of about 3. A thymine-thymine cyclobutane dimer located in the template strand is known to be a strong block to transcription. Addition of CSB to the blocked polymerase resulted in addition of one nucleotide to the nascent transcript. Finally, addition of transcription factor IIS is known to cause polymerase blocked at a thymine-thymine cyclobutane dimer to digest its nascent transcript, and CSB counteracted this transcript shortening action of transcription factor IIS. Thus a deficiency in transcription elongation may contribute to the CS phenotype.

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.

Kinetics of repair of UV-induced DNA damage in repair-proficient and -deficient cells as determined by quantitative polymerase chain reaction

Advances in methodologies to monitor gene-specific repair in human cells have facilitated a detailed understanding of the complexity of the nucleotide excision repair system. One of these procedures, quantitative polymerase chain reaction (QPCR), holds significant promise for dissecting the fine structure of the repair of UV-induced DNA damage. This assay was used to study the repair of UV photoproducts in both actively transcribed and nontranscribed genes from human cells that were capable of (1) repair of both cyclobutane pyrimidine dimers and 6-4 photoproducts; (2) removal of neither dimers nor 6-4 photoproducts; (3) strong preferential repair of 6-4 photoproducts relative to dimers; and (4) severely depressed rates of 6-4 photoproducts and dimers. Detailed kinetic analyses revealed that repair of both active and inactive genes can be studied with a very fine degree of precision and that the repair status of the cells can easily be detected by use of the procedures described.

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.

Cockayne syndrome: defective repair of transcription?

In the past years, it has become increasingly evident that basal metabolic processes within the cell are intimately linked and influenced by one another. One such link that recently has attracted much attention is the close interplay between nucleotide excision DNA repair and transcription. This is illustrated both by the preferential repair of the transcribed strand of active genes (a phenomenon known as transcription-coupled repair, TCR) as well as by the distinct dual involvement of proteins in both processes. The mechanism of TCR in eukaryotes is still largely unknown. It was first discovered in mammals by the pioneering studies of Hanawalt and colleagues, and subsequently identified in yeast and Escherichia coli. In the latter case, one protein, the transcription repair-coupling factor, was found to accomplish this function in vitro, and a plausible model for its activity was proposed. While the E. coli model still functions as a paradigm for TCR in eukaryotes, recent observations prompt us to believe that the situation in eukaryotes is much more complex, involving dual functionality of multiple proteins.

Photorepair mutants of Arabidopsis

UV radiation induces two major DNA damage products, the cyclobutane pyrimidine dimer (CPD) and, at a lower frequency, the pyrimidine (6-4) pyrimidinone dimer (6-4 product). Although Escherichia coli and Saccharomyes cerevisiae produce a CPD-specific photolyase that eliminates only this class of dimer, Arabidopsis thaliana, Drosphila melanogaster, Crotalus atrox, and Xenopus laevis have recently been shown to photoreactivate both CPDs and 6-4 products. We describe the isolation and characterization of two new classes of mutants of Arabidopsis, termed uvr2 and uvr3, that are defective in the photoreactivation of CPDs and 6-4 products, respectively. We demonstrate that the CPD photolyase mutation is genetically linked to a DNA sequence encoding a type II (metazoan) CPD photolyase. In addition, we are able to generate plants in which only CPDs or 6-4 products are photoreactivated in the nuclear genome by exposing these mutants to UV light and then allowing them to repair one or the other class of dimers. This provides us with a unique opportunity to study the biological consequences of each of these two major UV-induced photoproducts in an intact living system.

Processing of DNA prior to illegitimate recombination in mouse cells

In mammalian cells, the predominant pathway of chromosomal integration of exogenous DNA is random or illegitimate recombination; integration by homologous recombination is infrequent. Homologous recombination is initiated at double-strand DNA breaks which have been acted on by single-strand exonuclease. To further characterize the relationship between illegitimate and homologous recombination, we have investigated whether illegitimate recombination is also preceded by exonuclease digestion. Heteroduplex DNAs which included strand-specific restriction markers at each of four positions were generated. These DNAs were introduced into mouse embryonic stem cells, and stably transformed clones were isolated and analyzed to determine whether there was any strand bias in the retention of restriction markers with respect to their positions. Some of the mismatches appear to have been resolved by mismatch repair. Very significant strand bias was observed in the retention of restriction markers, and there was polarity of marker retention between adjacent positions. We conclude that DNA is frequently subjected to 5'-->3' exonuclease digestion prior to integration by illegitimate recombination and that the length of DNA removed by exonuclease digestion can be extensive. We also provide evidence which suggests that frequent but less extensive 3'-->5' exonuclease processing also occurs.

DNA damage-dependent transcriptional arrest and termination of RNA polymerase II elongation complexes in DNA template containing HIV-1 promoter

We have developed a new biochemical method to isolate a homogeneous population of RNA polymerase II (RNA pol II) elongation complexes arrested at a DNA damage site. The method involves triple-helix formation at a predetermined site in DNA template with a third strand labeled with psoralen at its 5'-end and a biotin at the 3'-end. After triplex formation and near-ultraviolet irradiation (360 nm), DNA templates modified with psoralen were immobilized on streptavidin-coated magnetic beads and used for in vitro transcription reactions with HeLa nuclear extracts. Separation of magnetic beads from solution results in isolation of arrested elongation complexes on the immobilized DNA templates. We have applied the method to arrest RNA pol II elongation complexes on a DNA template containing HIV-1 promoter. Our results indicate that psoralen crosslink in the template strand efficiently arrests elongation complexes, and psoralen monoadducts terminate transcription. Our results also demonstrate that a triple-helical structure stabilized by an intercalator, acridine, attached to the third strand of the helix inhibits transcription by a termination pathway. Isolation of stable RNA pol II elongation complexes arrested at DNA damage sites is a remarkable finding. This result demonstrates that arrested elongation complexes are impervious to DNA damage repair machinery and other regulatory proteins present in HeLa nuclear extracts. The method of delivering site-specific psoralen damage by a triplex structure and isolation of arrested RNA pol II elongation complexes should be generalizable to any promoter and DNA template sequences. This strategy provides a new approach to study the mechanism of transcription elongation and transcription-coupled DNA damage repair.

The molecular basis of xeroderma pigmentosum

BACKGROUND

Xeroderma pigmentosum is an extremely rare, autosomal recessive disease characterized by a more than 1000-fold increase in nonmelanoma skin cancer. Individuals with this disease can be divided into eight complementation groups: A-G and V for variant. Each one represents a different genetic defect in DNA repair.

OBJECTIVE

To review the molecular basis of xeroderma pigmentosum.

RESULTS

Deficiencies in various gene products in the nucleotide excision repair pathway cause xeroderma pigmentosum in complementation groups A-G. The molecular basis of the variant group remains to be elucidated.

CONCLUSIONS

Research into the genetic defects underlying xeroderma pigmentosum have led to an increased understanding of nucleotide excision repair.

Persistent DNA damage inhibits S-phase and G2 progression, and results in apoptosis

We used genetically related Chinese hamster ovary cell lines proficient or deficient in DNA repair to determine the direct role of UV-induced DNA photoproducts in inhibition of DNA replication and in induction of G2 arrest and apoptosis. UV irradiation of S-phase-synchronized cells causes delays in completion of the S-phase sometimes followed by an extended G2 arrest and apoptosis. The effects of UV irradiation during the S-phase on subsequent cell cycle progression are magnified in repair-deficient cells, indicating that these effects are initiated by persistent DNA damage and not by direct UV activation of signal transduction pathways. Moreover, among the lesions introduced by UV irradiation, persistence of (6-4) photoproducts inhibits DNA synthesis much more than persistence of cyclobutane pyrimidine dimers (which appear to be efficiently bypassed by the DNA replication apparatus). Apoptosis begins approximately 24 h after UV irradiation of S-phase-synchronized cells, occurs to a greater extent in repair-deficient cells, and correlates well with the inability to escape from an extended late S-phase-G2 arrest. We also find that nucleotide excision repair activity (including its coupling to transcription) is similar in the S-phase to what we have previously measured in G1 and G2.

The inhibition of antigen-presenting activity of dendritic cells resulting from UV irradiation of murine skin is restored by in vitro photorepair of cyclobutane pyrimidine dimers

Exposing skin to UVB (280-320 nm) radiation suppresses contact hypersensitivity by a mechanism that involves an alteration in the activity of cutaneous antigen-presenting cells (APC). UV-induced DNA damage appears to be an important molecular trigger for this effect. The specific target cells in the skin that sustain DNA damage relevant to the immunosuppressive effect have yet to be identified. We tested the hypothesis that UV-induced DNA damage in the cutaneous APC was responsible for their impaired ability to present antigen after in vivo UV irradiation. Cutaneous APC were collected from the draining lymph nodes of UVB-irradiated, hapten-sensitized mice and incubated in vitro with liposomes containing a photolyase (Photosomes; Applied Genetics, Freeport, NY), which, upon absorption of photoreactivating light, splits UV-induced cyclobutane pyrimidine dimers. Photosome treatment followed by photoreactivating light reduced the number of dimer-containing APC, restored the in vivo antigen-presenting activity of the draining lymph node cells, and blocked the induction of suppressor T cells. Neither Photosomes nor photoreactivating light alone, nor photoreactivating light given before Photosomes, restored APC activity, and Photosome treatment did not reverse the impairment of APC function when isopsoralen plus UVA (320-400 nm) radiation was used instead of UVB. These controls indicate that the restoration of APC function matched the requirements of Photosome-mediated DNA repair for dimers and post-treatment photoreactivating light. These results provide compelling evidence that it is UV-induced DNA damage in cutaneous APC that leads to reduced immune function.

Relationship between adduct formation, rates of excision repair and the cytotoxic and mutagenic effects of structurally-related polycyclic aromatic carcinogens

The cytotoxic and mutagenic effect of 1-nitrosopyrene (1-NOP) and N-acetoxy-2-acetylaminofluorene (N-AcO-AAF) were compared with that of (+/-)-7 beta, 8 alpha-dihydroxy-9 alpha, 10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (BPDE) as a function of the initial frequency of adducts formed in the DNA of repair-proficient diploid human fibroblasts and the fraction remaining at the time the cells replicate their DNA. The principal adducts of all three agents involve guanine. The initial level of BPDE-, 1-NOP-, or N-AcO-AAF-induced adducts per 10(6) nucleotides required to lower the survival of these cells to 37% of the control was 8, 25, and 50, respectively. The frequency of mutants per 10(6) clonable cells induced at those levels of initial adduct formation was 160, 80, and 40, respectively. We determined the rate of excision repair of these adducts from the overall genome, from the individual strands of the hypoxanthine phosphoribosyltransferase (HPRT) gene, and in the case of 1-NOP and BPDE, at the level of individual nucleotides in the nontranscribed strand of exon 3 of that gene, a region where mutations induced by those agents are particularly frequent. 1-NOP-induced adducts were excised from the overall genome and from the individual strands of HPRT at a rate 2-3 times faster than BPDE-induced adducts. The average rate of repair of 1-NOP-induced adducts in exon 3 was also 2-3 times faster than the average rate of repair of BPDE-induced adducts. However, at particular nucleotides 1-NOP-induced adducts were repaired much faster, or slower, or in some cases at a rate equal to that of BPDE-induced adducts. Excision repair of N-AcO-AAF-induced adducts (i.e., deacetylated aminofluorene residues) was significantly slower than that of BPDE- or 1-NOP-induced adducts, and was not strand-specific. In an in vitro assay, BPDE adducts were four times more effective in blocking transcription than were 1-NOP or N-AcO-AAF-induced adducts. We conclude that the cytotoxic and mutagenic effect of these carcinogens reflect a complex interplay of adduct conformation, ability of adducts to block replication and transcription, and variation in the rate of excision repair, even at the nucleotide level.

Chromatin structure modulates DNA repair by photolyase in vivo

Yeast and many other organisms use nucleotide excision repair (NER) and photolyase in the presence of light (photoreactivation) to repair cyclobutane pyrimidine dimers (CPDs), a major class of DNA lesions generated by UV light. To study the role of photoreactivation at the chromatin level in vivo, we used yeast strains which contained minichromosomes (YRpTRURAP, YRpCS1) with well-characterized chromatin structures. The strains were either proficient (RAD1) or deficient (rad1 delta) in NER. In contrast to NER, photolyase rapidly repairs CPDs in non-nucleosomal regions, including promoters of active genes (URA3, HIS3, DED1) and in linker DNA between nucleosomes. CPDs in nucleosomes are much more resistant to photoreactivation. These results demonstrate a direct role of chromatin in modulation of a DNA repair process and an important role of photolyase in repair of damaged promoters with presumptive effects on gene regulation. In addition, photoreactivation provides an in vivo test for chromatin structure and stability. In active genes (URA3, HIS3), photolyase repairs the non-transcribed strand faster than the transcribed strand and can match fast removal of lesions from the transcribed strand by NER (transcription-coupled repair). Thus, the combination of both repair pathways ensures efficient repair of active genes.

A common mutational pattern in Cockayne syndrome patients from xeroderma pigmentosum group G: implications for a second XPG function

Xeroderma pigmentosum (XP) patients have defects in nucleotide excision repair (NER), the versatile repair pathway that removes UV-induced damage and other bulky DNA adducts. Patients with Cockayne syndrome (CS), another rare sun-sensitive disorder, are specifically defective in the preferential removal of damage from the transcribed strand of active genes, a process known as transcription-coupled repair. These two disorders are usually clinically and genetically distinct, but complementation analyses have assigned a few CS patients to the rare XP groups B, D, or G. The XPG gene encodes a structure-specific endonuclease that nicks damaged DNA 3' to the lesion during NER. Here we show that three XPG/CS patients had mutations that would produce severely truncated XPG proteins. In contrast, two sibling XPG patients without CS are able to make full-length XPG, but with a missense mutation that inactivates its function in NER. These results suggest that XPG/CS mutations abolish interactions required for a second important XPG function and that it is the loss of this second function that leads to the CS clinical phenotype.

Model for XPC-independent transcription-coupled repair of pyrimidine dimers in humans

In humans, DNA lesions such as pyrimidine dimers in the template strand of genes transcribed by RNA polymerase II are repaired faster than those in the coding strand and nontranscribed regions of the genome. This phenomenon, referred to as transcription-coupled repair (i) requires active transcription, (ii) does not require the XPC gene product which is essential for general/basal repair reactions, and (iii) requires the CSA and CSB proteins. We have developed an in vitro model system that consists of purified human excision repair factors and a DNA substrate analogous to a transcription bubble terminating at a cyclobutane thymine dimer. In this system the thymine dimer was excised independent of XPC. Furthermore, the thymine dimer in the bubble-containing substrate was removed approximately 3-fold faster by the excision repair nuclease reconstituted with or without XPC, compared with the removal of thymine dimer from a base paired duplex by the entire set of excision nuclease factors. These results provide important insight into the mechanism of transcription-coupled repair in humans.

RNA polymerase II stalled at a thymine dimer: footprint and effect on excision repair

Bulky lesions in the template strand block the progression of RNA polymerase II (RNAP II) and are repaired more rapidly than lesions in the non-transcribed strand, which do not block transcription. In order to better understand the basis of this transcription-coupled repair we developed an in vitro system with purified transcription and nucleotide excision repair proteins and a plasmid containing the adenovirus major late promoter and a thymine dimer in the template strand downstream of the transcription start site. The footprint of RNAP II stalled at the thymine dimer, obtained using DNase I, lambda exonuclease and T4 polymerase 3'-->5'exonuclease, covers approximately 40 nt and is nearly symmetrical around the dimer. The ternary complex formed at the lesion site is rather stable, with a half-life of approximately 20 h. Surprisingly, addition of human repair proteins results in repair of transcription-blocking dimers in the ternary complex. The blocked polymerase neither inhibits nor stimulates repair and repair is observed in the absence of CSB protein, the putative human transcription-repair coupling factor.

Transcription and DNA damage: a link to a kink

Living organisms are constantly exposed to a variety of naturally occurring and man-made chemical and physical agents that pose threats to health by causing cancer and other illnesses, as well as cell death. One mechanism by which these moieties can exert their toxic effects is by inducing modifications to the genome. Such changes in DNA often result in the formation of nucleotides not normally found in the double helix, bases containing covalent chemical alterations, single- and double-strand breaks, and interstrand and intrastrand cross-links. When these lesions are present during replication, mutations often result in the newly synthesized DNA. Likewise, when such damage occurs in a gene, transcription elongation, and hence expression, can be adversely affected because of pausing or arresting of the RNA polymerase at or near the altered site; this could result in the synthesis of a defective RNA molecule. It has become increasingly clear that transcription and DNA damage are intimately linked, since the removal of certain adducts from the genome is highly dependent on their location. When such lesions are present on the transcribed strand of actively expressed genetic loci, they are better cleared from that strand when compared to the complementary DNA or other quiescent regions. This process is called transcription-coupled DNA repair, and it modulates the mutagenic spectrum of many DNA-damaging agents. Furthermore, based upon evidence from systems in which it is absent, this process has a profound effect on ameliorating the adverse consequences of exposure to many environmentally relevant genotoxins. The precise cellular pathway that mediates the preferential clearance of DNA damage from active genetic loci has not yet been established, but it appears to be effected by a repertoire of proteins that are also involved in other DNA repair pathways and transcription as well as some factors that might be unique to it. Because a cellular process as indispensable as gene expression can be thwarted by the presence of DNA damage, an understanding of the mechanism underlying transcription-coupled DNA repair is relevant to the continued discernment of how environmental genotoxins endanger human health.

Formation and processing of UV photoproducts: effects of DNA sequence and chromatin environment

Cyclobutane pyrimidine dimers and (6-4) photoproducts are the two major classes of lesions produced in DNA by UVB and UVC irradiation. Their distribution along genes is nucleotide sequence-dependent. In vivo, the frequency of these lesions at specific sites is modulated by nucleosomes and other DNA binding proteins. Repair of UV photoproducts is dependent on the transcriptional status of the sequences to be repaired and on the chromatin environment. The formation of DNA photolesions by UV light is responsible for the induction of mutations and the development of skin cancer. To understand the mechanisms of UV mutagenesis, it is important to know how these lesions are formed, by which cellular pathways they are repaired and how they are dealt with by DNA polymerases.

Basic mechanisms of transcript elongation and its regulation

Ternary complexes of DNA-dependent RNA polymerase with its DNA template and nascent transcript are central intermediates in transcription. In recent years, several unusual biochemical reactions have been discovered that affect the progression of RNA polymerase in ternary complexes through various transcription units. These reactions can be signaled intrinsically, by nucleic acid sequences and the RNA polymerase, or extrinsically, by protein or other regulatory factors. These factors can affect any of these processes, including promoter proximal and promoter distal pausing in both prokaryotes and eukaryotes, and therefore play a central role in regulation of gene expression. In eukaryotic systems, at least two of these factors appear to be related to cellular transformation and human cancers. New models for the structure of ternary complexes, and for the mechanism by which they move along DNA, provide plausible explanations for novel biochemical reactions that have been observed. These models predict that RNA polymerase moves along DNA without the constant possibility of dissociation and consequent termination. A further prediction of these models is that the polymerase can move in a discontinuous or inchworm-like manner. Many direct predictions of these models have been confirmed. However, one feature of RNA chain elongation not predicted by the model is that the DNA sequence can determine whether the enzyme moves discontinuously or monotonically. In at least two cases, the encounter between the RNA polymerase and a DNA block to elongation appears to specifically induce a discontinuous mode of synthesis. These findings provide important new insights into the RNA chain elongation process and offer the prospect of understanding many significant biological regulatory systems at the molecular level.

UV-induced ubiquitination of RNA polymerase II: a novel modification deficient in Cockayne syndrome cells

Damage to actively transcribed DNA is preferentially repaired by the transcription-coupled repair (TCR) system. TCR requires RNA polymerase II (Pol II), but the mechanism by which repair enzymes preferentially recognize and repair DNA lesions on Pol II-transcribed genes is incompletely understood. Herein we demonstrate that a fraction of the large subunit of Pol II (Pol II LS) is ubiquitinated after exposing cells to UV-radiation or cisplatin but not several other DNA damaging agents. This novel covalent modification of Pol II LS occurs within 15 min of exposing cells to UV-radiation and persists for about 8-12 hr. Ubiquitinated Pol II LS is also phosphorylated on the C-terminal domain. UV-induced ubiquitination of Pol II LS is deficient in fibroblasts from individuals with two forms of Cockayne syndrome (CS-A and CS-B), a rare disorder in which TCR is disrupted. UV-induced ubiquitination of Pol II LS can be restored by introducing cDNA constructs encoding the CSA or CSB genes, respectively, into CS-A or CS-B fibroblasts. These results suggest that ubiquitination of Pol II LS plays a role in the recognition and/or repair of damage to actively transcribed genes. Alternatively, these findings may reflect a role played by the CSA and CSB gene products in transcription.

TFIIH-mediated nucleotide excision repair and initiation of mRNA transcription in an optimized cell-free DNA repair and RNA transcription assay

In mammalian cells, mRNA transcription is initiated with the aid of transcription initiation factors. Of these, TFIIH has also been shown to play an essential role in nucleotide excision repair (NER), which is a versatile biochemical pathway that corrects a broad range of DNA damage. Since the dual role of TFIIH is conserved among eukaryotes, including yeast and mammalian cells, the sharing of TFIIH between NER and RNA transcription initiation might provide some survival advantage. However, the functional relationship between NER and RNA transcription initiation through TFIIH is not yet understood. We have developed an optimized cell-free assay which allows us to analyze NER and RNA transcription under identical conditions. In this assay, NER did not compete with RNA transcription, probably because the extracts contained sufficient amounts of TFIIH to support both processes. Thus, NER can be considered functionally independent of RNA transcription initiation despite the fact that both processes use the same factor.

Transcription-coupled and global genome repair in the Saccharomyces cerevisiae RPB2 gene at nucleotide resolution

Repair of UV-induced cyclobutane pyrimidine dimers (CPDs) was examined at single nucleotide resolution in the yeast Saccharomyces cerevisiae, using an improved protocol for genomic end-labelling. To obtain the sensitivity required for adduct detection in yeast, an oligonucleotide-directed enrichment step was introduced into the current methodology developed for adduct detection in Escherichia coli. With this method, heterogeneous repair of CPDs within the RPB2 locus is observed. Individual CPDs positioned in the transcribed strand are removed very efficiently with identical kinetics. This fast repair starts within 23 bases downstream of the transcription initiation site. The non-transcribed strand of the active gene exhibits slow repair without detectable repair variations between individual lesions. In contrast, CPDs positioned in the promoter region show profound repair heterogeneity. Here, CPDs at specific sites are removed very quickly, with comparable rates to CPDs positioned in the transcribed strand, while at other positions lesions are not repaired at all during the period studied. Interestingly, the fast repair in the promoter region is dependent on the RAD7 and RAD16 genes, as are the slowly repaired CPDs in this region and in the non-transcribed strand. This indicates that the global genome repair pathway is not intrinsically slow and at specific positions can be as efficient as the transcription-coupled repair pathway.

The RNA polymerase II general elongation factors

Synthesis of eukaryotic messenger RNA by RNA polymerase II is governed by the concerted action of a set of general transcription factors that control the activity of polymerase during both the initiation and elongation stages of transcription. To date, five general elongation factors [P-TEFb, SII, TFIIF, Elongin (SIII) and ELL] have been defined biochemically. Here, we discuss these transcription factors and their roles in controlling the activity of the RNA polymerase II elongation complex.

RNA polymerase signals UvrAB landing sites

Transcription when coupled to nucleotide excision repair specifies the location in active genes where preferential DNA repair is to take place. During DNA damage-induced recruitment of RNA polymerase (RNAP), there is a physical association of the beta subunit of Escherichia coli RNAP and the UvrA component of the repair apparatus (G. C. Lin and L. Grossman, submitted for publication). This molecular affinity is reflected in the ability of the RNAP to increase, in a promoter-dependent manner, DNA supercoiling by the UvrAB complex. In the presence of the RNAP, the UvrAB complex is able to bind to promoter regions and to translocate in a 5' to 3' direction along the non-transcribed strand. As a consequence of this helicase-catalyzed translocation, preferential incision of DNA damaged sites occurs downstream on the transcribed strand. Because of the helicase directionality, the initial binding of the UvrAB complex to the transcribed strand would inevitably lead to its collision with the RNAP. These results imply that the RNAP-induced DNA structure in the vicinity of the transcription start site signals a landing or entry site for the UvrAB complex on DNA.

Mismatch repair mutants in yeast are not defective in transcription-coupled DNA repair of UV-induced DNA damage

Transcription-coupled repair, the targeted repair of the transcribed strands of active genes, is defective in bacteria, yeast, and human cells carrying mutations in mfd, RAD26 and ERCC6, respectively. Other factors probably are also uniquely involved in transcription-repair coupling. Recently, a defect was described in transcription-coupled repair for Escherichia coli mismatch repair mutants and human tumor cell lines with mutations in mismatch repair genes. We examined removal of UV-induced DNA damage in yeast strains mutated in mismatch repair genes in an effort to confirm a defect in transcription-coupled repair in this system. In addition, we determined the contribution of the mismatch repair gene MSH2 to transcription-coupled repair in the absence of global genomic repair using rad7 delta mutants. We also determined whether the Rad26-independent transcription-coupled repair observed in rad26 delta and rad7 delta rad26 delta mutants depends on MSH2 by examining repair deficiencies of rad26 delta msh2 delta and rad7 delta rad26 delta msh2 delta mutants. We found no defects in transcription-coupled repair caused by mutations in the mismatch repair genes MSH2, MLH1, PMS1, and MSH3. Yeast appears to differ from bacteria and human cells in the capacity for transcription-coupled repair in a mismatch repair mutant background.

DNA DAMAGE AND REPAIR IN PLANTS

The biological impact of any DNA damaging agent is a combined function of the chemical nature of the induced lesions and the efficiency and accuracy of their repair. Although much has been learned from microbes and mammals about both the repair of DNA damage and the biological effects of the persistence of these lesions, much remains to be learned about the mechanism and tissue-specificity of repair in plants. This review focuses on recent work on the induction and repair of DNA damage in higher plants, with special emphasis on UV-induced DNA damage products.

Effects of aminofluorene and acetylaminofluorene DNA adducts on transcriptional elongation by RNA polymerase II

A prominent model for the mechanism of transcription-coupled DNA repair proposes that an arrested RNA polymerase directs the nucleotide excision repair complex to the transcription-blocking lesion. The specific role for RNA polymerase II in this mechanism can be examined by comparing the extent of polymerase arrest with the extent of transcription-coupled repair for a specific DNA lesion. Previously we reported that a cyclobutane pyrimidine dimer that is repaired preferentially in transcribed genes is a strong block to transcript elongation by RNA pol II (Donahue, B.A., Yin, S., Taylor, J.-S., Reines, D., and Hanawalt, P. C. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 8502-8506). Here we report the extent of RNA polymerase II arrest by the C-8 guanine DNA adduct formed by N-2-aminofluorene, a lesion that does not appear to be preferentially repaired. Templates for an in vitro transcription assay were constructed with either an N-2-aminofluorene adduct or the helix-distorting N-2-acetylaminofluorene adduct situated at a specific site downstream from the major late promoter of adenovirus. Consistent with the model for transcription-coupled repair, an aminofluorene adduct located on the transcribed strand was a weak pause site for RNA polymerase II. An acetylaminofluorene adduct located on the transcribed strand was an absolute block to transcriptional elongation. Either adduct located on the nontranscribed strand enhanced polymerase arrest at a nearby sequence-specific pause site.

Role of transcription-coupled DNA repair in susceptibility to environmental carcinogenesis

Susceptibility to environmental carcinogenesis is the consequence of a complex interplay between intrinsic hereditary factors and actual exposures to potential carcinogenic agents. We must learn the nature of these interactions as well as the genetic defects that confer enhanced risk. In some genetic diseases an increased cancer risk correlates with a defect in the repair or replications of damaged DNA. Examples include xeroderma pigmentosum (XP), ataxia telangiectasia, Fanconi's anemia, and Bloom's syndrome. In Cockayne's syndrome the Specific defect in transcription-coupled repair (TCR) does not predispose the patients to the sunlight-induced skin cancer characteristic of XP. The demonstration of TCR in the XP129 partial revertant of XP-A cells indicates that ultraviolet (UV) resistance correlates with repair of cyclobutane pyrimidine dimers in active genes. Repair measured as an average over the genome can be misleading, and it is necessary to consider genomic locations of DNA damage and repair for a meaningful assessment of the biological importance of particular DNA lesions. Mutations in the p53 tumor suppressor gene are found in many human tumors. TCR accounts for the resulting mutational spectra in the p53 gene in certain tumors. Li-Fraumeni syndrome fibroblasts expressing only mutant p53 are more UV-resistant and exhibit less UV-induced apoptosis than normal human cells or heterozygotes for mutations in only one allele of p53. The p53-defective cells are deficient in global excision repair capacity but have retained TCR. The loss of p53 function may lead to greater genomic instability by reducing the efficiency of global DNA repair while cellular resistance may be assured through the operation of TCR and the elimination of apoptosis.

Complete replication of plasmid DNA containing a single UV-induced lesion in human cell extracts

To investigate the effect of the major UV-induced lesions on SV40 origin-dependent DNA replication and mutagenesis in a mammalian cell extract, double-stranded plasmids containing a single cis,syn-cyclobutane dimer or a pyrimidine-pyrimidone (6-4) photoproduct at a unique TT sequence have been constructed. These plasmids have been used as templates in DNA replication-competent extracts from human HeLa cells. Plasmids containing a single pyrimidine cyclobutane dimer on the potential lagging strand for DNA replication are replicated with an efficiency approximately equal to that of an unmodified plasmid. A small decrease in replication efficiency of approximately 20% was observed when the lesion was located on the potential leading strand for DNA replication. In both orientations, DpnI-resistant, replicated closed circular plasmid DNA was sensitive to nicking by the pyrimidine dimer-specific enzyme, T4 endonuclease V, indicating that complete replication of the damaged plasmid occurs in vitro. In contrast, a (6-4) photoproduct, within the same site and sequence context on the lagging strand for DNA synthesis, inhibits replication in vitro by an average of approximately 50%, indicating that the mammalian replication complex responds differently to the two major UV-induced lesions during DNA replication in vitro. Analysis of the DpnI-resistant, replicated DNA for mutations targeted to the lesion site indicates that neither of these lesions resulted in significant mutagenesis. UV-induced lesions at TT sites may therefore be poorly mutagenic under these conditions for DNA replication in human cell extracts in vitro.

The molecular basis of somatic hypermutation of immunoglobulin genes

Somatic hypermutation amplifies the variable region repertoire of immunoglobulin genes. Recent experimental evidence has thrown light on various molecular models of somatic hypermutation. A link between somatic hypermutation and transcription coupled DNA repair is shaping up.