O6-methylguanine-induced transcriptional mutagenesis reduces p53 tumor-suppressor function.

Altered protein function due to mutagenesis plays an important role in disease development. This is perhaps most evident in tumorigenesis and the associated loss or gain of function of tumor-suppressor genes and oncogenes. The extent to which lesion-induced transcriptional mutagenesis (TM) influences protein function and its contribution to the development of disease is not well understood. In this study, the impact of O6-methylguanine on the transcription fidelity of p53 and the subsequent effects on the protein's function as a regulator of cell death and cell-cycle arrest were examined in human cells. Levels of TM were determined by RNA-sequencing. In cells with active DNA repair, misincorporation of uridine opposite the lesion occurred in 0.14% of the transcripts and increased to 14.7% when repair by alkylguanine-DNA alkyltransferase was compromised. Expression of the dominant-negative p53 R248W mutant due to TM significantly reduced the transactivation of several established p53 target genes that mediate the tumor-suppressor function, including CDKN1A (p21) and BBC3 (PUMA). This resulted in deregulated signaling through the retinoblastoma protein and loss of G1/S cell-cycle checkpoint function. In addition, we observed impaired activation of apoptosis coupled to the reduction of the tumor-suppressor functions of p53. Taking these findings together, this work provides evidence that TM can induce phenotypic changes in mammalian cells that have important implications for the role of TM in tumorigenesis.

Genetic instability associated with loop or stem-loop structures within transcription units can be independent of nucleotide excision repair.

Simple sequence repeats (SSRs) are found throughout the genome, and under some conditions can change in length over time. Germline and somatic expansions of trinucleotide repeats are associated with a series of severely disabling illnesses, including Huntington's disease. The underlying mechanisms that effect SSR expansions and contractions have been experimentally elusive, but models suggesting a role for DNA repair have been proposed, in particular the involvement of transcription-coupled nucleotide excision repair (TCNER) that removes transcription-blocking DNA damage from the transcribed strand of actively expressed genes. If the formation of secondary DNA structures that are associated with SSRs were to block RNA polymerase progression, TCNER could be activated, resulting in the removal of the aberrant structure and a concomitant change in the region's length. To test this, TCNER activity in primary human fibroblasts was assessed on defined DNA substrates containing extrahelical DNA loops that lack discernible internal base pairs or DNA stem-loops that contain base pairs within the stem. The results show that both structures impede transcription elongation, but there is no corresponding evidence that nucleotide excision repair (NER) or TCNER operates to remove them.

The Nonbulky DNA Lesions Spiroiminodihydantoin and 5-Guanidinohydantoin Significantly Block Human RNA Polymerase II Elongation in Vitro.

The most common, oxidatively generated lesion in cellular DNA is 8-oxo-7,8-dihydroguanine, which can be oxidized further to yield highly mutagenic spiroiminodihydantoin (Sp) and 5-guanidinohydantoin (Gh) in DNA. In human cell-free extracts, both lesions can be excised by base excision repair and global genomic nucleotide excision repair. However, it is not known if these lesions can be removed by transcription-coupled DNA repair (TCR), a pathway that clears lesions from DNA that impede RNA synthesis. To determine if Sp or Gh impedes transcription, which could make each a viable substrate for TCR, either an Sp or a Gh lesion was positioned on the transcribed strand of DNA under the control of a promoter that supports transcription by human RNA polymerase II. These constructs were incubated in HeLa nuclear extracts that contained active RNA polymerase II, and the resulting transcripts were resolved by denaturing polyacrylamide gel electrophoresis. The structurally rigid Sp strongly blocks transcription elongation, permitting 1.6 ± 0.5% nominal lesion bypass. In contrast, the conformationally flexible Gh poses less of a block to human RNAPII, allowing 9 ± 2% bypass. Furthermore, fractional lesion bypass for Sp and Gh is minimally affected by glycosylase activity found in the HeLa nuclear extract. These data specifically suggest that both Sp and Gh may well be susceptible to TCR because each poses a significant block to human RNA polymerase II progression. A more general principle is also proposed: Conformational flexibility may be an important structural feature of DNA lesions that enhances their transcriptional bypass.

Nucleotide Excision Repair and Transcription-coupled DNA Repair Abrogate the Impact of DNA Damage on Transcription.

DNA adducts derived from carcinogenic polycyclic aromatic hydrocarbons like benzo[a]pyrene (B[a]P) and benzo[c]phenanthrene (B[c]Ph) impede replication and transcription, resulting in aberrant cell division and gene expression. Global nucleotide excision repair (NER) and transcription-coupled DNA repair (TCR) are among the DNA repair pathways that evolved to maintain genome integrity by removing DNA damage. The interplay between global NER and TCR in repairing the polycyclic aromatic hydrocarbon-derived DNA adducts (+)-trans-anti-B[a]P-N(6)-dA, which is subject to NER and blocks transcription in vitro, and (+)-trans-anti-B[c]Ph-N(6)-dA, which is a poor substrate for NER but also blocks transcription in vitro, was tested. The results show that both adducts inhibit transcription in human cells that lack both NER and TCR. The (+)-trans-anti-B[a]P-N(6)-dA lesion exhibited no detectable effect on transcription in cells proficient in NER but lacking TCR, indicating that NER can remove the lesion in the absence of TCR, which is consistent with in vitro data. In primary human cells lacking NER, (+)-trans-anti-B[a]P-N(6)-dA exhibited a deleterious effect on transcription that was less severe than in cells lacking both pathways, suggesting that TCR can repair the adduct but not as effectively as global NER. In contrast, (+)-trans-anti-B[c]Ph-N(6)-dA dramatically reduces transcript production in cells proficient in global NER but lacking TCR, indicating that TCR is necessary for the removal of this adduct, which is consistent with in vitro data showing that it is a poor substrate for NER. Hence, both global NER and TCR enhance the recovery of gene expression following DNA damage, and TCR plays an important role in removing DNA damage that is refractory to NER.

O6-methylguanine induces altered proteins at the level of transcription in human cells.

O(6)-Methylguanine (O(6)-meG), which is produced in DNA following exposure to methylating agents, instructs human RNA polymerase II to mis-insert bases opposite the lesion during transcription. In this study, we examined the effect of O(6)-meG on transcription in human cells and investigated the subsequent effects on protein function following translation of the resulting mRNA. In HEK293 cells, O(6)-meG induced incorporation of uridine or cytidine in nascent RNA opposite the adduct. In cells containing active O(6)-alkylguanine-DNA alkyltransferase (AGT), which repairs O(6)-meG, 3% misincorporation of uridine was observed opposite the lesion. In cells where AGT function was compromised by addition of the AGT inhibitor O(6)-benzylguanine, ∼ 58% of the transcripts contained a uridine misincorporation opposite the lesion. Furthermore, the altered mRNA induced changes to protein function as demonstrated through recovery of functional red fluorescent protein (RFP) from DNA coding for a non-fluorescent variant of RFP. These data show that O(6)-meG is highly mutagenic at the level of transcription in human cells, leading to an altered protein load, especially when AGT is inhibited.

Benzo[a]pyrene diol epoxide stimulates an inflammatory response in normal human lung fibroblasts through a p53 and JNK mediated pathway.

Cellular responses to carcinogens are typically studied in transformed cell lines, which do not reflect the physiological status of normal tissues. To address this question, we have characterized the transcriptional program and cellular responses of human lung WI-38 fibroblasts upon exposure to the ultimate carcinogen benzo[a]pyrene diol epoxide (BPDE). In contrast to observations in cell lines, we find that BPDE treatment induces a strong inflammatory response in these normal fibroblasts. Whole-genome microarrays show induction of numerous inflammatory factors, including genes that encode interleukins (ILs), growth factors and enzymes related to prostaglandin synthesis and signaling. Real-time reverse transcription-polymerase chain reaction and enzyme-linked immunosorbent assay (ELISA) revealed a time- and dose-dependent-induced expression and production of cyclooxygenase 2, prostglandin E2 and IL1B, IL6 and IL8. In parallel, cell cycle progression and DNA repair processes were repressed, but DNA damage signaling was increased via p53-Ser15 phosphorylation and induced expression levels of GADD45A, CDKN1A, BTG2 and SESN1. Network analysis suggested that activator protein 1 transcription factors may link the cell cycle response and DNA damage signaling with the inflammatory stress-response in these cells. We confirmed this hypothesis by showing that p53-dependent signaling through c-jun N-terminal kinase (JNK) led to increased cJun-Ser63 phosphorylation and that inhibition of JNK-mediated cJun activation using p53- or JNK-specific inhibitors significantly reduced IL gene expression and subsequent production of IL8. This is the first demonstration that a strong inflammatory response is triggered in normal fibroblasts by BPDE and that this occurs through coordinated regulation with other cellular processes.

Transcription elongation past O6-methylguanine by human RNA polymerase II and bacteriophage T7 RNA polymerase.

O(6)-Methylguanine (O(6)-meG) is a major mutagenic, carcinogenic and cytotoxic DNA adduct produced by various endogenous and exogenous methylating agents. We report the results of transcription past a site-specifically modified O(6)-meG DNA template by bacteriophage T7 RNA polymerase and human RNA polymerase II. These data show that O(6)-meG partially blocks T7 RNA polymerase and human RNA polymerase II elongation. In both cases, the sequences of the truncated transcripts indicate that both polymerases stop precisely at the damaged site without nucleotide incorporation opposite the lesion, while extensive misincorporation of uracil is observed in the full-length RNA. For both polymerases, computer models suggest that bypass occurs only when O(6)-meG adopts an anti conformation around its glycosidic bond, with the methyl group in the proximal orientation; in contrast, blockage requires the methyl group to adopt a distal conformation. Furthermore, the selection of cytosine and uracil partners opposite O(6)-meG is rationalized with modeled hydrogen-bonding patterns that agree with experimentally observed O(6)-meG:C and O(6)-meG:U pairing schemes. Thus, in vitro, O(6)-meG contributes substantially to transcriptional mutagenesis. In addition, the partial blockage of RNA polymerase II suggests that transcription-coupled DNA repair could play an auxiliary role in the clearance of this lesion.

Transcription of DNA containing the 5-guanidino-4-nitroimidazole lesion by human RNA polymerase II and bacteriophage T7 RNA polymerase.

Damage in transcribed DNA presents a challenge to the cell because it can partially or completely block the progression of an RNA polymerase, interfering with transcription and compromising gene expression. While blockage of RNA polymerase progression is thought to trigger the recruitment of transcription-coupled DNA repair (TCR), bypass of the lesion can also occur, either error-prone or error-free. Error-prone transcription is often referred to as transcriptional mutagenesis (TM). Elucidating why some lesions pose blocks to transcription elongation while others do not remains a challenging problem. As part of an effort to understand this, we studied transcription past a 5-guanidino-4-nitroimidazole (NI) lesion, using two structurally different RNA polymerases, human RNA polymerase II (hRNAPII) and bacteriophage T7 RNA polymerase (T7RNAP). The NI damage results from the oxidation of guanine in DNA by peroxynitrite, a well known, biologically important oxidant. It is of structural interest because it is a ring-opened and conformationally flexible guanine lesion. Our results show that NI acts as a partial block to T7RNAP while posing a major block to hRNAPII, which has a more constrained active site than T7RNAP. Lesion bypass by T7RNAP induces base misincorporations and deletions opposite the lesion (C>A>-1 deletion >G >>> U), but hRNAPII exhibits error-free transcription although lesion bypass is a rare event. We employed molecular modeling methods to explain the observed blockage or bypass accompanied by nucleotide incorporation opposite the lesion. The results of the modeling studies indicate that NI's multiple hydrogen-bonding capabilities and torsional flexibility are important determinants of its effect on transcription in both enzymes. These influence the kinetics of lesion bypass and may well play a role in TM and TCR in cells.

Transcription processing at 1,N2-ethenoguanine by human RNA polymerase II and bacteriophage T7 RNA polymerase.

The DNA lesion 1,N(2)-ethenoguanine (1,N(2)-epsilon G) is formed endogenously as a by-product of lipid peroxidation or by reaction with epoxides that result from the metabolism of the industrial pollutant vinyl chloride, a known human carcinogen. DNA replication past 1,N(2)-epsilon G and site-specific mutagenesis studies on mammalian cells have established the highly mutagenic and genotoxic properties of the damaged base. However, there is as yet no information on the processing of this lesion during transcription. Here, we report the results of transcription past a site-specifically modified 1,N(2)-epsilon G DNA template. This lesion contains an exocyclic ring obstructing the Watson-Crick hydrogen-bonding edge of guanine. Our results show that 1,N(2)-epsilon G acts as a partial block to the bacteriophage T7 RNA polymerase (RNAP), which allows nucleotide incorporation in the growing RNA with the selectivity A>G>(C=-1 deletion)>>U. In contrast, 1,N(2)-epsilon G poses an absolute block to human RNAP II elongation, and nucleotide incorporation opposite the lesion is not observed. Computer modeling studies show that the more open active site of T7 RNAP allows lesion bypass when the 1,N(2)-epsilon G adopts the syn-conformation. This orientation places the exocyclic ring in a collision-free empty pocket of the polymerase, and the observed base incorporation preferences are in agreement with hydrogen-bonding possibilities between the incoming nucleotides and the Hoogsteen edge of the lesion. On the other hand, in the more crowded active site of the human RNAP II, the modeling studies show that both syn- and anti-conformations of the 1,N(2)-epsilon G are sterically impermissible. Polymerase stalling is currently believed to trigger the transcription-coupled nucleotide excision repair machinery. Thus, our data suggest that this repair pathway is likely engaged in the clearance of the 1,N(2)-epsilon G from actively transcribed DNA.

Increased flexibility enhances misincorporation: temperature effects on nucleotide incorporation opposite a bulky carcinogen-DNA adduct by a Y-family DNA polymerase.

The Y-family DNA polymerase Dpo4, from the thermophilic crenarchaeon Sulfolobus solfataricus P2, offers a valuable opportunity to investigate the effect of conformational flexibility on the bypass of bulky lesions because of its ability to function efficiently at a wide range of temperatures. Combined molecular modeling and experimental kinetic studies have been carried out for 10S-(+)-trans-anti-[BP]-N2-dG ((+)-ta-[BP]G), a lesion derived from the covalent reaction of a benzo[a]pyrene metabolite with guanine in DNA, at 55 degrees C and results compared with an earlier study at 37 degrees C (Perlow-Poehnelt, R. A., Likhterov, I., Scicchitano, D. A., Geacintov, N. E., and Broyde, S. (2004) J. Biol. Chem. 279, 36951-36961). The experimental results show that there is more overall nucleotide insertion opposite (+)-ta-[BP]G due to particularly enhanced mismatch incorporation at 55 degrees C compared with 37 degrees C. The molecular dynamics simulations suggest that mismatched nucleotide insertion opposite (+)-ta-[BP]G is increased at 55 degrees C compared with 37 degrees C because the higher temperature shifts the preference of the damaged base from the anti to the syn conformation, with the carcinogen on the more open major groove side. The mismatched dNTP structures are less distorted when the damaged base is syn than when it is anti, at the higher temperature. However, with the normal partner dCTP, the anti conformation with close to Watson-Crick alignment remains more favorable. The molecular dynamics simulations are consistent with the kcat values for nucleotide incorporation opposite the lesion studied, providing structural interpretation of the experimental observations. The observed temperature effect suggests that conformational flexibility plays a role in nucleotide incorporation and bypass fidelity opposite (+)-ta-[BP]G by Dpo4.

Transcription past DNA adducts derived from polycyclic aromatic hydrocarbons.

The ability of a DNA lesion to block transcription is a function of many variables: (1) the ability of the RNA polymerase active site to accommodate the damaged base; (2) the size and shape of the adduct, which includes the specific modified base; (3) the stereochemistry of the adduct; (4) the base incorporated into the growing transcript; (5) and the local DNA sequence. Each of these parameters, either alone or in combination, can influence how a particular lesion in the genome will affect transcription elongation, resulting in potential clearance of the lesion via transcription-coupled DNA repair or in the formation of truncated or full-length transcripts that might encode defective proteins.

Transcription and DNA adducts: what happens when the message gets cut off?

DNA damage located within a gene's transcription unit can cause RNA polymerase to stall at the modified site, resulting in a truncated transcript, or progress past, producing full-length RNA. However, it is not immediately apparent why some lesions pose strong barriers to elongation while others do not. Studies using site-specifically damaged DNA templates have demonstrated that a wide range of lesions can impede the progress of elongating transcription complexes. The collected results of this work provide evidence for the idea that subtle structural elements can influence how an RNA polymerase behaves when it encounters a DNA adduct during elongation. These elements include: (1) the ability of the RNA polymerase active site to accommodate the damaged base; (2) the size and shape of the adduct, which includes the specific modified base; (3) the stereochemistry of the adduct; (4) the base incorporated into the growing transcript; and (5) the local DNA sequence.

The spacious active site of a Y-family DNA polymerase facilitates promiscuous nucleotide incorporation opposite a bulky carcinogen-DNA adduct: elucidating the structure-function relationship through experimental and computational approaches.

Y-family DNA polymerases lack some of the mechanisms that replicative DNA polymerases employ to ensure fidelity, resulting in higher error rates during replication of undamaged DNA templates and the ability to bypass certain aberrant bases, such as those produced by exposure to carcinogens, including benzo[a]pyrene (BP). A tumorigenic metabolite of BP, (+)-anti-benzo-[a]pyrene diol epoxide, attacks DNA to form the major 10S (+)-trans-anti-[BP]-N(2)-dG adduct, which has been shown to be mutagenic in a number of prokaryotic and eukaryotic systems. The 10S (+)-trans-anti-[BP]-N(2)-dG adduct can cause all three base substitution mutations, and the SOS response in Escherichia coli increases bypass of bulky adducts, suggesting that Y-family DNA polymerases are involved in the bypass of such lesions. Dpo4 belongs to the DinB branch of the Y-family, which also includes E. coli pol IV and eukaryotic pol kappa. We carried out primer extension assays in conjunction with molecular modeling and molecular dynamics studies in order to elucidate the structure-function relationship involved in nucleotide incorporation opposite the bulky 10S (+)-trans-anti-[BP]-N(2)-dG adduct by Dpo4. Dpo4 is able to bypass the 10S (+)-trans-anti-[BP]-N(2)-dG adduct, albeit to a lesser extent than unmodified guanine, and the V(max) values for insertion of all four nucleotides opposite the adduct by Dpo4 are similar. Computational studies suggest that 10S (+)-trans-anti-[BP]-N(2)-dG can be accommodated in the active site of Dpo4 in either the anti or syn conformation due to the limited protein-DNA contacts and the open nature of both the minor and major groove sides of the nascent base pair, which can contribute to the promiscuous nucleotide incorporation opposite this lesion.

Human RNA polymerase II is partially blocked by DNA adducts derived from tumorigenic benzo[c]phenanthrene diol epoxides: relating biological consequences to conformational preferences.

Environmental polycyclic aromatic hydrocarbons (PAHs) are metabolically activated to diol epoxides that can react with DNA, resulting in covalent modifications to the bases. The (+)- and (-)-3,4-dihydroxy-1,2-epoxy-1,2,3,4-tetrahydro-benzo[c]phenanthrene (anti-BPhDE) isomers are diol epoxide metabolites of the PAH benzo[c]phenanthrene (BPh). These enantiomers readily react with DNA at the N6 position of adenine, forming bulky (+)-1R- or (-)-1S-trans-anti-[BPh]-N6-dA adducts. Transcription-coupled nucleotide excision repair clears such bulky adducts from cellular DNA, presumably in response to RNA polymerase transcription complexes that stall at the bulky lesions. Little is known about the effects of [BPh]-N6-dA lesions on RNA polymerase II, hence, the behavior of human RNA polymerase II was examined at these adducts. A site-specific, stereochemically pure [BPh]-N6-dA adduct was positioned on the transcribed or non-transcribed strand of a DNA template with a suitable promoter for RNA polymerase II located upstream from the lesion. Transcription reactions were then carried out with HeLa nuclear extract. Each [BPh]-dA isomer strongly impeded human RNA polymerase II progression when it was located on the transcribed strand; however, a small but significant degree of lesion bypass occurred, and the extent of polymerase blockage and bypass was dependent on the stereochemistry of the adduct. Molecular modeling of the lesions supports the idea that each adduct can exist in two orientations within the polymerase active site, one that permits nucleotide incorporation and another that blocks the RNA polymerase nucleotide entry channel, thus preventing base incorporation and causing the polymerase to stall or arrest.

Construction and purification of site-specifically modified DNA templates for transcription assays.

Chemical and physical agents can alter the structure of DNA by modifying the bases and the phosphate-sugar backbone, consequently compromising both replication and transcription. During transcription elongation, RNA polymerase complexes can stall at a damaged site in DNA and mark the lesion for repair by a subset of proteins that are utilized to execute nucleotide excision repair, a pathway commonly associated with the removal of bulky DNA damage from the genome. This RNA polymerase-induced repair pathway is called transcription-coupled nucleotide excision repair. Although our understanding of DNA lesion effects on transcription elongation and the associated effects of stalled transcription complexes on DNA repair is broadening, the attainment of critical data is somewhat impeded by labor-intensive, time- consuming processes that are required to prepare damaged DNA templates. Here, we describe an approach for building linear DNA templates that contain a single, site-specific DNA lesion and support transcription by human RNA polymerase II. The method is rapid, making use of biotin-avidin interactions and paramagnetic particles to purify the final product. Data are supplied demonstrating that these templates support transcription, and we emphasize the potential versatility of the protocol and compare it with other published methods.

DNA adducts from a tumorigenic metabolite of benzo[a]pyrene block human RNA polymerase II elongation in a sequence- and stereochemistry-dependent manner.

Many carcinogens exert their cancer-causing effects by reacting with DNA either directly or following metabolic activation, resulting in covalently linked combination molecules known as carcinogen-DNA adducts. The presence of such lesions in the genome increases the error frequency of the replication machinery, causing mutations that contribute to the initiation and progression of cancer. Cellular DNA repair pathways remove carcinogen adducts from DNA, thus averting the mutagenic potential of many DNA lesions by reducing their presence in the genome. Bulky DNA adducts, like those derived from a number of activated environmental carcinogens such as polycyclic aromatic hydrocarbons (PAHs), are primarily repaired by the nucleotide excision repair (NER) pathway. Transcription-coupled NER (TC-NER) preferentially removes lesions from the transcribed strand of actively expressed genes, and RNA polymerase II stalled at the lesion quite possibly initiates the pathway. Among the bulky DNA adducts that are subject to TC-NER are those resulting from the reaction of the metabolically activated PAH benzo[a]pyrene (BP) with DNA. The P450 mixed-function oxygenases convert BP into a number of reactive intermediates, including tumorigenic (+)- and non-tumorigenic (-)-anti-benzo[a]pyrene diol epoxide (BPDE) that react with DNA via trans epoxide opening to form (+)-trans-anti-[BP]-N(2)-dG ((+)-ta[BP]G) and (-)-trans-anti-[BP]-N(2)-dG ((-)-ta[BP]G), respectively. To test the effect of these lesions on RNA synthesis, in vitro transcription assays using human nuclear extracts were performed with DNA templates containing an RNAPII promoter and a stereochemically pure (+)- or (-)-ta[BP]G adduct on the transcribed or non-transcribed strand. Transcription past (+)- or (-)-ta[BP]G adducts was investigated in the same sequence context to examine stereochemical effects. The (+)-ta[BP]G adduct was investigated in two different local sequence contexts to determine if the surrounding bases influence the adduct's ability to block transcription. These experiments revealed that (+)- and (-)-ta[BP]G adducts on the transcribed strand of the DNA template block RNAPII in a sequence and stereochemistry-dependent manner; however, adducts on the non-transcribed strand do not block elongation significantly but may increase pausing at innate pause sites. In order to elucidate biologically influential differences between the (+)- and (-)-ta[BP]G structures, the DUPLEX program was used to carry out potential energy minimization searches at model transcription junctions. The lowest-energy minimum for the (+)-ta[BP]G adduct gives a structure in which the benzo[a]pyrenyl ring system resides in the minor groove of the heteroduplex region. In contrast, the lowest-energy minimum for a (-)-ta[BP]G adduct shows an orientation in which the benzo[a]pyrenyl group adopts a carcinogen/base-stacked conformation. These conformational preferences may contribute to the differential treatment of (+)- and (-)-ta[BP]G adducts by human RNAPII. In addition, while previous experiments showed that BPDE adducts cause T7RNAP to produce a ladder of truncated transcripts, RNAPII is blocked entirely at only one or two positions by the (+)- and (-)-ta[BP]G adducts, depending on sequence context. It is likely that these differences between the behaviors of T7RNAP and human RNAPII are a result of the structural characteristics of the enzymes' active sites, a hypothesis that is explored in light of their known crystal structures.

Base excision repair and nucleotide excision repair contribute to the removal of N-methylpurines from active genes.

Many different cellular pathways have evolved to protect the genome from the deleterious effects of DNA damage that result from exposure to chemical and physical agents. Among these is a process called transcription-coupled repair (TCR) that catalyzes the removal of DNA lesions from the transcribed strand of expressed genes, often resulting in a preferential bias of damage clearance from this strand relative to its non-transcribed counterpart. Lesions subject to this type of repair include cyclobutane pyrimidine dimers that are normally repaired by nucleotide excision repair (NER) and thymine glycols (TGs) that are removed primarily by base excision repair (BER). While the mechanism underlying TCR is not completely clear, it is known that its facilitation requires proteins used by other repair pathways like NER. It is also believed that the signal for TCR is the stalled RNA polymerase that results when DNA damage prevents its translocation during transcription elongation. While there is a clear role for some NER proteins in TCR, the involvement of BER proteins is less clear. To explore this further, we studied the removal of 7-methylguanine (7MeG) and 3-methyladenine (3MeA) from the dihydrofolate reductase (dhfr) gene of murine cell lines that vary in their repair phenotypes. 7MeG and 3MeA constitute the two principal N-methylpurines formed in DNA following exposure to methylating agents. In mammalian cells, alkyladenine DNA alkyladenine glycosylase (Aag) is the major enzyme required for the repair of these lesions via BER, and their removal from the total genome is quite rapid. There is no observable TCR of these lesions in specific genes in DNA repair proficient cells; however, it is possible that the rapid repair of these adducts by BER masks any TCR. The repair of 3MeA and 7MeG was examined in cells lacking Aag, NER, or both Aag and NER to determine if rapid overall repair masks TCR. The results show that both 3MeA and 7MeG are removed without strand bias from the dhfr gene of BER deficient (Aag deficient) and NER deficient murine cell lines. Furthermore, repair of 3MeA in this region is highly dependent on Aag, but repair of 7MeG is equally efficient in the repair proficient, BER deficient, and NER deficient cell lines. Strikingly, in the absence of both BER and NER, neither 7MeG nor 3MeA is repaired. These results demonstrate that NER, but not TCR, contributes to the repair of 7MeG, and to a lesser extent 3MeA.