The Tyr-265-to-Cys mutator mutant of DNA polymerase beta induces a mutator phenotype in mouse LN12 cells

Collapsed State Mediates the Low Fidelity of the DNA Polymerase β I260 Mutant

DNA polymerase β (Pol β) fills single nucleotide gaps during base excision repair. Deficiencies in Pol β can lead to increased mutagenesis and genomic instability in the cell, resulting in cancer. Our laboratory has previously shown that the I260 M somatic mutation of Pol β, which was first identified in prostate cancer, has reduced nucleotide discrimination in a sequence context-dependent manner. I260 M incorporates the incorrect G opposite A in this context more readily than WT. To identify the molecular mechanism of the reduced fidelity of I260M, we studied incorporation using single turnover kinetics and the nature and rates of conformational changes using steady-state fluorescence and Förster resonance energy transfer (FRET). Our data indicate that the I260 M mutation affects the fingers region of rat Pol β by creating a "collapsed" state in both the open (in the absence of nucleotide) and closed (prior to chemistry) states. I260 M is a temperature-sensitive mutator and binds nucleotides tighter than the WT protein, resulting in reduced fidelity compared to the WT. Additionally, we have generated a kinetic model of WT and I260 M using FRET and single turnover data, which demonstrates that I260 M precatalytic conformation changes differ compared to the WT as it is missing a precatalytic noncovalent step. Taken together, these results suggest that the collapsed state of I260 M may decrease its ability for nucleotide discrimination, illustrating the importance of the "fingers closing" conformational change for polymerase fidelity and accurate DNA synthesis.

DNA Polymerase β in the Context of Cancer

DNA polymerase beta (Pol β) is a 39 kD vertebrate polymerase that lacks proofreading ability, yet still maintains a moderate fidelity of DNA synthesis. Pol β is a key enzyme that functions in the base excision repair and non-homologous end joining pathways of DNA repair. Mechanisms of fidelity for Pol β are still being elucidated but are likely to involve dynamic conformational motions of the enzyme upon its binding to DNA and deoxynucleoside triphosphates. Recent studies have linked germline and somatic variants of Pol β with cancer and autoimmunity. These variants induce genomic instability by a number of mechanisms, including error-prone DNA synthesis and accumulation of single nucleotide gaps that lead to replication stress. Here, we review the structure and function of Pol β, and we provide insights into how structural changes in Pol β variants may contribute to genomic instability, mutagenesis, disease, cancer development, and impacts on treatment outcomes.

The hematopoietic compartment is sufficient for lupus development resulting from the POLB-Y265C mutation

Systemic lupus erythematosus is a chronic disease characterized by autoantibodies, renal and cutaneous disease, and immune complex formation. Emerging evidence suggests that aberrant DNA repair is an underlying mechanism of lupus development. We previously showed that the POLBY265C/C mutation, which results in development of an aberrant immune repertoire, leads to lupus-like disease in mice. To address whether the hematopoietic compartment is sufficient for lupus development, we transplanted bone marrow cells from POLBY265C/C and POLB+/+ into wild-type congenic mice. Only mice transplanted with the POLBY265C/C bone marrow develop high levels of antinuclear antibodies and renal disease. In conclusion, we show that the hematopoietic compartment harvested from the POLBY265C/C mice is sufficient for development of autoimmune disease.

DNA glycosylase deficiency leads to decreased severity of lupus in the Polb-Y265C mouse model

The Polb gene encodes DNA polymerase beta (Pol β), a DNA polymerase that functions in base excision repair (BER) and microhomology-mediated end-joining. The Pol β-Y265C protein exhibits low catalytic activity and fidelity, and is also deficient in microhomology-mediated end-joining. We have previously shown that the Polb^Y265C/+ and Polb^Y265C/C mice develop lupus. These mice exhibit high levels of antinuclear antibodies and severe glomerulonephritis. We also demonstrated that the low catalytic activity of the Pol β-Y265C protein resulted in accumulation of BER intermediates that lead to cell death. Debris released from dying cells in our mice could drive development of lupus. We hypothesized that deletion of the Neil1 and Ogg1 DNA glycosylases that act upstream of Pol β during BER would result in accumulation of fewer BER intermediates, resulting in less severe lupus. We found that high levels of antinuclear antibodies are present in the sera of Polb^Y265C/+ mice deleted of Ogg1 and Neil1 DNA glycosylases. However, these mice develop significantly less severe renal disease, most likely due to high levels of IgM in their sera.

Significance of base excision repair to human health

Oxidative and alkylating DNA damage occurs under normal physiological conditions and exogenous exposure to DNA damaging agents. To counteract DNA base damage, cells have evolved several defense mechanisms that act at different levels to prevent or repair DNA base damage. Cells combat genomic lesions like these including base modifications, abasic sites, as well as single-strand breaks, via the base excision repair (BER) pathway. In general, the core BER process involves well-coordinated five-step reactions to correct DNA base damage. In this review, we will uncover the current understanding of BER mechanisms to maintain genomic stability and the biological consequences of its failure due to repair gene mutations. The malfunction of BER can often lead to BER intermediate accumulation, which is genotoxic and can lead to different types of human disease. Finally, we will address the use of BER intermediates for targeted cancer therapy.

I260Q DNA polymerase β highlights precatalytic conformational rearrangements critical for fidelity

DNA polymerase β (pol β) fills single nucleotide gaps in DNA during base excision repair and non-homologous end-joining. Pol β must select the correct nucleotide from among a pool of four nucleotides with similar structures and properties in order to maintain genomic stability during DNA repair. Here, we use a combination of X-ray crystallography, fluorescence resonance energy transfer and nuclear magnetic resonance to show that pol β‘s ability to access the appropriate conformations both before and upon binding to nucleotide substrates is integral to its fidelity. Importantly, we also demonstrate that the inability of the I260Q mutator variant of pol β to properly navigate this conformational landscape results in error-prone DNA synthesis. Our work reveals that precatalytic conformational rearrangements themselves are an important underlying mechanism of substrate selection by DNA pol β.

The Pol β variant containing exon α is deficient in DNA polymerase but has full dRP lyase activity

DNA polymerase (Pol) β is a key enzyme in base excision repair (BER), an important repair system for maintaining genomic integrity. We previously reported the presence of a Pol β transcript containing exon α (105-nucleotide) in normal and colon cancer cell lines. The transcript carried an insertion between exons VI and VII and was predicted to encode a ~42 kDa variant of the wild-type 39 kDa enzyme. However, little is known about the biochemical properties of the exon α-containing Pol β (exon α Pol β) variant. Here, we first obtained evidence indicating expression of the 42 kDa exon α Pol β variant in mouse embryonic fibroblasts. The exon α Pol β variant was then overexpressed in E. coli, purified, and characterized for its biochemical properties. Kinetic studies of exon α Pol β revealed that it is deficient in DNA binding to gapped DNA, has strongly reduced polymerase activity and higher Km for dNTP during gap-filling. On the other hand, the 5'-dRP lyase activity of the exon α Pol β variant is similar to that of wild-type Pol β. These results indicate the exon α Pol β variant is base excision repair deficient, but does conduct 5'-trimming of a dRP group at the gap margin. Understanding the biological implications of this Pol β variant warrants further investigation.

DNA Polymerase β Cancer-Associated Variant I260M Exhibits Nonspecific Selectivity toward the β-γ Bridging Group of the Incoming dNTP

The hydrophobic hinge region of DNA polymerase β (pol β) is located between the fingers and palm subdomains. The hydrophobicity of the hinge region is important for maintaining the geometry of the binding pocket and for the selectivity of the enzyme. Various cancer-associated pol β variants in the hinge region have reduced fidelity resulting from a decreased discrimination at the level of dNTP binding. Specifically, I260M, a prostate cancer-associated variant of pol β, has been shown to have a reduced discrimination during dNTP binding and also during nucleotidyl transfer. To test whether fidelity of the I260M variant is dependent on leaving group chemistry, we employed a toolkit comprising dNTP bisphosphonate analogues modified at the β-γ bridging methylene to modulate leaving group (pCXYp mimicking PP_i) basicity. Construction of linear free energy relationship plots for the dependence of log(k_pol) on leaving group pK_a4 revealed that I260M catalyzes dNMP incorporation with a marked negative dependence on leaving group basicity, consistent with a chemical transition state, during both correct and incorrect incorporation. Additionally, we provide evidence that I260M fidelity is altered in the presence of some of the analogues, possibly resulting from a lack of coordination between the fingers and palm subdomains in the presence of the I260M mutation.

A Change in the Rate-Determining Step of Polymerization by the K289M DNA Polymerase β Cancer-Associated Variant

K289M is a variant of DNA polymerase β (pol β) that has previously been identified in colorectal cancer. The expression of this variant leads to a 16-fold increase in mutation frequency at a specific site in vivo and a reduction in fidelity in vitro in a sequence context-specific manner. Previous work shows that this reduction in fidelity results from a decreased level of discrimination against incorrect nucleotide incorporation at the level of polymerization. To probe the transition state of the K289M mutator variant of pol β, single-turnover kinetic experiments were performed using β,γ-CXY dGTP analogues with a wide range of leaving group monoacid dissociation constants (pK_a4), including a corresponding set of novel β,γ-CXY dCTP analogues. Surprisingly, we found that the values of the log of the catalytic rate constant (k_pol) for correct insertion by K289M, in contrast to those of wild-type pol β, do not decrease with increased leaving group pK_a4 for analogues with pK_a4 values of <11. This suggests that one of the relative rate constants differs for the K289M reaction in comparison to that of the wild type (WT). However, a plot of log(k_pol) values for incorrect insertion by K289M versus pK_a4 reveals a linear correlation with a negative slope, in this respect resembling k_pol values for misincorporation by the WT enzyme. We also show that some of these analogues improve the fidelity of K289M. Taken together, our data show that Lys289 critically influences the catalytic pathway of pol β.

Mutation of POLB causes lupus in mice

A replication study of a previous genome-wide association study (GWAS) suggested that a SNP linked to the POLB gene is associated with systemic lupus erythematosus (SLE). This SNP is correlated with decreased expression of Pol β, a key enzyme in the base excision repair (BER) pathway. To determine whether decreased Pol β activity results in SLE, we constructed a mouse model of POLB that encodes an enzyme with slow DNA polymerase activity. We show that mice expressing this hypomorphic POLB allele develop an autoimmune pathology that strongly resembles SLE. Of note, the mutant mice have shorter immunoglobulin heavy-chain junctions and somatic hypermutation is dramatically increased. These results demonstrate that decreased Pol β activity during the generation of immune diversity leads to lupus-like disease in mice, and suggest that decreased expression of Pol β in humans is an underlying cause of SLE.

Cellular roles of DNA polymerase beta

Since its discovery and purification in 1971, DNA polymerase ß (Pol ß) is one of the most well-studied DNA polymerases. Pol ß is a key enzyme in the base excision repair (BER) pathway that functions in gap filling DNA synthesis subsequent to the excision of damaged DNA bases. A major focus of our studies is on the cellular roles of Pol ß. We have shown that germline and tumor-associated variants of Pol ß catalyze aberrant BER that leads to genomic instability and cellular transformation. Our studies suggest that Pol ß is critical for the maintenance of genomic stability and that it is a tumor suppressor. We have also shown that Pol ß functions during Prophase I of meiosis. Pol ß localizes to the synaptonemal complex and is critical for removal of the Spo11 complex from the 5' ends of double-strand breaks. Studies with Pol ß mutant mice are currently being undertaken to more clearly understand the function of Pol ß during meiosis. In this review, we will highlight our contributions from our studies of Pol ß germline and cancer-associated variants.

Y265C DNA polymerase beta knockin mice survive past birth and accumulate base excision repair intermediate substrates

DNA is susceptible to damage by a wide variety of chemical agents that are generated either as byproducts of cellular metabolism or exposure to man-made and harmful environments. Therefore, to maintain genomic integrity, having reliable DNA repair systems is important. DNA polymerase β is known to be a key player in the base excision repair pathway, and mice devoid of DNA polymerase beta do not live beyond a few hours after birth. In this study, we characterized mice harboring an impaired pol β variant. This Y265C pol β variant exhibits slow DNA polymerase activity but WT lyase activity and has been shown to be a mutator polymerase. Mice expressing Y265C pol β are born at normal Mendelian ratios. However, they are small, and 60% die within a few hours after birth. Slow proliferation and significantly increased levels of cell death are observed in many organs of the E14 homozygous embryos compared with WT littermates. Mouse embryo fibroblasts prepared from the Y265C pol β embryos proliferate at a rate slower than WT cells and exhibit a gap-filling deficiency during base excision repair. As a result of this, chromosomal aberrations and single- and double-strand breaks are present at significantly higher levels in the homozygous mutant versus WT mouse embryo fibroblasts. This is study in mice is unique in that two enzymatic activities of pol β have been separated; the data clearly demonstrate that the DNA polymerase activity of pol β is essential for survival and genome stability.

DNA pol λ's extraordinary ability to stabilize misaligned DNA

DNA polymerases have the venerable task of maintaining genome stability during DNA replication and repair. Errors, nonetheless, occur with error propensities that are polymerase specific. For example, DNA polymerase λ (pol λ) generates single-base deletions through template-strand slippage within short repetitive DNA regions much more readily than does the closely related polymerase β (pol β). Here we present in silico evidence to help interpret pol λ's greater tendency for deletion errors than pol β by its more favorable protein/DNA electrostatic interactions immediately around the extrahelical nucleotide on the template strand. Our molecular dynamics and free energy analyses suggest that pol λ provides greater stabilization to misaligned DNA than aligned DNA. Our study of several pol λ mutants of Lys544 (Ala, Phe, Glu) probes the interactions between the extrahelical nucleotide and the adjacent Lys544 to show that the charge of the 544 residue controls stabilization of the DNA misalignment. In addition, we identify other thumb residues (Arg538, Lys521, Arg517, and Arg514) that play coordinating roles in stabilizing pol λ's interactions with misaligned DNA. Interestingly, their aggregate stabilization effect is more important than that of any one component residue, in contrast to aligned DNA systems, as we determined from mutations of these key residues and energetic analyses. No such comparable network of stabilizing misaligned DNA exists in pol β. Evolutionary needs for DNA repair on substrates with minimal base-pairing, such as those encountered by pol λ in the non-homologous end-joining pathway, may have been solved by a greater tolerance to deletion errors. Other base-flipping proteins share similar binding properties and motions for extrahelical nucleotides.

Human DNA polymerase beta mutations allowing efficient abasic site bypass

The DNA of every cell in the human body gets damaged more than 50,000 times a day. The most frequent damages are abasic sites. This kind of damage blocks proceeding DNA synthesis by several DNA polymerases that are involved in DNA replication and repair. The mechanistic basis for the incapability of these DNA polymerases to bypass abasic sites is not clarified. To gain insights into the mechanistic basis, we intended to identify amino acid residues that govern for the pausing of DNA polymerase β when incorporating a nucleotide opposite to abasic sites. Human DNA polymerase β was chosen because it is a well characterized DNA polymerase and serves as model enzyme for studies of DNA polymerase mechanisms. Moreover, it acts as the main gap-filling enzyme in base excision repair, and human tumor studies suggest a link between DNA polymerase β and cancer. In this study we employed high throughput screening of a library of more than 11,000 human DNA polymerase β variants. We identified two mutants that have increased ability to incorporate a nucleotide opposite to an abasic site. We found that the substitutions E232K and T233I promote incorporation opposite the lesion. In addition to this feature, the variants have an increased activity and a lower fidelity when processing nondamaged DNA. The mutations described in this work are located in well characterized regions but have not been reported before. A crystallographic structure of one of the mutants was obtained, providing structural insights.

Hinge residue I174 is critical for proper dNTP selection by DNA polymerase beta

DNA polymerase beta (pol beta) is the key gap-filling polymerase in base excision repair, the DNA repair pathway responsible for repairing up to 20000 endogenous lesions per cell per day. Pol beta is also widely used as a model polymerase for structure and function studies, and several structural regions have been identified as being critical for the fidelity of the enzyme. One of these regions is the hydrophobic hinge, a network of hydrophobic residues located between the palm and fingers subdomains. Previous work by our lab has shown that hinge residues Y265, I260, and F272 are critical for polymerase fidelity by functioning in discrimination of the correct from incorrect dNTP during ground state binding. Our work aimed to elucidate the role of hinge residue I174 in polymerase fidelity. To study this residue, we conducted a genetic screen to identify mutants with a substitution at residue I174 that resulted in a mutator polymerase. We then chose the mutator mutant I174S for further study and found that it follows the same general kinetic pathway as and has an overall protein folding similar to that of wild-type (WT) pol beta. Using single-turnover kinetic analysis, we found that I174S exhibits decreased fidelity when inserting a nucleotide opposite a template base G, and this loss of fidelity is due primarily to a loss of discrimination during ground state dNTP binding. Molecular dynamics simulations show that mutation of residue I174 to serine results in an overall tightening of the hinge region, resulting in aberrant protein dynamics and fidelity. These results point to the hinge region as being critical in the maintenance of the proper geometry of the dNTP binding pocket.

DNA polymerase family X: function, structure, and cellular roles

The X family of DNA polymerases in eukaryotic cells consists of terminal transferase and DNA polymerases beta, lambda, and mu. These enzymes have similar structural portraits, yet different biochemical properties, especially in their interactions with DNA. None of these enzymes possesses a proofreading subdomain, and their intrinsic fidelity of DNA synthesis is much lower than that of a polymerase that functions in cellular DNA replication. In this review, we discuss the similarities and differences of three members of Family X: polymerases beta, lambda, and mu. We focus on biochemical mechanisms, structural variation, fidelity and lesion bypass mechanisms, and cellular roles. Remarkably, although these enzymes have similar three-dimensional structures, their biochemical properties and cellular functions differ in important ways that impact cellular function.

The I260Q variant of DNA polymerase beta extends mispaired primer termini due to its increased affinity for deoxynucleotide triphosphate substrates

DNA polymerase beta plays a key role in base excision repair. We have previously shown that the hydrophobic hinge region of polymerase beta, which is distant from its active site, plays a critical role in the fidelity of DNA synthesis by this enzyme. The I260Q hinge variant of polymerase beta misincorporates nucleotides with a significantly higher catalytic efficiency than the wild-type enzyme. In the study described here, we show that I260Q extends mispaired primer termini. The kinetic basis for extension of mispairs is defective discrimination by I260Q at the level of ground-state binding of the dNTP substrate. Our results suggest that the hydrophobic hinge region influences the geometry of the dNTP binding pocket exclusively. Because the DNA forms part of the binding pocket, our data are also consistent with the interpretation that the mispaired primer terminus affects the geometry of the dNTP binding pocket such that the I260Q variant has a higher affinity for the incoming dNTP than wild-type polymerase beta.

Mismatched and matched dNTP incorporation by DNA polymerase beta proceed via analogous kinetic pathways

While matched nucleotide incorporation by DNA polymerase beta (Pol beta) has been well-studied, a true understanding of polymerase fidelity requires comparison of both matched and mismatched dNTP incorporation pathways. Here we examine the mechanism of misincorporation for wild-type (WT) Pol beta and an error-prone I260Q variant using stopped-flow fluorescence assays and steady-state fluorescence spectroscopy. In stopped-flow, a biphasic fluorescence trace is observed for both enzymes during mismatched dNTP incorporation. The fluorescence transitions are in the same direction as that observed for matched dNTP, albeit with lower amplitude. Assignments of the fast and slow fluorescence phases are designated to the same mechanistic steps previously determined for matched dNTP incorporation. For both WT and I260Q mismatched dNTP incorporation, the rate of the fast phase, reflecting subdomain closing, is comparable to that induced by correct dNTP. Pre-steady-state kinetic evaluation reveals that both enzymes display similar correct dNTP insertion profiles, and the lower fidelity intrinsic to the I260Q mutant results from enhanced efficiency of mismatched incorporation. Notably, in comparison to WT, I260Q demonstrates enhanced intensity of fluorescence emission upon mismatched ternary complex formation. Both kinetic and steady-state fluorescence data suggest that relaxed discrimination against incorrect dNTP by I260Q is a consequence of a loss in ability to destabilize the mismatched ternary complex. Overall, our results provide first direct evidence that mismatched and matched dNTP incorporations proceed via analogous kinetic pathways, and support our standing hypothesis that the fidelity of Pol beta originates from destabilization of the mismatched closed ternary complex and chemical transition state.

Loop II of DNA polymerase beta is important for polymerization activity and fidelity

The accurate replication and transmission of genetic information is critical in the life of an organism. During its entire lifespan, the genetic information is constantly under attack from endogenous and exogenous sources of damage. To ensure that the content of its genetic information is faithfully preserved for synthesis and transmission, eukaryotic cells have developed a complex system of genomic quality control. Key players in this process are DNA polymerases, the enzymes responsible for synthesizing the DNA, because errors introduced into the genome by polymerase can result in mutations. We use DNA polymerase beta (pol β) as a model system to investigate mechanisms of preserving fidelity during nucleotide incorporation. In the study described here, we characterized the role that loop II of pol β plays in maintaining the activity and fidelity of pol β. We report here that the absence or shortening of loop II compromises the catalytic activity of pol β. Our data also show that loop variants of a specific length have a lower fidelity when compared to the wild-type polymerase. Taken together, our results indicate that loop II is important for the catalytic activity and fidelity of pol β.

DNA polymerases and human diseases

DNA polymerases function in DNA replication, repair, recombination and translesion synthesis. Currently, 15 DNA polymerase genes have been identified in human cells, belonging to four distinct families. In this review, we briefly describe the biochemical activities and known cellular roles of each DNA polymerase. Our major focus is on the phenotypic consequences of mutation or ablation of individual DNA polymerase genes. We discuss phenotypes of current mouse models and altered polymerase functions and the relationship of DNA polymerase gene mutations to human cell phenotypes. Interestingly, over 120 single nucleotide polymorphisms (SNPs) have been identified in human populations that are predicted to result in nonsynonymous amino acid substitutions of DNA polymerases. We discuss the putative functional consequences of these SNPs in relation to human disease.

Genomic and transcriptional aberrations linked to breast cancer pathophysiologies

This study explores the roles of genome copy number abnormalities (CNAs) in breast cancer pathophysiology by identifying associations between recurrent CNAs, gene expression, and clinical outcome in a set of aggressively treated early-stage breast tumors. It shows that the recurrent CNAs differ between tumor subtypes defined by expression pattern and that stratification of patients according to outcome can be improved by measuring both expression and copy number, especially high-level amplification. Sixty-six genes deregulated by the high-level amplifications are potential therapeutic targets. Nine of these (FGFR1, IKBKB, ERBB2, PROCC, ADAM9, FNTA, ACACA, PNMT, and NR1D1) are considered druggable. Low-level CNAs appear to contribute to cancer progression by altering RNA and cellular metabolism.

Expression of DNA polymerase {beta} cancer-associated variants in mouse cells results in cellular transformation

Thirty percent of the 189 tumors studied to date express DNA polymerase beta variants. One of these variants was identified in a prostate carcinoma and is altered from isoleucine to methionine at position 260, within the hydrophobic hinge region of the protein. Another variant was identified in a colon carcinoma and is altered at position 289 from lysine to methionine, within helix N of the protein. We have shown that the types of mutations induced by these cancer-associated variants are different from those induced by the wild-type enzyme. In this study, we show that expression of the I260M and K289M cancer-associated variants in mouse C127 cells results in a transformed phenotype in the great majority of cell clones tested, as assessed by focus formation and anchorage-independent growth. Strikingly, cellular transformation occurs after a variable number of passages in culture but, once established, does not require continuous expression of the polymerase beta variant proteins, implying that it has a mutational basis. Because DNA polymerase beta functions in base excision repair, our results suggest that mutations that arise during this process can lead to the onset or progression of cancer.

Directed evolution of novel polymerases

DNA and RNA polymerases evolved to function in specific environments with specific substrates to propagate genetic information in all living organisms. The commercial availability of these polymerases has revolutionized the biotechnology industry, but for many applications native polymerases are limited by their stability or substrate recognition. Thus, there is great interest in the directed evolution of DNA and RNA polymerases to generate enzymes with novel, desired properties, such as thermal stability, resistance to inhibitors, and altered substrate specificity. Several screening and selection approaches have been developed, both in vivo and in vitro, and have been used to evolve polymerases with a variety of important activities. Both the techniques and the evolved polymerases are reviewed here, along with a comparison of the in vivo and in vitro approaches.

DNA polymerase beta interacts with TRF2 and induces telomere dysfunction in a murine mammary cell line

DNA polymerase beta (Polbeta) is a DNA repair protein that functions in base excision repair and meiosis. The enzyme has deoxyribose phosphate lyase and polymerase activity, but it is error prone because it bears no proofreading activity. Errors in DNA repair can lead to the accumulation of mutations and consequently to tumorigenesis. Polbeta expression has been found to be higher in tumors, and deregulation of its expression has been found to induce chromosomal instability, a hallmark of tumorigenesis, but the underlying mechanisms are unclear. In the present study, we have investigated whether ectopic expression of Polbeta influences the stability of chromosomes in a murine mammary cell line. The results demonstrate a telomere dysfunction phenotype: an increased rate of telomere loss and chromosome fusion, suggesting that ectopic expression of Polbeta leads to telomere dysfunction. In addition, Polbeta interacts with TRF2, a telomeric DNA binding protein. Colocalization of the two proteins occurs at nontelomeric sites and appears to be influenced by the change in the status of the telomeric complex.

A DNA polymerase beta mutant from colon cancer cells induces mutations

Previous investigations have shown that approximately 35% of the 90 tumors analyzed to date contain mutations within the DNA polymerasebeta (pol beta) gene. The existence of pol beta mutations in a substantial fraction of human tumors studied suggests a link between DNA pol beta and cancer. A DNA pol beta variant, in which Lys-289 has been altered to Met, was identified previously in a colorectal carcinoma. The K289M protein was expressed in mouse L cells containing the lambda cII mutational target. The lambda DNA was packaged and used to infect bacterial cells to obtain the spontaneous mutation frequency. We found that expression of K289M in the mouse cells resulted in a 2.5-fold increase in the mutation frequency. What was most interesting was that expression of K289M in these cells resulted in a 16-fold increase in the frequency of C to G or G to C base substitutions at a specific site within the cII target. By using this cII target sequence, kinetic analysis of the purified K289M protein revealed that it was able to misincorporate dCTP opposite template C and dGTP opposite template G with significantly higher efficiency than the wild-type pol beta protein. We provide evidence that misincorporation of nucleotides by K289M results from altered positioning of the DNA within the active site of the enzyme. Our data are consistent with the interpretation that misincorporation of nucleotides resulting from altered DNA positioning by the K289M protein has the potential to result in tumorigenesis or neoplastic progression.

Distinct function of conserved amino acids in the fingers of Saccharomyces cerevisiae DNA polymerase alpha

Structural differences between class A and B DNA polymerases suggest that the motif B region, a wall of the catalytic pocket, may have evolved differentially in the two polymerase families. This study examines the function of the motif B residues in Saccharomyces cerevisiae DNA polymerase alpha (pol alpha). Effects of the mutations were determined by biochemical analysis and genetic complementation of a yeast strain carrying a temperature-sensitive pol alpha mutant. Many conserved residues were viable with a variety of substitutions. Among them, mutations at Asn-948 or Tyr-951 conferred up to 8-fold higher colony formation frequency in a URA3 forward mutation assay, and 79-fold higher trp1 reversion frequency was observed for Y951P in yeast. Purified Y951P was as accurate as wild type in DNA synthesis but approximately 6-fold less processive and 22-fold less active in vitro. Therefore, Y951P may increase the frequency of mutant colony formation because of its low level of DNA polymerase activity in yeast. Mutations at Lys-944 or Gly-952 were not viable, which is consistent with the observation that mutants with substitutions at Gly-952 have strongly reduced catalytic activity in vitro. Gly-952 may provide a space for the nascent base pair and thus may play an essential function in S. cerevisiae DNA pol alpha. These results suggest that class B DNA polymerases have a unique structure in the catalytic pocket, which is distinct from the corresponding region in class A DNA polymerases.

Threonine 79 is a hinge residue that governs the fidelity of DNA polymerase beta by helping to position the DNA within the active site

DNA polymerase beta (pol beta) is an ideal system for studying the role of its different amino acid residues in the fidelity of DNA synthesis. In this study, the T79S variant of pol beta was identified using an in vivo genetic screen. T79S is located in the N-terminal 8-kDa domain of pol beta and has no contact with either the DNA template or the incoming dNTP substrate. The T79S protein produced 8-fold more multiple mutations in the herpes simplex virus type 1-thymidine kinase assay than wild-type pol beta. Surprisingly, T79S is a misincorporation mutator only when using a 3'-recessed primer-template. In the presence of a single nucleotide-gapped DNA substrate, T79S displays an antimutator phenotype when catalyzing DNA synthesis opposite template C and has similar fidelity as wild type opposite templates A, G, or T. Threonine 79 is located directly between two helix-hairpin-helix motifs located within the 8-kDa and thumb domains of pol beta. As the pol beta enzyme closes into its active form, the helix-hairpin-helix motifs appear to assist in the production and stabilization of a 90 degrees bend of the DNA. The function of the bent DNA is to present the templating base to the incoming nucleotide substrate. We propose that Thr-79 is part of a hydrogen bonding network within the helix-hairpin-helix motifs that is important for positioning the DNA within the active site. We suggest that alteration of Thr-79 to Ser disrupts this hydrogen bonding network and results in an enzyme that is unable to bend the DNA into the proper geometry for accurate DNA synthesis.

Genetic polymorphisms of XRCC1 and risk of the esophageal cancer

A variety of environmental factors were identified to be associated with the risk of esophageal cancer. The variation in capacity of DNA repair might influence environmental chemical-associated carcinogenesis. We hypothesized that the polymorphic XRCC1 genes might modify cancer susceptibility of the esophagus. To investigate the effect of XRCC1 genetic polymorphisms on codons 194, 280 and 399, we evaluated data from 105 patients of esophageal squamous cell carcinoma and 264 healthy controls, matching with age (+/-3 years), gender and ethnicity. The distribution of the 3 genotypes were not significantly different among patients and controls. However, among alcohol drinkers, the XRCC1399 Arg/Arg genotype was more frequently found in patients with esophageal cancer. After adjustment with other environmental confounders, the OR for the genotype of XRCC1399 Arg/Arg was 2.78 (95% CI =1.15-6.67) as compared with the XRCC1(399) Arg/Gln and XRCC1(399) Gln/Gln genotypes in the alcohol drinkers. Similar trends were observed among cigarette smokers and areca chewers. However, they did not reach a statistical significance. Our findings suggest that the polymorphic XRCC1 genes might modify the risk of alcohol-associated esophageal cancers.

Mutational spectrum analysis of RNase H(35) deficient Saccharomyces cerevisiae using fluorescence-based directed termination PCR

Mutational spectrum analysis has become an informative genetic tool to understand those protein functions involved in mutation avoidance pathways since specific types of mutations are often associated with particular protein defects involved in DNA replication and repair. In this study, we describe a novel, fluorescence-based procedure for direct determination of deletions and insertions with 100% accuracy. We performed two complementary directed termination PCR with near infrared dye-labeled primers, followed by visualization of termination fragments using an automated Li-cor DNA sequencer. This method is used for rapid analysis of mutational spectra generated in nuclease-defective strains of Saccharomyces cerevisiae to elucidate the role of RNase H(35) in RNA primer removal during DNA replication and in mutation avoidance. Strains deficient in RNH35 displayed a distinct spontaneous mutation spectrum of deletions characterized by a unique 4 bp deletion in a lys2-Bgl allele. This was in sharp contrast to strains deficient in rad27 that displayed duplication mutations. Further analysis of mutations in a rnh35/rad27 double mutant revealed a mixed spectrum. These results indicate that RNase H(35) may participate in a redundant pathway in Okazaki fragment processing and that mutational spectra caused by protein deficiencies may be more intermediate-specific than pathway-specific.

Low fidelity DNA synthesis by human DNA polymerase-eta

A superfamily of DNA polymerases that bypass lesions in DNA has been described. Some family members are described as error-prone because mutations that inactivate the polymerase reduce damage-induced mutagenesis. In contrast, mutations in the skin cancer susceptibility gene XPV, which encodes DNA polymerase (pol)-eta, lead to increased ultraviolet-induced mutagenesis. This, and the fact that pol-eta primarily inserts adenines during efficient bypass of thymine-thymine dimers in vitro, has led to the description of pol-eta as error-free. However, here we show that human pol-eta copies undamaged DNA with much lower fidelity than any other template-dependent DNA polymerase studied. Pol-eta lacks an intrinsic proofreading exonuclease activity and, depending on the mismatch, makes one base substitution error for every 18 to 380 nucleotides synthesized. This very low fidelity indicates a relaxed requirement for correct base pairing geometry and indicates that the function of pol-eta may be tightly controlled to prevent potentially mutagenic DNA synthesis.

DNA polymerase mu (Pol mu), homologous to TdT, could act as a DNA mutator in eukaryotic cells

A novel DNA polymerase has been identified in human cells. Human DNA polymerase mu (Pol mu), consisting of 494 amino acids, has 41% identity to terminal deoxynucleotidyltransferase (TdT). Human Pol mu, overproduced in Escherichia coli in a soluble form and purified to homogeneity, displays intrinsic terminal deoxynucleotidyltransferase activity and a strong preference for activating Mn(2+) ions. Interestingly, unlike TdT, the catalytic efficiency of polymerization carried out by Pol mu was enhanced by the presence of a template strand. Using activating Mg(2+) ions, template-enhanced polymerization was also template-directed, leading to the preferred insertion of complementary nucleotides, although with low discrimination values. In the presence of Mn(2+) ions, template-enhanced polymerization produced a random insertion of nucleotides. Northern-blotting and in situ analysis showed a preferential expression of Pol mu mRNA in peripheral lymphoid tissues. Moreover, a large proportion of the human expressed sequence tags corresponding to Pol mu, present in the databases, derived from germinal center B cells. Therefore, Pol mu is a good candidate to be the mutator polymerase responsible for somatic hyper- mutation of immunoglobulin genes.

Mice reconstituted with DNA polymerase beta-deficient fetal liver cells are able to mount a T cell-dependent immune response and mutate their Ig genes normally

The ubiquitously expressed, error-prone DNA polymerase beta (polbeta) plays a role in base excision repair, and the involvement of this molecule in the nonhomologous end joining (NHEJ) process of DNA repair has recently been demonstrated in yeast. Polbeta-deficient mice are not viable, and studies on conditional mutants revealed a competitive disadvantage of polbeta(-/-) vs. wild-type cells. We show here that polbeta-deficient mice survive up to day 18.5 postcoitum, but die perinatally; a circumstance that allowed the investigation of a potential role of polbeta in lymphocyte development by transfer of fetal liver cells (FLC) derived from polbeta(-/-) embryos into lethally irradiated hosts. FLC transfers using mutant cells lead to an almost normal reconstitution of the lymphocyte compartment, indicating that polbeta-deficiency does not prevent V(D)J recombination, which is known to employ factors of the NHEJ pathway. Mice reconstituted with polbeta(-/-) FLC mount a normal T cell-dependent immune response against the hapten (4-hydroxy-3-nitrophenyl) acetyl (NP). Moreover, germinal center B cells from NP-immunized reconstituted mice show normal levels and patterns of somatic point mutations in their rearranged antibody genes, demonstrating that polbeta is not critically involved in somatic hypermutation.