DNA polymerase alpha from HeLa cells synthesizes DNA with high fidelity in a reconstituted replication system

To determine the contribution that DNA polymerase alpha makes to the overall DNA replication fidelity in mammalian systems, we measured the fidelity of replication of the SV40-based shuttle vector, pZ189, in a reconstituted in vitro DNA replication system which contained purified HeLa DNA polymerase alpha (in addition to single-stranded DNA binding protein, topoisomerase II, DNA ligase, 5'----3' exonuclease, ribonuclease H, and SV40 T-antigen). We found that DNA polymerase alpha is highly accurate when carrying out bidirectional replication in this system. This high fidelity of replication by DNA polymerase alpha in the reconstituted replication system contrasts with a relatively low fidelity of gap-filling DNA synthesis on the same target gene by purified HeLa cell DNA polymerase alpha in the absence of other replication factors. The fidelity of DNA replication by DNA polymerase alpha, although relatively high in the reconstituted system, is about 4-fold lower than DNA replication in a crude HeLa cell extract which contains additional replication factors including DNA polymerase delta. These results demonstrate that DNA polymerase alpha has the capacity to replicate DNA with high fidelity when carrying out semiconservative DNA replication in a minimal reconstituted replication system, but additional cellular factors not present in the reconstituted system may contribute to the higher replication fidelity of the crude system.     

HeLa cell single-stranded DNA-binding protein increases the accuracy of DNA synthesis by DNA polymerase alpha in vitro.

To determine whether cellular replication factors can influence the fidelity of DNA replication, the effect of HeLa cell single-stranded DNA-binding protein (SSB) on the accuracy of DNA replication by HeLa cell DNA polymerase alpha has been examined. An in vitro gap-filling assay, in which the single-stranded gap contains the supF target gene, was used to measure mutagenesis. Addition of SSB to the in vitro DNA synthesis reaction increased the accuracy of DNA polymerase alpha by 2- to 8-fold. Analysis of the products of DNA synthesis indicated that SSB reduces pausing by the polymerase at specific sites in the single-stranded supF template. Sequence analysis of the types of errors resulting from synthesis in the absence or presence of SSB reveals that, while the errors are primarily base substitutions under both conditions, SSB reduces the number of errors found at 3 hotspots in the supF gene. Thus, a cellular replication factor (SSB) can influence the fidelity of a mammalian DNA polymerase in vitro, suggesting that the high accuracy of cellular DNA replication may be determined in part by the interaction between replication factors, DNA polymerase and the DNA template in the replication complex.     

Fidelity of DNA synthesis in a mammalian in vitro replication system.

We have used the simian virus 40 (SV40)-based shuttle vector pZ189 in a forward-mutation assay to determine the fidelity of DNA replication in the in vitro DNA replication system developed by J.J. Li and T.J. Kelly (Proc. Natl. Acad. Sci. USA 81:6973-6977, 1984). We find that very few base substitution errors (approximately 1/180,000 bases incorporated) are made during in vitro replication of the pZ189 vector in a system derived from CV-1 monkey cells. This replication is completely dependent on added SV40 T antigen and presumably reflects synthesis that is initiated at the SV40 replication origin. The observed level of fidelity is far greater than that reported for in vitro replication of DNA by conventionally purified eucaryotic DNA polymerases alpha and beta. Thus, there must be additional cellular factors in the crude in vitro system that serve to enhance the fidelity of DNA replication.     

Plant-virus-based vectors for gene transfer will be of limited use because of the high error frequency during viral RNA synthesis

Summary The error frequency during the RNA replication of alfalfa mosaic virus (AMV) was calculated to be significantly higher than 10⁻⁵. It may be expected that RNA synthesis in general will have low fidelity compared to DNA synthesis. The low fidelity of RNA replication will severely restrict the usefulness of vectors for genetic engineering which are based on RNA viruses, viroids or DNA viruses which are replicated via an RNA intermediate (e.g. caulimoviruses). Spontaneous mutants selected by host shift were found to be much less stable than UV-induced mutants. This difference points to variations in fidelity during RNA synthesis, probably due to the local sequence of the template.     

Fidelity of mammalian DNA replication and replicative DNA polymerases.

Current models suggest that two or more DNA polymerases may be required for high-fidelity semiconservative DNA replication in eukaryotic cells. In the present study, we directly compare the fidelity of SV40 origin-dependent DNA replication in human cell extracts to the fidelity of mammalian DNA polymerases alpha, delta, and epsilon using lacZ alpha of M13mp2 as a reporter gene. Their fidelity, in decreasing order, is replication greater than or equal to pol epsilon greater than pol delta greater than pol alpha. DNA sequence analysis of mutants derived from extract reactions suggests that replication is accurate when considering single-base substitutions, single-base frameshifts, and larger deletions. The exonuclease-containing calf thymus DNA polymerase epsilon is also highly accurate. When high concentrations of deoxynucleoside triphosphates and deoxyguanosine monophosphate are included in the pol epsilon reaction, both base substitution and frameshift error rates increase. This response suggests that exonucleolytic proofreading contributes to the high base substitution and frameshift fidelity. Exonuclease-containing calf thymus DNA polymerase delta, which requires proliferating cell nuclear antigen for efficient synthesis, is significantly less accurate than pol epsilon. In contrast to pol epsilon, pol delta generates errors during synthesis at a relatively modest concentration of deoxynucleoside triphosphates (100 microM), and the error rate did not increase upon addition of adenosine monophosphate. Thus, we are as yet unable to demonstrate that exonucleolytic proofreading contributes to accuracy during synthesis by DNA polymerase delta. The four-subunit DNA polymerase alpha-primase complex from both HeLa cells and calf thymus is the least accurate replicative polymerase. Fidelity is similar whether the enzyme is assayed immediately after purification or after being stored frozen.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA replication errors produced by the replicative apparatus of Escherichia coli.

It has been hard to detect forward mutations generated during DNA synthesis in vitro by replicative DNA polymerases, because of their extremely high fidelity and a high background level of pre-existing mutations in the single-stranded template DNA used. Using the oriC plasmid DNA replication in vitro system and the rpsL forward mutation assay, we examined the fidelity of DNA replication catalyzed by the replicative apparatus of Escherichia coli. Upon DNA synthesis by the fully reconstituted system, the frequency of rpsL-mutations in the product DNA was increased to 1.9x10(-4), 50-fold higher than the background level of the template DNA. Among the mutations generated in vitro, single-base frameshifts predominated and occurred with a pattern similar to those induced in mismatch-repair deficient E. coli cells, indicating that the major replication error was slippage at runs of the same nucleotide. Large deletions and other structural alterations of DNA appeared to be induced also during the action of the replicative apparatus.     

SOS and Mayday: multiple inducible mutagenic pathways in Escherichia coli

Environmental and physiological stress conditions can transiently alter the fidelity of DNA replication. The DNA damage-mediated SOS response in Escherichia coli is the best-known example of such an 'inducible mutagenesis' or 'transient mutator' pathway. Emerging evidence suggests the existence of a number of other stress-inducible pathways that also affect the fidelity of replication. Among the more provocative recent findings are UVM, an SOS-independent damage-inducible mutagenic pathway, and a new recA -dependent but umuD/C -independent pathway that appears to be provoked by translational stress. These findings alter our view of inducible mutagenesis, and anticipate the existence of previously unrecognized links between protein synthesis and DNA replication.     

Coordinating DNA polymerase traffic during high and low fidelity synthesis

With the discovery that organisms possess multiple DNA polymerases (Pols) displaying different fidelities, processivities, and activities came the realization that mechanisms must exist to manage the actions of these diverse enzymes to prevent gratuitous mutations. Although many of the Pols encoded by most organisms are largely accurate, and participate in DNA replication and DNA repair, a sizeable fraction display a reduced fidelity, and act to catalyze potentially error-prone translesion DNA synthesis (TLS) past lesions that persist in the DNA. Striking the proper balance between use of these different enzymes during DNA replication, DNA repair, and TLS is essential for ensuring accurate duplication of the cell's genome. This review highlights mechanisms that organisms utilize to manage the actions of their different Pols. A particular emphasis is placed on discussion of current models for how different Pols switch places with each other at the replication fork during high fidelity replication and potentially error-pone TLS.     

Efficiency, fidelity and enzymatic switching during translesion DNA synthesis

More than half of the 16 human DNA polymerases may have some role in DNA replication and potentially modulate the biological effects of DNA template lesions that impede replication fork progression. As one approach to understand how multiple polymerases are coordinated at the fork, we recently quantified the efficiency and fidelity with which one particular translesion synthesis enzyme, human DNA polymerase eta, copies templates containing cis-syn thymine dimers. Several observations from that study were unanticipated. Here we discuss the structural and biological implications of those results in light of earlier studies of translesion synthesis.     

On the activity and fidelity of chromatin-associated hepatic DNA polymerase-β in aging murine species of different life spans

Activity and accuracy of chromatin-directed DNA replication have been compared in young and aged Mus musculus and Peromyscus leucopus, two murine species with contrasting maximum lifespans. Chromatin isolated from livers of mature adults of both species copied efficiently exogenous DNA templates using predominantly DNA polymerase-β. The DNA synthetic activity of liver chromatin remained constant in both species throughout their lifetimes. The fidelity of chromatin-directed poly [d(A-T)] synthesis was similar for the comparatively short-lived M. musculus and the relatively long-lived P. leucopus and remained unaltered in old animals. The fidelity of poly [d(A-T)] copying catalyzed by DNA polymerase-β dissociated from liver chromatin was comparable to that of the chromatin-directed synthesis. The dissociated enzymes did not exhibit diminished fidelity of poly [d(A-T)] synthesis with age. In all ages of both species examined, the murine liver DNA polymerase-β, both chromatin-associated and solubilized, exhibited high error frequencies; approximately one dGMP was incorporated for every 500–1,000 complementary nucleotides polymerized. The relationship of these results to the accuracy of DNA replication and repair as a determinant of aging is considered.     

DNA replication fidelity

DNA replication fidelity plays fundamental role in faithful transmission of genetic material during cell division and during transfer of genetic material from parents to progeny. Replicative polymerases are the main guardian responsible for high replication fidelity of genomic DNA. DNA main replicative polymerases are also involved in many DNA repair processes. High fidelity of DNA replication is determined by correct nucleotide selectivity in polymerase active center, and exonucleolytic proofreading that removes mismatches from primer terminus. In this article we will focus on the mechanisms that are responsible for high fidelity of replications with the special emphasis on structural studies showing important conformational changes after substrate binding. We will also stress the importance of hydrogen bonding, base pair geometry, polymerase DNA interactions and the role of accessory proteins in replication fidelity.     

The fidelity of DNA synthesis by the catalytic subunit of yeast DNA polymerase alpha alone and with accessory proteins

The fidelity of DNA synthesis catalyzed by the 180-kDa catalytic subunit (p180) of DNA polymerase alpha from Saccharomyces cerevisiae has been determined. Despite the presence of a 3'----5' exonuclease activity (Brooke et al., 1991, J. Biol. Chem., 266, 3005-3015), its accuracy is similar to several exonuclease-deficient DNA polymerases and much lower than other DNA polymerases that have associated exonucleolytic proofreading activity. Average error rates are 1/9900 and 1/12,000, respectively, for single base-substitution and minus-one nucleotide frameshift errors; the polymerase generates deletions as well. Similar error rates are observed with reactions containing the 180-kDa subunit plus an 86-kDa subunit (p86), or with these two polypeptides plus two additional subunits (p58 and p49) comprising the DNA primase activity required for DNA replication. Finally, addition of yeast replication factor-A (RF-A), a protein preparation that stimulates DNA synthesis and has single-stranded DNA-binding activity, yields a polymerization reaction with 7 polypeptides required for replication, yet fidelity remains low relative to error rates for semiconservative replication. The data suggest that neither exonucleolytic proofreading activity, the beta subunit, the DNA primase subunits nor RF-A contributes substantially to base substitution or frameshift error discrimination by the DNA polymerase alpha catalytic subunit.     

DNA聚合酶在维持基因组稳定性中的多重功能及其相关疾病

遗传物质的稳定传递是生命繁衍的根本。基因组DNA的精确复制和分配是遗传物质传递的基础,也是细胞周期两大最核心的生物学事件。DNA聚合酶作为催化合成DNA双链的酶,是复制过程中最重要的因子之一。尽管对这类酶的研究已有将近60年的历史,但依然是生命科学基础研究的前沿之一。真核生物中已知的DNA聚合酶有十几种,它们不仅参与正常基因组DNA合成过程,也参与DNA损伤情况下多种修复过程。如此众多的具有不同特性的DNA聚合酶在细胞内是如何分工与合作的,在正常细胞传代与环境胁迫等情况下维护基因组稳定性中的关键作用及其分子机制又是什么。更有意思的是,最近的肿瘤细胞比较基因组数据表明,多种DNA聚合酶基因突变与某些肿瘤和遗传疾病相关,从而为这些疾病致病机理研究与诊治提供了新的思路和方法。对上述DNA聚合酶相关核心问题的最新研究进展进行了综述。     

The effect of nitrosoguanidine upon DNA synthesis in vitro

Summary Both the polymerase and the exonuclease activities of DNA polymerase III^* are inactivated by treatment with nitrosoguanidine. The treatment of the DNA template with the mutagen does not affect the template in supporting DNA synthesis. No effect of nitrosoguanidine upon fidelity of replication in vitro was detected.     

Xeroderma pigmentosum variant and error-prone DNA polymerases

Replicative DNA synthesis is a faithful event which requires undamaged DNA and high fidelity DNA polymerases. If unrepaired damage remains in the template DNA during replication, specialised low fidelity DNA polymerases synthesises DNA past lesions (translesion synthesis, TLS). Current evidence suggests that the polymerase switch from replicative to translesion polymerases might be mediated by post-translational modifications involving ubiquitination processes. One of these TLS polymerases, polymerase eta carries out TLS past UV photoproducts and is deficient in the variant form of xeroderma pigmentosum (XP-V). The dramatic proneness to skin cancer of XP-V individuals highlights the importance of this DNA polymerase in cancer avoidance. The UV hypermutability of XP-V cells suggests that, in the absence of a functional poleta, UV-induced lesions are bypassed by inaccurate DNA polymerase(s) which remain to be identified.     

Sloppier copier DNA polymerases involved in genome repair

When chromosomal replication is impeded in the presence of DNA damage, members of a newly discovered UmuC/DinB/Rev1/Rad30 superfamily of procaryotic and eucaryotic DNA polymerases catalyze translesion synthesis at blocked replication forks. Although these polymerases share sequence elements essentially unrelated to the standard replication and repair enzymes, some of them (such as the SOS-induced Escherichia coli pol V) catalyze 'error-prone' translesion synthesis leading to large increases in mutation, whereas others (an example being the Xeroderma pigmentosum variant gene product XPV pol eta) carry out aberrant, yet nonmutagenic translesion synthesis. Ongoing studies of these low fidelity polymerases could provide new insights into the mechanism of somatic hypermutation, a key element in the immune response.     

Proofreading of DNA polymerase eta-dependent replication errors

Human DNA polymerase eta, the product of the skin cancer susceptibility gene XPV, bypasses UV photoproducts in template DNA that block synthesis by other DNA polymerases. Pol eta lacks an intrinsic proofreading exonuclease and copies DNA with low fidelity, such that pol eta errors could contribute to mutagenesis unless they are corrected. Here we provide evidence that pol eta can compete with other human polymerases during replication of duplex DNA, and in so doing it lowers replication fidelity. However, we show that pol eta has low processivity and extends mismatched primer termini less efficiently than matched termini. These properties could provide an opportunity for extrinsic exonuclease(s) to proofread pol eta-induced replication errors. When we tested this hypothesis during replication in human cell extracts, pol eta-induced replication infidelity was found to be modulated by changing the dNTP concentration and to be enhanced by adding dGMP to a replication reaction. Both effects are classical hallmarks of exonucleolytic proofreading. Thus, pol eta is ideally suited for its role in reducing UV-induced mutagenesis and skin cancer risk, in that its relaxed base selectivity may facilitate efficient bypass of UV photoproducts, while subsequent proofreading by extrinsic exonuclease(s) may reduce its mutagenic potential.     

Misincorporation rate and type on the leading and lagging strands of UV-damaged DNA.

We have examined the fidelity of replication of the leading and lagging strands of UV-irradiated DNA by using an EBV-derived shuttle vector system which contains as marker gene for mutation analysis the bacterial gpt gene in both orientations relative to the EBV oriP. Human cells stably transformed with this vector were UV irradiated and gpt mutation rate and type were analysed. An increased mutagenicity associated with UV irradiation was observed, but the average error frequency was unaffected by the direction of replication of the target gene. Some variability by position and sequence context of leading and lagging strand errors was detected, suggesting that the different architecture of the replication complex for the two strands might, to some extent, affect mutation spectra. The comparable fidelity of translesion replication on the leading and lagging strands is in agreement with the current model for eukaryotic replication that postulates the simultaneous synthesis of both strands by a DNA polymerase with a proof-reading exonuclease.     

The Werner syndrome exonuclease facilitates DNA degradation and high fidelity DNA polymerization by human DNA polymerase δ

DNA Polymerase δ (Pol δ) and the Werner syndrome protein, WRN, are involved in maintaining cellular genomic stability. Pol δ synthesizes the lagging strand during replication of genomic DNA and also functions in the synthesis steps of DNA repair and recombination. WRN is a member of the RecQ helicase family, loss of which results in the premature aging and cancer-prone disorder, Werner syndrome. Both Pol δ and WRN encode 3' → 5' DNA exonuclease activities. Pol δ exonuclease removes 3'-terminal mismatched nucleotides incorporated during replication to ensure high fidelity DNA synthesis. WRN exonuclease degrades DNA containing alternate secondary structures to prevent formation and enable resolution of stalled replication forks. We now observe that similarly to WRN, Pol δ degrades alternate DNA structures including bubbles, four-way junctions, and D-loops. Moreover, WRN and Pol δ form a complex with enhanced ability to hydrolyze these structures. We also present evidence that WRN can proofread for Pol δ; WRN excises 3'-terminal mismatches to enable primer extension by Pol δ. Consistent with our in vitro observations, we show that WRN contributes to the maintenance of DNA synthesis fidelity in vivo. Cells expressing limiting amounts (～10% of normal) of WRN have elevated mutation frequencies compared with wild-type cells. Together, our data highlight the importance of WRN exonuclease activity and its cooperativity with Pol δ in preserving genome stability, which is compromised by the loss of WRN in Werner syndrome.     

Fidelity of replication of the leading and the lagging DNA strands opposite N-methyl-N-nitrosourea-induced DNA damage in human cells.

Semi-conservative replication of double-stranded DNA in eukaryotic cells is an asymmetric process involving leading and lagging strand synthesis and different DNA polymerases. We report a study to analyze the effect of these asymmetries when the replication machinery encounters alkylation-induced DNA adducts. The model system is an EBV-derived shuttle vector which replicates in synchrony with the host human cells and carries as marker gene the bacterial gpt gene. A preferential distribution of N-methyl-N-nitrosourea (MNU)-induced mutations in the non transcribed DNA strand of the shuttle vector pF1-EBV was previously reported. The hypermutated strand was the leading strand. To test whether the different fidelity of DNA polymerases synthesizing the leading and the lagging strands might contribute to MNU-induced mutation distribution the mutagenesis study was repeated on the shuttle vector pTF-EBV which contains the gpt gene in the inverted orientation. We show that the base substitution error rates on an alkylated substrate are similar for the replication of the leading and lagging strands. Moreover, we present evidence that the fidelity of replication opposite O6-methylguanine adducts of both the leading and lagging strands is not affected by the 3' flanking base. The preferential targeting of mutations after replication of alkylated DNA is mainly driven by the base at the 5' side of the G residues.