Deletion errors generated during replication of CAG repeats.

Triplet repeat sequence instability is associated with hereditary neurological diseases and with certain types of cancer. Here we study one form of this instability, deletion of triplet repeats during replication of template (CAG)(n)sequences by DNA polymerases. To monitor loss of triplet codons, we inserted (CAG)(9)and (CAG)(17)repeats into the lacZ sequence in M13mp2 and changed one repeat to a TAG codon to yield DNA substrates with colorless plaque phenotypes. Templates containing these inserts within gaps were copied and errors were scored as blue plaque Lac revertants whose DNA was sequenced to determine if loss of the TAG codon resulted from substitutions or deletions. DNA synthesis by either DNA polymerase beta or exonuclease-deficient T7 DNA polymerase produced deletions involving loss of from 1 to 8 of 9 or 15 of 17 repeats. Thus, these polymerases utilize misaligned template-primers containing from 3 to 45 extra template strand nucleotides. Deletion frequencies were much higher than substitution frequencies at the TAG codon in certain repeats, indicating that triplet repeats are at high risk for mutation in the absence of error correction. Proofreading-proficient T7 DNA polymerase generated deletions at 2- to 10-fold lower frequencies than did its exonuclease-deficient derivative. This suggests that misaligned triplet repeat sequences are subject to proofreading, but at reduced efficiency compared to editing of single-base mismatches.     

Structural factors that determine selectivity of a high fidelity DNA polymerase for deoxy-, dideoxy-, and ribonucleotides

In addition to discriminating against base pair mismatches, DNA polymerases exhibit a high degree of selectivity for deoxyribonucleotides over ribo- or dideoxynucleotides. It has been proposed that a single active site residue (steric gate) blocks productive binding of nucleotides containing 2'-hydroxyls. Although this steric gate plays a role in sugar moiety discrimination, its interactions do not account fully for the observed behavior of mutants. Here we present 10 high resolution crystal structures and enzyme kinetic analyses of Bacillus DNA polymerase I large fragment variants complexed with deoxy-, ribo-, and dideoxynucleotides and a DNA substrate. Taken together, these data present a more nuanced and general mechanism for nucleotide discrimination in which ensembles of intermediate conformations in the active site trap non-cognate substrates. It is known that the active site O-helix transitions from an open state in the absence of nucleotide substrates to a ternary complex closed state in which the reactive groups are aligned for catalysis. Substrate misalignment in the closed state plays a fundamental part in preventing non-cognate nucleotide misincorpation. The structures presented here show that additional O-helix conformations intermediate between the open and closed state extremes create an ensemble of binding sites that trap and misalign non-cognate nucleotides. Water-mediated interactions, absent in the fully closed state, play an important role in formation of these binding sites and can be remodeled to accommodate different non-cognate substrates. This mechanism may extend also to base pair discrimination.     

Substitution of a residue contacting the triphosphate moiety of the incoming nucleotide increases the fidelity of yeast DNA polymerase zeta

DNA polymerase zeta (pol zeta), which is required for DNA damage-induced mutagenesis, functions in the error-prone replication of a wide range of DNA lesions. During this process, pol zeta extends from nucleotides incorporated opposite template lesions by other polymerases. Unlike classical polymerases, pol zeta efficiently extends from primer-terminal base pairs containing mismatches or lesions, and it synthesizes DNA with moderate fidelity. Here we describe genetic and biochemical studies of three yeast pol zeta mutant proteins containing substitutions of highly conserved amino acid residues that contact the triphosphate moiety of the incoming nucleotide. The R1057A and K1086A proteins do not complement the rev3Delta mutation, and these proteins have significantly reduced polymerase activity relative to the wild-type protein. In contrast, the K1061A protein partially complements the rev3Delta mutation and has nearly normal polymerase activity. Interestingly, the K1061A protein has increased fidelity relative to wild-type pol zeta and is somewhat less efficient at extending from mismatched primer-terminal base pairs. These findings have important implications both for the evolutionary divergence of pol zeta from classical polymerases and for the mechanism by which this enzyme accommodates distortions in the DNA caused by mismatches and lesions.     

Role of a GAG hinge in the nucleotide-induced conformational change governing nucleotide specificity by T7 DNA polymerase

A nucleotide-induced change in DNA polymerase structure governs the kinetics of polymerization by high fidelity DNA polymerases. Mutation of a GAG hinge (G542A/G544A) in T7 DNA polymerase resulted in a 1000-fold slower rate of conformational change, which then limited the rate of correct nucleotide incorporation. Rates of misincorporation were comparable to that seen for wild-type enzyme so that the net effect of the mutation was a large decrease in fidelity. We demonstrate that a presumably modest change from glycine to alanine 20 Å from the active site can severely restrict the flexibility of the enzyme structure needed to recognize and incorporate correct substrates with high specificity. These results emphasize the importance of the substrate-induced conformational change in governing nucleotide selectivity by accelerating the incorporation of correct base pairs but not mismatches.     

Analysis of non-template-directed nucleotide addition and template switching by DNA polymerase

DNA polymerases use an uninterrupted template strand to direct synthesis of DNA. However, some DNA polymerases can synthesize DNA across two discontinuous templates by binding and juxtaposing them, resulting in synthesis across the junction. Primer/template duplexes with 3' overhangs are especially efficient substrates, suggesting that DNA polymerases use the overhangs as regions of microhomology for template synapsis. The formation of these overhangs may be the result of non-template-directed nucleotide addition by DNA polymerases. To examine the relative magnitude and mechanism of template switching, we studied the in vitro enzyme kinetics of template switching and non-template-directed nucleotide addition by the 3'-5' exonuclease-deficient large fragment of Escherichia coli DNA polymerase I. Non-template-directed nucleotide addition and template switching were compared to that of standard primer extension. We found that non-template-directed nucleotide addition and template switching showed similar rates and were approximately 100-fold slower than normal template-directed DNA synthesis. Furthermore, non-template-directed nucleotide addition showed a 10-fold preference for adding dAMP to the ends of DNA over that of the other three nucleotides. For template switching, kinetic analysis revealed that the two template substrates acted as a random bireactant system with mixed-type inhibition of substrate binding by one substrate over the other. These data are the first to establish the binding kinetics of two discontinuous DNA substrates to a single DNA polymerase. Our results suggest that although the activities are relatively weak, non-template-directed nucleotide addition and template switching allow DNA polymerases to overcome breaks in the template strand in an error-prone manner.     

Kinetic analysis of base substitution mutagenesis by transient misalignment of DNA and by miscoding

We measured the insertion fidelity of DNA polymerases alpha and beta and yeast DNA polymerase I at a template site that was previously observed to yield a high frequency of T----G transversions when copied by DNA polymerase beta but not by the other two polymerases. The results provide direct biochemical evidence that base substitution errors by DNA polymerase beta can result from a dislocation mechanism governed by DNA template-primer misalignment. In contrast to DNA polymerase beta, neither Drosophila DNA polymerase alpha nor yeast DNA polymerase I appear to misinsert nucleotides by a dislocation mechanism in either the genetic or kinetic fidelity assays. Dislocation errors by DNA polymerase beta are characterized primarily by a substantial reduction in the apparent Km for inserting a "correct," but ultimately errant, nucleotide compared to the apparent Km governing direct misinsertion. For synthesis by DNA polymerase beta, dislocation results in a 35-fold increase in dCMP incorporation opposite template T (T----G transversion) and a 20-35-fold increase in dTMP incorporation opposite T (T----A transversion); these results are consistent with parallel genetic fidelity measurements. DNA polymerase beta also produces base substitution errors by direct misinsertion. Here nucleotide insertion fidelity results from substantial differences in both Km and Vmax for correct versus incorrect substrates and is influenced strongly by local base sequence.     

Efficiency of correct nucleotide insertion governs DNA polymerase fidelity

DNA polymerase fidelity or specificity expresses the ability of a polymerase to select a correct nucleoside triphosphate (dNTP) from a pool of structurally similar molecules. Fidelity is quantified from the ratio of specificity constants (catalytic efficiencies) for alternate substrates (i.e. correct and incorrect dNTPs). An analysis of the efficiency of dNTP (correct and incorrect) insertion for a low fidelity mutant of DNA polymerase beta (R283A) and exonuclease-deficient DNA polymerases from five families derived from a variety of biological sources reveals that a strong correlation exists between the ability to synthesize DNA and the probability that the polymerase will make a mistake (i.e. base substitution error). Unexpectedly, this analysis indicates that the difference between low and high fidelity DNA polymerases is related to the efficiency of correct, but not incorrect, nucleotide insertion. In contrast to the loss of fidelity observed with the catalytically inefficient R283A mutant, the fidelity of another inefficient mutant of DNA polymerase beta (G274P) is not altered. Thus, although all natural low fidelity DNA polymerases are inefficient, not every inefficient DNA polymerase has low fidelity. Low fidelity polymerases appear to be an evolutionary solution to how to replicate damaged DNA or DNA repair intermediates without burdening the genome with excessive polymerase-initiated errors.     

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 base substitution fidelity of DNA polymerase beta-dependent single nucleotide base excision repair

Damaged DNA bases are removed from mammalian genomes by base excision repair (BER). Single nucleotide BER requires several enzymatic activities, including DNA polymerase and 5',2'-deoxyribose-5-phosphate lyase. Both activities are intrinsic to four human DNA polymerases whose base substitution error rate during gap-filling DNA synthesis varies by more than 10,000-fold. This suggests that BER fidelity could vary over a wide range in an enzyme dependent manner. To investigate this possibility, here we describe an assay to measure the fidelity of BER reactions reconstituted with purified enzymes. When human uracil DNA glycosylase, AP endonuclease, DNA polymerase beta, and DNA ligase 1 replace uracil opposite template A or G, base substitution error rates are 相似文献   

Low fidelity DNA synthesis by a y family DNA polymerase due to misalignment in the active site

Sulfolobus solfataricus DNA polymerase IV (Dpo4) is a member of the Y family of DNA polymerases whose crystal structure has recently been solved. As a model for other evolutionarily conserved Y family members that perform translesion DNA synthesis and have low fidelity, we describe here the base substitution and frameshift fidelity of DNA synthesis by Dpo4. Dpo4 generates all 12 base-base mismatches at high rates, 11 of which are similar to those of its human homolog, DNA polymerase kappa. This result is consistent with the Dpo4 structure, implying lower geometric selection for correct base pairs. Surprisingly, Dpo4 generates C.dCMP mismatches at an unusually high average rate and preferentially at cytosine flanked by 5'-template guanine. Dpo4 also has very low frameshift fidelity and frequently generates deletions of even noniterated nucleotides, especially cytosine flanked by a 5'-template guanine. Both unusual features of error specificity suggest that Dpo4 can incorporate dNTP precursors when two template nucleotides are present in the active site binding pocket. These results have implications for mutagenesis resulting from DNA synthesis by Y family polymerases.     

A mass spectrometry-based approach for identifying novel DNA polymerase substrates from a pool of dNTP analogues

There has been a long-standing interest in the discovery of unnatural nucleotides that can be incorporated into DNA by polymerases. However, it is difficult to predict which nucleotide analogs will prove to have biological relevance. Therefore, we have developed a new screening method to identify novel substrates for DNA polymerases. This technique uses the polymerase itself to select a dNTP from a pool of potential substrates via incorporation onto a short oligonucleotide. The unnatural nucleotide(s) is then identified by high-resolution mass spectrometry. By using a DNA polymerase as a selection tool, only the biologically relevant members of a small nucleotide library can be quickly determined. We have demonstrated that this method can be used to discover unnatural base pairs in DNA with a detection threshold of ≤10% incorporation.     

A real-time fluorescence method for enzymatic characterization of specialized human DNA polymerases

Specialized DNA polymerases are involved in DNA synthesis during base-excision repair and translesion synthesis across a wide range of chemically modified DNA templates. Notable features of these enzymes include low catalytic efficiency, low processivity and low fidelity. Traditionally, in vitro studies of these enzymes have utilized radiolabeled substrates and gel electrophoretic separation of products. We have developed a simple homogeneous fluorescence-based method to study the enzymology of specialized DNA polymerases in real time. The method is based on fluorescent reporter strand displacement from a tripartite substrate containing a quencher-labeled template strand, an unlabeled primer and a fluorophore-labeled reporter. With this method, we could follow the activity of human DNA polymerases β, η, ι and κ under different reaction conditions, and we investigated incorporation of the aberrant nucleotide, 8-oxodGTP, as well as bypass of an abasic site or 8-oxoG DNA template lesion in different configurations. Lastly, we demonstrate that the method can be used for small molecule inhibitor discovery and characterization in highly miniaturized settings, and we report the first nanomolar inhibitors of Y-family DNA polymerases ι and η. The fluorogenic method presented here should facilitate mechanistic and inhibitor investigations of these polymerases and is also applicable to the study of highly processive replicative polymerases.     

A unique error signature for human DNA polymerase nu

Human DNA polymerase nu (pol nu) is one of three A family polymerases conserved in vertebrates. Although its biological functions are unknown, pol nu has been implicated in DNA repair and in translesion DNA synthesis (TLS). Pol nu lacks intrinsic exonucleolytic proofreading activity and discriminates poorly against misinsertion of dNTP opposite template thymine or guanine, implying that it should copy DNA with low base substitution fidelity. To test this prediction and to comprehensively examine pol nu DNA synthesis fidelity as a clue to its function, here we describe human pol nu error rates for all 12 single base-base mismatches and for insertion and deletion errors during synthesis to copy the lacZ alpha-complementation sequence in M13mp2 DNA. Pol nu copies this DNA with average single-base insertion and deletion error rates of 7 x 10(-5) and 17 x 10(-5), respectively. This accuracy is comparable to that of replicative polymerases in the B family, lower than that of its A family homolog, human pol gamma, and much higher than that of Y family TLS polymerases. In contrast, the average single-base substitution error rate of human pol nu is 3.5 x 10(-3), which is inaccurate compared to the replicative polymerases and comparable to Y family polymerases. Interestingly, the vast majority of errors made by pol nu reflect stable misincorporation of dTMP opposite template G, at average rates that are much higher than for homologous A family members. This pol nu error is especially prevalent in sequence contexts wherein the template G is preceded by a C-G or G-C base pair, where error rates can exceed 10%. Amino acid sequence alignments based on the structures of more accurate A family polymerases suggest substantial differences in the O-helix of pol nu that could contribute to this unique error signature.     

Functions of human DNA polymerases eta,kappa and iota suggested by their properties,including fidelity with undamaged DNA templates

Human DNA polymerases eta, kappa and iota are template-dependent, Y-family DNA polymerases that have been implicated in translesion DNA synthesis (TLS) in human cells. Here, we briefly review evidence that these exonuclease-deficient polymerases copy undamaged DNA with very low fidelity and unusual error specificity. Based on the base substitution specificity and other biochemical properties of DNA polymerases eta and iota, we consider the possibility that they participate in specialized DNA transactions that repair damaged DNA and/or generate mutations in the variable regions of immunoglobulin genes.     

Ribonucleotide discrimination by translesion synthesis DNA polymerases

The well-being of all living organisms relies on the accurate duplication of their genomes. This is usually achieved by highly elaborate replicase complexes which ensure that this task is accomplished timely and efficiently. However, cells often must resort to the help of various additional “specialized” DNA polymerases that gain access to genomic DNA when replication fork progression is hindered. One such specialized polymerase family consists of the so-called “translesion synthesis” (TLS) polymerases; enzymes that have evolved to replicate damaged DNA. To fulfill their main cellular mission, TLS polymerases often must sacrifice precision when selecting nucleotide substrates. Low base-substitution fidelity is a well-documented inherent property of these enzymes. However, incorrect nucleotide substrates are not only those which do not comply with Watson–Crick base complementarity, but also those whose sugar moiety is incorrect. Does relaxed base-selectivity automatically mean that the TLS polymerases are unable to efficiently discriminate between ribonucleoside triphosphates and deoxyribonucleoside triphosphates that differ by only a single atom? Which strategies do TLS polymerases employ to select suitable nucleotide substrates? In this review, we will collate and summarize data accumulated over the past decade from biochemical and structural studies, which aim to answer these questions.     

Herpes simplex virus-1 primase: a polymerase with extraordinarily low fidelity

We utilized templates of defined sequence to investigate the fidelity and mechanism of NTP misincorporation by DNA primase from herpes simplex virus-1. Herpes primase generated a wide range of mismatches during primer synthesis, including purine-purine, pyrimidine-pyrimidine, and purine-pyrimidine mismatches, and could even polymerize consecutive incorrect NTPs. Polymerization of noncognate NTPs resulted from primase misreading the template, as opposed to a primer slippage or dislocation mutagenesis mechanism. Primase did not efficiently misincorporate NTPs during the initiation reaction (i.e., dinucleotide synthesis). However, during primer elongation (after dinucleotide formation), herpes primase was extraordinarily inaccurate. It misincorporated NTPs at frequencies as high as 1 in 7, although frequencies of 1 in 25 to 1 in 60 were more common. In every case, however, misincorporation frequencies were no less than 1 in 100. For a specific mismatch, the DNA sequences flanking the site where misincorporation occurred could influence the frequency of misincorporation. This remarkably low level of fidelity is as low as that observed for the least accurate members of the Y class DNA polymerases involved in lesion bypass. Thus, herpes primase is one of the least accurate nucleotide polymerizing enzymes known.     

Dissecting and tuning primer editing by proofreading polymerases

Proofreading polymerases have 3′ to 5′ exonuclease activity that allows the excision and correction of mis-incorporated bases during DNA replication. In a previous study, we demonstrated that in addition to correcting substitution errors and lowering the error rate of DNA amplification, proofreading polymerases can also edit PCR primers to match template sequences. Primer editing is a feature that can be advantageous in certain experimental contexts, such as amplicon-based microbiome profiling. Here we develop a set of synthetic DNA standards to report on primer editing activity and use these standards to dissect this phenomenon. The primer editing standards allow next-generation sequencing-based enzymological measurements, reveal the extent of editing, and allow the comparison of different polymerases and cycling conditions. We demonstrate that proofreading polymerases edit PCR primers in a concentration-dependent manner, and we examine whether primer editing exhibits any sequence specificity. In addition, we use these standards to show that primer editing is tunable through the incorporation of phosphorothioate linkages. Finally, we demonstrate the ability of primer editing to robustly rescue the drop-out of taxa with 16S rRNA gene-targeting primer mismatches using mock communities and human skin microbiome samples.     

Deoxynucleotide triphosphate binding mode conserved in Y family DNA polymerases

Although DNA polymerase eta (Pol eta) and other Y family polymerases differ in sequence and function from classical DNA polymerases, they all share a similar right-handed architecture with the palm, fingers, and thumb domains. Here, we examine the role in Saccharomyces cerevisiae Pol eta of three conserved residues, tyrosine 64, arginine 67, and lysine 279, which come into close contact with the triphosphate moiety of the incoming nucleotide, in nucleotide incorporation. We find that mutational alteration of these residues reduces the efficiency of correct nucleotide incorporation very considerably. The high degree of conservation of these residues among the various Y family DNA polymerases suggests that these residues are also crucial for nucleotide incorporation in the other members of the family. Furthermore, we note that tyrosine 64 and arginine 67 are functionally equivalent to the deoxynucleotide triphosphate binding residues arginine 518 and histidine 506 in T7 DNA polymerase, respectively.     

Saccharomyces cerevisiae DNA polymerase delta: high fidelity for base substitutions but lower fidelity for single- and multi-base deletions

Eukaryotic DNA polymerase delta (Pol delta) plays an essential role in replicating large nuclear genomes, a process that must be accurate to maintain stability over many generations. Based on kinetic studies of insertion of individual dNTPs opposite a template guanine, Pol delta is believed to have high selectivity for inserting correct nucleotides. This high selectivity, in conjunction with an intrinsic 3'-exonuclease activity, implies that Pol delta should have high base substitution fidelity. Here we demonstrate that the wild type Saccharomyces cerevisiae three-subunit Pol delta does indeed have high base substitution fidelity for the 12 possible base-base mismatches, producing on average less than 1.3 stable misincorporations/100,000 nucleotides polymerized. Measurements with exonuclease-deficient Pol delta confirm the high nucleotide selectivity of the polymerase and further indicate that proofreading enhances the base substitution fidelity of the wild type enzyme by at least 60-fold. However, Pol delta inefficiently proofreads single nucleotide deletion mismatches in homopolymeric runs, such that the error rate is 30 single nucleotide deletions/100,000 nucleotides polymerized. Moreover, wild type Pol delta frequently deletes larger numbers of nucleotides between distantly spaced direct repeats of three or more base pairs. Although wild type Pol delta and Pol epsilon both have high base substitution fidelity, Pol delta is much less accurate than Pol epsilon for deletions involving repetitive sequences. Thus, strand slippage during replication by wild type Pol delta may be a primary source of insertion and deletion mutagenesis in eukaryotic genomes.