Thomas A. Kunkel

The Y-Family of DNA Polymerases

We would like to thank Tomoo Ogi for generating the unrooted phylogenetic tree shown in Figure 1Figure 1 and Junetsu Ito for his comments on our proposal.

Efficient site-directed mutagenesis using uracil-containing DNA

Publisher Summary Oligonucleotide-directed mutagenesis is a widely used procedure for studying the structure and function of DNA and the macromolecules for which it codes. The most commonly used strategy for site-directed mutagenesis is to clone the segment of DNA to be mutated into a vector whose DNA can be obtained in single-stranded form. An oligonucleotide partially complementary to the region to be altered, but containing the mutation to be introduced, is hybridized to the single-stranded DNA. A complementary strand is synthesized by DNA polymerase using the oligonucleotide as a primer. The efficiency of site-directed mutagenesis, that is, the proportion of progeny containing the desired sequence alteration, depends on the quality of each of the steps in the procedure. The number of progeny clones that must be monitored to obtain the desired mutant increases as the efficiency of mutagenesis decreases.

Requirement for PCNA in DNA Mismatch Repair at a Step Preceding DNA Resynthesis

A two-hybrid system was used to screen yeast and human expression libraries for proteins that interact with mismatch repair proteins. PCNA was recovered from both libraries and shown in the case of yeast to interact with both MLH1 and MSH2. A yeast strain containing a mutation in the PCNA gene had a strongly elevated mutation rate in a dinucleotide repeat, and the rate was not further elevated in a strain also containing a mutation in MLH1. Mismatch repair activity was examined in human cell extracts using an assay that does not require DNA repair synthesis. Activity was inhibited by p21WAF1 or a p21 peptide, both of which bind to PCNA, and activity was restored to inhibited reactions by addition of PCNA. The data suggest a PCNA requirement in mismatch repair at a step preceding DNA resynthesis. The ability of PCNA to bind to MLH1 and MSH2 may reflect linkage between mismatch repair and replication and may be relevant to the roles of mismatch repair proteins in other DNA transactions.

MEIOTIC PACHYTENE ARREST IN MLH1-DEFICIENT MICE

Germ line mutations in DNA mismatch repair genes including MLH1 cause hereditary nonpolyposis colon cancer. To understand the role of MLH1 in normal growth and development, we generated mice that have a null mutation of this gene. Mice homozygous for this mutation show a replication error phenotype, and extracts of these cells are deficient in mismatch repair activity. Homozygous mutant males show normal mating behavior but have no detectable mature sperm. Examination of meiosis in these males reveals that the cells enter meiotic prophase and arrest at pachytene. Homozygous mutant females have normal estrous cycles and reproductive and mating behavior but are infertile. The phenotypes of the mlh1 mutant mice are distinct from those deficient in msh2 and pms2. The different phenotypes of the three types of mutant mice suggest that these three genes may have independent functions in mammalian meiosis.

Cadmium is a mutagen that acts by inhibiting mismatch repair

Most errors that arise during DNA replication can be corrected by DNA polymerase proofreading or by post-replication mismatch repair (MMR). Inactivation of both mutation-avoidance systems results in extremely high mutability that can lead to error catastrophe. High mutability and the likelihood of cancer can be caused by mutations and epigenetic changes that reduce MMR. Hypermutability can also be caused by external factors that directly inhibit MMR. Identifying such factors has important implications for understanding the role of the environment in genome stability. We found that chronic exposure of yeast to environmentally relevant concentrations of cadmium, a known human carcinogen, can result in extreme hypermutability. The mutation specificity along with responses in proofreading-deficient and MMR-deficient mutants indicate that cadmium reduces the capacity for MMR of small misalignments and base-base mismatches. In extracts of human cells, cadmium inhibited at least one step leading to mismatch removal. Together, our data show that a high level of genetic instability can result from environmental impediment of a mutation-avoidance system.

The fidelity of DNA synthesis by eukaryotic replicative and translesion synthesis polymerases

In their seminal publication describing the structure of the DNA double helix 1, Watson and Crick wrote what may be one of the greatest understatements in the scientific literature, namely that “It has not escaped our notice that the specific pairing we have postulated immediately suggests a possible copying mechanism for the genetic material.” Half a century later, we more fully appreciate what a huge challenge it is to replicate six billion nucleotides with the accuracy needed to stably maintain the human genome over many generations. This challenge is perhaps greater than was realized 50 years ago, because subsequent studies have revealed that the genome can be destabilized not only by environmental stresses that generate a large number and variety of potentially cytotoxic and mutagenic lesions in DNA but also by various sequence motifs of normal DNA that present challenges to replication. Towards a better understanding of the many determinants of genome stability, this chapter reviews the fidelity with which undamaged and damaged DNA is copied, with a focus on the eukaryotic B- and Y-family DNA polymerases, and considers how this fidelity is achieved.

Division of labor at the eukaryotic replication fork.

DNA polymerase delta (Pol delta) and DNA polymerase epsilon (Pol epsilon) are both required for efficient replication of the nuclear genome, yet the division of labor between these enzymes has remained unclear for many years. Here we investigate the contribution of Pol delta to replication of the leading and lagging strand templates in Saccharomyces cerevisiae using a mutant Pol delta allele (pol3-L612M) whose error rate is higher for one mismatch (e.g., T x dGTP) than for its complement (A x dCTP). We find that strand-specific mutation rates strongly depend on the orientation of a reporter gene relative to an adjacent replication origin, in a manner implying that >90% of Pol delta replication is performed using the lagging strand template. When combined with recent evidence implicating Pol epsilon in leading strand replication, these data support a model of the replication fork wherein the leading and lagging strand templates are primarily copied by Pol epsilon and Pol delta, respectively.

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)-η, lead to increased ultraviolet-induced mutagenesis. This, and the fact that pol-η primarily inserts adenines during efficient bypass of thymine–thymine dimers in vitro, has led to the description of pol-η as error-free. However, here we show that human pol-η copies undamaged DNA with much lower fidelity than any other template-dependent DNA polymerase studied. Pol-η 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-η may be tightly controlled to prevent potentially mutagenic DNA synthesis.

Mutation in the mismatch repair gene Msh6 causes cancer susceptibility

Mice carrying a null mutation in the mismatch repair gene Msh6 were generated by gene targeting. Cells that were homozygous for the mutation did not produce any detectable MSH6 protein, and extracts prepared from these cells were defective for repair of single nucleotide mismatches. Repair of 1, 2, and 4 nucleotide insertion/deletion mismatches was unaffected. Mice that were homozygous for the mutation had a reduced life span. The mice developed a spectrum of tumors, the most predominant of which were gastrointestinal tumors and B- as well as T-cell lymphomas. The tumors did not show any microsatellite instability. We conclude that MSH6 mutations, like those in some other members of the family of mismatch repair genes, lead to cancer susceptibility, and germline mutations in this gene may be associated with a cancer predisposition syndrome that does not show microsatellite instability.

Somatic mutation hotspots correlate with DNA polymerase |[eta]| error spectrum

Mutational spectra analysis of 15 immunoglobulin genes suggested that consensus motifs RGYW and WA were universal descriptors of somatic hypermutation. Highly mutable sites, “hotspots”, that matched WA were preferentially found in one DNA strand and RGYW hotspots were found in both strands. Analysis of base-substitution hotspots in DNA polymerase error spectra showed that 33 of 36 hotspots in the human polymerase η spectrum conformed to the WA consensus. This and four other characteristics of polymerase η substitution specificity suggest that errors introduced by this enzyme during synthesis of the nontranscribed DNA strand in variable regions may contribute to strand-specific somatic hypermutagenesis of immunoglobulin genes at A-T base pairs.