Connie Holm

Evidence for Involvement of Yeast Proliferating Cell Nuclear Antigen in DNA Mismatch Repair

DNA mismatch repair plays a key role in the maintenance of genetic fidelity. Mutations in the human mismatch repair genes hMSH2, hMLH1, hPMS1, and hPMS2 are associated with hereditary nonpolyposis colorectal cancer. The proliferating cell nuclear antigen (PCNA) is essential for DNA replication, where it acts as a processivity factor. Here, we identify a point mutation, pol30-104, in the Saccharomyces cerevisiae POL30 gene encoding PCNA that increases the rate of instability of simple repetitive DNA sequences and raises the rate of spontaneous forward mutation. Epistasis analyses with mutations in mismatch repair genes MSH2, MLH1, and PMS1 suggest that the pol30-104 mutation impairs MSH2/MLH1/PMS1-dependent mismatch repair, consistent with the hypothesis that PCNA functions in mismatch repair. MSH2 functions in mismatch repair with either MSH3 or MSH6, and the MSH2-MSH3 and MSH2-MSH6 heterodimers have a role in the recognition of DNA mismatches. Consistent with the genetic data, we find specific interaction of PCNA with the MSH2-MSH3 heterodimer.

The function of DNA polymerase alpha at telomeric G tails is important for telomere homeostasis.

ABSTRACT Telomere length control is influenced by several factors, including telomerase, the components of telomeric chromatin structure, and the conventional replication machinery. Although known components of the replication machinery can influence telomere length equilibrium, little is known about why mutations in certain replication proteins cause dramatic telomere lengthening. To investigate the cause of telomere elongation in cdc17/pol1 (DNA polymerase α) mutants, we examined telomeric chromatin, as measured by its ability to repress transcription on telomere-proximal genes, and telomeric DNA end structures in pol1-17 mutants. pol1-17 mutants with elongated telomeres show a dramatic loss of the repression of telomere-proximal genes, or telomeric silencing. In addition,cdc17/pol1 mutants grown under telomere-elongating conditions exhibit significant increases in single-stranded character in telomeric DNA but not at internal sequences. The single strandedness is manifested as a terminal extension of the G-rich strand (G tails) that can occur independently of telomerase, suggesting thatcdc17/pol1 mutants exhibit defects in telomeric lagging-strand synthesis. Interestingly, the loss of telomeric silencing and the increase in the sizes of the G tails at the telomeres temporally coincide and occur before any detectable telomere lengthening is observed. Moreover, the G tails observed incdc17/pol1 mutants incubated at the semipermissive temperature appear only when the cells pass through S phase and are processed by the time cells reach G1. These results suggest that lagging-strand synthesis is coordinated with telomerase-mediated telomere maintenance to ensure proper telomere length control.

Saccharomyces cerevisiae pol30(Proliferating Cell Nuclear Antigen) Mutations Impair Replication Fidelity and Mismatch Repair

ABSTRACT To understand the role of POL30 in mutation suppression, 11 Saccharomyces cerevisiae pol30 mutator mutants were characterized. These mutants were grouped based on their mutagenic defects. Many pol30 mutants harbor multiple mutagenic defects and were placed in more than one group. Group A mutations (pol30-52, -104, -108, and -126) caused defects in mismatch repair (MMR). These mutants exhibited mutation rates and spectra reminiscent of MMR-defective mutants and were defective in an in vivo MMR assay. The mutation rates of group A mutants were enhanced by a msh2or a msh6 mutation, indicating that MMR deficiency is not the only mutagenic defect present. Group B mutants (pol30-45, -103, -105, -126, and -114) exhibited increased accumulation of either deletions alone or a combination of deletions and duplications (4 to 60 bp). All deletion and duplication breakpoints were flanked by 3 to 7 bp of imperfect direct repeats. Genetic analysis of one representative group B mutant, pol30-126, suggested polymerase slippage as the likely mutagenic mechanism. Group C mutants (pol30-100, -103, -105, -108, and -114) accumulated base substitutions and exhibited synergistic increases in mutation rate when combined withmsh6 mutations, suggesting increased DNA polymerase misincorporation as a mutagenic defect. The synthetic lethality between a group A mutant, pol30-104, and rad52 was almost completely suppressed by the inactivation of MSH2. Moreover, pol30-104 caused a hyperrecombination phenotype that was partially suppressed by a msh2 mutation. These results suggest that pol30-104 strains accumulate DNA breaks in a MSH2-dependent manner.

Specific DNA replication mutations affect telomere length in Saccharomyces cerevisiae.

To investigate the relationship between the DNA replication apparatus and the control of telomere length, we examined the effects of several DNA replication mutations on telomere length in Saccharomyces cerevisiae. We report that a mutation in the structural gene for the large subunit of DNA replication factor C (cdc44/rfc1) causes striking increases in telomere length. A similar effect is seen with mutations in only one other DNA replication gene: the structural gene for DNA polymerase alpha (cdc17/pol1) (M.J. Carson and L. Hartwell, Cell 42:249-257, 1985). For both genes, the telomere elongation phenotype is allele specific and appears to correlate with the penetrance of the mutations. Furthermore, fluorescence-activated cell sorter analysis reveals that those alleles that cause elongation also exhibit a slowing of DNA replication. To determine whether elongation is mediated by telomerase or by slippage of the DNA polymerase, we created cdc17-1 mutants carrying deletions of the gene encoding the RNA component of telomerase (TLC1). cdc17-1 strains that would normally undergo telomere elongation failed to do so in the absence of telomerase activity. This result implies that telomere elongation in cdc17-1 mutants is mediated by the action of telomerase. Since DNA replication involves transfer of the nascent strand from polymerase alpha to replication factor C (T. Tsurimoto and B. Stillman, J. Biol. Chem. 266:1950-1960, 1991; T. Tsurimoto and B. Stillman, J. Biol. Chem. 266:1961-1968, 1991; S. Waga and B. Stillman, Nature [London] 369:207-212, 1994), one possibility is that this step affects the regulation of telomere length.