Replication-compromised cells require the mitotic checkpoint to prevent tetraploidization.

Replication stress often induces chromosome instability. In this study, we explore which factors in replication-compromised cells promote abnormal chromosome ploidy. We expressed mutant forms of either polymerase α (Polα) or polymerase δ (Polδ) in normal human fibroblasts to compromise DNA replication.

Rad3-dependent phosphorylation of the checkpoint clamp regulates repair-pathway choice.

When replication forks collapse, Rad3 phosphorylates the checkpoint-clamp protein Rad9 in a manner that depends on Thr 225, a residue within the PCNA-like domain. The physiological function of Thr 225-dependent Rad9 phosphorylation, however, remains elusive. Here, we show that Thr 225-dependent Rad9 phosphorylation by Rad3 regulates DNA repair pathways.

Rad4TopBP1 associates with Srr2, an Spc1 MAPK-regulated protein, in response to environmental stress.

Rad4(TopBP1) is a scaffold in a protein complex containing both replication proteins and checkpoint proteins and plays essential roles in both replication and checkpoint responses. We have previously identified four novel fission yeast mutants of rad4+(TopBP1) to explore how Rad4(TopBP1), a single protein, can play multiple roles in genomic integrity maintenance. Among the four novel mutants, rad4-c17(TopBP1) is a thermosensitive mutant.

Methods for studying mutagenesis and checkpoints in Schizosaccharomyces pombe.

Mutations in genome caretaker genes can induce genomic instability, which are potentially early events in tumorigenesis. Cells have evolved biological processes to cope with the genomic insults. One is a multifaceted response, termed checkpoint, which is a network of signaling pathways to coordinate cell cycle transition with DNA repair, activation of transcriptional programs, and induction of tolerance of the genomic perturbations.

Rad4TopBP1, a scaffold protein, plays separate roles in DNA damage and replication checkpoints and DNA replication.

Rad4TopBP1, a BRCT domain protein, is required for both DNA replication and checkpoint responses. Little is known about how the multiple roles of Rad4TopBP1 are coordinated in maintaining genome integrity. We show here that Rad4TopBP1 of fission yeast physically interacts with the checkpoint sensor proteins, the replicative DNA polymerases, and a WD-repeat protein, Crb3.

Replication checkpoint kinase Cds1 regulates Mus81 to preserve genome integrity during replication stress.

The replication checkpoint kinase Cds1 preserves genome integrity by stabilizing stalled replication forks. Cds1 targets substrates through its FHA domain. The Cds1 FHA domain interacts with Mus81, a subunit of the Mus81-Eme1 structure-specific endonuclease.

A coordinated temporal interplay of nucleosome reorganization factor, sister chromatin cohesion factor, and DNA polymerase alpha facilitates DNA replication.

DNA replication depends critically upon chromatin structure. Little is known about how the replication complex overcomes the nucleosome packages in chromatin during DNA replication. To address this question, we investigate factors that interact in vivo with the principal initiation DNA polymerase, DNA polymerase alpha (Polalpha).

The B-subunit of DNA polymerase alpha-primase associates with the origin recognition complex for initiation of DNA replication.

The B-subunit (p70/Pol12p) of the DNA polymerase alpha-primase (Polalpha-primase) complex is thought to have a regulatory role in an early stage of S phase. We generated a panel of fission yeast thermosensitive mutants of the B-subunit (termed Spb70) to investigate its role in initiation of DNA replication by genetic and biochemical approaches. Here, we show that the fission yeast Spb70 genetically interacts and coprecipitates with origin recognition complex proteins Orp1/Orc1 and Orp2/Orc2 and primase coupling subunit Spp2/p58.

Checkpoint responses to replication stalling: inducing tolerance and preventing mutagenesis.

Replication mutants often exhibit a mutator phenotype characterized by point mutations, single base frameshifts, and the deletion or duplication of sequences flanked by homologous repeats. Mutation in genes encoding checkpoint proteins can significantly affect the mutator phenotype. Here, we use fission yeast (Schizosaccharomyces pombe) as a model system to discuss the checkpoint responses to replication perturbations induced by replication mutants.

Genomic instability induced by mutations in Saccharomyces cerevisiae POL1.

Mutations of chromosome replication genes can be one of the early events that promote genomic instability. Among genes that are involved in chromosomal replication, DNA polymerase alpha is essential for initiation of replication and lagging-strand synthesis. Here we examined the effect of two mutations in S.

Replication proteins influence the maintenance of telomere length and telomerase protein stability.

We investigated the effects of fission yeast replication genes on telomere length maintenance and identified 20 mutant alleles that confer lengthening or shortening of telomeres. The telomere elongation was telomerase dependent in the replication mutants analyzed. Furthermore, the telomerase catalytic subunit, Trt1, and the principal initiation and lagging-strand synthesis DNA polymerase, Polalpha, were reciprocally coimmunoprecipitated, indicating these proteins physically coexist as a complex in vivo.

Checkpoint activation regulates mutagenic translesion synthesis.

Cells have evolved checkpoint responses to arrest or delay the cell cycle, activate DNA repair networks, or induce apoptosis after genomic perturbation. Cells have also evolved the translesion synthesis processes to tolerate genomic lesions by either error-free or error-prone repair. Here, we show that after a replication perturbation, cells exhibit a mutator phenotype, which can be significantly affected by mutations in the checkpoint elements Cds1 and Rad17 or translesion synthesis polymerases DinB and Polzeta.