Characterization of the checkpoint gene RAD53/MEC2 in Saccharomyces cerevisiae.

Saccharomyces cerevisiae cells carrying mutations in RAD53/MEC2 fail to arrest in the S phase when DNA replication is blocked (the S/M checkpoint) or in the G2 phase when DNA is damaged (the G2/M checkpoint). We isolated and determined the DNA sequence of RAD53 and found that it is identical to the SPK1 gene previously identified by Stern et al. (1991). In addition to its checkpoint functions, we show here that RAD53 is essential for cell viability because null mutants are inviable. Weak genomic suppressors of the essential function do arise frequently, though they do not suppress the checkpoint defects of the null mutant. This genetically separates the essential and checkpoint functions. We show genetically that the protein kinase domain is essential for all RAD53-dependent functions tested because a site-specific mutation that inactivates the protein kinase activity results in a mutant phenotype indistinguishable from that of a null mutant. Overexpression of RAD53, or its kinase domain alone, resulted in a delay in cell-cycle progression that required the intact kinase function. The cell-cycle delay did not require any of the checkpoint genes tested (e.g. rad9 or mecl), indicating that the cell-cycle delay is either unrelated to the checkpoint responses, or that it occurs constitutively because RAD53 acts further downstream of the checkpoint genes tested. Finally, elimination of sequences in the promoter region of RAD53 revealed complex regulatory elements.

Distinct roles of yeast MEC and RAD checkpoint genes in transcriptional induction after DNA damage and implications for function.

In eukaryotic cells, checkpoint genes cause arrest of cell division when DNA is damaged or when DNA replication is blocked. In this study of budding yeast checkpoint genes, we identify and characterize another role for these checkpoint genes after DNA damage-transcriptional induction of genes. We found that three checkpoint genes (of six genes tested) have strong and distinct roles in transcriptional induction in four distinct pathways of regulation (each defined by induction of specific genes). MEC1 mediates the response in three transcriptional pathways, RAD53 mediates two of these pathways, and RAD17 mediates but a single pathway. The three other checkpoint genes (including RAD9) have small (twofold) but significant roles in transcriptional induction in all pathways. One of the pathways that we identify here leads to induction of MEC1 and RAD53 checkpoint genes themselves. This suggests a positive feedback circuit that may increase the cell's ability to respond to DNA damage. We make two primary conclusions from these studies. First, MEC1 appears to be the key regulator because it is required for all responses (both transcriptional and cell cycle arrest), while other genes serve only a subset of these responses. Second, the two types of responses, transcriptional induction and cell cycle arrest, appear distinct because both require MEC1 yet only cell cycle arrest requires RAD9. These and other results were used to formulate a working model of checkpoint gene function that accounts for roles of different checkpoint genes in different responses and after different types of damage. The conclusion that the yeast MEC1 gene is a key regulator also has implications for the role of a putative human homologue, the ATM gene.

GUF1, a gene encoding a novel evolutionarily conserved GTPase in budding yeast.

While sequencing a region of chromosome IV adjacent to the checkpoint gene MEC3, we identified a gene we call GUF1 (GTPase of Unknown Function), which predicts a 586 amino acid GTPase of the elongation factor-type class. The predicted Guf1p protein bears striking sequence similarity to both LepA from Escherichia coli (43% identical) and LK1236.1 from Caenorhabditis elegans (42% identical). Analysis of both a guf1 delta deletion and a putative constitutive-activating mutant (GUF1HG) revealed that GUF1 is not essential nor did mutant cells reveal any marked phenotype.

Mitotic checkpoint genes in budding yeast and the dependence of mitosis on DNA replication and repair.

In eukaryotes a cell-cycle control termed a checkpoint causes arrest in the S or G2 phases when chromosomes are incompletely replicated or damaged. Previously, we showed in budding yeast that RAD9 and RAD17 are checkpoint genes required for arrest in the G2 phase after DNA damage. Here, we describe a genetic strategy that identified four additional checkpoint genes that act in two pathways. Both classes of genes are required for arrest in the G2 phase after DNA damage, and one class of genes is also required for arrest in S phase when DNA replication is incomplete. The G2-specific genes include MEC3 (for mitosis entry checkpoint), RAD9, RAD17, and RAD24. The genes common to both S phase and G2 phase pathways are MEC1 and MEC2. The MEC2 gene proves to be identical to the RAD53 gene. Checkpoint mutants were identified by their interactions with a temperature-sensitive allele of the cell division cycle gene CDC13; cdc13 mutants arrested in G2 and survived at the restrictive temperature, whereas all cdc13 checkpoint double mutants failed to arrest in G2 and died rapidly at the restrictive temperature. The cell-cycle roles of the RAD and MEC genes were examined by combination of rad and mec mutant alleles with 10 cdc mutant alleles that arrest in different stages of the cell cycle at the restrictive temperature and by the response of rad and mec mutant alleles to DNA damaging agents and to hydroxyurea, a drug that inhibits DNA replication. We conclude that the checkpoint in budding yeast consists of overlapping S-phase and G2-phase pathways that respond to incomplete DNA replication and/or DNA damage and cause arret of cells before mitosis.

Cell cycle arrest of cdc mutants and specificity of the RAD9 checkpoint.

In eucaryotes a cell cycle control called a checkpoint ensures that mitosis occurs only after chromosomes are completely replicated and any damage is repaired. The function of this checkpoint in budding yeast requires the RAD9 gene. Here we examine the role of the RAD9 gene in the arrest of the 12 cell division cycle (cdc) mutants, temperature-sensitive lethal mutants that arrest in specific phases of the cell cycle at a restrictive temperature. We found that in four cdc mutants the cdc rad9 cells failed to arrest after a shift to the restrictive temperature, rather they continued cell division and died rapidly, whereas the cdc RAD cells arrested and remained viable. The cell cycle and genetic phenotypes of the 12 cdc RAD mutants indicate the function of the RAD9 checkpoint is phase-specific and signal-specific. First, the four cdc RAD mutants that required RAD9 each arrested in the late S/G2 phase after a shift to the restrictive temperature when DNA replication was complete or nearly complete, and second, each leaves DNA lesions when the CDC gene product is limiting for cell division. Three of the four CDC genes are known to encode DNA replication enzymes. We found that the RAD17 gene is also essential for the function of the RAD9 checkpoint because it is required for phase-specific arrest of the same four cdc mutants. We also show that both X- or UV-irradiated cells require the RAD9 and RAD17 genes for delay in the G2 phase. Together, these results indicate that the RAD9 checkpoint is apparently activated only by DNA lesions and arrests cell division only in the late S/G2 phase.

Dual cell cycle checkpoints sensitive to chromosome replication and DNA damage in the budding yeast Saccharomyces cerevisiae.

In eucaryotic cells chromosomes must be fully replicated and repaired before mitosis begins. Genetic studies indicate that this dependence of mitosis on completion of DNA replication and DNA repair derives from a negative control called a checkpoint which somehow checks for replication and DNA damage and blocks cell entry into mitosis. Here we summarize our current understanding of the genetic components of the cell cycle checkpoint in budding yeast. Mutants were identified and their phase and signal specificity tested primarily through interactions of the arrest-defective mutants with cell division cycle mutants. The results indicate that dual checkpoint controls exist in budding yeast, one control sensitive to inhibition of DNA replication (S-phase checkpoint), and a distinct but overlapping control sensitive to DNA repair (G2 checkpoint). Six genes are required for arrest in G2 phase after DNA damage (RAD9, RAD17, RAD24, MEC1, MEC2, and MEC3), and two of these are also essential for arrest in S phase when DNA replication is blocked (MEC1 and MEC2).

Characterization of RAD9 of Saccharomyces cerevisiae and evidence that its function acts posttranslationally in cell cycle arrest after DNA damage.

In eucaryotic cells, incompletely replicated or damaged chromosomes induce cell cycle arrest in G2 before mitosis, and in the yeast Saccharomyces cerevisiae the RAD9 gene is essential for the cell cycle arrest (T.A. Weinert and L. H. Hartwell, Science 241:317-322, 1988). In this report, we extend the analysis of RAD9-dependent cell cycle control. We found that both induction of RAD9-dependent arrest in G2 and recovery from arrest could occur in the presence of the protein synthesis inhibitor cycloheximide, showing that the mechanism of RAD9-dependent control involves a posttranslational mechanism(s). We have isolated and determined the DNA sequence of the RAD9 gene, confirming the DNA sequence reported previously (R. H. Schiestl, P. Reynolds, S. Prakash, and L. Prakash, Mol. Cell. Biol. 9:1882-1886, 1989). The predicted protein sequence for the Rad9 protein bears no similarity to sequences of known proteins. We also found that synthesis of the RAD9 transcript in the cell cycle was constitutive and not induced by X-irradiation. We constructed yeast cells containing a complete deletion of the RAD9 gene; the rad9 null mutants were viable, sensitive to X- and UV irradiation, and defective for cell cycle arrest after DNA damage. Although Rad+ and rad9 delta cells had similar growth rates and cell cycle kinetics in unirradiated cells, the spontaneous rate of chromosome loss (in unirradiated cells) was elevated 7- to 21-fold in rad9 delta cells. These studies show that in the presence of induced or endogenous DNA damage, RAD9 is a negative regulator that inhibits progression from G2 in order to preserve cell viability and to maintain the fidelity of chromosome transmission.

Checkpoints: controls that ensure the order of cell cycle events.

The events of the cell cycle of most organisms are ordered into dependent pathways in which the initiation of late events is dependent on the completion of early events. In eukaryotes, for example, mitosis is dependent on the completion of DNA synthesis. Some dependencies can be relieved by mutation (mitosis may then occur before completion of DNA synthesis), suggesting that the dependency is due to a control mechanism and not an intrinsic feature of the events themselves. Control mechanisms enforcing dependency in the cell cycle are here called checkpoints. Elimination of checkpoints may result in cell death, infidelity in the distribution of chromosomes or other organelles, or increased susceptibility to environmental perturbations such as DNA damaging agents. It appears that some checkpoints are eliminated during the early embryonic development of some organisms; this fact may pose special problems for the fidelity of embryonic cell division.

The RAD9 gene controls the cell cycle response to DNA damage in Saccharomyces cerevisiae.

Cell division is arrested in many organisms in response to DNA damage. Examinations of the genetic basis for this response in the yeast Saccharomyces cerevisiae indicate that the RAD9 gene product is essential for arrest of cell division induced by DNA damage. Wild-type haploid cells irradiated with x-rays either arrest or delay cell division in the G2 phase of the cell cycle. Irradiated G1 and M phase haploid cells arrest irreversibly in G2 and die, whereas irradiated G2 phase haploid cells delay in G2 for a time proportional to the extent of damage before resuming cell division. In contrast, irradiated rad9 cells in any phase of the cycle do not delay cell division in G2, but continue to divide for several generations and die. However, efficient DNA repair can occur in irradiated rad9 cells if irradiated cells are blocked for several hours in G2 by treatment with a microtubule poison. The RAD9-dependent response detects potentially lethal DNA damage and causes arrest of cells in G2 until such damage is repaired.

Replicative and conservative transpositional recombination of insertion sequences.

We have presented the results of experiments with IS903- and IS10- derived transposons that have led us to the following conclusions: The predominant mechanism of transpositional recombination of these IS elements is a donor-suicide process that results intermolecularly in a simple IS insertion. This process presumably involves little or no replication of the IS. Intramolecular transposition by this process normally results in nonviable products. However, in the particular situation where the transpositional target lies within the transposon, viable products are obtained; these are deletions and deletion-inversions. Deletions between an IS and a target lying outside the element (the conventional "adjacent deletion") occur by a fully replicative process analogous to the formation of cointegrate molecules in intermolecular transposition. The ability of an IS to promote adjacent deletions correlates closely with its ability to fuse replicons into a cointegrate. Before transposition can occur, a complex of the transposase and both IS ends is probably formed. Requirement for such a pretranspositional complex is suggested by the effect on transpositional frequency of changing the distance between the ends. Our results do not support any of the asymmetrical models for transposition. They are, however, compatible with a modified version of the symmetric model proposed by Shapiro (1979). It is interesting to note the similarity between the structures generated by intramolecular simple transposition of an inverse transposon and the circular structures apparently formed by retroviral and copia autointegrative transposition. Shoemaker et al. (1981a,b) and Flavell and Ish-Horowicz (1983) have characterized circular molecules from retrovirally infected cells and Drosophila tissue-culture cells, respectively. The structures of some of the circular molecules resemble deletions and deletion-inversions (Fig. 3B). To our knowledge, a circular species containing two long terminal repeats (LTRs) and an adjacent deletion, which we predict could only occur by a fully replicative process given the similarity in geometry of an LTR to an IS, have not been found. It would appear, then, that the molecule containing two LTRs acts as an inverse transposon, integrating into itself. Shoemaker et al. (1981b) and Flavell and Ish-Horowicz (1983) have also suggested that these products arise from molecules containing two LTRs. We suggest that the two inside LTR ends interact in a conservative, intramolecular, simple transpositionlike event.

Insertion sequence duplication in transpositional recombination.

Insertion sequences (IS) are discrete segments of DNA that can transpose from one genomic site to another and promote genetic rearrangements. A question that is central to understanding the mechanism of transpositional recombination is whether genetic rearrangements are accompanied by duplication of the IS that promotes them. Analysis of adjacent deletions mediated by IS903 provides the strongest evidence to date than any IS-mediated transpositional recombination can occur by an efficient replicative mechanism.