Inhibition of DNA replication in Saccharomyces cerevisiae by araCMP

Candida albicans Dbf4-dependent Cdc7 kinase plays a novel role in the inhibition of hyphal development

Candida albicans is an opportunistic human fungal pathogen. The ability to switch among multiple cellular forms is key to its pathogenesis. The Dbf4-dependent protein kinase gene CDC7 is conserved due to its role in initiating DNA replication. Because a C. albicans Cdc7 (Cacdc7) homozygous null was not viable, we generated a C. albicans strain with a deleted C. albicans CDC7 (CaCDC7) allele and an expression-repressible allele. Surprisingly, cells of the strain grew as hyphae under the repressed conditions. The in vitro kinase assays confirmed that CaCdc7 (K232) and CaCdc7 (T437) are critical for catalytic and phosphoacceptor of activation activity, respectively. C. albicans cells formed hyphae when expressing either the catalytically inactive CaCdc7 (K232R) or the phosphoacceptor-deficient CaCdc7 (T437A). While CaCdc7 interacted with CaDbf4, cells of the strain in which CaCDC7 was repressed were not rescued by constitutively expressing C. albicans DBF4 or vice versa. We conclude that CaDBF4-dependent CaCDC7 is an essential gene suppressing the hyphal development.

Induction of S. cerevisiae filamentous differentiation by slowed DNA synthesis involves Mec1, Rad53 and Swe1 checkpoint proteins

A key question in eukaryotic differentiation is whether there are common regulators or biochemical events that are required for diverse types of differentiation or whether there is a core mechanism for differentiation. The unicellular model organism Saccharomyces cerevisiae undergoes filamentous differentiation in response to environmental cues. Because conserved cell cycle regulators, the mitotic cyclin-dependent kinase Clb2/Cdc28, and its inhibitor Swe1 were found to be involved in both nitrogen starvation- and short chain alcohol-induced filamentous differentiation, they were identified as components of the core mechanism for filamentous differentiation. We report here that slowed DNA synthesis also induces yeast filamentous differentiation through conserved checkpoint proteins Mec1 and Rad53. Swe1 and Clb2 are also involved in this form of differentiation, and the core status of Swe1/Clb2/Cdc28 in the mechanism of filamentous differentiation has therefore been confirmed. Because the cAMP and filamentous growth mitogen-activated protein kinase pathways that mediate nitrogen starvation-induced filamentous differentiation are not required for slowed DNA synthesis-induced filamentous growth, they can therefore be excluded from the core mechanism. More significantly, slowed DNA synthesis also induces differentiation in mammalian cancer cells, and such stimulus conservation may indicate that the core mechanism for yeast filamentous differentiation is conserved in mammalian differentiation.

A novel mechanism-based mammalian cell assay for the identification of SH2-domain-specific protein-protein inhibitors

BACKGROUND

Many intracellular signal-transduction pathways are regulated by specific protein-protein interactions. These interactions are mediated by structural domains within signaling proteins that modulate a protein's cellular location, stability or activity. For example, Src-homology 2 (SH2) domains mediate protein-protein interactions through short contiguous amino acid motifs containing phosphotyrosine. As SH2 domains have been recognized as key regulatory molecules in a variety of cellular processes, they have become attractive drug targets.

RESULTS

We have developed a novel mechanism-based cellular assay to monitor specific SH2-domain-dependent protein-protein interactions. The assay is based on a two-hybrid system adapted to function in mammalian cells where the SH2 domain ligand is phosphorylated, and binding to a specific SH2 domain can be induced and easily monitored. As examples, we have generated a series of mammalian cell lines that can be used to monitor SH2-domain-dependent activity of the signaling proteins ZAP-70 and Src. We are utilizing these cell lines to screen for immunosuppressive and anti-osteoclastic compounds, respectively, and demonstrate here the utility of this system for the identification of small-molecule, cell-permeant SH2 domain inhibitors.

CONCLUSIONS

A mechanism-based mammalian cell assay has been developed to identify inhibitors of SH2-domain-dependent protein-protein interactions. Mechanism-based assays similar to that described here might have general use as screens for cell-permeant, nontoxic inhibitors of protein-protein interactions.

Effects of a novel DNA-damaging agent on the budding yeast Saccharomyces cerevisiae cell cycle

We have investigated the effects on Saccharomyces cerevisiae of a novel antitumour agent (FCE24517 or Tallimustine) which causes selective alkylations to adenines in the minor groove of DNA. Tallimustine, added to wild-type cells for short periods, reduced the growth rate and increased the percentage of budded cells and delayed the cell cycle in the late S + G2 + M phases. In the rad9 delta null mutant cells, Tallimustine treatment did not affect growth rate and the percentage of budded cells but greatly reduced cell viability compared to isogenic cells. Consistent with a role of RAD9 in inducing a transient delay in G2 phase which preserves cell viability, the potent cytotoxic effect of the drug on rad9 delta cells was alleviated by treatment with nocodazole. Tallimustine was also found to delay the resumption from G1 arrest of wild-type but not of rad9 delta cells. These data indicate that the effects of Tallimustine on cell cycle progression in yeast are mediated by the RAD9 gene product. From our data it appears that yeast could be a valuable model system to study the mode of action of this alkylating drug and of minor groove alkylators in general.

Deoxyribonucleoside triphosphate pools in mutagen sensitive mutants of Neurospora crassa

Deoxyribonucleoside triphosphate (dNTP) levels were measured in wild type Neurospora and nine mutagen-sensitive mutants, at nine different genes. Eight of these mutants are sensitive to hydroxyurea and histidine and show chromosomal instability, a phenotype which could result from altered levels of dNTPs. Two patterns were seen. Five of the mutants had altered ratios of dNTPs, with relatively high levels of dATP and dGTP and low levels of dCTP, but changes in the dTTP/dCTP ratio did not correlate with changes in spontaneous mutation levels. During exponential growth all but two of the mutants had small but consistent increases in dNTP pools compared to wild type. DNA content per microgram dry hyphae was altered in several mutants but these changes showed no correlation with the dNTP pool alterations.

Enhanced canavanine uptake is associated with nucleotide permeability in a thymidylate auxotroph of Saccharomyces cerevisiae

The recovery of spontaneous canavanine-resistant mutants is reduced dramatically in a strain of Saccharomyces cerevisiae that carries a suppressed can 1-100 allele and is permeable to and auxotrophic for thymidylate. This effect does not occur in an isogenic strain that neither takes up nor requires the nucleotide. However, it is observed for another isogenic strain which is permeable to but not auxotrophic for thymidylate, indicating that the effect is related to thymidylate permeability. Apparently, increased sensitivity of the permeable cells to growth inhibition by canavanine accounts for the diminished mutant recovery. In turn, enhanced uptake of canavanine in these cells seems to be responsible for the increased sensitivity. The experimental findings suggest that the elevated transport of canavanine in the thymidylate auxotroph is unlikely to be due to enhanced suppression of the can 1-100 allele or to activation of the yeast general amino acid permease.

Deoxyribonucleoside triphosphate pools in Neurospora crassa: effects of histidine and hydroxyurea

An effective HPLC method for detecting deoxyribonucleoside triphosphates in hyphae from the fungus Neurospora crassa has been developed. In rapidly growing cells the nucleotide levels vary from 11.8 pmoles/micrograms DNA for dGTP to 24.2 pmoles/micrograms DNA for dTTP. These levels fall by approximately one half in stationary-phase cultures but the ratio of each pool to dGTP remains the same. The dNTP pools in conidia are at least 5-fold lower than in rapidly growing cells. The pool sizes are the same in static and shaking cultures. When the ribonucleotide reductase inhibitor, hydroxyurea (30 mM), is added to rapidly growing cultures, DNA synthesis is stopped and the dGTP pool is reduced by 39%, while the size of the other pools remains the same. In the presence of 11 mM histidine, DNA synthesis is also stopped and the size of the dGTP pool reduced by 46% while the deoxypyrimidine pools are somewhat increased. This suggests that the toxicity of excess histidine in Neurospora may be due to its ability to interact with the ribonucleotide reductase, inactivating the enzyme. Histidine may react with the free radical at the active site, as does hydroxyurea.