Opposite effects of tor1 and tor2 on nitrogen starvation responses in fission yeast

The TOR protein kinases exhibit a conserved role in regulating cellular growth and proliferation. In the fission yeast two TOR homologs are present. tor1(+) is required for starvation and stress responses, while tor2(+) is essential. We report here that Tor2 depleted cells show a phenotype very similar to that of wild-type cells starved for nitrogen, including arrest at the G(1) phase of the cell cycle, induction of nitrogen-starvation-specific genes, and entrance into the sexual development pathway. The phenotype of tor2 mutants is in a striking contrast to the failure of tor1 mutants to initiate sexual development or arrest in G(1) under nitrogen starvation conditions. Tsc1 and Tsc2, the genes mutated in the human tuberous sclerosis complex syndrome, negatively regulate the mammalian TOR via inactivation of the GTPase Rheb. We analyzed the genetic relationship between the two TOR genes and the Schizosaccharomyces pombe orthologs of TSC1, TSC2, and Rheb. Our data suggest that like in higher eukaryotes, the Tsc1-2 complex negatively regulates Tor2. In contrast, the Tsc1-2 complex and Tor1 appear to work in parallel, both positively regulating amino acid uptake through the control of expression of amino acid permeases. Additionally, either Tsc1/2 or Tor1 are required for growth on a poor nitrogen source such as proline. Mutants lacking Tsc1 or Tsc2 are highly sensitive to rapamycin under poor nitrogen conditions, suggesting that the function of Tor1 under such conditions is sensitive to rapamycin. We discuss the complex genetic interactions between tor1(+), tor2(+), and tsc1/2(+) and the implications for rapamycin sensitivity in tsc1 or tsc2 mutants.     

Bcl-2 and CCND1/CDK4 expression levels predict the cellular effects of mTOR inhibitors in human ovarian carcinoma

Molecular markers enabling the prediction of sensitivity/resistance to rapamycin may facilitate further clinical development of rapamycin and its derivatives as anticancer agents. In this study, several human ovarian cancer cell lines (IGROV1, OVCAR-3, A2780, SK-OV-3) were evaluated for susceptibility to rapamycin-mediated growth inhibition. The differential expression profiles of genes coding for proteins known to be involved in the mTOR signaling pathway, cell cycle control and apoptosis were studied before and after drug exposure by RT-PCR. In cells exposed to rapamycin, we observed a dose-dependent downregulation of CCND1 (cyclin D1) and CDK4 gene expression and late G1 cell cycle arrest. Among these cell lines, SK-OV-3 cells resistant to both rapamycin and RAD001 were the sole to show the expression of the anti-apoptotic gene Bcl-2. Bcl-2/bclxL-specific antisense oligonucleotides restored the sensitivity of SK-OV-3 cells to apoptosis induction by rapamycin and RAD001. These results indicate that baseline Bcl-2 expression and therapy-induced downexpression of CCND1 and CDK4 may be regarded as molecular markers enabling the prediction and follow-up of the cellular effects on cell cycle and apoptosis induction of rapamycin in ovarian cancer. Furthermore, strategies to down regulate Bcl-2 in ovarian cancer may prove useful in combination with rapamycin or RAD001 for ovarian cancer.     

The Saccharomyces cerevisiae Ptc1 protein phosphatase attenuates G2‐M cell cycle blockage caused by activation of the cell wall integrity pathway

Lack of the yeast Ptc1 Ser/Thr protein phosphatase results in numerous phenotypic defects. A parallel search for high‐copy number suppressors of three of these phenotypes (sensitivity to Calcofluor White, rapamycin and alkaline pH), allowed the isolation of 25 suppressor genes, which could be assigned to three main functional categories: maintenance of cell wall integrity (CWI), vacuolar function and protein sorting, and cell cycle regulation. The characterization of these genetic interactions strengthens the relevant role of Ptc1 in downregulating the Slt2‐mediated CWI pathway. We show that under stress conditions activating the CWI pathway the ptc1 mutant displays hyperphosphorylated Cdc28 kinase and that these cells accumulate with duplicated DNA content, indicative of a G2‐M arrest. Clb2‐associated Cdc28 activity was also reduced in ptc1 cells. These alterations are attenuated by mutation of the MKK1 gene, encoding a MAP kinase kinase upstream Slt2. Therefore, our data show that Ptc1 is required for proper G2‐M cell cycle transition after activation of the CWI pathway.     

Actin-related protein Arp4 functions in kinetochore assembly

The actin-related proteins (Arps) comprise a conserved protein family. Arp4p is found in large multisubunits of the INO80 and SWR1 chromatin remodeling complexes and in the NuA4 histone acetyltransferase complex. Here we show that arp4 (arp4S23A/D159A) temperature-sensitive cells are defective in G2/M phase function. arp4 mutants are sensitive to the microtubule depolymerizing agent benomyl and arrest at G2/M phase at restrictive temperature. Arp4p is associated with centromeric and telomeric regions throughout cell cycle. Ino80p, Esa1p and Swr1p, components of the INO80, NuA4 and SWR1 complexes, respectively, also associate with centromeres. The association of many kinetochore components including Cse4p, a component of the centromere nucleosome, Mtw1p and Ctf3p is partially impaired in arp4 cells, suggesting that the G2/M arrest of arp4 mutant cells is due to a defect in formation of the chromosomal segregation apparatus.     

Cell cycle arrest determines the intensity of the global transcriptional response of Saccharomyces cerevisiae to ionizing radiation

Whole-genome analysis was performed using DNA microarrays to define the changes in the gene expression patterns occurring in Saccharomyces cerevisiae cells exposed to ionizing radiation. The effects of sublethal dose on wild-type, rad53 (enhanced sensitivity to radiation and impaired in a cell cycle damage checkpoint), and rad6 (enhanced sensitivity to radiation and functional cell cycle block by radiation) mutant backgrounds and of a higher dose on the wild-type and G(2)-phase-arrested cells were analyzed. Several gene pathways were identified as being implicated in the response to radiation. In particular, the cell cycle blockage that occurred in the wild-type strain after a high radiation dose and in the rad6 mutant after a lower dose entailed modifications of defined gene expression patterns, which are described here and are compared with the gene modulation patterns observed in the rad53 strain in the absence of efficient blockage. Loss of the RAD53 function caused a major increase in the number of genes modulated by radiation. Given that Rad53-Sad1p, the protein encoded by RAD53, has functions other than those directly connected to cell cycle arrest, we determined the gene patterns that were modulated upon irradiation of rad53 cells that had been forced to arrest in G(2) phase by nocodazole treatment. These differential whole-genome analyses shed light on the multiplicity of functions of the pivotal Rad53-Sad1p protein. The results obtained describe how the cells respond to different irradiation conditions by modulating important gene classes, including those associated with stress defense, ribosomal proteins, histones, ergosterol and GCR1-controlled sugar metabolism.