؉ , but the overhang reappeared following concomitant deletion of pku70 ؉ . Our data suggest that the Rad50 complex can process DSB ends and telomere ends in the presence of the Ku heterodimer. However, the Ku heterodimer inhibits processing of DSB ends and telomere ends by alternative nucleases in the absence of the Rad50-Rad32 protein complex. While we have identified Exo1 as the alternative nuclease targeting DNA break sites, the identity of the nuclease acting on the telomere ends remains elusive.
The target of rapamycin (Tor) plays a pivotal role in cell growth and metabolism. Yeast contains two related proteins, Tor1 and Tor2. In fission yeast, Tor1 is dispensable for normal growth but is involved in amino acid uptake and cell survival under various stress conditions. In contrast, Tor2 is essential for cell proliferation; however, its physiological function remains unknown. Here we characterize the roles of fission yeast Tor2 by creating temperature sensitive ( tor2 ts ) mutants. Remarkably, we have found that tor2 ts mimics nitrogen starvation responses, because the mutant displays a number of phenotypes that are normally induced only on nitrogen deprivation. These include G1 cell-cycle arrest with a small cell size, induction of autophagy and commitment to sexual differentiation. By contrast, tor1∆ ∆ ∆ ∆ tor2 ts double mutant cells show distinct phenotypes, as the cells cease division with normal cell size in the absence of G1 arrest. Tor2 physically interacts with the conserved Rhb1/GTPase. Intriguingly, over-expression of rhb1 + or deletion of Rhb1-GAPencoding tsc2 + is capable of rescuing stress-sensitive phenotypes of the tor1 mutant, implying that Tor1 and Tor2 also share functions in cell survival under adverse environment. We propose that Tor1 and Tor2 are involved in both corroborative and independent roles in nutrient sensing and stress response pathways.
It has been suggested that the Schizosaccharomyces pombe Rad50 (Rad50-Rad32-Nbs1) complex is required for the resection of the C-rich strand at telomere ends in taz1-d cells. However, the nuclease-deficient Rad32-D25A mutant can still resect the C-rich strand, suggesting the existence of a nuclease that resects the C-rich strand. Here, we demonstrate that a taz1-d dna2-2C double mutant lost the G-rich overhang at a semipermissive temperature. The amount of G-rich overhang in S phase in the dna2-C2 mutant was lower than that in wild-type cells at the semipermissive temperature. Dna2 bound to telomere DNA in a chromatin immunoprecipitation assay. Moreover, telomere length decreased with each generation after shift of the dna2-2C mutant to the semipermissive temperature. These results suggest that Dna2 is involved in the generation of G-rich overhangs in both wild-type cells and taz1-d cells. The dna2-C2 mutant was not gamma ray sensitive at the semipermissive temperature, suggesting that the ability to process double-strand break (DSB) ends was not affected in the dna2-C2 mutant. Our results reveal that DSB ends and telomere ends are processed by different mechanisms.
The protein kinase TOR (target of rapamycin) controls several steps of ribosome biogenesis, including gene expression of rRNA and ribosomal proteins, and processing of the 35S rRNA precursor, in the budding yeast Saccharomyces cerevisiae. Here we show that TOR also regulates late stages of ribosome maturation in the nucleoplasm via the nuclear GTP‐binding protein Nog1. Nog1 formed a complex that included 60S ribosomal proteins and pre‐ribosomal proteins Nop7 and Rlp24. The Nog1 complex shuttled between the nucleolus and the nucleoplasm for ribosome biogenesis, but it was tethered to the nucleolus by both nutrient depletion and TOR inactivation, causing cessation of the late stages of ribosome biogenesis. Furthermore, after this, Nog1 and Nop7 proteins were lost, leading to complete cessation of ribosome maturation. Thus, the Nog1 complex is a critical regulator of ribosome biogenesis mediated by TOR. This is the first description of a physiological regulation of nucleolus‐to‐nucleoplasm translocation of pre‐ribosome complexes.
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