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Loss of the TOR Kinase Tor2 Mimics Nitrogen Starvation and Activates the Sexual Development Pathway in Fission Yeast ^,

Tomohiko Matsuo ,^1,, Yoko Otsubo,^1, Jun Urano,² Fuyuhiko Tamanoi,² and Masayuki Yamamoto^1*

Department of Biophysics and Biochemistry, Graduate School of Science, University of Tokyo, Tokyo 113-0033, Japan,¹ Department of Microbiology, Immunology and Molecular Genetics, Jonsson Comprehensive Cancer Center, Molecular Biology Institute, University of California, Los Angeles, California 90095-1489²

Received 12 June 2006/ Returned for modification 24 July 2006/ Accepted 16 January 2007

	ABSTRACT

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Fission yeast has two TOR (target of rapamycin) kinases, namely Tor1 and Tor2. Tor1 is required for survival under stressed conditions, proper G₁ arrest, and sexual development. In contrast, Tor2 is essential for growth. To analyze the functions of Tor2, we constructed two temperature-sensitive tor2 mutants. Interestingly, at the restrictive temperature, these mutants mimicked nitrogen starvation by arresting the cell cycle in G₁ phase and initiating sexual development. Microarray analysis indicated that expression of nitrogen starvation-responsive genes was induced extensively when Tor2 function was suppressed, suggesting that Tor2 normally mediates a signal from the nitrogen source. As with mammalian and budding yeast TOR, we find that fission yeast TOR also forms multiprotein complexes analogous to TORC1 and TORC2. The raptor homologue, Mip1, likely forms a complex predominantly with Tor2, producing TORC1. The rictor/Avo3 homologue, Ste20, and the Avo1 homologue, Sin1, appear to form TORC2 mainly with Tor1 but may also bind Tor2. The Lst8 homologue, Wat1, binds to both Tor1 and Tor2. Our analysis shows, with respect to promotion of G₁ arrest and sexual development, that the loss of Tor1 (TORC2) and the loss of Tor2 (TORC1) exhibit opposite effects. This highlights an intriguing functional relationship among TOR kinase complexes in the fission yeast Schizosaccharomyces pombe.

	INTRODUCTION

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TOR (target of rapamycin) is a serine/threonine kinase of the phosphatidylinositol kinase-related kinase family, which is structurally and functionally conserved from yeast to mammals. Members of this family include ATM, ATR, and DNA-dependent protein kinase. They share conserved structural motifs such as an extended region of HEAT repeats as well as FAT and FATC domains (1). In mammalian cells, mTOR is a critical player in the tuberous sclerosis complex (TSC)/Rheb/mTOR signaling pathway that regulates protein synthesis in response to growth factors and nutrient and energy conditions. The regulation of protein synthesis is mediated by the phosphorylation of S6K, a kinase responsible for the phosphorylation of the ribosomal protein S6. In addition, mTOR phosphorylates 4EBP1, an inhibitor of protein synthesis (reviewed in references 39 and 54). TOR is activated by Rheb, a unique family of the Ras superfamily GTPase (2, 20, 41). Rheb is negatively regulated by the TSC1/TSC2 complex that acts as a GTPase activating protein for Rheb. Mutations in the TSC1 or TSC2 gene cause tuberous sclerosis, a genetic disorder associated with the appearance of benign tumors in various organs (reviewed in reference 22).

Fission yeast Schizosaccharomyces pombe has recently emerged as an ideal system to investigate the function of TOR. Homologues of TSC, Rheb, and TOR have been identified in fission yeast. Like the mammalian system, fission yeast TSC proteins (Tsc1 and Tsc2) form a complex that acts to downregulate Rheb (Rhb1) (24, 45). This contrasts with budding yeast that does not have TSC genes. Fission yeast has two TOR genes, namely tor1 and tor2 (15, 48). Fission yeast tor1 is not essential; however, tor1 cells are unable to properly arrest in G₁ in response to nutrient starvation, to initiate sexual differentiation, and to survive under stressed conditions (15, 50). These functions are mediated, at least in part, by Gad8, an AGC family protein kinase that functions downstream of Tor1 (25). Unlike tor1, tor2 is essential for growth. However, it remains unknown how tor2 supports cell growth. We have recently shown that Rhb1 interacts with Tor2 in a GTP-dependent manner and activates it (44). rhb1 encoding Rhb1 is also an essential gene, and its inhibition leads to small, round G₀/G₁ phase cells (21, 55). To further dissect the function of fission yeast Tor2, we constructed temperature-sensitive tor2 mutants. These mutants arrested in G₁ phase and unexpectedly initiated sexual differentiation when shifted to the restrictive temperature. Our results on Tor2 suggest that this TOR protein has functions that are distinct from those of Tor1.

Recent studies in mammalian cells and in budding yeast revealed that TOR proteins exist as multiprotein complexes. In mammalian cells, TOR has been shown to form two types of multiprotein complex called TORC1 and TORC2 (19, 34). TORC1 contains raptor and is sensitive to rapamycin, an inhibitor of TOR kinase. This complex mediates effects on protein synthesis and cell growth. On the other hand, TORC2, which contains rictor, mediates regulation to Akt and also affects actin cytoskeleton (14, 35). Budding yeast has two TOR genes encoding Tor1 and Tor2. Either Tor1 or Tor2 can form TORC1 together with Lst8, Tco89, and the raptor orthologue Kog1, indicating that the two Saccharomyces cerevisiae TOR proteins can perform a redundant function. In addition, Tor2, but not Tor1, constitutes TORC2 with Lst8, Avo1, Avo2, Bit61, and the rictor orthologue Avo3, which regulates a different range of downstream targets from TORC1. Inhibition of budding yeast TORC1, either by mutation or by rapamycin, causes cell cycle arrest at G₁ phase, whereas TORC2 appears to carry out an essential function for cellular polarization and cytoskeletal reorganization (54).

In this study we also investigated the composition of fission yeast TOR complexes. We have previously identified the raptor homologue Mip1 (40). In addition, the rictor/Avo3 homologue Ste20 (11), the Lst8 homologue Wat1/Pop3 (16), and the Avo1 homologue Sin1 (52) have been identified in fission yeast. We examined association of these proteins with TOR proteins and found that Tor1 and Tor2 have distinct binding partners.

	MATERIALS AND METHODS

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General methods and strains. Table 1 summarizes S. pombe strains used in this study. General genetic procedures for S. pombe were described previously (9, 26). Transformation of S. pombe was done by a lithium acetate method (32). To generate a temperature-sensitive allele of tor2, we introduced random mutations into the tor2 open reading frame carried on a plasmid by a PCR method (56). Cells of JV530 (h⁹⁰ tor2::kan^r harboring pREP42-tor2) were transformed with linear DNA fragments carrying mutagenized tor2 alleles. Integrants of a functional tor2 allele at the correct locus were screened at 26.5°C by monitoring their resistance to fluoroorotic acid (indicating loss of ura4⁺-based pREP42-tor2) and sensitivity to G418 (indicating loss of kan^r). Temperature-sensitive mutants were selected from these integrants by replica plating. To carry out tor2 shutoff experiments, we replaced the authentic tor2 promoter with the nmt81 promoter. When necessary, rapamycin was added to liquid and agar medium to a final concentration of 0.1 µg/ml (51). An equal volume of a drug vehicle solution (1:1 dimethyl sulfoxide-methanol) was added to the controls.

Immunoprecipitation. JT176 (mip1-HA), JT164 (ste20-HA), JT294 (wat1-myc), and JT295 (sin1-myc) were transformed with either pREP41-His6Flag2-tor2 or pREP41-His6Flag2-tor1. Cells grown in minimal medium (MM) at 30°C to the concentration of 4 x 10⁶ cells/ml were harvested and disrupted with glass beads in buffer B (50 mM Tris-HCl [pH 7.6], 150 mM KCl, 5 mM EDTA, 1 mM dithiothreitol, 10% glycerol, 0.2% NP-40, 20 mM ß-glycerophosphate, 0.1 mM Na₃VO₄, 15 mM para-nitrophenyl phosphate, 1 mM phenylmethylsulfonyl fluoride, and protease inhibitor cocktail [Complete Mini EDTA-free; Roche]). Lysates were centrifuged, and 1/10 of each supernatant was saved as "total," and the rest was subjected to immunoprecipitation. A mixture of 5 µl of anti-FLAG M2 monoclonal antibody (Sigma) and 25 µl of Dynabeads protein G (Dynal) was added to each sample, which was then incubated at 4°C for 30 min. After being washed three times with buffer B without protease inhibitors, precipitates were run in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Mouse anti-hemagglutinin (anti-HA) antibody 12CA5 (Sigma) or mouse anti-myc antibody 9E10 (Santa Cruz) was used to detect Mip1-HA, Ste20-HA, Wat1-myc, and Sin1-myc.

	RESULTS

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Isolation of tor2-ts mutants. To investigate the function of Tor2, we randomly introduced mutations into the open reading frame of the chromosomal tor2 gene using PCR-based mutagenesis as described in Materials and Methods. We then screened for strains that could grow at 25°C but not at 37°C. Altogether, 15 clones that satisfied this criterion were isolated. Two of them, named tor2-ts6 and tor2-ts10, showed elevated temperature sensitivity, growing poorly even at 30°C (Fig. 1A). To confirm that the temperature-sensitive growth of these strains was due to mutations in the tor2 gene, we transformed them with a plasmid carrying tor2. The transformants recovered growth at the restrictive temperature (see Fig. 5C), suggesting that they were indeed defective in tor2. Subsequent cloning analysis confirmed that mutations were indeed introduced into the tor2 gene in these temperature-sensitive strains (see below).

View larger version (41K): [in this window] [in a new window]   FIG. 1. Loss of tor2 function causes G1 arrest. (A) Temperature-sensitive growth of the tor2-ts strains. Cells of JY878 (wt), JT177 (tor2-ts6), and JT178 (tor2-ts10) were streaked on nutrient medium YE and incubated either at 25°C or 30°C for 3 days. (B) Cells of JY476 (wt), JV302 (tor2-ts6), and JV305 (tor2-ts10) were cultured in liquid YE medium at 25°C to exponential phase and shifted to 30°C at a concentration of about 1 x 106 cells/ml. Aliquots were taken at indicated time points, and the cellular DNA content of each sample was measured by FACS analysis. (C) Cells of JV981, in which tor2 is driven by the nmt81 promoter, were grown in liquid MM medium to exponential phase (2 x 106 cells/ml), and thiamine was added to a half of the culture to a concentration of 2 µM to shut off the transcription from the nmt81 promoter. Aliquots were taken at indicated time points, and the cellular DNA content of each sample with (+) or without (–) thiamine was measured by FACS analysis.

View larger version (38K): [in this window] [in a new window]   FIG. 5. Interaction of the temperature-sensitive Tor2 proteins with Mip1. (A) Physical interaction of Tor2-ts6 with Mip1, examined by IP as described in the legend of Fig. 4A. (B) Physical interaction of Tor2-ts10 with Mip1, examined by IP as described in the legend of Fig. 4A. Only samples prepared from cells grown at the permissive temperature 25°C are shown. (C) Genetic interaction: suppression of tor2-ts6 by overexpression of mip1. JV304 (tor2-ts6) and JV306 (tor2-ts10) were transformed with vector pREP41, pREP41-tor2, and pREP41-mip1. Transformants of JV304 were incubated on MM at 32°C for 9 days, whereas transformants of JV306 were incubated on MM at 28°C for 8 days.

To confirm that the arrest in G₁ observed in tor2-ts mutants was due to loss of the Tor2 activity rather than acquisition of an abnormal activity, we constructed a system in which production of Tor2 could be shut off artificially by the use of the thiamine-repressible promoter nmt81. When expression of tor2 from the nmt81 promoter was blocked in heterothallic JV981 cells by the addition of thiamine to the medium, the cells gradually arrested in G₁, like tor2-ts cells, indicating that loss of tor2 function causes G₁ arrest in the cell cycle (Fig. 1C).

To our surprise, microscopic observation of homothallic tor2-ts cells incubated at the restrictive temperature for 24 h revealed that they contained zygotes and asci (Fig. 2A). This was a unique cell cycle mutant phenotype, which to our knowledge has never been described in fission yeast. Both temperature-sensitive mutants exhibited increased mating efficiency at the restrictive temperature of 30°C (Fig. 2B). The tor2-ts10 mutant showed a higher mating frequency than the tor2-ts6 mutant. However, the former grew slightly more slowly than the latter at the permissive temperature 25°C (Fig. 1A), implying that Tor2-ts10 is more labile than Tor2-ts6 and may already be partially inactive at the permissive temperature (see below). Sporulation was observed in homothallic (Fig. 2A) but not in heterothallic (Fig. 2C) tor2-ts cells subjected to the temperature shift, suggesting that the tor2 deficiency does not provoke haploid meiosis such as that induced by the pat1-ts mutation (13, 30). However, heterothallic tor2-ts cells became smaller at the restrictive temperature, suggesting that they might have entered a state of quiescence (Fig. 2C). We integrated the tor2 shutoff system into a homothallic strain (JT300). This strain grew very poorly even in the absence of thiamine, and microscopic observation indicated that about half of the cells had initiated mating and sporulation in growth medium (Fig. 2D). This is probably because the nmt81 promoter used to drive tor2 in this strain was not strong enough under the derepressed conditions. When thiamine was added, the cells stopped growing completely and generated many asci, confirming that loss of Tor2 function provokes sexual development.

View larger version (71K): [in this window] [in a new window]   FIG. 2. Sexual development of tor2-ts cells grown at the restrictive temperature. (A) The three homothallic haploid strains analyzed in the experiment shown in Fig. 1B were examined microscopically after 24 h of incubation at the restrictive temperature. Bar, 10 µm. (B) Calculated mating efficiency of the three strains shown in panel A. (C) Cells of heterothallic haploid strains incubated at the restrictive temperature for 24 h. wt, JY333; tor2-ts6, JV304; and tor2-ts10, JV306. Bar, 10 µm. (D) Cells of a homothallic strain JT300, in which tor2 is driven by the nmt81 promoter, were grown vegetatively on MM plates (– thiamine). They have undergone mating and sporulation even before shutoff of the promoter. Bar, 10 µm. (E) Expression of starvation-responsive genes in tor2-ts cells. Expression of three nitrogen starvation-responsive genes (ste11, isp6, and fnx1), and one glucose starvation-responsive gene (fbp1) was measured in wt (JY333), tor2-ts6 (JV304), and tor2-ts10 (JV306) cells at time zero and 3.5 and 7 h after the shift to the restrictive temperature. Their expression in pka1-defective cells (JX384) was also examined. rRNA stained with ethidium bromide is shown as a loading control.

Nitrogen starvation-responsive genes are largely controlled by tor2. To determine alterations in global gene expression profile due to the inhibition of Tor2, we performed microarray analysis of the tor2-ts6 mutant after shifting the cultures to 34°C for 0, 1, 3, and 8 h. A similar time course was performed with a wt strain to control for gene expression changes that may occur due to the temperature shift. RNA preparation was converted to cDNA and was used to hybridize against an oligonucleotide array of S. pombe genome. The data were analyzed using dChip. Genes showing a variation (standard deviation/mean) of greater than 0.5 were filtered and clustered.

Figure 3 shows hierarchical clustering analysis of the filtered genes to identify gene clusters. We looked for a set of genes whose expression is specifically altered in response to loss of tor2 function. A total of 194 genes are identified to be induced specifically (Fig. 3, cluster induced by loss of tor2). It is interesting that almost all the genes with altered expression show increased expression by the loss of tor2 function. This may suggest that fission yeast Tor2 generally functions to repress expression of genes.

View larger version (20K): [in this window] [in a new window]   FIG. 3. Microarray analysis of loss of tor2 activity. Global expression profiles from tor2+ (JY450) or tor2-ts6 (JV303) incubated for the indicated times at 34°C were assessed using the GeneChip Yeast Genome 2.0 Array. The raw data were normalized and modeled using dChip. Genes showing a variation (standard deviation/mean) of >0.5 were clustered. The cluster of genes that are induced by loss of tor2 is indicated. Red indicates induction, and green indicates suppression relative to expression of the gene in tor2+ cells at 0 h.

Induction of permease and transporter genes by the loss of tor2. Another group of genes we found to be induced by the loss of tor2 function can be classified as permeases and transporters (Table 3). We find known as well as predicted permeases and transporters for amino acids and other nutrients such as purine and thiamine. We have previously shown that Rhb1 regulates uptake of amino acids and that Rhb1 directly interacts with Tor2 (44). Thus, part of the Rhb1 effects may involve alteration of expression of amino acid permeases. Alteration of expression of genes encoding amino acid permeases has also been observed in tsc mutants (45, 27). In fact, we find a number of transporters and permeases (isp5, SPAC869.10c, SPAC11D3.18c, SPAC1039.01, mam1, and SPBPB2B2.01) in our cluster whose expression levels are also altered by the loss of tsc function.

View larger version (47K): [in this window] [in a new window]   FIG. 4. Physical interaction of TOR kinases with raptor Mip1, rictor Ste20, and two other TORC members. (A) IP assay to detect interaction of Mip1 with Tor1 or Tor2. Detailed procedures are given in Materials and Methods. (B) IP assay to detect interaction of Ste20 with Tor1 or Tor2. (C) IP assay to detect interaction of Wat1 with Tor1 or Tor2. (D) IP assay to detect interaction of Sin1 with Tor1 or Tor2. (E) A summary of known components of TORC1 and TORC2 in three kinds of organisms. , anti.

Further characterization of the tor2-ts mutants. We set out to identify the mutated amino acid residue responsible for the temperature sensitivity in the tor2-ts6 and tor2-ts10 alleles. DNA sequencing revealed that each allele carries as many as four substituted residues. Subsequent analysis indicated that two mutations in the HEAT domain, S550P and K711M, either of which confers only weak temperature sensitivity, are together responsible for tor2-ts6. In the case of tor2-ts10, the temperature sensitivity stems from the combination of A1399E in the FAT domain and F2198L in the kinase domain, neither of which alone confers temperature sensitivity. The latter observation appears intriguing, as we have seen that tor2-activating mutations cluster in either the FAT domain or the kinase domain (J. Urano et al., unpublished results).

To examine the nature of the defects in Tor2-ts proteins, we tested their ability to bind to Mip1 by coimmunoprecipitation as before. Compared to wt Tor2, Tor2-ts6 bound Mip1 poorly, even at the permissive temperature, suggesting that the affinity for Mip1 is affected in this mutant protein (Fig. 5A). The affinity was further lowered after a 4-h incubation at the restrictive temperature. Tor2-ts10 also appeared to have little affinity for Mip1, but more striking was its scarcity in the cell, even at the permissive temperature (Fig. 5B). We suspect that Tor2-ts10 may be nonfunctional because it is labile and degrades readily.

Genetic interaction between TOR kinase and its associated proteins. In addition to physical interaction, we found genetic interaction between mip1 and tor2. The tor2-ts6 mutation was suppressed partially by overexpression of wt mip1 at 32°C (Fig. 5C). The tor2-ts10 mutation was not suppressed by overexpression of mip1. This is consistent with the idea that Tor2-ts6 is stable but lowered in its affinity for Mip1, whereas Tor2-ts10 is unstable and readily destroyed. Interestingly, it seems that mip1 overexpression rather enhances the temperature sensitivity of tor2-ts10 (Fig. 5C) (see Discussion).

The above observations showing that Tor2 and Mip1 cooperate intimately in function reinforce the finding that they constitute the fission yeast TORC1. Also, as Tor1 and Ste20 are both members of the fission yeast TORC2, it is likely that they function together. However, this point has not been shown. Thus, we compared phenotypes of the two mutant strains. Results are summarized in Fig. 6. Both tor1 and ste20 cells exhibited an elongated morphology (Fig. 6A), and their growth was sensitive to high osmotic pressure (Fig. 6B) and high temperature (data not shown) just like gad8 cells. Importantly, ste20 could be partially suppressed by an activated form of gad8 (gad8-S527D/S546D) (Fig. 6C), as was the case with tor1 (25). Thus, it is highly likely that Tor1 and Ste20 cooperate in the same biological process.

View larger version (53K): [in this window] [in a new window]   FIG. 6. Comparison of phenotypes between tor1 and ste20. (A) Comparison of cell morphology. Cells of each homothallic haploid strain were grown on YE medium at 30°C for 4 days. (B) Osmo-sensitive growth was examined on YE medium containing 1 M KCl. Incubation was done at 30°C for 4 days. wt, JY450; tor1, JW950; ste20, JT293; and gad8, JW944. (C) Suppression of tor1 (JW950) and ste20 (JT293) by gad8-S527D/S546D. The wt and mutant gad8 alleles were expressed from plasmid pR3C (25). Growth on MM containing 0.6 M KCl at 30°C was followed for 4 days. (D) Examination of mutual suppression between tor1 and tor2-ts. The double mutants and control strains were tested for growth at 32°C. (E) Suppression of the growth defect of ade6-M216 tsc2 under low adenine supply by tor2-ts mutations. Indicated strains were grown on Edinburgh minimal medium plates supplemented with either 1 mg/ml or 0.25 mg/ml of adenine.

We also tested whether Rhb1, an activator of Tor2 (44), could be a suppressor of tor2-ts6 and tor2-ts10. However, an activated rhb1 allele, rhb1-N153T (44), did not suppress temperature sensitivity of the two mutants (data not shown). Deletion of tsc2, which codes for a negative regulator of Rhb1, also did not significantly affect the temperature sensitivity of tor2-ts6 and tor2-ts10 (data not shown). In contrast, we found that the poor growth of the tsc2 ade6 mutant on medium containing a low concentration of adenine (24) could be suppressed by either tor2-ts6 or tor2-ts10 (Fig. 6E). Whereas the tsc2::kanMX ade6-M216 strains grew poorly on minimal Edinburgh minimal medium plates containing 0.25 mg/ml adenine, the tsc2::kanMX ade6-M216 tor2-ts triple mutants showed healthy growth almost wt levels at 25°C. These results reinforce the idea that Tsc2 and Rhb1 function upstream of Tor2.

In S. cerevisiae, TORC2, which contains Tor2, is involved in actin organization (38). To see whether putative fission yeast TORC1 or TORC2 was to play a similar role, we stained F-actin with BODIPY FL phallacidin in tor1 cells at 30°C and in tor2-ts6 and tor2-ts10 cells at the permissive (25°C) and restrictive (30°C) temperatures. Consequently no significant disorganization of actin was observed, except that actin cables in tor1 cells might be slightly thicker than ones in the wt (data not shown). We therefore suppose that fission yeast TOR may not be directly relevant to actin organization.

	DISCUSSION

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Tor2 function in nitrogen signaling. In this study, we have presented evidence that Tor2 plays critical roles in the nitrogen signaling pathway. Inhibition of Tor2 function leads to the accumulation of G₀/G₁ phase cells. These accumulated cells are small and round. In addition, expression of the ste11, isp6, and fnx1 genes is induced upon the loss of Tor2 function. Microarray analysis further provided strong evidence for the idea that Tor2 functions in the nitrogen signaling pathway, as genes induced by the loss of Tor2 function overlap significantly with the genes induced by nitrogen starvation. It is interesting to point out that these phenotypes of tor2 loss of function strongly resemble those that are observed by the loss of rhb1 function. Both genes are essential, and their inhibition leads to small, round G₀/G₁ cells (21, 55). Inhibition of rhb1 also causes induction of ste11, mei2, and fnx1 genes (21, 43). These results support the idea that Rhb1 and Tor2 function in the same manner to stimulate cell growth and cell cycle progression. This is in line with our recent observation that Rhb1 interacts directly with the Tor2 complex (44). We have shown that adenine uptake in the tsc2 strain can be rescued by either the tor2-ts6 or the tor2-ts10 mutation; this result further supports the idea that fission yeast possesses the TSC-Rheb-TOR pathway similar to mammalian cells.

Our microarray analysis revealed global negative regulation of the expression of a number of permease and transporter genes by Tor2. These genes include amino acid permeases, purine permeases, and thiamine transporter. Transcriptional regulation of permease genes has also been reported from the analyses of tsc mutants (27, 45). In these cases, expression of these genes is suppressed. Regulation of permeases may be a response to starved conditions. Indeed, a large number of permeases and transporters are shown to be upregulated upon nitrogen starvation (23).

We have compared the cluster of genes upregulated in the tor2-ts6 mutant with genes whose expression is altered in the tsc1 and tsc2 mutants (27, 45). Four genes in our cluster (SPCC1223.09, isp5, isp4, and SPAC869.10c) are found among 14 genes reported to be downregulated in both tsc1 and tsc2 (45). Six genes (SPAC1039.01, SPAC11D3.03c, mei2, gpa1, SPBC1683.02, and SPBPB2B2.01) are found among 31 genes whose expression is not induced in response to nitrogen starvation in tsc1 and tsc2 (27). Although there are clear overlaps, they may not be as extensive as one might expect. The reason for this limited overlapping is uncertain. It may reflect differences in experimental parameters such as resolution or setting of the thresholds or indicate that growing tsc1 and tsc2 cells have undergone certain physiological adaptation. Alternatively, it may indicate that Tsc2 is not the only regulator for the Tor2 pathway, as might be presumed from the observation that tsc2 cells are still able to arrest in G₁ and mate (24), even though they show a delay in nitrogen starvation responses. It is also possible that there are Tor-independent functions for Tsc2. Further analyses are necessary to fully understand the regulation of TOR by Tsc2 in fission yeast.

The initiation of sexual development in fission yeast depends largely on nutrient conditions, as in many other microorganisms. Our results suggest that Tor2 negatively regulates sexual development, as the inhibition of Tor2 leads to increased meiosis. Previous studies have shown that both nitrogen and glucose are important for sexual development; although depletion of nitrogen is crucial for sexual development, depletion of glucose is not. However, reduction of glucose facilitates sexual development, and a high concentration of glucose suppresses it. Our study has shown clearly that the function of Tor2 is related to the recognition of a nitrogen source but not a carbon source and is likely to be independent of the cyclic AMP-protein kinase A pathway. In S. cerevisiae, it has been shown that Tor1 and Tor2 are involved in nitrogen catabolite repression, a regulatory event in which transcription of certain genes is downregulated by a good nitrogen source such as glutamine but upregulated by a poor nitrogen source such as proline (4, 6, 7, 10, 17). Therefore, the involvement of TOR in nitrogen signaling may be a widely conserved phenomenon among various organisms.

In contrast to tor2, tor1 is not an essential gene. However, tor1 mutants exhibit phenotypes that are distinct from those of the tor2 mutants (48, 15). These mutants exhibit deficiency in properly arresting in G₁ in response to nitrogen starvation and in initiating sexual development. This is opposite from our results on Tor2 that show that the inhibition of fission yeast Tor2 promotes G₁ arrest and the initiation of sexual development. This sharp contrast between tor1 and tor2 mutant phenotypes suggests that Tor1 and Tor2 have opposing functions. However, loss of either function cannot be complemented by loss of the other, indicating that the two proteins are likely to be involved in distinct biological processes.

Possible TOR kinase complexes. Our IP analysis showed that the raptor homologue Mip1 is likely to form a complex predominantly with Tor2. This complex, which may correspond to budding yeast TORC1, appears to be necessary to repress nitrogen starvation-responsive genes and to stimulate cell cycle progression at G₁. On the other hand, the rictor/Avo3 homologue Ste20 forms a complex with Tor1, and the ste20 strain is phenotypically quite similar to tor1. This suggests that Tor1 is likely to be the major partner of Ste20, although our analysis has suggested that Tor2 may also form a complex with Ste20. It is currently unclear whether this complex is physiologically significant or simply an artifact due to overproduction of Tor2 in our analysis. So far, our trials to detect interaction of Tor1 or Tor2 with their associated proteins under physiological conditions (i.e., with no overexpression) have not given IP bands clear enough to deliver unambiguous conclusions. We tentatively suppose that Tor1 and Ste20, together with the Avo1 homologue Sin1, constitute a complex that corresponds to budding yeast TORC2. This putative fission yeast TORC2 is required for G₁ arrest and sexual development. Thus, with regard to nitrogen response and sexual development, TORC2 appears to have effects opposite from those of TORC1. In addition, TORC2 may control stress response, as the tor1 strain exhibits reduced stress resistance. Our analysis suggests that neither TORC1 nor TORC2 plays a significant role in actin organization in fission yeast. However, as disorganization of actin patches has been reported in the wat1 mutant (16), we cannot exclude the possibility that TORC1 and TORC2 control actin in a redundant fashion. Alternatively, Wat1 may have a TOR-unrelated function in actin organization. It is also currently unexplained why wat1 is not lethal, although Wat1 is apparently a component of both TORC1 and TORC2. Deletion of S. cerevisiae LST8, the homologue of wat1, is lethal (33). These observations altogether may suggest that, although fission yeast, like the budding yeast, has two TOR kinases and two TOR complexes, the functions of each do not necessarily match those of the budding yeast counterpart.

In mammalian cells and budding yeast, TORC1 is sensitive to rapamycin, while TORC2 is relatively insensitive to this drug (36, 54). In fission yeast, however, rapamycin affects some Tor1-dependent functions but generally does not inhibit TOR-related growth functions (47, 49, 51). Our results agree with the idea that Tor2 is insensitive to rapamycin. First, we find that rapamycin does not significantly block growth of wt cells, as initially reported by Weisman (49). In addition, our study revealed that the inhibition of Tor2 leads to induction of sexual development. This is in contrast to the observation that rapamycin blocks sexual development, due to the inhibition of Fkh1 (50). Finally, we have seen that addition of rapamycin does not activate nitrogen starvation-responsive genes (unpublished results).

A conceivable explanation for the lack of effect by rapamycin on wt cells may be that both TORC1 and TORC2 are inhibited, and because they have opposite effects on nitrogen response and sexual development, inhibition of both may cancel out each other. However, this is unlikely to be the case, as tor1 is not able to suppress the temperature sensitivity of the tor2-ts mutants. Taken together, it appears that TORC1 in fission yeast is insensitive to rapamycin.

Two alleles of tor2 temperature-sensitive mutants. Our characterization of the tor2 temperature-sensitive mutants has indicated that tor2-ts6 and tor2-ts10 represent two different mutant alleles, the former of which may be impaired in the interaction with Mip1, whereas the latter may generate a labile gene product. Interestingly, they behaved quite differently when suppression of the temperature-sensitive growth by mip1N (Mip1 lacking the N-terminal region) was examined. Mip1N is defective in function but can act in a dominant fashion to inhibit meiosis (40). Overexpression of mip1N (mip1-15) suppressed temperature sensitivity of tor2-ts10 but not tor2-ts6 (unpublished results). As described above, overexpression of wt mip1 suppressed temperature sensitivity of tor2-ts6 but enhanced temperature sensitivity of tor2-ts10. Further characterization of these two tor2 temperature-sensitive alleles and the mip1N mutation may provide insight into how TORC1 regulates growth and meiosis in fission yeast.

	ADDENDUM

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While we were revising this article, two papers containing data that partially overlap with ours were published (1a, 44a).

	ACKNOWLEDGMENTS

 
We thank Kayoko Tanaka and Akira Yamashita for helpful discussion. Microarray analysis was carried out in the UCLA/JCCC DNA microarray core.

This work was supported by a Grant-in-Aid for Specially Promoted Research from the Ministry of Education, Culture, Sports, Science, and Technology of Japan to Y.M. and by NIH grant CA41996 and NSF grant CCF-0326605 to F.T.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Biophysics and Biochemistry, Graduate School of Science, University of Tokyo, Tokyo 113-0033, Japan. Phone: 81 3 5841 4386. Fax: 81 3 5802 2042. E-mail: yamamoto{at}biochem.s.u-tokyo.ac.jp

Published ahead of print on 29 January 2007.

Supplemental material for this article may be found at http://mcb.asm.org/.

T.M. and Y.O. made equal contributions to this work.

Present address: Department of Zoology and Animal Biology and National Center of Competence in Research Frontiers in Genetics, University of Geneva, 30 Quai Ernest Ansermet, 1211 Geneva, Switzerland.

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