Rapamycin Induces the G0 Program of Transcriptional Repression in Yeast by Interfering with the TOR Signaling Pathway

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Mol Cell Biol, August 1998, p. 4463-4470, Vol. 18, No. 8
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Rapamycin Induces the G₀ Program of Transcriptional Repression in Yeast by Interfering with the TOR Signaling Pathway

Dean Zaragoza,¹ Ataollah Ghavidel,¹ Joseph Heitman,² and Michael C. Schultz¹^*

Department of Biochemistry, University of Alberta, Edmonton, Alberta, Canada T6G 2H7,¹ and Departments of Genetics and Pharmacology, Howard Hughes Medical Institute, Duke University Medical Center, Durham, North Carolina 27710²

Received 2 April 1998/Returned for modification 7 May 1998/Accepted 13 May 1998

	ABSTRACT

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The macrolide antibiotic rapamycin inhibits cellular proliferation by interfering with the highly conserved TOR (for targetof rapamycin) signaling pathway. Growth arrest of budding yeastcells treated with rapamycin is followed by the program of molecularevents that characterizes entry into G₀ (stationary phase), includingthe induction of polymerase (Pol) II genes typically expressedonly in G₀. Normally, progression into G₀ is characterized bytranscriptional repression of the Pol I and III genes. Here, weshow that rapamycin treatment also causes the transcriptionalrepression of Pol I and III genes. The down-regulation of PolIII transcription is TOR dependent. While it coincides with translationalrepression by rapamycin, transcriptional repression is due inpart to a translation-independent effect that is evident in extractsfrom a conditional tor2 mutant. Biochemical experiments revealthat RNA Pol III and probably transcription initiation factorTFIIIB are targets of repression by rapamycin. In view of previousevidence that TFIIIB and Pol III are inhibited when protein phosphatase2A (PP2A) function is impaired, and that PP2A is a component ofthe TOR pathway, our results suggest that TOR signaling regulatesPol I and Pol III transcription in response to nutrient growthsignals.

	INTRODUCTION

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Gradual nutrient depletion in Saccharomyces cerevisiae provokes a broad spectrum of morphological and biochemical changesthat result in a terminal cell cycle arrest phenotype called G₀or stationary phase (reviewed in references 44 and 45). Stationary-phasecells have a 1n DNA content, are uniformly large and unbudded,and display a prominent vacuole. The G₀ state is further characterizedby reduced protein synthesis, and the pattern of RNA polymerase(Pol) II transcripts is distinct in cycling and G₀ cells. Thus,more than 95% of Pol II genes are repressed in G₀, and a subsetof Pol II genes whose products promote survival under conditionsof nutrient limitation are massively induced at the transcriptionallevel (8). Induction of the G₀ pattern of Pol II transcriptionin yeast accompanies the repression of transcription of the largerRNA genes by Pol I and the tRNA and 5S rRNA genes by Pol III(9, 26, 33, 36). Since tRNA and rRNA synthesis accountsfor about 70% of nuclear transcription, this regulatory mechanismmay enhance survival in G₀ by limiting the energetically costlyproduction of relatively stable RNA products not immediately requiredfor viability.

While there is striking repression of translation in G₀, some critical aspects of the stationary-phase response are not simplydownstream consequences of a decreased rate of protein synthesis.For example, treatment of cultures with cycloheximide does notcause the accumulation of large unbudded cells or cells with a1n DNA content (6), and in some strains there is no inhibitionof Pol I or Pol III transcription in extracts from cells treatedwith cycloheximide (9). Key physiological steps in the differentiationof a stationary-phase cell are therefore likely to involve signalingmechanisms that act independently of, but in parallel with, effectson translation.

The signaling pathway involved in setting the G₀ pattern of Pol II transcription is the TOR (for target of rapamycin) pathway,which is comprised of the highly conserved TOR kinases (Tor1pand Tor2p), protein phosphatase 2A (PP2A), and the type 2A-relatedphosphatase Sit4p (4, 10). As its name indicates, the TORpathway was originally defined by the sensitivity of the TOR kinasesto the macrolide antibiotic rapamycin, and indeed, rapamycin treatmentof yeast induces many aspects of the normal response to nutrientlimitation, including the induction of G₀-specific Pol II genes(4, 10). The observation that TOR signaling is involved insetting the G₀ pattern of Pol II transcription raises the possibilitythat the repression of Pol I and Pol III transcription in stationaryphase is also under TOR control. This possibility was tested bythe experiments described in the present study. We find that rapamycinrepresses transcription initiation by RNA Pol I and Pol III. Thedown-regulation of Pol III transcription is TOR-dependent, and,although coincident with inhibition of protein synthesis by rapamycin,it includes an effect that is independent of translational repression.

We have explored the biochemical basis of Pol III repression by rapamycin. In all species, the core Pol III transcriptionmachinery consists of RNA Pol III, TFIIIC, a sequence-specificDNA binding factor, and TFIIIB, which is recruited to the promoterby TFIIIC and in turn recruits Pol III (13, 47). Biochemicalexperiments reveal that RNA Pol III and possibly TFIIIB are repressedin extracts from rapamycin-treated cells. The same componentsof the Pol III transcriptional machinery are known to be inhibitedwhen the regulation of PP2A, a component of the TOR pathway, isperturbed by inactivation of its noncatalytic A subunit (10,41). Our results are consistent with the proposal that Pol IIItranscription is regulated according to nutrient availabilityby a signal transduction pathway that includes the TOR kinases.

	MATERIALS AND METHODS

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Strains and extract preparation. Extracts were prepared from S. cerevisiae W303-1A (a ade2-1 trp1-1 can1-100 leu2-3,112 his3-11,15 ura3-1 [38]), JK9-3D $alpha$ ( $alpha$ ura3-52 leu2-3,112 his4 trp1-1 rme1 HMLa [7]), JHY3-3B (JK9-3D $alpha$ fpr1::URA3 [19]), MH346-1a TOR2 ( $Delta$ tor1 $Delta$ tor2/TOR2 [7]), MH346-1ator2-ts4 ( $Delta$ tor1 $Delta$ tor2/tor2-ts4 [7]), and cdc28-1 ( $alpha$ cdc28-1ade1 gal1 lys2 met14 his7 tyr1 [21] [Yeast Genetic Stock Center])after breaking of frozen cells with a motorized mortar grinder(large-scale extracts) or a hand-held coffee mill (34).

Yeast culture. For rapamycin experiments, extracts were prepared from strains W303-1A, JK9-3D $alpha$ , and JHY3-3B. Rapamycin treatment inducedG₀ arrest and transcriptional repression in all FPR1 strain backgrounds,although the repression was more pronounced in extracts from rapamycin-treatedJK9-3D $alpha$ cells than in extracts from treated W303-1A cells (notshown). Cells were cultured in YPD (2% yeast extract-1% BactoPeptone-2% dextrose) at 30°C with vigorous shaking. The mediumwas supplemented at indicated points in the growth cycle withthe drug vehicle (in control cultures) or rapamycin (added froma 2 mM stock solution in 90% ethanol-10% Tween 20). One hour ofrapamycin treatment was performed by adding the drug to a finalconcentration of 10 µg/ml when the cells reached an optical densityat 600 nm (OD₆₀₀) of 1.0. For 24-h treatments, rapamycin was addedto a final concentration of 1 µg/ml when the cells reached anOD₆₀₀ of 0.1. Extracts from 24-h-treated cells were about halfthe protein concentration of control extracts, indicating thatcells are harder to disrupt after rapamycin treatment. This phenotypeis similar to the increased zymolyase resistance of G₀ cells (reviewedin reference 44). Strain cdc28-1 was grown in YPD at 30°C toan OD₆₀₀ of 1.0 and then incubated at 37°C for 4 h and harvested.Strains MH346-1a TOR2 and MH346-1a tor2-ts4 were grown in YPDat 25°C to an OD₆₀₀ of 0.9 and harvested as usual.

Cell viability assay following rapamycin treatment. Strain W303-1A was grown to an OD₆₀₀ of 0.1 and treated with either rapamycin to 1 µg/ml or the drug vehicle for 24 h. TheOD₆₀₀ was taken and aliquots (nominally 100 and 200 cells) ofeach culture were plated on YPD. The plates were incubated at30°C for 3 days, and the number of colonies on each plate wascounted. This assay was performed in triplicate.

Measurement of bulk protein synthesis in vivo. In vivo labeling of total yeast proteins was performed according to the method of Barbet et al. (4) with slight modifications.One-milliliter cultures of JK9-3D $alpha$ were grown to an OD₆₀₀ of 1.0and treated with either 10 µg of rapamycin per ml or the drugvehicle for 1 h at 30°C. The cells were then washed with ice-coldwater and resuspended in 1 ml of synthetic glucose-minus-methioninemedium plus fresh rapamycin or vehicle. Then, 500 µCi of [³⁵S]methionine (NEN) was added, and the cells were labeled withshaking for 20 min at 30°C. After incubation, 120 µl of each culturewas removed and transferred into separate screw-capped tubes containing250 µl of 1 mM NaN₃. Proteins were isolated as described by Werner-Washburneet al. (43), modified as follows. The cells were pelleted andwashed with 250 µl of ice-cold NaN₃ (1 mM) and with 250 µl ofice-cold water. They were then resuspended in 300 µl of breakingbuffer (10 mM Tris-HCl [pH 7.9]-5 mM MgCl₂-50 µg of RNase A perml) with ~0.3 g of glass beads (0.3 to 0.5 mm in diameter) andlysed by vortexing vigorously six times for 30 s each, with a30-s incubation on ice after each vortexing. The mixture was centrifugedand the supernatant was acetone precipitated. The protein precipitatewas resuspended in 50 µl of lysis buffer (9.5 M urea-2% [wt/vol]Nonidet P-40-5% $beta$ -mercaptoethanol) and quantitated by scintillationcounting. To control for the amount of cell breakage, nonradioactivesamples were prepared identically and measured for protein concentrationby the method of Bradford (5). The protein concentrations ofsamples obtained from rapamycin and control cultures were foundto be similar.

In vitro transcription reactions. Multiple-round transcription reactions were performed as described previously (22, 33, 35). The templates for 5S rRNAand tRNA runoff transcription were pY5S (400 ng/20-µl reactionmixture) and pGE2, which contains the tRNA^Leu gene (25ng/20-µl reaction mixture). RNA Pol III reactions wereperformed for 30 min at 30°C with [ $alpha$ -³²P]UTP (3,000 Ci/mmol; NEN). RNA Pol I transcription was assayedwith pBYr11AL, which contains the yeast 35S rDNA promoter (400ng/20-µl reaction mixture). pBYr11AL is identical to pBYr11A (33)except for the insertion of a linker oligonucleotide (XbaI, SalI,BglII, BamHI) between the XbaI and BamHI sites. The specific templatewas added after preincubation of the extracts with 400 ng of HpaII-digestedpBluescript II KS+ for 10 min at room temperature. Reactions werestopped after 45 min at room temperature. Extract amounts arenoted in the figures. The products from pBYr11AL were detectedby S1 nuclease protection analysis using an end-labeled oligonucleotideprobe (33). Pol III reactions with MH346-1a TOR2 and MH346-1ator2-ts4 extracts were performed by incubating the extract withall components except the template and nucleotides at the indicatedtemperature (22 or 37°C) for 5 min. A template-nucleotide mixwas then added, and transcription was performed at the indicatedtemperature for 30 min. In one pair of extracts, the temperature-dependentrepression of Pol III transcription in tor2-ts4 extracts was accentuatedby performing the reactions with fivefold less unlabeled UTP thanusual (10 µM final concentration). Quantitation of specific transcriptionwas performed by phosphorimager analysis (Fujix Bas 1000 bioimaginganalyzer; MacBAS software). Background was subtracted from allsignals.

Purification and assay of Pol III transcription factors. Transcription factors were prepared from large-scale whole-cell extracts of a YPH250 derivative, YDH6 (18), grown to anOD₆₀₀ of 2, and from the protease-deficient strain BJ5626 (25),grown to an OD₆₀₀ of 3. The methods of purification were adoptedfrom Kassavetis et al. (27), as described by Ghavidel and Schultz(15). TFIIIB was purified to the hydroxyapatite step, and TFIIICwas obtained by oligonucleotide affinity chromatography and monitoredfor activity by a standard gel mobility shift assay. After collectionof the 300 mM Pol III-TFIIIC fraction from DEAE-Sepharose, asdescribed previously (15), the resin was eluted with 600 mMKCl to obtain crude RNA Pol III. The specific activities of PolIII in the Pol III-TFIIIC and 600 mM fractions are similar (nonspecificactivity assay, as described below); however, the 600 mM fractionis devoid of TFIIIB and TFIIIC (determined by Western blottingand gel mobility shift assay, respectively). The 600 mM fractionhas no specific initiation activity on its own. The effect ofwild-type transcription factors added to extracts from rapamycin-treatedcells was tested by incubating whole-cell extracts with the indicatedamount of factor for 5 min at room temperature prior to addingthe template and nucleotides. Nonspecific (bulk) RNA Pol III reactionswere performed according to published methods (17, 32) for20 min at 22°C in 25-µl mixtures containing 50 mM Tris-HCl (pH8), 200 mM (NH₄)₂SO₄, 0.6 mM (each) ATP, CTP, and GTP, 0.06 mMUTP, 16 µg of sheared calf thymus DNA per ml, 2 mM MnCl₂, 50 µgof $alpha$ -amanatin per ml, and 1 µl of [5,6-³H]UTP (36.1 Ci/mmol; NEN). Twenty microliters of each reactionwas stopped by spotting onto DE-81 paper and was processed accordingto the method of Roeder (32).

CKII assay. The casein kinase II (CKII) assay was performed essentially as described previously (reference 22, with modifications inreference 15). Reactions were performed in 25-µl volumes with6.25 µg of extract protein under the conditions for Pol I andIII transcription, except that $alpha$ -amanatin was omitted. Each datapoint is the mean result of four reactions.

	RESULTS

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Repression of translation and transcription resulting from treatment of cells with rapamycin. The effects of rapamycin on transcription were tested with extracts from cells treated for 1 or 24 h with the drug. Controlextracts (cells treated only with the rapamycin solvent) wereprepared in parallel from cells harvested at the density recordedfor cultures treated with rapamycin. Extracts were made by a methodthat preserves transcription by RNA Pol I, II, and III (33,35), chromatin assembly (34), and various physiological responsesincluding down-regulation of the Pol I and Pol III transcriptionthat occurs normally when yeast cells enter G₀ (33, 49). Theextracts were assayed in parallel for the capacity to supporttranscription with exogenous tRNA and 5S rRNA genes and a 35SrDNA promoter construct. Pol III transcription was measured bya runoff assay, and Pol I transcripts were detected by S1 nucleaseprotection analysis. In order to establish that rapamycin waseliciting the expected cellular responses, we variously monitoredgross morphology, plating efficiency, and translation for comparisonwith effects that have been extensively documented elsewhere (4,19, 20).

As reported in the literature (4), rapamycin treatment for 1 h inhibited translation in vivo by approximately 80% (Fig.1A) without changing the budding index of the cell populationas a whole (not shown). Extracts from 1-h-treated cells were two-to fourfold less active for Pol III transcription than were controlextracts (Fig. 1B), suggesting that the transcriptional machineryresponds quickly to rapamycin treatment, although in magnitudethe effect is not comparable to repression of translation. Rapamycintreatment for 24 h resulted in a uniform morphological phenotype(>90% large unbudded cells, consistent with arrest in G₀) butno cell death; plating efficiencies determined at the conclusionof the treatment period were identical between rapamycin-treatedand control cells (not shown). Compared to extracts from cellstreated for 1 h, a substantially more severe repression effecton Pol III transcription was observed in extracts from cells treatedwith rapamycin for 24 h (Fig. 2A and B). We conclude that rapamycintreatment in vivo leads to repression of Pol III transcriptionin vitro and that repression occurs progressively rather thaninstantaneously.

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FIG. 1. Translation and Pol III transcription are repressed by short-term treatment (1 h) of cells with rapamycin. (A) Repression of translation. Translation was measured as [³⁵S]methionine incorporation during a 20-min labeling period at 30°C. Results are shown for two experiments. (B) Repression of Pol III transcription. 5S rRNA transcription was measured in increasing amounts of extracts from control and rapamycin-treated cells.

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FIG. 2. Transcription by RNA Pol I and III is strongly repressed in extracts from cells treated for 24 h with rapamycin. 5S rRNA (A), tRNA^Leu (B), and 35S rRNA (Pol I) (C) transcription was assayed in increasing amounts of extracts from control and treated cells. Note that the extracts from rapamycin-treated cells support Pol III transcription over only a narrow range of protein concentrations and that there is an unusually sharp decline in 5S rRNA transcription from 80 to 100 µg of extracts; these effects were reproducible but remain unexplained.

Since Pol I and Pol III transcription are coordinately regulated under many circumstances (see reference 9), we testedwhether Pol I transcription is also affected in extracts fromrapamycin-treated cells, compared to control cells. As shown,Pol I transcription is repressed in extracts from cells treatedfor 24 h with rapamycin (Fig. 2C). Furthermore, the magnitudeof this effect is similar to that observed for Pol III (Fig. 2Band C). We conclude that long-term rapamycin treatment globallyrepresses transcription of the nuclear genes encoding the mostabundant nontranslated RNAs.

Rapamycin treatment does not result in the appearance of a Pol III transcription inhibitor in extracts. The results in Fig. 1 and 2 could be explained if an excess of nonspecific inhibitor of the transcriptional machinery is generatedin the extract by rapamycin treatment of cells (see, for example,reference 41). In order to test this possibility, we performeda mixing experiment using extracts from 24-h-treated and controlcells (Fig. 3). This is a severe test because indirect inhibitoryeffects are expected to be most pronounced in cells subjectedto prolonged exposure to rapamycin. When 10 µg of extracts fromrapamycin-treated cells is mixed with 10 µg of control extracts,the level of transcription (Fig. 3, lane 3) is intermediate betweenthe levels obtained with 10 and 20 µg of control extracts (Fig.3, lanes 1 and 2) and is greater than the sum of the signal from10 µg of rapamycin and control extracts individually (Fig. 3,lanes 1 and 4). A similar result was obtained when a mixture of20 µg of each extract was compared to 40 µg of rapamycin and controlextracts alone (not shown). Therefore, the extracts from rapamycin-treatedcells do not contain an excess of a transcription inhibitor, suggestingthat a component of the transcription machinery is directly repressedby rapamycin. We further note that rapamycin extracts supportnormal levels of a variety of biochemical activities, includingchromatin assembly (not shown). Transcriptional repression inextracts, therefore, is not due to a general inhibitory effectsuch as would result from the activation of DNases or vacuolarproteases.

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FIG. 3. Repression of Pol III transcription is not due to an excess of inhibitor in extracts from rapamycin-treated cells. tRNA^Leu transcription was compared in the indicated amounts of extracts from control cells and cells cultured in the presence of rapamycin for 24 h.

Rapamycin treatment does not mimic a G₁ effect on transcription. Since rapamycin induces a transient G₁ arrest in yeast (4), our results may reflect inhibition of Pol III transcriptionin G₁ of the cell cycle. Indeed, White et al. (46) have demonstratedin a mammalian system that Pol III activity is very low in G₁extracts compared to extracts from asynchronously growing cells.To test if rapamycin treatment mimics a G₁ Pol III transcriptionphenotype in yeast, we compared transcription in extracts fromrapamycin-treated cells and cdc28^ts cells cultured at the restrictive temperature for 4 h, at whichtime ~90% of cdc28 cells are arrested in G₁. As shown in Fig.4, extracts from cdc28^ts cells support a significantly higher level of transcription thanextracts from rapamycin treated-cells. We conclude that in yeast,rapamycin treatment does not mimic the phenotype of Pol III transcriptionin G₁.

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FIG. 4. Repression of pol III transcription in extracts from rapamycin-treated cells does not reproduce the transcription phenotype of G₁ extracts. tRNA^Leu transcription was compared in extracts from rapamycin-treated (24 h) wild-type cells and from G₁-arrested cdc28 cells.

The rapamycin effect is TOR dependent. The inhibition of TOR-dependent cellular functions by rapamycin requires the presence of the intracellular ligand for rapamycin,FKBP12 (encoded by FPR1 in yeast [7, 19, 30, 37, 50;reviewed in reference 28]). Therefore, rapamycin phenotypesthat normally result from interference with TOR signaling becomeinsensitive to rapamycin when FKBP12 is absent. Based upon thisfact, it was possible to examine the TOR dependency of the rapamycineffect on Pol III transcription by comparing transcription inextracts from rapamycin-treated wild-type (FPR1) and fpr1 null( $Delta$ fpr1) strains. As expected, rapamycin treatment of wild-typecells for 24 h strongly inhibits Pol III transcription in vitro(Fig. 5A, top panel). In contrast, extracts from $Delta$ fpr1 cells showno decline in transcription in response to rapamycin treatmentfor 24 h (Fig. 5A, bottom panel). We conclude that the effectof rapamycin on Pol III transcription results from interferencewith the TOR signaling pathway.

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FIG. 5. (A) Repression of Pol III transcription by rapamycin treatment in vivo results from interference with TOR signaling. 5S rRNA transcription is compared in parallel extracts from FPR1 wild-type and fpr1 null cells that were or were not treated with rapamycin (24 h). An overexposure is shown for the FPR1 experiment to demonstrate the low level of transcription in extracts from treated cells (control extracts from FPR1 and $Delta$ fpr1 cells supported the same level of transcription). (B) Inhibition of CKII does not account for the repression of Pol III transcription by rapamycin. CKII activity is expressed as kilocounts per minute incorporated during a 5-min reaction at 22°C in the presence (+) or absence ( $-$ ) of the specific peptide substrate for CKII. Results are shown for two experiments using the FPR1 extract analyzed in panel A.

In mammalian cells (24), the rapamycin binding protein FKBP25 is found in a complex with the highly conserved protein kinaseCKII (reviewed in references 2, 29, 31, and 48). CKIIin yeast phosphorylates one member of the FKBP family, Fpr3p (48),and is required for efficient Pol III transcription in vivo andin vitro (15, 22). This evidence raises the possibility thatrapamycin interferes with Pol III transcription by inhibitingCKII. We therefore tested whether the repression of Pol III transcriptionin extracts from rapamycin-treated cells is associated with reducedCKII activity. Figure 5B shows that bulk CKII activity, as measuredwith a specific peptide substrate of CKII (15, 22), is identicalin extracts from control and treated cells. This result arguesthat rapamycin does not exert its effect on Pol III transcriptionby inhibiting CKII.

Conditional repression of Pol III transcription in extracts from a temperature-sensitive tor2 mutant. Repression of Pol III transcription in extracts from rapamycin-treated cells may result from the inhibitory effect of rapamycinon translation, resulting, for example, in inadequate synthesisof a labile transcription factor in treated cells (11, 39,40). We refer to this as a "passive" mechanism of repression.However, our results do not rule out the possibility that interferencewith TOR signaling represses transcription by a "direct" mechanismthat is independent of interference with translation. We thereforetested whether interference with TOR function is involved in translation-independentrepression by assaying transcription in extracts from a temperature-sensitivemutant of tor2 and an isogenic wild-type strain. Extracts wereprepared in parallel from TOR2 and tor2^ts cells harvested at the permissive temperature; at this temperature,Tor2p activity and abundance are identical in these strains (7).Since the transcription reactions do not support translation andare insensitive to 100 µg of cycloheximide per ml (16), anydifference in transcription between wild-type and mutant extractsis independent of protein synthesis.

Figure 6 shows transcription in wild-type TOR2 and mutant tor2^ts extracts prepared and assayed in parallel. The extracts supporta high level of transcription when reactions are performed at22°C, and the wild-type extract is slightly more active than themutant at 15 and 30 µg of input protein. At 37°C, the differencein activity between the extracts is substantially enhanced. Thiseffect is most clearly revealed by plotting the ratio of transcriptionin wild-type/mutant extract against the amount of extract used(Fig. 6B). At 37°C, there is up to a 5.5-fold inhibition of transcriptionin tor2^ts extract, compared to 2.0-fold inhibition at 22°C in reactionswith the same amount of protein. Similar results were obtainedwith two additional pairs of extracts prepared independently fromthose used in the experiments depicted in Fig. 6. We concludethat interference with TOR function in vitro represses Pol IIItranscription by a mechanism that is independent of TOR-mediatedeffects on translation.

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FIG. 6. Temperature-dependent repression of Pol III transcription in extracts from a tor2^ts mutant. (A) Pol III transcription is inhibited at the restrictive temperature in tor2 extracts. tRNA^Leu transcription at 22 and 37°C was compared in extracts from TOR2 and tor2^ts cells harvested at the permissive temperature. Although transcription is inhibited at 37°C in wild-type and mutant extracts, the effect is more pronounced in the mutant. (B) Quantitation of the experiment represented in panel A (bands indicated by the arrows were analyzed; see references 3 and 12). Data are plotted as the ratio of transcription in wild-type/mutant extracts for the indicated amounts of protein. A quantifiable signal was detected in lane 8 for the 37°C reaction upon long exposure of the film and phosphorimager plate.

In the absence of the data in Fig. 6, it remained formally possible that rapamycin represses transcription by an FPR1-dependentbut TOR-independent mechanism: for example, direct binding ofthe drug to a component of the Pol III transcription machinery.This scenario seems highly unlikely, given that all documentedeffects of rapamycin act at the level of the TOR kinases (seethe introduction) and that we observed repression in vitro usingextracts from tor2^ts cells without rapamycin treatment.

Biochemical analysis of the transcription defect in extracts from cells treated with rapamycin. Interference with TOR function in vivo is likely to affect Pol III transcription by a passive mechanism involving repressionof translation and by a direct mechanism that is independent ofthe inhibition of translation. In order to gain an appreciationof the full spectrum of effects on the Pol III transcriptionalmachinery (i.e., passive and direct) resulting from short-terminterference with TOR function, we investigated the biochemicalbasis of the modest transcription defect (two- to threefold inthis experiment) in extracts from cells treated for 1 h with rapamycin.

Since the pattern of labeled transcription products in extracts from treated and untreated cells is virtually identical instandard 8% polyacrylamide sequencing gels, we conclude that interferencewith TOR function affects transcription at the level of initiationrather than of pausing, termination, or start site selection.The effect of rapamycin is therefore likely to impinge on thecore Pol III transcription machinery, namely RNA Pol III, TFIIIB,and TFIIIC. TFIIIB was considered a likely target, since it issignificantly down-regulated when cells enter G₀ (36) and, atleast under some conditions, when cells are treated with cycloheximide(11; compare with reference 9). We therefore tested whetherTFIIIB purified from untreated cells could overcome the transcriptiondefect of extracts from rapamycin-treated cells. As shown in Fig.7A and B, TFIIIB slightly stimulates transcription in controlextract, consistent with reports that TFIIIB is normally limitingin vivo and in vitro (see reference 36). An amount of TFIIIBthat stimulates wild-type extract by 31% rescues transcriptionin extract from rapamycin-treated cells to the level observedin control extract supplemented with the same amount of TFIIIB(Fig. 7B). This result is consistent with repression of TFIIIBas a result of short-term treatment with rapamycin.

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FIG. 7. Identification of TFIIIB as a possible target of repression by rapamycin. (A) Extracts (40 µg) from control and rapamycin-treated (1 h) cells were supplemented with TFIIIB (0, 5, and 10 µl) or buffer. (B) Quantitation of the gel in panel A. (C) TFIIIC does not restore transcription in extracts from rapamycin-treated (1 h) cells. TFIIIC was added in increasing amounts to extracts (25 µg) in the presence (+) or absence ( $-$ ) of a saturating amount of TFIIIB (as defined in the experiments represented in panel A).

Interestingly, a larger amount of TFIIIB further stimulates control extracts but not rapamycin-treated extracts (Fig. 7A;compare lanes 2 and 3 to lanes 5 and 6). Indeed, large amountsof TFIIIB added to extracts from treated cells inhibit transcription,perhaps by unproductive interaction of soluble TFIIIB with anotherfactor that has become limiting (see Fig. 4A in reference 36for a similar example). In other words, inhibition of extractsfrom rapamycin-treated cells by large amounts of TFIIIB suggeststhat a component of the transcription machinery that is in excessof TFIIIB in control extracts is repressed in treated extracts.We tested whether this component is TFIIIC by adding a saturatingamount of TFIIIB and increasing amounts of affinity-purified TFIIICto extracts from treated cells. As shown in Fig. 7C, TFIIIC doesnot stimulate transcription in treated extracts supplemented witha saturating amount of TFIIIB. Therefore, rapamycin probably doesnot repress TFIIIC.

Our next step was to test whether RNA Pol III is repressed by rapamycin. Measurements of bulk Pol III activity in extractsfrom treated and untreated cells revealed that Pol III is significantlyinhibited in extracts from cells treated for 1 h with rapamycin(by 49% at the 100-µg point in the titration in Fig. 8A). BulkPol III activity in 100 µg of extract from cells exposed to rapamycinfor 24 h is also inhibited (by 59% [not shown]). To confirm thatPol III is repressed by rapamycin, we titrated a crude Pol IIIpreparation from untreated cells into rapamycin-treated extracts(1 h) supplemented with a saturating amount of TFIIIB (Fig. 8B).In marked contrast to the result obtained with TFIIIC, Pol IIIdoes stimulate transcription in the presence of excess TFIIIB.Quantitation reveals a 2.1-fold effect (Fig. 8C). Therefore, rapamycindown-regulates Pol III transcription in part by an effect on RNAPol III.

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FIG. 8. Identification of RNA Pol III as a target of repression by rapamycin. (A) Measurement of bulk Pol III activity in extracts from control and rapamycin-treated (1 h) cells. (B) Stimulation of specific transcription by addition of Pol III to extracts (25 µg) from rapamycin-treated (1 h) cells. (C) Quantitation of the gel in panel B.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

A TOR-dependent mechanism induces the G₀ program of transcription in yeast. Previous studies have revealed that interference with TOR signaling induces all aspects of the stationary-phase response sofar examined, namely, cell cycle arrest with 1n DNA content, repressionof translation, cell wall thickening, glycogen deposition, transcriptionalinduction of G₀-specific Pol II genes, vacuolar enlargement, andincreased thermotolerance (4, 7, 10). Our experimentswith rapamycin and a conditional tor2 mutant further demonstraterepression of Pol I and Pol III transcription when TOR functionis perturbed. Taken together, the available data support the notionthat TOR signaling in yeast occupies a central position in theglobal regulation of nuclear transcription in response to nutrientavailability. Since a universal component of growth control ineukaryotes is the down-regulation of Pol I and Pol III transcriptionin G₀, and since the kinase domain of a mammalian TOR homologcan provide rapamycin-sensitive TOR function in yeast (1),it is attractive to consider that in all eukaryotes TOR signalingmay be involved in establishing the pattern of nuclear transcriptionin G₀.

Transcriptional repression by a Tor2p-dependent mechanism that does not involve translational repression. Interference with Tor2p function in extracts from a temperature-sensitive tor2 mutant represses transcription by a mechanismthat is independent of TOR effects on translation. Consideringthat TOR kinases regulate a broad spectrum of cellular responsesassociated with entry into stationary phase and our observationthat rapamycin treatment of cells represses Pol III transcriptionin vitro, we take the tor2^ts result to indicate that Pol III down-regulation during entryinto G₀ is not exclusively a passive consequence of the inhibitionof translation. Repression in stationary phase indeed may resultexclusively from direct regulation of the transcriptional machineryby a signaling network involving the TOR kinases.

Effects of PP2A and TOR on transcription: how are they related?. The defect in Pol III transcription in yeast mutants of the regulatory A subunit of PP2A stems from the inhibition of PolIII and TFIIIB under restrictive conditions (41). In this instance,misregulated PP2A is proposed to dephosphorylate and activatean inhibitor of transcription. Considering that PP2A is a componentof the TOR pathway (10) and that Pol III and probably TFIIIBare under TOR control in yeast, repression of Pol III transcriptionby rapamycin may reflect interference with a TOR-PP2A signal transductionpathway that regulates Pol III transcription. An appealing extensionof this model is that a TOR-responsive kinase and PP2A act onthe same transcriptional inhibitor, the TOR-dependent kinase asa repressor of the inhibitor and PP2A as an activator. To date,however, we have no evidence for such an inhibitor in extractsfrom cells exposed to rapamycin, even in the extreme case of a24-h treatment. The precise relationship between the dominantinhibitory effect involving PP2A and TOR-dependent transcriptionalrepression, therefore, remains to be fully elucidated.

Since the TOR-PP2A pathway regulates the pattern of Pol II transcription in G₀ (4), alterations in PP2A function that perturbPol III transcription might also be expected to affect Pol IItranscription. That the transcription of some Pol II genes indeedis impaired in PP2A mutants (41) lends support to the hypothesisthat TOR-PP2A signaling is involved in setting the overall patternof nuclear transcription in G₀.

What other protein kinases might be involved in TOR effects on pol III transcription? The only protein kinase previously shown to influence pol III transcription in yeast is CKII (14, 15, 22). Our results,however, argue against an involvement of CKII in TOR signalingto the Pol III transcriptional machinery. We were unable to detectany change in bulk CKII activity in extracts from cells treatedwith rapamycin compared to control extracts, and the elongationcapacity of Pol III is not affected when CKII is inactivated (15).

Recent evidence suggests that TOR functions related to the control of progression into stationary phase involve genes implicatedin protein kinase C signaling (20). tor2 mutations affectingtranslation and cell cycle arrest in yeast are suppressed by overexpressionof (i) MSS4, a phosphatidylinositol 4-phosphate kinase homologthat may be upstream of the yeast protein kinase C (Pkc1p), and(ii) PLC1, a phosphoinositide-specific phospholipase C homologthat is likely to function in the same pathway as Pkc1p. Theseobservations, in view of reports that Pol III transcription issensitive to protein kinase C in metazoans (23, 42), suggestthe intriguing possibility that a TOR-protein kinase C signalingpathway impinges on the Pol III transcriptional machinery in yeast.

Mechanism of repression at the level of transcriptional machinery. Our working model is that TOR signaling regulates Pol III transcription by modulating the activity of TFIIIB and Pol III.At present, however, it remains to be shown that TFIIIB is defectivein extracts in which TOR function is impaired, and the molecularbasis of the repression of Pol III is not known. Theoretically,the decreased Pol III activity in extracts from rapamycin-treatedcells could be a secondary consequence of the inhibition of TFIIIB.For example, when TFIIIB is inhibited, Pol III could be releasedinto the nucleoplasm, where it would be susceptible to inactivationby soluble factors. We do not favor this possibility because inother cases where TFIIIB is inhibited in vivo, there is no declinein Pol III activity in vitro (11, 15, 36). Rather, basedupon the observation that some subunits of Pol III are phosphoproteinsin vivo (see reference 41), we favor a model in which TOR-dependentsignaling regulates the phosphorylation state and therefore theactivity of Pol III. It remains possible, however, that TOR signalingimpinges on the Pol III transcriptional machinery not by affectingthe phosphorylation status of components of the transcriptionalmachinery but by activating other regulatory mechanisms such as,for example, targeted degradation pathways (see reference 11).

Previous studies of Pol III transcriptional repression in yeast have not provided any evidence for regulation of the polymerase(11, 36) except in a case in which perturbation of PP2A functionapparently induces a transcriptional inhibitor (41). In thesestudies, transcription was analyzed in nuclear extracts or inwhole-cell extracts made by cell disruption nominally at 4°C.On the other hand, using whole-cell extracts prepared from cellsbroken open while they are frozen, we find that interference withTOR function represses Pol III by a mechanism that is distinctfrom the dominant-negative effect in PP2A mutants (41). Ourdemonstration that Pol III activity is sensitive to TOR kinases,which control all aspects of the stationary-phase response sofar examined, justifies reexamination of the physiological regulationof Pol III in yeast.

	ACKNOWLEDGMENTS

Bernard Leduc and Suren Sehgal of Wyeth-Ayerst Research are thanked for supplying rapamycin. Valuable technical assistancewas afforded by Darren Hockman, and Brent Altheim kindly providedextracts from cdc28 cells.

This work was supported by an establishment grant from the Alberta Heritage Foundation for Medical Research and by operatinggrants from the Canadian NCI and MRC. M.C.S. is a scholar of theMRC. D.Z. was supported in part by a 75th Anniversary Scholarshipfrom the University of Alberta.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biochemistry, University of Alberta, Edmonton, Alberta, Canada T6G 2H7.Phone: (403) 492-9144. Fax: (403) 492-9556. E-mail: michael.schultz{at}ualberta.ca.

REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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