Saccharomyces cerevisiae Rot1 Is an Essential Molecular Chaperone in the Endoplasmic Reticulum

Masato Takeuchi, Yukio Kimata, and Kenji Kohno

Graduate School of Biological Sciences, Nara Institute of Science and Technology, Nara 630-0192, Japan

Submitted December 26, 2007; Revised April 21, 2008; Accepted May 16, 2008
Monitoring Editor: Reid Gilmore

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Molecular chaperones prevent aggregation of denatured proteinsin vitro and are thought to support folding of diverse proteinsin vivo. Chaperones may have some selectivity for their substrateproteins, but knowledge of particular in vivo substrates isstill poor. We here show that yeast Rot1, an essential, type-IER membrane protein functions as a chaperone. Recombinant Rot1exhibited antiaggregation activity in vitro, which was partlyimpaired by a temperature-sensitive rot1-2 mutation. In vivo,the rot1-2 mutation caused accelerated degradation of five proteinsin the secretory pathway via ER-associated degradation, resultingin a decrease in their cellular levels. Furthermore, we demonstratea physical and probably transient interaction of Rot1 with fourof these proteins. Collectively, these results indicate thatRot1 functions as a chaperone in vivo supporting the foldingof those proteins. Their folding also requires BiP, and oneof these proteins was simultaneously associated with both Rot1and BiP, suggesting that they can cooperate to facilitate proteinfolding. The Rot1-dependent proteins include a soluble, typeI and II, and polytopic membrane proteins, and they do not sharestructural similarities. In addition, their dependency on Rot1appeared different. We therefore propose that Rot1 is a generalchaperone with some substrate specificity.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Newly synthesized polypeptides need to be correctly folded toa proper three-dimensional structure to mature into functionalproteins. In the cell, a variety of proteins assist in the foldingof nascent proteins and are collectively called molecular chaperones.A molecular chaperone is basically defined as a protein thattransiently associates with nascent proteins and promotes theirfolding and/or assembly. Based on their degree of substratespecificity, molecular chaperones can be classified from "general"ones interacting with diverse proteins to "specific" ones interactingwith specific proteins or protein families. The primary functionof a molecular chaperone is the stabilization of the unfoldedand unstable polypeptide, and in vitro, a general chaperoneis often capable of preventing aggregation of denatured proteins(Hartl, 1996). The 70-kDa heat-shock protein (Hsp70) is an abundantand the most prominent general chaperone. Hsp70 is thought toassist most nascent proteins just after and/or during theirsynthesis. Another abundant chaperone, Hsp90 protects severaldenatured proteins in vitro (Freeman and Morimoto, 1996), whichsuggests that Hsp90 can function as a chaperone for diverseproteins. However, in vivo, Hsp90 seems to be engaged in thefolding of specific subsets of proteins such as steroid hormonereceptors and some kinases (Young et al., 2004; Caplan et al.,2007). The eukaryotic chaperonin is also thought to possesssome specificity for its client proteins (Spiess et al., 2004).To understand the functions of individual chaperones in a cell,it is essential to elucidate their in vivo substrate proteins,as well as to characterize the dependency of the substrateson these chaperones. Kerner et al. (2006) showed that diverseproteins are bound to the bacterial general chaperone, GroEL/ES,but suggested that only one-third of the substrates absolutelyrequire the chaperone for folding. To date, we only have knowledgeof the in vivo substrates and their dependency on general chaperonesfor several chaperones.

The endoplasmic reticulum (ER) is the site of protein foldingin the secretory pathway. In the ER, many proteins are glycosylatedand subjected to disulfide bond formation. Insertion of themembrane proteins into the membrane and the glycophosphatidylinositol(GPI) anchoring of some surface proteins also occur in the ER(Alberts et al., 2002). BiP, or Kar2 in yeast, the ER residentHsp70, promotes translocation and folding of nascent polypeptides(Fewell et al., 2001). In addition to BiP/Kar2, various molecularchaperones and folding enzymes such as calnexin and proteindisulfide isomerase fulfill many of the complex requirementsfor protein folding in the ER. Calnexin is a chaperone thatis basically specific to N-glycosylated proteins (Williams,2006), and protein disulfide isomerase promotes the formationand rearrangement of the disulfide bonds (Freedman, 2002; Hosodaet al., 2003). The ER also functions as the quality controlcompartment of folding proteins (Ellgaard et al., 1999). Proteinsthat fail to gain native conformation are retained in the ERand eventually degraded via a pathway called ER-associated degradation(ERAD). In the ERAD pathway, substrate proteins are retro-translocatedto the cytosol, ubiquitylated and degraded by the proteasome(Carvalho et al., 2006; Denic et al., 2006). ER retention and/orERAD of a protein strongly suggests that it is misfolded and/orunassembled.

We previously proposed that an essential, type-I ER membraneprotein, Rot1 cooperates with BiP/Kar2 in the folding of nascentproteins in the ER of yeast cells (Takeuchi et al., 2006a,b).Several lines of evidences have suggested that Rot1 is involvedin protein folding: ROT1 genetically interacts with genes encodingER chaperones such as BiP/Kar2, and the unfolded protein response(Kimata et al., 2007; Kohno 2007) was induced in the temperature-sensitiverot1-2 mutant. Furthermore, folding of disulfide-reduced carboxypeptidaseY(CPY) was likely to be severely perturbed in kar2-1 rot1-2 doublemutant cells (Takeuchi et al., 2006a). Rot1 does not have anyknown functional motif, and the details of its molecular functionshave not been elucidated yet. In this report, we show that Rot1itself functions as a general chaperone. Recombinant Rot1 proteinprevented aggregation of denatured proteins in vitro. Moreover,we found several reliable or possible in vivo Rot1 substrateswith various properties.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Media, Plasmids, Yeast Strains, and Antibodies
Plasmids used in this study were constructed mainly using productsof genomic PCR and are listed in Table 1. Yeast cells were grownin YPD (2% glucose, 1% yeast extract, 2% polypeptone, and 0.02%adenine sulfate) or SC (2% glucose, 0.67% yeast nitrogen basew/o amino acids; BD, Franklin Lakes, NJ) and supplemental aminoacids (Kaiser et al., 1994). Standard genetic manipulationsof yeast cells were performed as described (Kaiser et al., 1994).Yeast strains used in this study are listed in Table 2. Fordisruption of UBC7, a disruption cassette was amplified by PCRfrom the genome of strain W303-CQ (Hiller et al., 1996), andthe resulting DNA fragment was introduced to strain YM16 (ROT1)and YM18 (rot1-2) to generate YM23 (ROT1 ubc7 ${Delta}$ ) and YM24 (rot1-2ubc7 ${Delta}$ ), respectively. The kar2-1 mutation was introduced intothe strains YM16 and YM18 by transformation with SpeI/SalI-digestedpB-kar2-1-LEU2. LEU⁺, and temperature-sensitive clones weresubsequently selected (examined at 39 and 32°C for YM88[ROT1 kar2-1] and YM89 [rot1-2 kar2-1], respectively). For expressionof the epitope-tagged proteins, the cells (YM16, 18, 23, 24,88, and 89) were transformed with the corresponding plasmidsdigested by the indicated restrictive enzymes (see Table 1).Integration of the introduced DNA fragments into the targetgenes was confirmed by genomic PCR. To introduce the sec12-4mutation, YM41 (ROT1 HA-KRE6) was transformed with pB-sec12-URA3digested by XbaI/XhoI, and the URA⁺, and temperature-sensitiveclones were selected. Anti-Kar2, Anti-Rot1, and anti-Sec61 antibodieswere previously described (Takeuchi et al., 2006a). Anti-Mnn9antibody was kindly provided by Dr. Koji Yoda (Tokyo University).Anti-hemagglutinin (HA; 12CA5, Roche, Basel, Switzerland) andanti-CPY (Rockland Immunochemicals, Gilbertsville, PA) werepurchased.

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Table 1. Plasmids used in this study

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Table 2. S. cerevisiae strains used in this study

Production and Purification of Recombinant Rot1 Protein
For production of Rot1HAHis₈, YM199 (FY23 harboring pYEX-ROT1-HA-His)was incubated in SC not containing leucine to A₆₀₀ = 1.5–1.8at 30°C. The following procedures were performed at 4°C.The cells were lysed in L buffer (50 mM KH₂PO₄/K₂HPO₄, pH 7.4,at 4°C, 500 mM KCl, 2 mM MgCl₂, 5 mM imidazole, 1 mM 2-mercaptoethanol,1%[wt/vol] Triton X-100, 20%[vol/vol] glycerol) containing aprotease inhibitor (PI) mix (1 mM PMSF, 0.2 mg/ml leupeptinand pepstatin A [Peptide Institute, Osaka, Japan], 1 mg/ml benzamidine[final concentrations]) by agitation with glass beads usingBead-beater (Biospec, Bartlesville, OK). The lysate was clarifiedby centrifugation at 100,000 x g for 1 h and incubated withNi-NTA agarose resin (Qiagen, Hilden, Germany) o/n. The resinwas washed with W buffer (L buffer containing 20 mM imidazole),and Rot1 was eluted with C buffer (20 mM HEPES, pH 7.4, at 4°C,500 mM KCl, 2 mM MgCl₂, 1 mM 2-mercaptoethanol, and 20% glycerol)containing 250 mM imidazole. The eluted protein was furtherpurified by gel filtration on Superdex75 (GE Healthcare, Amershamplc, United Kingdom) column equilibrated with C buffer. PurifiedRot1 was bound to Ni-NTA agarose again, eluted, dialyzed againstS buffer (C buffer containing 50% glycerol), and stored at –20°C.The rot1-2HAHis₈ mutant protein was produced in YM200, purified,and stored similarly.

Aggregation Protection Assay
${alpha}$ -Mannosidase (Sigma, St. Louis, MO) and citrate synthase (Roche)were dialyzed against A buffer (50 mM AcOH/AcONa, pH 5.5, at4°C, 150 mM KCl, 0.1 mM ZnSO₄, and 10% glycerol) and B buffer(20 mM HEPES, pH 7.0, at 4°C, 150 mM KCl, 2 mM MgCl₂, and10% glycerol), respectively, at 4°C. The proteins were dividedinto aliquots, frozen with liquid N₂, and stored at –80°C.For denaturation, ${alpha}$ -mannosidase (30 µM) and citrate synthase(40 µM) were mixed with equal volumes of D buffer (R buffer[20 mM HEPES, pH 7.0, at 30°C, 50 mM KCl, and 2 mM MgCl₂]containing 8 M guanidine-HCl) and incubated at RT for 1 h. Denatured ${alpha}$ -mannosidase or citrate synthase was diluted 50-fold in R bufferto 0.3 or 0.4 µM, respectively, and aggregation was monitoredby following an increase in A₃₂₀. The indicated amounts of Rot1,rot1-2 mutant protein, or BSA were incubated together.

Examination of the Cellular Amount of Proteins
To examine the cellular amount of proteins by Western blotting,the KRE5-HA (YM27, 28), HA-KRE6 (YM41, 42) and BIG1-HA (YM85,86) strains were cultured in YPD, and the strains expressingATG22-HA (YM191, 192), DRS2-HA (YM183, 184) and GUP1-HA (YM181,182) were grown in SC not containing tryptophan (Trp) at 23,30, or 23°C and shifted to 37°C for 2, 4, or 6 h. Thecells were harvested at A₆₀₀ = 0.8–1.0 and lysed in 1%SDS-TBES (50 mM Tris, pH 7.4, at 4°C, 150 mM NaCl, and 5mM EDTA) containing PI mix. The lysates were analyzed by Westernblotting using anti-HA, anti-Rot1, or anti-Sec61 antibody. Fordetection of each protein, cell lysates containing the followingamount of proteins were loaded: 5 µg for Kre5-HA and Atg22-HA;0.5 µg for HA-Kre6; 10 µg for Big1-HA, Drs2-HA,and Gup1-HA; and 20 µg for Rot1 and Sec61.

Pulse-Chase Experiments
For [³⁵S]methionine/cysteine (Met/Cys) pulse-chase experiments,SC medium not containing Met/Cys was used, referred to hereafteras SC. The cells were grown exponentially in SC at 23°Cto A₆₀₀ = 0.7–1.0, concentrated to 10 OD cells/ml, andincubated for 10 min at 37°C. The cells were labeled with[³⁵S]Met/Cys (EXPRESS protein labeling mix; PerkinElmer, Waltham,MA) at 4 MBq/ml for 10 min at 37°C. At the beginning ofthe chase period, 1/50 vol of the chase solution (1% Met and0.8% Cys in 0.1 N HCl) was added to the culture. At the indicatedtimes, 200 µl of the culture was taken, mixed with 200µl of YPD containing 20 mM NaN₃, and placed on ice. Thecells were lysed by agitation with glass beads in 100 µlof 1% SDS-TBES (1% S-TBES) containing PI mix at 4°C, andthe lysate was incubated at 50°C for 5 min and centrifugedat 15,000 x g at RT for 5 min. The cleared lysate was dilutedwith 4 vol of 2.5% Triton X-100-TBES (2.5% T-TBES) and incubatedwith 1 µg of anti-HA antibody or 10 µg of anti-CPYantibody and 10 µl bed vol of protein A-Sepharose (GEHealthcare) at 4°C for 2 h or overnight. The beads werewashed with 200 µl each of 1% T-TBES once, 1% T-TBES containing0.5 M NaCl twice, and 1% T-TBES once again at RT. Recoveredproteins were separated by SDS-PAGE and detected by autoradiographyusing the BAS2500 system (Fujifilm, Tokyo, Japan). For quantificationof the radioactive signal of protein bands, Image Gauge ver.4 software (Fujifilm) was used. For Figure 2B, cells were exponentiallygrown in YPD and incubated in SC for 1 h at 23°C (A₆₀₀ =0.6–1.0). The cells were then incubated for 10 min at33°C, labeled with [³⁵S]Met/Cys for 10 min, and chased for30 min at 33°C. For Figure 4E, the cells were incubatedfor 10 min at 37°C, labeled with [³⁵S]Met/Cys at 20 MBq/mlfor 10 min, and chased for the indicated periods at 37°C.Cells (2 OD) were lysed in 100 µl 1% T-TBES containingprotease inhibitors and centrifuged at 15,000 x g for 5 minat 4°C. Cleared lysates were incubated with 400 µlof 1% T-TBES, 5 µl anti-Rot1 antibody or nonimmune guineapig serum and 10 µl bed vol of ProteinA-Sepharose for2 h at 4°C, and the beads were washed four times with 200µl of 1% T-TBES at 4°C. Precipitated proteins wereeluted by incubation with 100 µl of 1% S-TBES for 10 minat 65°C. Immunoprecipitation of HA-Kre6 was performed asdescribed above. Similar results were obtained in three independentexperiments.

Subcellular Fractionation
YM41 (ROT1 HA-KRE6) cells were grown in 500 ml of YPD to A₆₀₀= 1.0 at 30°C. The cells were treated with 10 mM NaN₃ for5 min, collected, and incubated in 20 ml of reduction buffer(50 mM Tris, pH 9.6, at 25°C, 10 mM dithiothreitol, 10 mMNaN₃) for 10 min at 30°C. The cells were spheroplasted in10 ml spheroplasting buffer (20 mM Tris, pH 7.4, at 4°C,150 mM NaCl, 1 M sorbitol, and 10 mM NaN₃) with 2 mg of zymolyaseT100 (Seikagaku Corporation, Tokyo, Japan) for 1 h at 30°C.The spheroplasts were collected, dissociated in 1.4 ml lysisbuffer (50 mM Tris, pH 7.4, at 4°C, 150 mM KCl, 2 mM MgCl₂,and 200 mM sucrose) containing PI mix and disrupted by a Douncehomogenizer at 4°C. The lysates were centrifuged at 600x g, 4°C for 30 min, and 1 ml of cleared lysate was layeredon the top of a 11 ml, 20–80% step sucrose gradient (fromthe bottom, 1 ml each of the lysis buffer containing 80, 70,60, 55, 50, 45, 40, 35, 30, 25, and 20% sucrose was piled up).The gradient was centrifuged at 150,000 x g, 4°C for 8 hin the SW40Ti rotor (Beckman Coulter, Fullerton, CA) and 1-mlfractions were collected manually from the top of the gradient.

Coimmunoprecipitation
For coimmunoprecipitation of Rot1 with HA-Kre6 or Big1-HA, thecells (YM41 and 42 or YM85 and 86) were grown in YPD to A₆₀₀= 1.0 at 23°C and incubated at 37°C for 10 min. Whereindicated, cycloheximide (CHX) was added to the culture to 0.1mg/ml, and the cells were further incubated for 10 or 20 minat 37°C. For coimmunoprecipitation of Rot1 with Kre5-HAor Drs2-HA, the cells (YM27 or 194) were grown in YPD or SCnot containing Trp, respectively, to A₆₀₀ = 1.0 at 30°C.Then, the cells were treated with 10 mM NaN₃ briefly and harvested.Cell lysis and immunoprecipitation (IP) were performed undernondenaturing conditions at 4°C as follows. Cells (2.5 OD)were disrupted by agitation with glass beads in 200 µlof 1% T-TBES containing PI mix. The lysate was cleared by thecentrifugation at 15,000 x g for 5 min, and 2.5 µl ofnonimmune serum and 10 µl bed vol of protein A-Sepharosewere added, and the mixture was incubated for 1 h. The mixturewas centrifuged at 15,000 x g for 5 min, and in the case ofcoIP with Kre5-HA and Drs2-HA, the supernatant was diluted twofoldwith 1% T-TBES. Then, 2.5 µl of anti-Rot1 antibody ornonimmune serum and 10 µl bed vol of protein A-Sepharosewere added, and the mixture was rotated for 2 h. The beads werewashed four times with 200 µl of 1% T-TBES, and the immunoprecipitants(one fifth of the sample for HA-Kre6, two thirds for Big1-HA;for Kre5-HA and Drs2-HA, similarly prepared two samples werecombined) were analyzed by Western blotting. Similar resultswere obtained in at least three independent experiments.

For double-immunoprecipitation in Figure 9, the cells (YM41and YM42) were incubated, treated with NaN₃, and harvested asabove. Cells (5 OD) were dissociated in 400 µl of PBSand incubated with 2 mM dithiobis(succinimidyl)propionate (DSP;freshly prepared in DMSO at 200 mM) and 10 mM NaN₃ for 1 h at37°C, and Tris (pH 8.0 at RT) was added to 100 mM to quenchthe reaction. The cells were lysed in 200 µl of 1% S-TBEScontaining PI mix, incubated for 10 min at 65°C, and centrifugedat 15,000 x g for 5 min at RT. The cleared lysates were incubatedwith 800 µl of 2.5% T-TBES, 5 µl of nonimmune serumand 10 µl bed vol of protein A-Sepharose for 2 h at 4°C,centrifuged at 15,000 x g for 5 min at 4°C, and the supernatantwas further incubated with 10 µl of anti-Rot1 or nonimmuneserum and 10 µl bed vol of protein A-Sepharose overnightat 4°C. The beads were washed with 200 µl each of1% T-TBES once, 1% T-TBES containing 0.5 M NaCl twice, and 1%T-TBES once again at RT. Recovered proteins were eluted by incubationwith 100 µl of 1% S-TBES for 10 min at 65°C and incubatedwith 400 µl of 2.5% T-TBES, 1 µl of anti-Kar2 ornonimmune rabbit serum, and 10 µl bed vol of protein A-Sepharosefor 2 h at 4°C. The beads were washed as above, and theimmunoprecipitants were analyzed by Western blotting.

CHX Chase
The BIG1-HA cells (YM84, 85, 86, 87, 96, and 97) were grownin YPD at 23°C and incubated at 37°C for 2 h. Beforethe temperature shift, the density of the cultures was properlycontrolled so that the A₆₀₀ of the culture was 0.8–1.0after 2-h incubation at 37°C. CHX was then added to a final0.1 mg/ml, and the cells were further incubated at 37°C.Aliquots were taken at the indicated times, and the cell lysates(equivalent to 0.05 OD cells) were subjected to Western blottingto detect Big1-HA. The protein bands on the x-ray films werescanned by ImageScanner (GE Healthcare) and quantified by ImageGauge ver. 4.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Recombinant Rot1 Prevents Aggregation of Denatured Proteins In Vitro
To elucidate the chaperone function of Rot1, we first generateda recombinant Rot1 and performed in vitro experiments. The recombinantRot1 protein in which the C-terminal transmembrane region wasreplaced with the HA-His₈ tag, and the N-terminal signal sequencewas intact, was expressed in yeast cells from the strong TDH3promoter. The protein was purified by Ni⁺²-chelated affinity-chromatographyand gel filtration (Figure 1A). The rot1-2 mutant version wasalso generated and purified. Endoglycosidase H (EndoH) treatmentincreased the mobility of the proteins on SDS-PAGE, indicatingthat they were translocated into the ER and N-glycosylated asexpected (Figure 1A).

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Figure 1. Recombinant Rot1 prevents aggregation of denatured proteins in vitro. (A) Purified recombinant Rot1. Wild-type Rot1 and rot1-2 proteins were expressed and purified as described in Materials and Methods. Protein, 3 µg each, was resolved by SDS-PAGE (12%), and the gel was stained with Coomasie Brilliant Blue. Where indicated, the proteins were treated with EndoHf (New England Biolabs, Beverly, MA) according to manufacturer's instructions. Asterisks, EndoHf. (B and C) Rot1 prevents aggregation of denatured ${alpha}$ -mannosidase and citrate synthase. ${alpha}$ -Mannosidase (B) or citrate synthase (C) was denatured with 4 M guanidine-HCl and diluted 50-fold to 0.3 µM (B) or 0.4 µM (C) at time 0. Indicated amounts of Rot1, rot1-2, or control protein BSA was incubated together, and A₃₂₀ was measured at RT for the indicated periods. A₃₂₀ of the buffer alone reaction at 10 min (B) or 5 min (C) is set to 100%, and the relative extent of the aggregation of denatured ${alpha}$ -mannosidase or citrate synthase for each conditions of the reaction is shown. The averages of at least three reactions are shown. For simplicity, SDs are shown only for 5 and 10 min (B) or 2.5 and 5 min (C). Because the purity of rot1-2 was lower than Rot1, the actual concentration of rot1-2 in the reactions was estimated to be $~$ 75% that of Rot1.

When a protein is denatured in a chemical denaturant such asguanidine and the denaturant is rapidly diluted, the denaturedprotein tends to aggregate. In many cases, general chaperonesbind to such denatured proteins and prevent their aggregation.We denatured ${alpha}$ -mannosidase by guanidine and diluted it into anassay buffer. Aggregation was monitored by measuring absorbanceat 320 nm, which indicates light scattering of protein aggregates.As shown in Figure 1B, Rot1 prevented aggregation of denatured ${alpha}$ -mannosidase. The mutant rot1-2 protein also inhibited aggregation,albeit less efficiently than the wild-type Rot1 (Figure 1B).Aggregation of denatured citrate synthase was also inhibitedby Rot1 (Figure 1C). These results indicate that Rot1 can directlybind to an unfolded protein, which is closely related to thein vivo functions of Rot1.

Proteins Important for Cell Wall 1,6-β-Glucan Synthesis Are Decreased in the rot1-2 Mutant
ROT1 was initially reported as a gene required for the 1,6-β-glucansynthesis (Bickle et al., 1998; Machi et al., 2004). We speculatedthat Rot1 is required for the maturation of proteins involvedin the 1,6-β-glucan synthesis, so we checked the effectsof the rot1-2 mutation on the cellular amount of three proteins,Kre5, Kre6, and Big1, which are especially important for thisprocess. Kre5 is an ER-localized soluble protein that has similarityto UDP-glucose:glycoprotein glucosyltransferase (UGGT; Levinsonet al., 2002). Kre6 was initially reported to be a Golgi-localizedtype-II membrane protein and was predicted to be a glucosidaseor transglucosylase (Montijn et al., 1999; Li et al., 2002).However, a recent report suggested that Kre6 predominantly localizesin the ER and functions with an ER membrane protein named Keg1(Nakamata et al., 2007). Big1 is an ER-localized type-I membraneprotein that does not have any known functional motif (Azumaet al., 2002). The sequence encoding the HA epitope tag wasintegrated into the chromosomal KRE5, KRE6, or BIG1 locus toexpress tagged versions of each of these proteins. As shownin Figure 2, the rot1-2 mutation caused a drastic reductionin the levels of Kre5, Kre6, and Big1, as quantitated by Westernblot analysis of the tagged proteins. Kre6 was the most severelyaffected: in rot1-2 cells, Kre6 was detected only faintly evenat 23°C (a permissive temperature for the rot1-2 mutant)and was almost undetectable at 37°C (a restrictive temperature).Kre5 and Big1 expression were considerably decreased by a temperatureshift to 37°C in the rot1-2 cells but not in the ROT1 cells.The rot1-2 mutation also caused a reduction in Rot1 itself (therot1-2 mutation changes the mobility of the protein on SDS-PAGE;Takeuchi et al., 2006a). In contrast, expression of Sec61, the ${alpha}$ -subunit of the protein translocation channel of the ER membrane,was not affected by the rot1-2 mutation. These results suggeststhat severe defect in 1,6-β-glucan synthesis originallyobserved in rot1 mutant cells is caused by decreases in thecellular levels of Kre5, Kre6, and Big1.

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Figure 2. Cellular levels of proteins important for cell wall 1,6-β-glucan synthesis are decreased by the rot1-2 mutation. YM27 (ROT1 KRE5-HA), YM28 (rot1-2 KRE5-HA), YM41 (ROT1 HA-KRE6), YM42 (rot1-2 HA-KRE6), YM84 (ROT1 BIG1-HA), and YM85 (rot1-2 BIG1-HA) were incubated in YPD at 23 or 30°C or shifted from 23 to 37°C for the indicated times. The cell lysates were subjected to Western blotting using anti-HA, anti-Rot1, and anti-Sec61. The cellular level of Sec61 was not affected by the rot1-2 mutation and served as a loading control.

Rot1 Is a Molecular Chaperone for Kre6
We next examined the relationship between Rot1 and Kre6 in detail.Kre6 appeared as three protein bands in cell lysate Westernblots, and we designated the fastest migrating species as theA form, the middle one as the B form, and the slowest one asthe C form (Figure 3A). These bands were shifted almost equallyby EndoH digestion, so these differences in the gel mobilityare not due to the number or modification of N-linked oligosaccharidechains. Because the predicted molecular mass of unmodified Kre6is 80 kDa, Kre6 is likely to undergo another modification(s)such as O-glycosylation or phosphorylation (Roemer et al., 1994

).To follow the modification of Kre6, we used a pulse-chase protocolin which the cells were metabolically labeled with [³⁵S]Met/Cysand chased in the presence of excess unlabeled Met/Cys. At thebeginning of the chase period, only the A form was detected,and the B and C forms appeared after 30 min (Figure 3B). Thisindicates that the A form was synthesized first and subsequentlyconverted to the B or C forms, albeit not completely. When thetransport from the ER to the Golgi was blocked by the sec12-4mutation (Stevens et al., 1982

), this conversion was not observed(Figure 3B), suggesting that Kre6 was modified to the B or Cform in the Golgi. CPY served as a control confirming blockageof ER–Golgi transport in the sec12-4 mutant: only theER form of CPY was detected in the mutant even after 30 minof chase, whereas the Golgi and the vacuolar forms were observedin the SEC12 cells (Figure 3B). Although a large portion ofKre6 in the cell lysate was of the B form (Figure 3A), Nakamataet al. (2007)

recently showed that Kre6 is mainly localizedto the ER. To address this discrepancy, we examined the intracellulardistribution of Kre6 by subcellular fractionation using sucrosegradient ultracentrifugation. This analysis revealed that abouttwo thirds of the A and B forms and most of the C form of Kre6exist in the ER, and the rest is located in the Golgi (Figure 3C).This finding suggests that Kre6 cycles between the ER and theGolgi, which is consistent with Nakamata et al. (2007)

. Suchcycling has also been reported for another protein, Mnn9 (Todorowet al., 2000

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Figure 3. Modification and localization of Kre6. (A) Western blot detection of HA-Kre6. ROT1 cells expressing HA-Kre6 (YM41) was incubated in YPD at 30°C, and the cell lysates were subjected to anti-HA Western blotting. Where indicated, the lysate was treated with EndoHf. The positions of the three forms of HA-Kre6 not treated with EndoHf are indicated in the left of the panel. (B) Conversion of HA-Kre6 requires transport from the ER to Golgi. The cells (YM41 and YM132 [ROT1 HA-KRE6 sec12-4]) were incubated in SC for 1 h at 23°C, labeled with [³⁵S]Met/Cys for 10 min at 33°C and chased for 30 min at 33°C. The cells were lysed, and HA-Kre6 or CPY was immunoprecipitated, separated by SDS-PAGE and detected by autoradiography. The positions of each forms of HA-Kre6 and CPY (E, ER; G, Golgi; V, vacuole) are indicated. (C) Intracellular distribution of HA-Kre6. YM41 was incubated in YPD at 30°C, spheroplasted and lysed gently with a Dounce homogenizer. The lysate was fractionated by a 20–80% sucrose step gradient ultracentrifugation. The fractions were subjected to Western blotting to detect HA-Kre6, Mnn9, and Sec61. Mnn9 and Sec61 were used as a Golgi or an ER marker, respectively.

To investigate the effects of the rot1-2 mutation on the modificationand stability of Kre6, a pulse-chase experiment was performedat the restrictive temperature of 37°C. In the rot1-2 mutant,only the A form was detected (Figure 4A), which implies thatKre6 was retained in the ER. In addition, the rot1-2 mutationcaused a rapid degradation of Kre6. Kre6 radioactivity was quantified,as shown in Figure 4B. Ubc7 is a ubiquitin-conjugating enzymeespecially important for the ERAD, and ubc7 ${Delta}$ strongly interferesthe ERAD of most known substrates (Hiller et al., 1996

; Vashistand Ng, 2004

; Kota et al., 2007

). Kre6 degradation was inhibitedin the rot1-2 ubc7 ${Delta}$ double mutant, indicating that Kre6 was degradedby the ERAD in the rot1-2 cells (Figure 4B). On the other hand,ubc7 ${Delta}$ did not affect the stability of Kre6 in a ROT1 background.These results indicate that the rot1-2 mutation causes ER retentionand ERAD of Kre6, which strongly suggests that Kre6 failed tofold in the rot1-2 mutant.

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Figure 4. Rot1 is a molecular chaperone for Kre6. (A) Conversion of HA-Kre6 does not occur in the rot1-2 mutant. ROT1 and rot1-2 cells expressing HA-Kre6 (YM41 and YM42) were incubated for 10 min at 37°C, labeled with [³⁵S]Met/Cys for 10 min and chased for indicated periods at 37°C. Radiolabeled HA-Kre6 was recovered and detected as in Figure 3B. The positions of the A and the B forms of Kre6 are indicated in the left of the panel. The C form was barely detected under the conditions of this experiment. (B) HA-Kre6 is degraded by the ERAD in the rot1-2 cells. Pulse-chase experiments for HA-Kre6 were performed as in A, using the HA-KRE6 strains: YM41, YM42, and YM43 (ROT1 ubc7 ${Delta}$ ); YM44 (rot1-2 ubc7 ${Delta}$ ); YM90 (ROT1 kar2-1); and YM91 (rot1-2 kar2-1). Radioactive signals of HA-Kre6 (the A plus the B forms) were quantified, and the averages and SDs of at least five independent experiments are shown. Signal intensities of HA-Kre6 at the beginning of the chase period are set to 100%. (C and D) Rot1 interacts with HA-Kre6. Cells (YM41 and YM42) were grown in YPD at 23°C and incubated at 37°C for 10 min. Where indicated, the cells were further incubated with CHX (0.1 mg/ml) for the indicated times. Cell lysis and IP using anti-Rot1 antibody or a nonimmune serum (n.i.; as a negative control) were performed under a nondenaturing conditions at 4°C. The cell lysates (C) or the immunoprecipitants (D) were analyzed by Western blotting using anti-HA and anti-Rot1 antibodies. HC, immunoglobulin heavy chain. (E) Transient interaction of Rot1 and Kre6. Cells (YM41) were incubated, labeled with [³⁵S]Met/Cys and chased for the indicated periods as in A. Anti-HA IP (lanes 1 and 2) or double-IP against Rot1 (or nonimmune serum) first and then HA (lanes 3–6) were performed. Relative amounts of recovered radioactive HA-Kre6 in the representative experiments are shown under the panel.

One important characteristic of molecular chaperones is theirtransient interaction with the substrate protein. To detectthe interaction between Rot1 and Kre6, Rot1 was immunoprecipitatedby an anti-Rot1 antibody, and coprecipitated Kre6 was analyzedby Western blotting. As shown in Figure 4D, Kre6 was found inanti-Rot1 precipitates (lane 2), but not nonimmune serum precipitates(lane 1). Importantly, although the majority of Kre6 detectedin cell lysates was of the B form (Figure 4C, lane 1), the Aform of Kre6 was predominantly copurified with Rot1. This findingsuggests that Rot1 selectively and transiently binds to recentlysynthesized Kre6. To confirm this idea, we performed double-immunoprecipitationin combination with a [³⁵S]Met/Cys pulse-chase experiment. Thecells were labeled and chased, and Rot1 was first immunoprecipitated.Then, the precipitate was subjected to a second immunoprecipitationto recover Kre6, which was separated by SDS-PAGE. Although the³⁵S-labeled Kre6 was stable and converted to the B and C formsduring the chase period (Figure 4E, lane 1, 2), only the A formof Kre6 was found to interact with Rot1, and the amount of Rot1-boundKre6 rapidly decreased (Figure 4E, lane 4–6). This dataindicates that Rot1 transiently interacts with newly synthesizedKre6. Blockage of protein synthesis by the translation inhibitorCHX also caused a time-dependent decrease in the amount of Rot1-Kre6complex detected (Figure 4D, lane 3 and 4), whereas the amountof cellular Kre6 was virtually unaffected (Figure 4C, lanes1–3). An interaction between the rot1-2 mutant proteinand Kre6 was also detected (Figure 4D, lane 6), but was lesscompared with the amount of Kre6 copurified with wild-type Rot1(Figure 4D, compare lane 2 and 6). This result implies thatthe rot1-2 mutation impaired, but did not completely abolishthe ability of Rot1 to bind to Kre6, as suggested by the invitro experiments (Figure 1, B and C). However, we cannot excludea possibility that lower abundance of Kre6 in rot1-2 cells resultedin less observed Rot1-Kre6 complex. Taken together, we concludethat Rot1 functions as a molecular chaperone for Kre6.

Rot1 Is a Molecular Chaperone for Big1
We next tested whether Rot1 also functions as a molecular chaperonefor Big1. Because Big1 contains only small number of Met andCys residues and was not labeled efficiently by [³⁵S]Met/Cys,we used a CHX chase protocol. To follow the fate of Big1 synthesizedat 37°C, the cells were incubated at 37°C for 2 h, andthen CHX was added to the culture to inhibit further proteinsynthesis. Big1 in the cell lysates was detected by Westernblotting (Figure 5A) and quantified (Figure 5B). The data clearlydemonstrate that degradation of Big1 was accelerated by therot1-2 mutation and that ubc7 ${Delta}$ stabilized Big1 only in the rot1-2background. This finding indicates that the rot1-2 mutationcauses the ERAD of Big1. In addition, a coIP analysis demonstratedan interaction between Rot1 and Big1, which was decreased byCHX treatment (Figure 5, C and D). This suggests that Rot1 transientlyassociates with Big1, probably while Big1 is still nascent.The Rot1-Big1 complex was only faintly detected in the rot1-2cells (Figure 5D, lane 6). Taken together, these data indicatethat Rot1 likely acts as a molecular chaperone for Big1.

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Figure 5. Rot1 is a molecular chaperone for Big1. (A) CHX chase of Big1-HA. ROT1 and rot1-2 cells expressing Big1-HA (YM84 and YM85) were grown in YPD at 23°C and incubated at 37°C for 2 h. The cells were further incubated with CHX (0.1 mg/ml) for indicated period at 37°C. The cell lysates were subjected to Western blotting to detect Big1-HA. (B) Big1-HA is degraded by the ERAD in the rot1-2 cells. CHX chase experiments were performed as in A using the BIG1-HA strains: YM84, YM85, and YM86 (ROT1 ubc7 ${Delta}$ ); YM87 (rot1-2 ubc7 ${Delta}$ ); YM96 (ROT1 kar2-1); and YM97 (rot1-2 kar2-1). The signal intensity of Big1-HA was quantified, and the averages and SDs of at least four independent experiments are shown. (C and D) Rot1 interacts with Big1-HA. Lysis of YM84 and YM85 cells and IP were performed, and results are presented as Figure 4, C and D.

Rot1 May Chaperone Kre5 and Atg22
The relationship of Rot1 with maturation of Kre5 was also examined.Kre5 stability was examined by the [³⁵S]Met/Cys pulse-chaseexperiment. As shown in Figure 6A and B, the rot1-2 mutationcaused a weak but significant acceleration of Kre5 degradation.IP of Rot1 coprecipitated Kre5 (Figure 6C), indicating an interactionbetween Rot1 and Kre5. We suggest that Rot1 is involved in thefolding and/or stabilization of Kre5, although the drastic reductionof Kre5 observed in the rot1-2 cells (Figure 2) could also bea separate and indirect consequence of prolonged incubationat 37°C.

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Figure 6. The relationship of Rot1 with Kre5 and Atg22 (A and B) The stability of Kre5-HA in YM27 (ROT1 KRE5-HA), YM28 (rot1-2 KRE5-HA), YM214 (ROT1 kar2-1), and YM215 (rot1-2 kar2-1) was examined by [³⁵S]Met/Cys pulse-chase experiments as described for HA-Kre6 (Figure 4, A and B). A representative autoradiograph is shown in A. Kre5-HA radioactivity was quantified, and the averages and SDs of at least four independent experiments are shown in B. (C) Interaction between Rot1 and Kre5-HA. YM27 was incubated in YPD at 30°C and lysed, and IP using anti-Rot1 antibody or nonimmune serum (n.i.) was performed under nondenaturing conditions at 4°C. The immunoprecipitants were subjected to Western blotting to detect Kre5-HA and Rot1. (D) Cellular level of Atg22-HA is decreased by the rot1-2 mutation. ROT1 and rot1-2 cells expressing ATG22-HA from a centromeric plasmid (YM191 and YM192 [pRS314-ATG22-HA]) were incubated in SC at 23°C or shifted to 37°C for 6 h. The cells were lysed, and Atg22-HA and Sec61 were detected by Western blotting.

We previously showed that the lysis of the autophagic bodiesis perturbed in the rot1-2 mutant (Takeuchi et al., 2006a

).We thus asked if Rot1 chaperones proteins that are involvedin this cellular event. Atg22 is a polytopic membrane proteinand probably acts as an amino acid permease in the vacuolarmembrane (Yang et al., 2006

). We found that the cellular levelof Atg22 was decreased by the rot1-2 mutation at 37°C (Figure 6D).Because of some technical reasons, neither ³⁵S-metabolic labelingof Atg22 nor the CHX chase protocol was successful for checkingstability of Atg22.

Finding Rot1-dependent Proteins from the E-MAP
To find other Rot1-dependent proteins, we utilized an epistaticminiarray profile (E-MAP) of yeast genes reported by Schuldineret al. (2005), which illustrates the genetic relationship amongmutant alleles of 424 genes related to the secretory pathway.In their study, 57 essential genes, including ROT1, were mutagenizedby insertion of a nucleotide sequence to destabilize the productmRNAs, whereas another 367 genes were deleted. Next, the interactionsof most of the gene pairs were estimated by checking the growthphenotype of the double mutant of the two genes. The combinationsof the 424 mutations were examined, except for pairs of essentialgenes, and this comprehensive data set comprises the E-MAP.

Here we assumed the following scenario. If the product of geneS is a substrate protein of Rot1, its cellular level would decreaseupon introduction of the rot1 mutation. On the other hand, themutation in S also causes loss or reduction of its own product.Therefore, the mutations in ROT1 and S would show similar phenotypes,which in this case, is a genetic interaction(s) with anothergene(s). On the basis of this model, we chose four genes, DRS2,GUP1, OPI3, and PMR1, as candidates for gene S from the 424genes.

Drs2 is a polytopic membrane protein belonging to the P-typeATPases and cycles between the trans-Golgi network and the plasmamembrane (Saito et al., 2004). The HA-tagging sequence was integratedinto the chromosomal DRS2 locus to generate Drs2-HA. Westernblot analysis of cell lysates revealed that, compared with ROT1cells, Drs2-HA protein levels were lower in rot1-2 mutants incubatedat 23°C and drastically lower in rot1-2 mutants incubatedat 37°C (Figure 7A). We next examined the stability of Drs2by [³⁵S]Met/Cys pulse-chase. In this experiment, Drs2-HA wasexpressed from a multicopy plasmid for efficient detection.As shown in Figure 7, B and C, Drs2 was degraded more quicklyin the rot1-2 cells than in the ROT1 cells. In addition, wedetected an association between Rot1 and Drs2 by coIP (Figure 7D).These findings suggest that Rot1 functions as a chaperone forDrs2. We could not determine if the ubc7 ${Delta}$ mutation stabilizesDrs2 in the rot1-2 cells, because it unexpectedly induced degradationof Drs2 even in the ROT1 cells (data not shown).

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Figure 7. The relationship between Rot1 and Drs2. (A) Cellular amount of Drs2-HA is decreased by the rot1-2 mutation. The cells (YM183 [ROT1 DRS2-HA] and YM184 [rot1-2 DRS2-HA]) were incubated in SC at 23°C or shifted to 37°C for 6 h, lysed, and analyzed by anti-HA and anti-Sec61 Western blotting. (B and C) Accelerated degradation of Drs2-HA in the rot1-2 cells. ROT1 and rot1-2 cells expressing Drs2-HA from a multicopy plasmid (YM193 [ROT1], YM194 [rot1-2], YM212 [ROT1 kar2-1], and YM213 [rot1-2 kar2-1]; pRS424-DRS2-HA) were subjected to the [³⁵S]-Met/Cys pulse-chase experiments to examine stability of Drs2-HA as described for HA-Kre6 (Figure 4, A and B). Representative autoradiograph is shown in B. The amount of radiolabeled Drs2-HA was quantified, and the averages and SDs of at least four independent experiments are shown in C. (D) Interaction between Rot1 and Drs2-HA. YM193 was incubated in SC at 30°C and lysed, and IP using anti-Rot1 antibody or nonimmune serum (n.i.) was performed under a nondenaturing condition. Then the immunoprecipitants were analyzed by anti-HA and anti-Rot1 Western blotting.

Gup1 is a multispanning membrane protein that is located inthe ER and is involved in remodeling of the GPI anchor (Bossonet al., 2006

). HA-tagged Gup1 was expressed under the controlof its native promoter from a centromeric plasmid. Western blotanalysis revealed that the cellular level of Gup1 was reducedby the rot1-2 mutation, especially at 37°C (Figure 8A).By the [³⁵S]Met/Cys pulse-chase protocol, stability of Gup1expressed from a multicopy plasmid was examined. The rot1-2mutation caused accelerated degradation of Gup1, an effect thatwas weakly but significantly alleviated by the ubc7 ${Delta}$ mutation(Figure 8, B and C). Comigration of Gup1 with the immunoglobulinheavy chain on SDS-PAGE prevented us from detecting an interactionof Rot1 and Gup1 by coIP.

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Figure 8. The relationship between Rot1 and Gup1. (A) Cellular level of Gup1-HA was decreased by the rot1-2 mutation. ROT1 and rot1-2 cells expressing Gup1-HA from a centromeric plasmid (YM181 and YM182 [pT10-GUP1-HA]) were incubated in SC at 23°C or shifted to 37°C for 6 h. Gup1-HA and Sec61 in the cell lysates were detected by Western blotting. (B and C) Accelerated degradation of Gup1-HA in the rot1-2 cells. Stability of Gup1-HA was examined by [³⁵S]Met/Cys pulse-chase experiments as described for HA-Kre6 (Figure 4, A and B) using the strains (YM195 [ROT1], YM196 [rot1-2], YM173 [ROT1 ubc7 ${Delta}$ ], YM174 [rot1-2 ubc7 ${Delta}$ ], YM210 [ROT1 kar2-1], and YM211 [rot1-2 kar2-1]) harboring a multicopy plasmid for expression of Gup1-HA (pT20-GUP1-HA). Representative autoradiograph is shown in B. Radioactive signals of Gup1-HA were quantified, and the averages and SDs of at least four independent experiments are shown in C.

Our analysis of Opi3 and Pmr1 showed little or no effect ofthe rot-2 mutation on their cellular amount or stability (SupplementalFigure 1), eliminating these as potential substrates. Takentogether, these data suggest that Rot1 is a chaperone for Drs2and Gup1, but not for Opi3 or Pmr1.

Rot1 May Cooperate with BiP/Kar2 in the Folding of Kre6
We previously proposed that Rot1 cooperates with BiP/Kar2 innascent protein folding (Takeuchi et al., 2006a,b), and we examinedthis possibility here. The kar2-1 mutation causes an amino acidsubstitution in the peptide binding region of BiP/Kar2, andkar2-1 cells are likely to be defective in protein folding andERAD (Brodsky et al., 1999; Kimata et al., 2003). We found thatthe kar2-1 mutation accelerated degradation of most of the Rot1-substrateproteins, viz. Kre6, Big1, Drs2, and Gup1 (Figures 4B, 5B, 7C,and 8C), which suggests that BiP/Kar2 is also involved in theirfolding. Although the kar2-1 mutation alone did not seem toaffect the stability of Kre5, the rot1-2 kar2-1 double mutationcaused a rapid degradation of Kre5 (Figure 6B). The combinationof rot1-2 and kar2-1 also enhanced degradation of Drs2 (Figure 7C).In the case of Big1, kar2-1 apparently stabilized this proteinin a rot1-2 background, perhaps due to inhibition of ERAD (Figure 5B).

If Rot1 and BiP/Kar2 cooperate in protein folding, we wouldexpect them to simultaneously associate with the substrate proteins.To detect this potential ternary complex, cells were treatedwith a membrane-permeable and thiol-cleavable cross-linker,DSP, lysed, and double-immunoprecipitation was performed againstRot1 first and then BiP/Kar2. Kre6 was detected in the secondimmunoprecipitant (Figure 9, lane 4), indicating that Rot1,BiP/Kar2, and Kre6 form a ternary complex. The ternary complexwas also detected in the rot1-2 cells (Figure 9, lane 5). Theseresults strongly suggest that Rot1 cooperates with BiP/Kar2in the folding of Kre6.

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Figure 9. Rot1 forms a ternary complex with BiP/Kar2 and Kre6. ROT1 and rot1-2 cells expressing HA-Kre6 (YM41 and YM42) were incubated for 10 min at 37°C, dissociated in PBS, and treated with 10 mM NaN₃ and 2 mM DSP (or the vehicle, DMSO only) for 1 h at 37°C. Double immunoprecipitation was performed against Rot1 first and then Kar2. Nonimmune serums (n.i.) were used for negative controls. The second immunoprecipitants were analyzed by Western blotting using anti-HA and anti-Kar2 antibodies.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In this report, we provided evidence showing that Rot1 functionsas a molecular chaperone in the ER. A molecular chaperone transientlyinteracts with unfolded proteins to inhibit their aggregationand support their folding and/or assembly. The recombinant Rot1protein prevented aggregation of denatured proteins in vitro(Figure 1, B and C), indicating that Rot1 can bind directlyto unfolded proteins. The rot1-2 mutation partially impairedthis function in vitro (Figure 1, B and C), and observationsin vivo also implied it (Figures 4D and 5D). Therefore, interactionwith unfolded proteins probably underlies the function of Rot1in cells. Moreover, cellular levels of six proteins in the secretorypathway were lower in the rot1-2 mutation (Figures 2, 6D, 7A,and 8A). As for five of these proteins, we demonstrated thatthe rot1-2 mutation accelerates degradation, which at leastfor three of them depends on the Ubc7-mediated ERAD pathway(Figures 4B, 5B, 6B, 7C, and 8C). These findings strongly suggestthat Rot1 stabilizes these proteins by supporting their foldingand/or assembly. In addition, we demonstrated a physical interactionof Rot1 with four of those Rot1-dependent proteins (Figures 4D,5D, 6C, and 7D). In particular, Rot1 was found to transientlyassociate with newly synthesized Kre6 (Figure 4E). Taken together,we propose that Rot1 functions as a molecular chaperone thatdirectly and probably transiently interacts with nascent unfoldedproteins and assists in their folding and/or assembly.

The Rot1-dependent proteins presented in this study are listedin Table 3. It should be noted that they display different properties.They include a soluble protein, and type I and II and polytopicmembrane proteins. Their subcellular localizations and functionsare diverse, and each of the proteins is categorized into differentfamilies. Considering together that Rot1 directly interactswith two model denatured proteins in vitro, we propose thatRot1 is a general chaperone. As described above, informationabout the dependency of the substrate proteins on individualchaperones is also important to understanding protein foldingin a cell. In our study, Kre6 stability was severely affectedby the rot1-2 mutation, suggesting that Kre6 is an obligatesubstrate of Rot1. On the other hand, Big1, Kre5, Drs2, andGup1 each exhibited different dependencies on Rot1. We alsofound that some proteins may be folded independent of Rot1.Although Drs2 and Pmr1 are both P-type ATPases, only Drs2 wasdependent on Rot1 (Figure 7 and Supplemental Figure 1). Moreover,we previously reported that CPY was normally folded in rot1-2single mutant cells (Takeuchi et al., 2006a). Therefore, wesuggest that Rot1 functions with some specificity in the cells,as do Hsp90 and the eukaryotic chaperonin. It is unlikely thatall of the Rot1-client proteins inevitably require Rot1 fortheir folding. Nevertheless, Rot1 is an essential protein, andwe believe that Rot1 plays a unique role(s) in protein foldingin the ER. To illustrate Rot1-dependent protein folding in vivomore comprehensively, large-scale identification and examinationof the substrate proteins using a proteomic approach such thatof Kerner et al. (2005) and Jessop et al. (2007) would be desirable.

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Table 3. Rot1-depending proteins examined in this study

Although the mutant rot1-2 protein exhibited impaired substratebinding, this defect was not complete, and the rot1-2 proteinmay be partially active. Therefore, the dependency of proteinssuch as Big1, Kre5, Drs2, and Gup1 on Rot1 may be underestimatedin this study comparing rot1-2 to wild-type cells. It is alsopossible that there are other proteins with functions redundantto Rot1 caused. We previously demonstrated that deletion ofCNE1, LHS1, or SCJ1 aggravates the defective growth phenotypeof rot1-2 cells, and conversely, that overexpression of eachof them partially rescues it (Takeuchi et al., 2006a

). Proteinsencoded by these genes are ER-resident chaperones and may sharepartially redundant function(s) with Rot1. We have also reportedthat the rot1-2 kar2-1 double mutation causes temperature-dependentsynthetic lethality (Takeuchi et al., 2006a

). In this study,we showed that BiP/Kar2 is also required for the folding ofRot1-dependent proteins, except for Kre5 (Figures 4B, 5B, 6B,7C, and 8C) and that Rot1 and BiP/Kar2 interact with Kre6 simultaneously(Figure 9). These findings suggest that Rot1 and BiP/Kar2 playdistinct roles and cooperate in the folding of Kre6 and possiblyother proteins. On the other hand, the additive effects of therot1-2 and kar2-1 mutations on destabilization of Kre5 and Drs2imply partial functional redundancy of Rot1 and BiP/Kar2.

Recently, three reports from other groups have reported possiblefunctions of Rot1. Orlowski et al. (2007) reported that multicopyexpression of ROT1 suppressed the sec59-1 mutation. Sec59 isan ER-localized polytopic membrane protein that functions asa dolichol kinase. We speculate that Rot1 can support the correctfolding of the mutant sec59-1 protein. Second, Juanes et al.(2007) reported that in a Rot1-depleted cells, apical growthof bud and septum formation were perturbed. It is likely thatthese phenotypes are the secondary effects of misfolding and/ordestabilization of Rot1-client proteins, because in their experiments,the cells were incubated for more than 6 h under conditionswhere Rot1 was depleted. Drs2 and its family members have beenhypothesized to generate a biased distribution of aminophospholipidsbetween the two leaflets of the lipid bilayer, and this maybe important for assembly of the cortical actin patch requiredfor apical bud growth (Kishimoto et al., 2005). In addition,Kre6 was shown to interact with the actin patch assembly proteins,Las21 and Sla1, through its cytoplasmic tail (Li et al., 2002).We speculate that a decrease in Drs2, Kre6, and other Rot1-dependentproteins collectively could cause abnormalities in actin patchassembly and septum formation. Finally, Nakamata et al. (2007)reported that an essential, ER membrane protein, Keg1, interactswith Kre6 and that overexpression of ROT1 suppresses the temperature-sensitivegrowth defect of the keg1-1 mutant. As they suggested, it ispossible that Rot1 chaperones the mutant keg1-1 protein and/orindirectly supports its function by chaperoning Kre6. As describedabove, Rot1 was initially reported as a protein involved incell wall 1,6-β-glucan synthesis, but importantly, thesepleiotropic phenotypes of the rot1 mutation and overexpressionof ROT1 are consistent with our idea that Rot1 is a generalchaperone.

We have shown here that Rot1 functions as a molecular chaperoneand acts together with BiP/Kar2 in some cases. Hsp70 cofactorssuch as Hsp40 possess chaperone activity and bind to substrateproteins together with Hsp70. At the same time, Hsp70 cofactorsgenerally regulate the ATPase activity of Hsp70. We speculatethat Rot1 cooperates with BiP/Kar2 in a similar manner. CanRot1 bind BiP/Kar2 directly and regulate its ATPase activity?This is an important question to be addressed in future studies.Although Rot1 homologues are found only in yeast species, theremay exist a protein(s) having functions similar to Rot1 in theER of higher eukaryotes, because some of the Rot1-client proteinsare evolutionally conserved. Alternatively, Rot1 may meet therequirements specific to the yeast ER. Large-scale identificationof Rot1 substrates and a detailed analysis of Rot1 functions,including possible cooperation with BiP/Kar2, will deepen ourunderstanding of protein folding in the ER.

ACKNOWLEDGMENTS

We thank Drs. Akihiko Nakano (The University of Tokyo, Riken),Satoshi Harashima (Osaka University), and Koji Yoda (The Universityof Tokyo) for the yeast strain, plasmid and antibody, respectively.We are grateful to Junko Iida, Hisayo Masuda, and Miki Matsumurafor technical assistance. M.T. thanks all members of Kohno'slaboratory for helpful discussions and everyday conversation.This work was supported by Grants-in-Aids for Scientific Researchon Priority Areas (14037240, 19058010 to K. K., 18050024 toY. K.) and for 21st Century COE Program from MEXT, and JSPS.KAKENHI(18570179 to Y.K.).

Footnotes

This was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/italic) on May 28,2008.

Address correspondence to: Kenji Kohno (kkouno{at}bs.naist.jp)

Abbreviations used: CHX, cycloheximide; CPY, carboxypeptidase Y; DSP, dithiobis(succinimidyl)propionate; EndoH, endoglycosidase H; ER, endoplasmic reticulum; ERAD, ER-associated degradation; GPI, glycophosphatidylinositol; Hsp, heat-shock protein; HC, immunoglobulin heavy chain; IP, immunoprecipitation; n.i., nonimmune serum.; PI, protease inhibitor.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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