Ydj1 Protects Nascent Protein Kinases from Degradation and Controls the Rate of Their Maturation

Ydj1 is a Saccharomyces cerevisiae Hsp40 molecular chaperonethat functions with Hsp70 to promote polypeptide folding. Weidentified Ydj1 as being important for maintaining steady-statelevels of protein kinases after screening several chaperonesand cochaperones in gene deletion mutant strains. Pulse-chaseanalyses revealed that a portion of Tpk2 kinase was degradedshortly after synthesis in a ydj1 ${Delta}$ mutant, while the remainderwas capable of maturing but with reduced kinetics compared tothe wild type. Cdc28 maturation was also delayed in the ydj1 ${Delta}$ mutant strain. Ydj1 protects nascent kinases in different contexts,such as when Hsp90 is inhibited with geldanamycin or when CDC37is mutated. The protective function of Ydj1 is due partly toits intrinsic chaperone function, but this is minor comparedto the protective effect resulting from its interaction withHsp70. SIS1, a type II Hsp40, was unable to suppress defectsin kinase accumulation in the ydj1 ${Delta}$ mutant, suggesting some specificityin Ydj1 chaperone action. However, analysis of chimeric proteinsthat contained the chaperone modules of Ydj1 or Sis1 indicatedthat Ydj1 promotes kinase accumulation independently of itsclient-binding specificity. Our results suggest that Ydj1 canboth protect nascent chains against degradation and controlthe rate of kinase maturation.

INTRODUCTION

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INTRODUCTION

Molecular chaperones prevent polypeptides from misfolding andpromote acquisition of the folded state. In their absence, nascentpolypeptides or proteins that become unfolded aggregate or becometargeted for degradation via the ubiquitin proteasome pathway(22). Hsp70 is a molecular chaperone that functions early inprotein folding process by interacting with nascent polypeptidechains cotranslationally or immediately after translation. Hsp70functions in association with cochaperones that facilitate thecycle of nascent chain binding and release. Cochaperones thatpromote polypeptide loading are members of the Hsp40 family(12, 15). Those that stimulate polypeptide dissociation functionin nucleotide exchange and belong to several structurally distinctprotein families (1, 25, 28, 46).

Hsp40 chaperones comprise a large and diverse protein family(12, 15). Each member has a conserved "J" domain that functionsin stimulating Hsp70's ATPase. Members of type I and type IIHsp40s also interact with unfolded proteins and help to loadthem onto Hsp70. Once a polypeptide is bound to Hsp70, the Hsp40J domain stimulates Hsp70's ATPase, which helps stabilize theinteraction by leading to closure of a helical lid structureover the polypeptide binding site. Binding of unfolded polypeptidesto Hsp70 or Hsp40s is via hydrophobic interactions, and thisprevents polypeptide aggregation (18). Polypeptide release iscatalyzed by nucleotide exchange factors that facilitate releaseof ADP from Hsp70, allowing for ATP binding and opening of thelid retaining the polypeptide in the chaperone client-bindingsite. Cycles of binding and release, catalyzed by Hsp40 andnucleotide exchange factors, can promote folding and preventaggregation.

In addition to preventing aggregation, chaperones also functionin the degradation of misfolded proteins by the proteasome.Inhibition of Hsp90, for example, leads to ubiquitination anddegradation of many protein kinases and several nuclear receptors(52). Hsp90 is required in yeast for degradation of heterologouslyexpressed proteins that are not folded by this chaperone, suggestingthat it has distinct roles in both folding and degradation (38).In mammalian cells, chaperones promote degradation via interactionwith the E3 ubiquitin ligase, Chip, which binds to both Hsp70and Hsp90 via tetratricopeptide motifs (14, 39). Chip integratesthe quality control process by regulating heat shock factor-dependentgene expression and also acting itself as a chaperone (16, 44).

The mechanisms underlying chaperone and cochaperone functionin targeting polypeptides toward the proteasome are not wellunderstood, although a common factor is Hsp70. Several geneticand biochemical studies have shown that Hsp70 is important forthe degradation of misfolded cytosolic proteins (4, 38, 40).Hsp40s cooperate with Hsp70 in this process, based on the findingthat YDJ1 and HLJ1 promote the degradation of cytosolic andmembrane bound polypeptides (30, 40, 54). The results from biochemicalstudies support the view that Hsp40s promote degradation. Forexample, endoplasmic reticulum-associated degradation of misfoldedmembrane proteins is promoted by Hdj2, a Ydj1 ortholog (57).A more direct targeting function has been discovered for a neuronalHsp40, Hsj1, which interacts directly with polyubiquitin chainsvia a ubiquitin interaction motif, and promotes ubiquitinylationof polypeptides in association with Chip (51).

Protein kinases represent a class of protein whose folding isdependent on the Hsp90 and Cdc37 in addition to the Hsp70/Hsp40chaperone pair (9). Using in vitro chaperone-kinase assemblyreactions, Arlander et al. demonstrated that chaperones bindto a misfolded kinase in a sequential manner, beginning withHsp70/Hsp40 (2). The interaction of these chaperones with themisfolded kinase was required for subsequent Cdc37 binding,which led to Hsp90 recruitment. This final step is also promotedby the Hsp organizing protein called Hop, which acts as bridgebetween Hsp70 and Hsp90 (2, 31, 32). Cdc37 interacts primarilywith the kinase N-lobe, while Hsp90 interacts with both N-lobeand C-lobe of a kinase catalytic subunit (42, 59). Complementarystudies using yeast genetics identified similar chaperone componentsfor kinase folding (17, 29, 31, 32) and showed that Cdc37 hasa general role in kinome biogenesis in addition to protectingnascent kinase chains from degradation during or shortly aftertranslation (36). In addition to the folding of nascent kinases,molecular chaperones also function to maintain the mature stateof mutant kinases, such as oncogenic forms of Src or Lck (26,53).

In the present study, we screened for chaperones that affectedkinase steady-state levels in a similar manner to Cdc37. Ydj1,a yeast type I Hsp40 chaperone was identified as having sucha role. We demonstrate here that Ydj1 protects a cohort of kinasessimilar to that protected by Cdc37. Our findings support thehypothesis that Ydj1 protects nascent chains during or immediatelyafter synthesis and contrasts with other studies showing thatthis Hsp40 promotes degradation. In addition, we show that newlysynthesized protein kinases that escape triage in ydj1 ${Delta}$ cellsare largely protected from further degradation but fold slowlyfor a period of up to 2 h.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Strains and plasmids. In the present study we used yeast strains from the TAP-taggedlibrary (Open Biosystems, Huntsville, AL) based on strain S288C(MATa his3 ${Delta}$ 1 leu2 ${Delta}$ 0 met15 ${Delta}$ 0 ura3 ${Delta}$ 0) (24). The strain genotype wasverified by PCR analysis using primers specific to the tag andkinase gene of interest. The yeast ydj1 ${Delta}$ and erg6 ${Delta}$ knockout strainswere constructed by introducing KanMX4 module as described earlier(36). In the ydj1 and erg6 double mutant, YDJ1 was replacedby URA3 and ERG6 replaced by KanMX4.

The H34Q mutant was prepared from pRS315-Ydj1. Amino acid substitutionwas performed by using a QuikChange site-directed mutagenesiskit (Stratagene, La Jolla, CA). The mutation was confirmed byDNA sequencing. pGAL-Ydj1 was constructed by excising a 1.3-kbEcoR1 fragment from pAV2 (8) and ligating into the low-copy-numbervector pSEYc58GalP containing the GAL1-10 promoter. Plasmidsexpressing YDJ1, SIS1, YSY, and SYS in pRS315 were kindly providedby Doug Cyr (University of North Carolina, Chapel Hill). pRS317-ydj1 ${Delta}$ G/Fwas a gift from E. Craig (University of Wisconsin, Madison).Ydj1 ${Delta}$ G/F was subsequently subcloned into pRS315 by using Not1and Xma1. The plasmid expressing Escherichia coli dnaJ was describedpreviously (7).

Solubility assay. Cells expressing TAP-tagged kinases were grown at 30°C,harvested, washed once with sterile water, and resuspended in500 µl of 20 mM Tris (pH 7.5), 150 mM NaCl, 1 mM dithiothreitol,1 mM phenylmethylsulfonyl fluoride, and 0.1 mg of pepstatinA/ml. Cells were lysed by bead beating and clarified by centrifugationat 16,000 x g for 10 min at 4°C. A portion (150 µl)of this supernatant was kept aside as total protein, and another150 µl was spun in a Beckman TLA45 rotor at 100,000 xg for 30 min at 4°C. The supernatant was removed and designatedas the soluble fraction. The pellet was washed once with thebuffer described above and solubilized with 200 µl of1x sodium dodecyl sulfate (SDS) sample buffer. Then, 50 µlof 4x SDS sample buffer was added to the total-protein and soluble-fractionsamples. Equal amounts of each fraction were analyzed by SDS-polyacrylamidegel electrophoresis, followed by immunoblot analysis with anti-TAPantibody (Open Biosystems).

Western blot analysis. Western blot analysis was performed on whole-cell extracts preparedin IPP150 (10 mM Tris-HCl [pH 8.0], 150 mM NaCl, 0.1% NP-40)or in 50 mM Tris (pH 7.5)-0.1 mM EDTA-1% SDS plus Complete proteaseinhibitor (Boehringer Mannheim) by glass bead lysis. The steady-statekinase level was quantified by Odyssey Li-Cor image processingsoftware. Galactose induction experiments shown in Fig. 5 wereconducted by growing cultures in raffinose (2%) overnight. Cultureswere diluted to an A₆₀₀ of 0.2 and supplemented with eithergalactose or glucose (2% [vol/vol]), followed by incubationfor 8 h with shaking at 30°C before extract preparationas described above.

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FIG. 5. Effect of Ydj1 on the stability of nascent protein kinases under conditions that promote their degradation. (A) Effect of GA treatment on the stability of TAP-Slt2 kinase in wild-type and ydj1 ${Delta}$ cells, as indicated. Chase times are given in hours after pulse-labeling in the absence and presence of 50 µM GA. (B) Quantitation of Slt2 based on the data shown in panel A and other data (n = 3 ± the standard error). (C) Pulse-chase analysis of TAP-Tpk2 in the absence and presence of 50 µM GA in ydj1 ${Delta}$ cells. The chase times are indicated in hours. Mature (M) and immature (I) forms of Tpk2 are indicated. (D) Pulse-chase analysis of TAP-Tpk2 from cells containing pGAL-YDJ1 under noninducing condition (glucose; Glu) and inducing conditions (galactose, Gal). The lower panel shows pulse-chase results for Tpk2 in cells containing galactose but not the pGAL-YDJ1 plasmid. (E) Western blot analysis of Ydj1 protein before and after overexpression using the same cultures as in panel D. Pgk1 is shown as a loading control. (F) Effect of YDJ1 overexpression on TAP-Slt2 stability in the presence of GA (50 µM). Inducing and noninduced states are as described in panel D.

Polyclonal antisera to Hsp90, Ydj1, and Sis1 were describedpreviously (8, 35, 43). Hsp70 mouse monoclonal antisera waspurchased from Stressgen (spa-822). Antisera to E. coli dnaJwas kindly provided by Ulrich Hartl. Anti-TAP was purchasedfrom Open Biosystems.

Pulse-labeling. Pulse-labeling and immunoprecipitations were performed as describedpreviously (5).

Kinase assays. Kinase assay of wild-type and ydj1 ${Delta}$ cells expressing TAP-taggedforms of Tpk2 and Rim11 were performed as described previously(36). Briefly, wild-type and ydj1 ${Delta}$ strains were grown overnightat 30°C in 100 ml of synthetic complete medium (minus histidine)to log phase. Cell extracts were prepared in IPP150 buffer,and the amount of protein was quantified by using Bradford reagent.Tpk2 was immunoprecipitated from 0.1 to 0.5 mg of extract fromwild-type cells and from 3 mg of extracts from ydj1 ${Delta}$ mutant cells.The cell extracts were diluted to 0.45 ml in IPP150 and incubatedwith 50 µl of 50% (vol/vol) immunoglobulin G-Sepharoseresin (GE) for 1 h at 4°C. The resin was washed and dividedinto two aliquots. One aliquot was used for the kinase assay,while the other was used for Western blot analysis with anti-TAP.The Western blots were quantified by using a Li-Cor Odysseyinfrared detection system. Kinase assays for Tpk2 were performedby using a Pep-Tag nonradioactive protein kinase assay kit andquantified by spectrophotometry of agarose gel slices as describedby the manufacturer (Promega), while Rim11 was assayed by measuringits ability to phosphorylate myelin basic protein (Upstate Biotechnology)and quantified by phosphorimaging.

RESULTS

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RESULTS

Ydj1 influences the steady-state levels of protein kinases. We searched for molecular chaperones and cochaperones besidesCdc37 that could affect the levels of yeast protein kinases,starting with C-terminal TAP tagged Tpk2, a homologue of mammaliancAMP-dependent protein kinase (PKA). The chaperones or cochaperonesAHA1, CPR6, CPR7, HCH1, SBA1, SSE1, STI1, and YDJ1 were deletedfrom strains expressing a TAP-TPK2. These genes encode proteinsthat modulate Hsp90's ATPase activity (e.g., Aha1, Hch1, Sti1,and Sba1), act as chaperones (Cpr6, Cpr7, Sba1, Sse1 and Ydj1),and/or have peptidyl prolyl isomerase activity (Cpr6 and Cpr7[37, 41]).

Tpk2 levels were assessed by Western blotting in comparisonto a wild-type strain, using Pgk1 as a loading control. Theresults demonstrated that only upon deletion of the Hsp40 chaperoneYDJ1 were Tpk2 levels reproducibly lowered compared to the wildtype (Fig. 1A and data not shown). Reduction in kinase levelswas associated with increased amounts of Hsp90 and Hsp70, althoughPgk1 levels were unaffected by any of the chaperone deletions.Similar reductions in kinase levels and increases in Hsp90/Hsp70were observed in a ydj1 ${Delta}$ strain expressing TAP-Rim11 (Fig. 1B).These increases suggest that deletion of YDJ1 promotes a stressresponse in these cells.

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FIG. 1. Effect of YDJ1 deletion on protein kinase levels. (A) Steady-state level of Tpk2 in wild-type and ydj1 ${Delta}$ yeast cells; (B) Rim11 in wild-type and ydj1 ${Delta}$ cells. Wild-type and ydj1 ${Delta}$ yeast cells were grown overnight at 30°C and kinases identified with anti-TAP. Western blots of the same samples were performed with anti-Pgk1, anti-Ydj1, anti-Hsp70, and anti-Hsp90. Pgk1 levels are shown as a loading control. (C) Steady-state levels of kinases in ydj1 ${Delta}$ strain. The results are expressed as the percentages of levels in wild-type cells in each case based on Western blot analysis. The bars indicate the standard deviation from three to four independent experiments. WT, wild type.

In a previous study we analyzed 65 different kinases for stabilityin a yeast strain mutated for CDC37, a chaperone essential forprotein kinase folding (36). Among the 65 kinases tested, 51had reduced levels compared to those present in the wild-typestrain. We therefore tested a sampling of kinases that wereunstable or stable in the cdc37 mutant for a similar phenotypein the ydj1 ${Delta}$ mutant. For these experiments we analyzed Cdc28,Cmk1, Fus3, Pho85, and Slt2 as examples of kinases that wereunstable in the cdc37 mutant, and Cmk2 and Snf1 as kinases thatwere stable. Prs5, a component of ribosylphosphotransferase,was added to this analysis as an example of a kinase-relatedprotein that was unaffected by mutation in CDC37. In accordwith results from the cdc37 mutant, we observed that Cdc28,Cmk1, Fus3, Pho85, and Slt2 had reduced levels in the ydj1 ${Delta}$ mutant(Fig. 1C). The mean reduction was $~$ 2-fold, but Fus3 levels werereduced the most at 6-fold compared to the wild type. Strikingly,kinases that were stable in the cdc37 mutant, Cmk2, and Snf1displayed the least dependence on Ydj1 for their steady-statelevels. Cmk2 steady-state levels were completely unaffectedby the loss of Ydj1. Prs5, which was unaffected by mutationin CDC37, was reduced in the ydj1 ${Delta}$ mutant.

The fate of residual Tpk2 kinase that was synthesized and stablein a ydj1 ${Delta}$ mutant was addressed in two ways. First, we investigatedwhether the kinase accumulated in a soluble form or whetherit aggregated. Lysates containing Tpk2 synthesized in the presenceor absence of Ydj1 protein were centrifuged at 100,000 x g for1 h. A small enrichment of Tpk2 was observed in the pellet fractionin the ydj1 ${Delta}$ mutant, although the vast majority of the kinasewas soluble. Next, we determined the specific activity of Tpk2synthesized in the ydj1 ${Delta}$ mutant. Since there was less Tpk2 atsteady state in the ydj1 ${Delta}$ mutant compared to the wild type, wefirst generated a standard curve of Tpk2 activity from the wild-typestrain (Fig. 2B). The specific activity of a single concentrationof Tpk2 isolated from the ydj1 ${Delta}$ mutant was then determined bycomparison with the standard curve. As shown in Fig. 2B, thespecific activity of Tpk2 in both strains was similar, althoughslightly reduced in the ydj1 ${Delta}$ mutant. Therefore, Tpk2 is capableof acquiring the native state in the absence of Ydj1, but inreduced amounts. Similar findings were recorded for Rim11, whichalso has a very similar specific activity when derived fromwild-type or ydj1 ${Delta}$ mutant strains, although its steady-statelevels are reduced in the absence of Ydj1 (Fig. 1 and 2C).

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FIG. 2. Solubility and activity of protein kinases in ydj1 ${Delta}$ mutant strains. (A) Solubility assay of Tpk2 kinase. The solubility of Tpk2 was assayed in wild-type and ydj1 ${Delta}$ cells by comparing equal amounts of total lysate (T), supernatant (S), and pellet (P) fractions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting. The same blot was analyzed with anti-Hsp70, anti-Pgk1, and anti-Atp2, which encodes the β subunit of the mitochondrial F1 ATPase. (B) Tpk2 activity in wild-type and ydj1 ${Delta}$ mutant strains. The upper panel shows the Tpk2 activity after immunoprecipitation of the kinase from various amounts of wild-type extract (expressed in milligrams) and from a 3-mg portion of extracts from ydj1 ${Delta}$ cells. The panel shows the fluorescence from a labeled peptide whose migration in an agarose gel depends on phosphorylation by immunoprecipitated Tpk2. The lower panel shows the amount of Tpk2 in each reaction as determined by Western blotting. The bar graph at the right shows the quantitation of Tpk2 activity after normalization to the amount of enzyme in the assay. Bars indicate the standard error of the mean values of three independent experiments. (C) Assay of Rim11 activity. The upper panel shows Western blot results of TAP-Rim11 immunoprecipitates and the amount of ³²P-labeled myelin basic protein (MBP) used in the assay. The panel on the right shows the MBP data quantified. Bars represent the standard error (n = 3). WT, wild type.

Ydj1 affects the rate of protein kinase maturation. Previous studies showed that Cdc37 protects newly made proteinkinases from degradation either during or shortly after translation(36). Since Ydj1 functions upstream of Cdc37 in in vitro kinase-chaperoneassembly reactions (2), it seemed likely that Ydj1 might behavein similar manner, especially given that both chaperones interactwith the same cohort of protein kinases.

We addressed the role of Ydj1 in biogenesis of newly translatedTpk2 and Cdc28 by pulse-chase analysis. For Tpk2, pulse-chaseexperiments revealed the presence of two distinct bands afterdenaturing gel electrophoresis (Fig. 3A). Based on previousstudies with mammalian PKA, these represent immature (inactive,nonphosphorylated; faster migrating) and mature (active, autophosphorylated;slower migrating) conformers (56). This was verified with phosphatasetreatment of ³⁵S-labeled wild-type cell extracts, which resultedin partial conversion of Tpk2 from the slow-migrating form tothe fast-migrating form (PKA is relatively resistant to phosphatasetreatment) (47). Mammalian PKA autophosphorylates in cells attwo sites: Ser197 and Ser338 (27). The former is in the activationloop and is necessary for enzyme activity, while the latterfacilitates stabilization of the kinase N-lobe (3, 56). It islikely, therefore, that the immature form of the kinase is anunstable conformer.

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FIG. 3. Pulse-chase analysis of Tpk2 kinase in the wild type and the ydj1 ${Delta}$ mutant. (A) Pulse-chase analysis of TAP-tagged Tpk2 in wild-type (YDJ1) and ydj1 ${Delta}$ mutant cells. The chase times are indicated in minutes. (B) Pulse-chase analysis of wild-type cells after a 2-min pulse and chase from 0 to 10 min. (C) Pulse-chase analysis of TAP-Tpk2 in ydj1 ${Delta}$ cells. Cells were treated with dimethyl sulfoxide or 100 µM MG132 for 30 min before labeling. The strain background is erg6 ${Delta}$ , which improves MG132 permeability. The chase times are indicated in minutes. Mature (M, phosphorylated) and immature (I, nonphosphorylated) forms of Tpk2 are denoted by arrows. The relative amounts of mature and immature kinase in each lane were quantified, and the numbers appear below the panel.

In the wild-type strain, the faster-migrating form of Tpk2 isa minor component after a 10-min pulse-labeling that disappearsafter 30 min of chase. In the ydj1 ${Delta}$ mutant, there is a lowerlevel of Tpk2 after the pulse, a finding consistent with decreasedlevels found at steady state (Fig. 3A). Also, the faster-migratingband is more prominent at zero time of chase and appears toconvert into the slower-migrating band over the 2-h chase time.This interpretation is based on the apparent decrease in faster-migratingband intensity and an increase in the amount of the slower-migratingband after 30 min of chase. The faster-migrating band then slowlydisappears over the next 90 min (Fig. 3A and C). The relationshipbetween the two forms of Tpk2 was investigated further in wild-typecells using short (2 min) pulse-labeling and chase reactions(Fig. 3B). Under these conditions, most Tpk2 was in the faster-migratingform after the short pulse that converts to the slower-migratingmature form completely within 10 min. In ydj1 ${Delta}$ cells this conversiontakes 60 to 120 min (Fig. 3A and C).

When the pulse-chase reaction was performed in the ydj1 ${Delta}$ strainwith the proteasome inhibitor MG132 (Fig. 3C), we noted increasedTpk2 levels after the pulse compared to the dimethyl sulfoxide-treatedsample. This suggests that some nascent Tpk2 is targeted fordegradation rapidly after translation in a manner similar tothat of the quality control we observed in a cdc37 mutant strain.In addition, the ratio of immature to mature Tpk2 was clearlyaltered in the two samples at 30 min of chase. In the MG132-treated sample, there were increased amounts of immature kinase,suggesting that some of the nascent Tpk2 was targeted for degradationin absence of Ydj1. However, it is also clear that a large proportionof the immature kinase managed to adopt the mature state after120 min of chase, even in the presence of MG132. This showsthat, in the absence of Ydj1, the nascent Tpk2 fate is in thebalance, with some being susceptible to degradation while mostcan adopt the mature state.

A similar function for Ydj1 in affecting the rate of proteinkinase maturation was characterized for Cdc28 (Fig. 4). In thiscase, there were similar levels of kinase produced after pulse-labelingin both wild-type and ydj1 ${Delta}$ mutant strains. However, Cdc28 inthe ydj1 ${Delta}$ mutant had a slower migration at zero time of pulseand quantitatively converted into a faster migrating band after30 min. In wild-type cells, Cdc28 always appears as the faster-migratingband, even after pulse-labeling. Based on previous studies withCdc28 (20, 23) and mammalian Cdk2 (6), the slower-migratingband is the immature, nonphosphorylated form, whereas the faster-migratingband results from phosphorylation with the Cdk activating kinase,Cak1. Note that the immature and mature forms of Cdc28 are theinverse of those observed for Tpk2. Importantly, Ydj1 does notappear to affect the levels of nascent Cdc28 after pulse-labelingas dramatically as does mutation in CDC37 (compare Fig. 4A toFig. 6A), only the rate with which it is converted from theimmature form to the mature form. However, the kinase does appearto be degraded to some extent over the 2 h of chase, a findingconsistent with the decrease we observed under steady-stateconditions. These studies were conducted with nontagged Cdc28,but similar findings were made with TAP-Cdc28 (Fig. 4C). Thesecombined studies show that Ydj1 functions to protect nascentkinases from degradation and also functions to promote efficientfolding and/or maturation. The effect of Ydj1 on the rate ofmaturation is remarkable. In wild-type cells both Cdc28 andTpk2 are almost quantitatively in the mature state within the10-min pulse-labeling period. In the absence of Ydj1, its takesup to 2 h for Tpk2 to become fully mature, while for Cdc28 thefully mature state was generated within 30 min.

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FIG. 4. Pulse-chase analysis of Cdc28. (A) Pulse-chase analysis of untagged Cdc28 immunoprecipitated with anti-PSTAIRE (which recognizes a peptide in the ${alpha}$ -C helix) in wild-type and ydj1 ${Delta}$ mutant cells. Chase times are indicated in minutes. Cdc28 is denoted by arrow. The band labeled with an asterisk is nonspecific. The inset shows the difference in mobility of Cdc28 at 0 and 30 min of chase time. I, immature form of Cdc28; M, mature form. (B) Quantitation of Cdc28 levels in wild-type (WT) and ydj1 ${Delta}$ cells after phosphorimaging. The results are expressed as the percentages of the levels in wild-type cells at 0-min chase. Bars indicate the standard deviations of three independent experiments. Bars: ${blacksquare}$ , wild type; , ydj1 ${Delta}$ mutant. (C) Pulse-chase analysis of TAP-tagged Cdc28 in wild-type and ydj1 ${Delta}$ cells as described above.

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FIG. 6. Ydj1 protects against degradation of unstable Cdc28 in a cdc37 mutant strain. (A) Pulse-chase analysis of Cdc28 in wild-type and cdc37^S14A mutant cells without or with overexpression of YDJ1 or the mutant ydj1^H34Q. Chase times are given in minutes. Immature (I) and mature (M) forms of Cdc28 are indicated. The band labeled with an asterisk is nonspecific. (B) Quantitation of the data shown in panel A. Symbols: •, wild type; ${blacksquare}$ , cdc37^S14A mutant; ${blacktriangleup}$ , cdc37^S14A mutant with YDJ1 overexpressed; ${circ}$ , cdc37^S14A mutant with ydj1^H34Q overexpressed. (C) Western blot analysis of Cdc28 in wild-type and cdc37^S14A mutant cells (S14A) either with (+) or without (–) YDJ1 overexpression. The lower panel shows the Ydj1 levels. The band labeled with an asterisk is nonspecific. WT, wild type.

Ydj1 protects nascent kinases against degradation promoted by Hsp90 inhibition or mutation in CDC37. Previous analyses of Ydj1 suggested that it promotes polypeptidedegradation (30, 40, 54), whereas in our case it appears toprotect newly synthesized kinases from this same fate. We thereforeaddressed the extent of Ydj1's protective function in nascentprotein kinase quality control using other models that enhancedegradation. The first model involved use of the Hsp90 inhibitor,geldanamycin (GA), which promotes degradation of nascent kinasesin yeast (9, 36). For Slt2 kinase, we observed that GA treatmentresulted in a modest decline in kinase levels over a 2-h period(Fig. 5A and B). In contrast, Slt2 levels were reduced by ca.80% in the presence of GA in ydj1 ${Delta}$ cells. These findings showthat Ydj1 protects Slt2 from degradation when Hsp90 is inhibited.Tpk2, in contrast, is degraded in the presence of GA in wild-typecells or ydj1 ${Delta}$ mutant cells to a similar extent (compare Fig.5C with the glucose panel in Fig. 5D).

Previous studies have noted differential degradation of kinasesin GA-treated cells derived from human tumors and healthy tissues(11, 48, 58), but the underlying basis for this has never beenfully established. One possibility is that chaperones controllingkinase degradation could be modulated. To test this, we extendedthe findings presented above by analyzing whether YDJ1 overexpressionhad any further capability to protect nascent kinases from degradationin the presence of GA. YDJ1 was inducibly overexpressed froma galactose-regulated promoter in wild-type cells for theseexperiments (Fig. 5D and E). In the presence of glucose, whichrepressed YDJ1 overexpression, GA promotes the degradation ofTpk2 over a 2-h period as described previously (36). However,this effect was suppressed by YDJ1 overexpression (Fig. 5D,middle panel). This effect was not due to galactose replacingglucose in the medium since galactose by itself did not influencethe degradation of Tpk2 in the presence of GA (Fig. 5D, lowerpanel). A similar finding was made for Slt2 kinase (Fig. 5F).Ydj1 is therefore not saturating for its capacity to protectnascent protein kinases from degradation in the presence ofGA. For Tpk2, the protective action for Ydj1 in the presenceof GA appears to be a gain of function since deletion of thechaperone did not influence GA-dependent kinase degradation(Fig. 5C and D).

The studies described above place Ydj1 in a similar role toCdc37 as a protector of nascent kinases. We next explored whetherthese roles were redundant with each other. If this were so,then overexpression of YDJ1 might suppress degradation occurringdue to mutation in CDC37. Our model for these studies utilizeddegradation of Cdc28 in the cdc37^S14A mutant. As shown in Fig.6A, Cdc28 is degraded rapidly in the cdc37^S14A mutant, as describedpreviously (36). In contrast, YDJ1 overexpression from a multicopyplasmid results in a reduced rate of degradation of Cdc28 inthe cdc37^S14A mutant (Fig. 6A and the quantification shown inFig. 6B). Importantly, a similar finding was observed when theydj1^H34Q mutant was similarly overexpressed in the cdc37^S14Amutant (Fig. 6A and B). The ydj1^H34Q mutant contains a pointmutation in the J domain that inhibits interaction of Ydj1 withHsp70 (49). The ability of ydj1^H34Q to phenocopy wild-type Ydj1suggests a direct role for Ydj1 in chaperoning nascent kinasesthat is independent of Hsp70. In contrast, overexpression ofeither the YDJ1 or the ydj1^H34Q mutant in cdc37^S14A only delaysthe degradation of Cdc28, it does not completely prevent it.This is revealed by the failure of Cdc28 to achieve the maturestate when YDJ1 is overexpressed in cdc37^S14A in the pulse-chaseanalysis (Fig. 6A and data not shown). Furthermore, Westernblot analysis of Cdc28 shows that its levels are only marginallyhigher in the cdc37^S14A mutant overexpressing YDJ1 (Fig. 6C).These findings suggest that Ydj1 has overlapping functions withCdc37 in stabilizing nascent kinases. The overlapping functionis manifest in the way Ydj1 delays Cdc28 degradation in thecdc37^S14A mutant, although it clearly fails to promote maturation.This is probably related to Cdc37 chaperone function directlyor indirectly in recruiting Hsp90.

Specificity of Ydj1 function in protein kinase maturation. The experiments described above suggest a model in which Ydj1protects nascent kinases in association with Cdc37. In addition,Ydj1 contributes to the rate of kinase maturation. The resultsof experiments with ydj1^H34Q suggested a model in which thechaperone action of Ydj1 functioned to protect nascent kinasesindependently of Ydj1's interaction with Hsp70 (Fig. 6A and B).However, when Tpk2 levels were assayed in the ydj1 ${Delta}$ strain expressingydj1^H34Q from a low-copy-number plasmid (Fig. 7A), they weresimilar to those found in the ydj1 ${Delta}$ mutant alone. Similar findingswere made when Tpk2 maturation was followed by pulse-chase analysis(data not shown). This indicates that under normal conditions,Ydj1 function in Tpk2 maturation involves Hsp70.

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FIG. 7. Steady-state TAP-Tpk2 levels in ydj1 mutants. (A) Western blot analysis of TAP-Tpk2 (Tpk2) in wild-type and ydj1 ${Delta}$ cells without or with the ydj1^H34Q mutant expressed from a low-copy-number plasmid. The middle panel shows Ydj1 levels, and the lower panel shows the levels of Pgk1 as a loading control. (B) Western blot analysis of wild-type and ydj1 ${Delta}$ mutants without or with overexpression of SIS1. The middle panel shows the levels of Pgk1 as a loading control, while the lower panel shows the levels of Ydj1 and Sis1. (C) Western blot of TAP-Tpk2 in wild-type and ydj1 ${Delta}$ cells with or without Sis1, YSY, and SYS chimeric chaperones as indicated. The middle panel shows Pgk1, and the lower panel shows the levels of Sis1 and Ydj1/Sis1 chimeras using anti-Sis1. (D) Effect of Ydj1's G/F region in kinase accumulation. Tpk2 levels were analyzed in wild-type and Ydj1 ${Delta}$ G/F-expressing cells in a ydj1 ${Delta}$ background. (E) Effect of bacterial DnaJ in kinase accumulation. The Tpk2 levels were measured after overexpression of DnaJ in wild-type and ydj1 ${Delta}$ yeast strains. DnaJ expression was carried out after induction with galactose for 8 h. Tpk2 was identified with anti-TAP antibody. The kinase levels were quantified and are shown as a percentage of the wild-type levels. Western blot anlayses with the same samples were performed with anti-Pgk1, anti-DnaJ, and anti-Ydj1. Pgk1 levels served as a loading control. WT, wild type.

To further address the relationship between Ydj1 and Hsp70 inkinase maturation, we overexpressed the type II Hsp40, Sis1,in the ydj1 ${Delta}$ mutant. Previous studies showed that Sis1, a typeII Hsp40, partially suppressed the slow-growth phenotype ofa ydj1 ${Delta}$ mutant (8); accordingly, Sis1 may compensate for theloss of Ydj1 in kinase biogenesis. However, SIS1 overexpressionwas largely unable to suppress reduced levels of Tpk2 in theydj1 ${Delta}$ mutant strain (Fig. 7B). This finding suggested some specificityin the way in which Ydj1 and Hsp70 promote kinase maturation.

Both Ydj1 and Sis1 have distinct chaperone modules that areexchangeable and can specify Sis1 or Ydj1 action in a chimera(19). When we assayed these chimeras, however, those containingthe Sis1 chaperone module (YSY; where Y represents Ydj1 domains,and S represents the Sis1 chaperone domain) were more effectiveat suppressing the loss of Tpk2 than those containing the Ydj1chaperone module (SYS; Fig. 7C). These findings with Sis1 andSis1/Ydj1 chimeras suggest that the relationship between Ydj1and Hsp70 for kinase folding is more complex than expected.They cannot be attributed just to J-domain regulation of Hsp70'sATPase or to specificity in polypeptide-binding by Ydj1. Similarly,deletion of the Ydj1 G/F domain, which separates the J domainfrom the chaperone-binding module, had little effect on Tpk2maturation (Fig. 7D).

Finally, we investigated whether the specificity of Ydj1 couldbe retained by another type I dnaJ protein with the same domainorganization. We analyzed E. coli dnaJ for this purpose, whichis similar to Ydj1, although it is missing the farnesylationmotif. The expression of dnaJ led to complete suppression ofthe ydj1 ${Delta}$ phenotype for Tpk2 and resulted in even greater levelsof kinase in both wild-type and ydj1 ${Delta}$ strains, suggesting itis a more effective chaperone (Fig. 7E). These combined resultsprovide insight into the importance of the C-terminal and perhapsdimerization domains of type I Hsp40s in protecting nascentchains from degradation, while the farnesylation of the Ydj1,which helps to anchor it to membranes (10), is not requiredfor this function.

DISCUSSION

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DISCUSSION

As polypeptide chains emerge from the ribosome, they interactwith several chaperone machines. Among these are componentsof the RAC complex, which includes ribosome-binding Hsp70 andHsp40 chaperones that promote efficient polypeptide translation(50). Other members of the Hsp70 and Hsp110 families also participatein nascent chain binding (55). More specific chaperones interactwith nascent chains from distinct protein families, such asCdc37, which protects nascent protein kinases from rapid degradationby the proteasome. In the present study, we characterized thetype I Hsp40, Ydj1, as also having a protective role in proteinkinase biogenesis at the earliest stages posttranslation. Ydj1also has a role in kinase biogenesis that is distinct from Cdc37,by controlling the rate of kinase maturation as well as theyield of mature kinase.

Ydj1's ability to protect nascent protein kinases results froma direct effect and an indirect one via Hsp70. Of the two, itis the latter that has the greatest contribution to stabilizingprotein kinases. In the cdc37^S14A mutant, overexpression ofwild-type YDJ1 or the mutant ydj1^H34Q led to a temporary stabilizationof Cdc28. Since the ydj1^H34Q mutant cannot interact with Hsp70,these findings suggest that the intrinsic chaperone functionof Ydj1 promoted the stabilization, albeit weakly. Furthermore,the overall effects of expressing ydj1^H34Q in place of wild-typeYdj1 were negligible at steady state for Tpk2 (Fig. 7A), suggestingthat Hsp70 binding is required for complete protection againstdegradation. As noted previously, Ste11 kinase synthesized ina ydj1 ${Delta}$ mutant had decreased amounts of bound Hsp70 (32), reinforcingthe notion that Ydj1 interacts with nascent kinases in orderto protect them, but this effect must be integrated with subsequentbinding to Hsp70 to avoid degradation. Notably, Hsp90 and Cdc37could still bind to Ste11 even in a ydj1 ${Delta}$ strain (32). Such bindinglikely represents a quality control step in kinase maturationthat is at least partially distinct from that managed by Ydj1.This is because even in the absence of Ydj1 there is a strongeffect of GA in promoting kinase degradation (Fig. 5C). Thesedata therefore point to a role for both Hsp70 and Hsp90 chaperonemachines in protecting newly synthesized kinases from degradation,as well as helping them to fold. Interestingly, both chaperonesare upregulated in cells with YDJ1 deleted (Fig. 1).

The notion that both Hsp70 and Hsp90 contribute to kinase stabilityfits with our finding that Tpk2 degradation is biphasic. Thefirst phase is during the 10-min pulse-labeling period, in amanner similar to the way in which Tpk2 is degraded in the cdc37mutant (36). Like Cdc37, therefore, Ydj1 protects nascent chainsand, in its absence, the newly made kinase is largely directedtoward the ubiquitin/proteasome system. Tpk2 that escapes initialtriage either folds slowly or is subsequently degraded in aslower process. We did not observe the fast degradation of Cdc28in a ydj1 ${Delta}$ strain, a finding consistent with a similar findingfor the cdc37 mutant (Fig. 6) (36). Instead, there is a delayin Cdc28 maturation, followed by a slow decrease in kinase levels.For both Cdc28 and Tpk2, however, the rate of kinase degradationis much more pronounced in the cdc37 mutant than in the ydj1 ${Delta}$ strain. Despite this difference, Ydj1 and Cdc37 both contributein a similar manner to the folding process; each stabilizesnascent kinases and helps promote binding to another chaperone,Hsp70 in the case of Ydj1 and Hsp90 in the case of Cdc37. AlthoughYdj1 is an abundant protein, it is still limiting in its capacityto protect newly synthesized kinases. When overexpressed, Ydj1promotes greater stability of Tpk2 and Slt2 kinases in the presenceof GA. Similarly, overexpressed Ydj1 or ydj1^H34Q delayed thedegradation of unstable Cdc28 in cdc37^S14A mutant cells (Fig.5 and Fig. 6).

Although our results provide strong support for a protectiverole for Ydj1 in kinase biogenesis, this is not a universalfunction. There have been several published reports showingthat there is reduced degradation of unstable proteins in amutant of YDJ1 called ydj1-151 (30, 40, 54). However, we foundthat the expression of ydj1-151 largely suppressed the effectof complete YDJ1 deletion and led to the accumulation of foldedTpk2 as measured by enzyme activity (data not shown). Our model,therefore, is that Ydj1 functions to promote kinase foldingbut is not involved in targeting misfolded kinases to the degradationmachinery, at least under nonstress conditions.

Besides acting to protect nascent kinases, Ydj1 also affectsthe rate at which maturation takes place. This effect occurredin ydj1 ${Delta}$ and ydj1^H34Q mutants (Fig. 3 and data not shown), indicatingthat the effect depends more on the relationship between Ydj1and Hsp70 than on the intrinsic chaperone action of Ydj1 itself.The basis for the reduced rate of kinase maturation in the ydj1mutations, however, remains obscure. One possibility relatesto the finding that ydj1 mutants grow slowly and thus have reducedrates of metabolic processes. However, pulse-chase analysesof Tpk2 maturation in other chaperone mutants that grow slowly(cpr7 ${Delta}$ and sse1 ${Delta}$ ) suggested that this is not the case (not shown).

The ability of Ydj1 to protect nascent kinases has some specificitysince SIS1 overexpression was unable to suppress defects inkinase biogenesis in a ydj1 ${Delta}$ mutant. The lack of suppressionoccurs despite the finding that SIS1 overexpression can improvegrowth of ydj1 ${Delta}$ cells (8). Furthermore, the growth of ydj1 ${Delta}$ cellscan be improved by just increasing the abundance of the J domain,suggesting that impairment to Hsp70's functional cycle is themain factor that limits growth of ydj1 ${Delta}$ cells (45). Tests ofwhich domains impart the functional specificity were largelynegative but demonstrated that the chaperone modules specificto type I and type II Hsp40s were not responsible (Fig. 7).Further support for this view derives from the finding thatmammalian Hdj2 (type I) and Hsp40 (type I) are interchangeablefor their function in folding of progesterone receptor and Chk1protein kinase (13, 21). Based on this, the specificity withwhich we observed Ydj1 function may have more to do with howSis1 is unable to interact with kinases or nuclear receptorsin the presence of Hsp70. Previous studies showed that Ydj1is capable of refolding luciferase in association with Hsp70in vitro, whereas Sis1 does not function as efficiently in thiscapacity (34). The basis for their differential function isdue in part to each having a distinct chaperone module, whichcan specify the function of Sis1 or Ydj1 in chimeric molecules(19). We note, however, that Sis1 also has a more stable interactionwith the Hsp70 C terminus than does Ydj1 (33). The C-terminalregion of Hsp70 interacts with the peptide-binding groove inthe chaperone module of Sis1, suggesting that there could becompetitive interactions. This might preclude Sis1 binding tonascent kinases in the presence of Hsp70. We speculate thatsuch binding of Hsp70 to the Sis1 chaperone module is disruptedin the YSY chimera and that this is why it proves so effectivecompared to Sis1 alone (Fig. 7).

In conclusion, our combined findings suggest a model in whichYdj1 has two specific functions in protein kinase folding. Thefirst involves protecting the newly synthesized kinase chainfrom degradation, and the second involves promoting efficientfolding and maturation. Ydj1 by itself can protect nascent kinases,but not to the same extent that it can in association with Hsp70.The unexpected finding that Ydj1 can affect the rate of kinasematuration presents a new paradigm for its action in cellularquality control.

ACKNOWLEDGMENTS

We thank Doug Cyr, Betty Craig, Costa Georgopolis, and UlrichHartl for providing plasmids and antisera used in this study.We also thank Maria Theodoraki, Doug Cyr, and Jeff Brodsky fordiscussions and insight and Paul Lee for initial contributionsto the study.

This study was supported by NIH grant GM70596.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biology, City College New York, Convent Avenue at 138th Street, New York, NY 10031. Phone: (212) 650-8614. Fax: (212) 650-8585. E-mail: acaplan{at}sci.ccny.cuny.edu

Published ahead of print on 28 April 2008.

REFERENCES

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