©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
A Conserved HPD Sequence of the J-domain Is Necessary for YDJ1 Stimulation of Hsp70 ATPase Activity at a Site Distinct from Substrate Binding (*)

(Received for publication, October 17, 1995; and in revised form, February 7, 1996)

Joyce Tsai (§) Michael G. Douglas (¶)

From the Department of Biochemistry and Biophysics, School of Medicine, University of North Carolina at Chapel Hill, Chapel Hill, North Carolina 27599

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The 46-kDa protein YDJ1 is one of several known yeast homologues of the Escherichia coli DnaJ protein. Like all J homologues, it shares homology with the highly conserved NH(2)-terminal ``J-domain'' of DnaJ. A component of the DnaK (Hsp70) chaperone machinery that mediates protein folding, DnaJ is necessary for survival at elevated temperatures. It stimulates ATP hydrolysis by DnaK and effects the release of DnaK-bound polypeptides. Previous genetic and biochemical studies indicate that the J-domain is necessary for these functions. Using peptides corresponding to J-domain sequence, we show that a peptide containing the highly conserved His-Pro-Asp sequence at positions 34-36 in the J-domain competes off YDJ1 stimulation of Hsp70 ATPase activity. Inhibitory concentrations of peptide do not prevent binding of folding substrates, therefore YDJ1 must interact with Hsp70 at a site distinct from that for substrate binding. This interaction is critical for Hsp70 activity, since a mutant YDJ1 protein harboring a H34Q change (ydj1Q34) stimulates neither Hsp70 ATPase nor substrate release. The importance of the proper function of this region of the protein is supported by the poor growth and temperature-sensitive phenotype of yeast expressing ydj1Q34.


INTRODUCTION

The heat shock family of proteins (Hsps) (^1)include members now known to function as molecular chaperones. These Hsps bind nascent polypeptides as they emerge from cytosolic ribosomes (Beckmann et al., 1990; Nelson et al., 1992), escort fully translated proteins to their destinations in cellular organelles, maintain them in a transport-competent partially unfolded state (Deshaies, 1988), and are necessary on both sides of the membrane for the efficient transport of proteins into mitochondria (Cheng et al., 1989; Kang et al., 1990; Caplan et al., 1992a) and endoplasmic reticulum (Vogel et al., 1990; Scherer et al., 1990; Nguyen et al., 1991). The roles of chaperones in protein folding have been extensively studied (for recent review, see Hartl et al.(1992)). There are two major chaperone families identified as mediators in protein folding. First, the Hsp70s bind short (7-9-amino acid) sequences of extended polypeptides (Flynn et al., 1991). Second, the Hsp60s bind to emergent secondary structures on folding proteins (Landry and Gierasch, 1991). Neither the Hsp70s nor the Hsp60s act alone; they require co-chaperones, which modulate their activities (Georgopoulos et al., 1990).

YDJ1 is a co-chaperone protein in Saccharomyces cerevisiae which modulates the activity of Hsp70 (Cyr et al., 1992). It shares extensive homology to the Escherichia coli protein DnaJ and is one of several homologues of DnaJ identified in yeast. Each of the homologues has evolved to occupy a specific niche in the eukaryotic cell. Whereas YDJ1 is largely cytosolic and endoplasmic reticulum membrane-associated (Caplan and Douglas, 1991), SIS1 is predominantly nuclear and cytosolic ribosome-associated (Luke et al., 1991), SCJ1 is found in the endoplasmic reticulum matrix (Schlenstedt et al., 1995), MDJ1 is associated with the mitochondrial inner membrane (Rowley et al., 1994), SEC63 is an endoplasmic reticulum integral membrane protein (Sadler et al., 1989), Zuotin is nuclear and possesses DNA binding properties (Zhang et al., 1992), and CAJ1 is membrane-associated and appears to bind calmodulin (Mukai et al., 1994). Another J homologue, XDJ1, is either a silent gene or transcribed under unknown conditions (Schwarz et al., 1994). The common feature of all of these proteins which defines them as J homologues is homology to the NH(2)-terminal 80 amino acids of DnaJ protein. This sequence is defined as the J-domain. Whereas SEC63, Zuotin, and CAJ1 share only this J-domain, the other yeast homologues, including YDJ1, share homology and structural features with DnaJ elsewhere in the protein as well (Caplan et al., 1993). Presumably, each eukaryotic J homologue is specialized to perform, within its cellular environment, one or a few of the many known functions of DnaJ. Of the yeast homologues, YDJ1 and SCJ1 are most closely related to DnaJ (Caplan et al., 1993). However, YDJ1 is distinguished among the homologues by being farnesylated (Caplan et al., 1992b).

The prototype J homologue, DnaJ, was first identified as a gene product necessary for -phage replication in E. coli and has been cloned and sequenced (Bardwell et al., 1986; Ohki et al., 1986). Since its initial characterization, DnaJ has been shown to act in conjunction with the E. coli Hsp70 prototype, DnaK, and a third protein, GrpE. Together, this trio participates in such diverse functions as -phage replication (Osipiuk et al., 1993; Hoffmann et al., 1992), plasmid P1 replication (Sozhamannan and Chattoraj, 1993; Wickner et al., 1992), chromosomal DNA replication (Hupp and Kaguni, 1993), folding of nascent polypeptides (Hendrick et al., 1993), export of fully translated polypeptides from the bacterium (Wild et al., 1992), the repair of heat-induced protein damage (Schroder et al., 1993; Ziemienowicz et al., 1993), and the assembly of macromolecular complexes in flagellum synthesis (Shi et al., 1992). In the folding of nascent polypeptides and denatured proteins, DnaK binds and releases extended hydrophobic regions, preventing protein misfolding (Langer et al., 1992). Each cycle of binding and release is dependent upon ATP hydrolysis, at which DnaK is slow. DnaJ stimulates the ATP hydrolytic activity of DnaK, allowing a completed cycle of peptide binding and release, whereas GrpE acts as a nucleotide exchanger, promoting continued cycles of activity (Liberek et al., 1991a). Interestingly, DnaJ also possesses chaperone ability in its own right; a recent report suggests that DnaJ binds polypeptides first, recruiting DnaK for subsequent binding (Henrick et al., 1993).

Recent genetic and biochemical evidence supports the long standing idea that the conserved J-domain of DnaJ and its homologues mediates interaction with DnaK and cognate Hsp70s. Mutations in this region prevent function of SEC63 in conjunction with the endoplasmic reticulum Hsp70, Kar2 (Scidmore et al., 1993). In E. coli, characterization of the dnaJ259 mutant that cannot support -phage replication (Sell et al., 1990) revealed a single amino acid change in a highly conserved region within the J-domain. The NH(2)-terminal 108 amino acids of DnaJ alone, containing the full J-domain, are sufficient to support -phage replication and to stimulate DnaK ATP hydrolysis (Wall et al., 1994).

Previous work from this laboratory demonstrated that YDJ1 stimulates the ATPase activity of and polypeptide substrate release from its most likely cytosolic cognate Hsp70, SSA1 (Cyr et al., 1992). In the present study, we have used synthetic peptides corresponding to J-domain sequence to compete with purified YDJ1 protein to ask which regions specifically interact with Hsp70 to stimulate these activities. One such region was identified, mutagenized, and tested in for in vivo effects and in vitro activity.


MATERIALS AND METHODS

Peptides

Peptides were synthesized in the University of North Carolina/Program in Molecular Biology and Biotechnology microprotein chemistry facility located in the Department of Microbiology, University of North Carolina School of Medicine, using Fmoc chemistry in a Rainin (Woburn, MA) Symphony multiple peptide synthesizer. Polyethylene glycol-polystyrene resins and appropriately protected Fmoc amino acids were purchased from Millipore (Marlborough, MA). After cleavage and deprotection, the peptides were precipitated in ice-cold ether, lyophilized, and purified by reverse phase HPLC (Waters Chromatography, Milford, MA) on a 10-mm times 25-cm W-Porex C(18) column (Phenomenex, Torrance, CA) using a gradient of 0.1% trifluoroacetic acid with increasing acetonitrile. Column eluent was monitored simultaneously at 214 and 254 nm, and peaks were collected and analyzed by fast atom bombardment mass spectroscopy.

Nine peptides corresponding to the YDJ1 sequence (Caplan and Douglas, 1991) were synthesized. Four 20-mers, p1-20, p21-40, p41-60, and p61-80, span the NH(2)-terminal 80 amino acids of YDJ1. Additionally, pYHPD, X(3)YHPDX(3), and YHPDX correspond to amino acids 33-36, 30-39, and 33-52, respectively. p21-40H34Q sequence was identical to p21-40 with the exception that glutamine was substituted for histidine at position 34. Two peptides containing the YDJ1 COOH-terminal sequence were designated pSASQ and pC-farnesyl. pSASQ was a 13-mer comprised of the COOH-terminal amino acids encoded by the YDJ1 nucleotide sequence, with the exception that serine was substituted for cysteine at amino acid 406. pC-farnesyl was a 10-mer corresponding to the COOH terminus of the mature protein and was farnesylated before use in competition experiments.

Farnesylation of pC-farnesyl was performed chemically. (^2)A 1.2 molar ratio of farnesyl bromide (Aldrich) diluted in 2 µl of dimethyl sulfoxide was added to 0.3 mg of peptide dissolved in 70% CH(3)CN, 70 mM NaHCO(3). The reaction proceeded for 4 h at 4 °C, after which farnesylated peptide was separated from nonfarnesylated peptide, farnesyl bromide, and farnesyl hydroxide by reverse phase HPLC (10-mm times 25-cm Selectosil C(18), 300 Å, Phenomenex) using a gradient of 32-100% CH(3)CN, 0.1% trifluoroacetic acid, over 70 min. pC-farnesyl eluted at 43 min. The column eluent was monitored at 254 nm.

Protein Purification

Hsp70 was purified from the yeast strain MW141 as described previously (Cyr et al., 1992). MW141 (MATa, ura3-52, leu2-3, 112, his3-11, 15, ssa1::HIS3, ssa2::LEU2, ssa4::URA3, pGAL1-SSA1) is a strain engineered to overproduce SSA1. This strain was grown to late log phase overnight in YPgal medium at 30 °C. After harvesting, the cells were resuspended in 50 mM HEPES, pH 7.4, 500 mM NaCl, 10 mM DTT, 2 mM MgCl(2), 0.5 mM EDTA, 1 mM phenylmethylsulfonyl fluoride, 10 µM leupeptin, 10 µM pepstatin. Cells were disrupted by agitation with 0.5-mm glass beads using 6 times 30-s bursts in a Beadbeater (Biospec). Following a 100,000 times g spin, the extract was loaded onto ATP-agarose (Sigma 2767) equilibrated in lysis buffer. After washing with 3 volumes each of lysis buffer and low salt (20 mM NaCl) buffer, bound proteins were eluted using 3 mM ATP in low salt buffer. Fractions containing Hsp70 were identified using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Coomassie Blue staining. The peak was then directly loaded onto DEAE-cellulose (Whatman DE52) equilibrated in 50 mM HEPES, pH 7.4, 10 mM DTT, and 1 mM phenylmethylsulfonyl fluoride. After washing with 5 column volumes of buffer, bound proteins were eluted using a linear 0-500 mM NaCl gradient. Fractions containing SSA1p were then pooled and dialyzed against 5 mM sodium phosphate, pH 7.0, 10 mM DTT, 0.5 mM EDTA, 1 mM phenylmethylsulfonyl fluoride (buffer A) before loading onto hydroxyapatite (Bio-Rad). The column was washed with 3 volumes of buffer, and bound proteins were eluted using a 5-400 mM sodium phosphate gradient. Peak fractions were pooled, concentrated, and dialyzed against 50 mM HEPES, pH 7.4, 50 mM NaCl, 10 mM DTT, 10% glycerol (buffer B), aliquoted, and snap frozen in liquid N(2) before storage at -80 °C.

YDJ1 and ydj1Q34 were purified as described previously (Cyr et al., 1992) from BL21(DE3) E. coli (Novagen, Madison, WI) containing pET9dYDJ1 (Caplan et al., 1992b) and pET9dYQPD, respectively. Cells were grown in LB + kanamycin at 37 °C until A = 1.0. Isopropyl-1-thio-beta-D-galactopyranoside was added to 0.5 mM, and induction proceeded for 2 h, after which cells were harvested and resuspended in ice-cold 20 mM MOPS, pH 7.5, 10 mM DTT, 0.5 mM EDTA, 1.0 mM phenylmethylsulfonyl fluoride, 10.0 µM leupeptin, and 10.0 µM pepstatin. After cell disruption by sonication, the lysate was cleared by centrifugation at 100,000 times g and loaded onto DE52 equilibrated with lysis buffer. The column was washed with 3 column volumes of buffer, and elution was performed using a 0-500 mM NaCl gradient over 20 volumes. Eluted protein was detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Coomassie staining of column fractions, pooled and dialyzed against buffer A, and separated using hydroxyapatite as described above. Purified YDJ1 or ydj1Q34 was then dialyzed against buffer B, aliquoted, and snap frozen in liquid N(2) before storage at -80 °C.

Mutagenesis

The ydj1Q34 allele was created by in vitro mutagenesis using 4-primer recombinant PCR technology (Higuchi, 1990) in which the T of codon 34 in the YDJ1 open reading frame was replaced by an A, changing the codon from histidine to glutamine. A 2.0-kilobase PCR product containing the ydj1Q34 open reading frame and upstream promoter region was cloned into the BamHI site of the low copy plasmid pRS314 (tryptophan selection) and termed pYQPD. Sequence analysis assured no unintentional PCR-introduced mutations. JOY4 was created by transforming pYQPD into yeast strain ACY95b. In this strain the chromosomal YDJ1 gene is replaced by HIS3; and YDJ1 is instead carried on a plasmid under uracid selection (Caplan and Douglas, 1991). His, Trp, Ura colonies were selected on 5-fluoroorotic acid (Sikorski and Boeke, 1991). JOY1 is the isogenic wild type strain and was described previously (Caplan et al., 1992b). General yeast methods followed those detailed in Guthrie and Fink(1991).

For overexpression in and purification from E. coli, a 1.3-kilobase PCR product comprising the open reading frame of ydj1Q34 was cloned in-frame behind the T7 promoter, into the NcoI and BamHI sites of pET9d (Novagen). The construct was then transformed into BL21(DE3), which contains the T7 polymerase gene under the control of the lacUV5 promoter (Studier et al., 1990). The resulting strain overexpressed ydj1Q34 upon induction with isopropyl-1-thio-beta-D-galactopyranoside, as roughly 30% of total protein. Overexpression of wild type YDJ1 in BL21(DE3) was described previously (Caplan et al., 1992b). General molecular biology methods followed those in Sambrook et al.(1989).

ATP Hydrolysis and Gel Shift Assays

To assay the ATPase activity of Hsp70in vitro, 50-µl reactions contained 10 mM HEPES, pH 7.4, 20 mM NaCl, 10 mM DTT, 1 mM MgCl(2), 100 µM ATP, and [alpha-P]ATP (Amersham Corp.). Purified proteins and peptides at indicated concentrations were pipetted on ice. The reaction mixtures were incubated for 15 min at 30 C, after which the reaction was stopped by placing the tubes on ice. Five µl of 0.1 mM ATP + 0.1 mM ADP was added to each reaction as fluorescent indicators of ATP and ADP migration. A 2-µl aliquot was removed from each tube and spotted, in duplicate, onto polyethyleneimine-cellulose F thin layer plates (EM Industries). Polyethyleneimine plates were developed using 1 M formic acid, 0.5 M LiCl. After drying, spots were visualized under UV light and excised, and radioactivity was quantitated by liquid scintillation counting. Average values for [alpha-P]ADP formation were normalized with respect to total counts for each sample and corrected for the rate of spontaneous ATP hydrolysis.

Nondenaturing gel shift assays were performed to assess the binding of substrate by Hsp70 as described previously (Cyr et al., 1992). Carboxymethyllactalbumin (CMLA, Sigma) was iodinated with NaI (ICN Radiochemicals) using the IODO-BEAD (Pierce) method according to the manufacturer's instructions and desalted on a G-25 column preblocked with bovine serum albumin. Radiolabeled CMLA was incubated with SSA1, YDJ1, ydj1Q34, and peptides at indicated concentrations, in 40-µl samples containing a reaction buffer of 50 mM HEPES, pH 7.4, 50 mM NaCl, 10 mM DTT, 1 mM ATP, 2 mM MgCl(2), 0.4% bovine serum albumin. After pipetting on ice, the reactions were incubated at 30 °C for 15 min. Reactions were stopped on ice, and 20 µl of ice-cold reaction buffer in 40% glycerol, 0.01% bromphenol blue was added to each sample. Thirty µl of each sample was loaded onto duplicate nondenaturing 7.5-15% acrylamide nondenaturing gels, which were run on ice at 10 mA/gel. Gels were dried and exposed to x-ray film. I-CMLA-SSA1 complexes were quantitated by densitometry (Molecular Dynamics)


RESULTS

The Hinge Region between Helices 2 and 3 of the J-domain Mediates Interaction with Hsp70

We initially used synthetic peptides representing different regions of the J-domain of YDJ1 to compete with YDJ1p for interaction with Hsp70. These experiments would identify regions within the J-domain which are necessary for stimulation of Hsp70. Four peptides that were 20 amino acids long were synthesized to span the first 80 amino acids of YDJ1: p1-20, p21-40, p41-60, and p61-80 (Fig. 1). Each of these peptides was incubated with purified Hsp70 in the presence and absence of YDJ1 under assay conditions to ascertain which peptides, if any, might compete off YDJ1-stimulated Hsp70 ATPase activity and/or stimulate ATPase activity in the absence of YDJ1. Of the four peptides, only p21-40 significantly reduced YDJ1-stimulated Hsp70 ATPase activity ( Fig. 2and Table 1). 0.5 µM SSA1 or 0.5 µM SSA1 + 1.0 µM YDJ1 were incubated with increasing amounts of either p1-20 or p21-40. At a 1:1 ratio of p21-40 to YDJ1, ATPase activity was reduced by roughly 50%. At a 50:1 ratio, only 21% of the initial YDJ1-stimulated increase in ATPase activity remained. By contrast, neither p1-20 (Fig. 2) nor the other two peptides reduced SSA1 ATPase activity (Table 1). Therefore p21-40 includes a J-domain sequence necessary for interaction with Hsp70, which alone is capable of competing with full-length YDJ1 for that interaction. None of the peptides alone could stimulate Hsp70 ATPase activity ( Fig. 2and data not shown).


Figure 1: YDJ1 structure and J-domain peptides. Panel A, amino acids 1-70 of YDJ1 comprise the J-domain, the presence of which defines it as a DnaJ homologue. This conserved J-domain is followed by a flexible glycine/phenylalanine-rich region between positions 80 and 104, four repeats of the motif CXXCXGXG between positions 143 and 207, and a region of lower homology, which are also present in DnaJ and some yeast homologues. Finally, the COOH terminus of YDJ1 is uniquely farnesylated. Panel B, the J-domain forms four alpha-helices in solution. Four peptides, p1-20, p21-40, p41-60, and p61-80, were designed to span the J-domain. Another four peptides, YHPD, YHPDX, X(3)YHPDx(3), and p21-40H34Q, were utilized to assess the role of amino acids 34-36 in YDJ1 function. p21-40H34Q contains the same sequence as p21-40 except for the substitution of glutamine for histidine at position 34.




Figure 2: Ability of p21-40 to reduce YDJ1-stimulated Hsp70 ATP hydrolysis. 0.5 µM purified SSA1 or 0.5 µM SSA1 and 1.0 µM YDJ1 was incubated with 0.0, 1.0, 10.0, 20.0, and 50.0 µM p1-20 or p21-40 in the presence of Mg and [alpha-P]ATP. ADP formation was determined after a 15-min incubation at 30 °C by spotting a 2-µl aliquot onto polyethyleneimine-cellulose, chromatographic separation, and quantitation of radioactivity in ADP- and ATP-containing spots. Results were normalized with respect to total counts in each sample and adjusted for spontaneous ATP hydrolysis. Neither p1-20 nor p21-40 stimulated SSA1 ATPase activity. However, p21-40 reduced ATP hydrolysis in the samples containing YDJ1, indicating that p21-40 might be competing with YDJ1 for interaction with SSA1 and that a sequence within amino acids 21-40 of the J-domain mediates this interaction. By contrast, no competition was observed for p1-20.





To identify candidate sequences within p21-40 which might mediate interaction with Hsp70, we considered both sequence conservation and the context within the predicted protein structure. Although the entire J-domain is quite highly conserved, the amino acids at positions 34-36 (HPD) are absolutely conserved between DnaJ and all of the known yeast homologues. Moreover, this sequence is situated in a loop or hinge region between the two alpha-helices that were initially predicted after sequence analysis of DnaJ (Bardwell et al., 1986). These helices might serve to present a conserved loop sequence for interaction with other proteins. To test the possibility that this conserved sequence could interact with Hsp70, three synthetic peptides from this region were used to compete with YDJ1p. A 4-mer with the sequence YHPD could not compete off YDJ1-stimulated ATPase activity. We examined the possibility that sequences within amino acids 21-32 were responsible for the reduction in ATPase stimulation by using the 20-mer pYHPDX in competition experiments. This peptide, corresponding to amino acids 33-52, exhibited a weak ability to compete compared with p21-40. This weak competition could not be attributed to amino acids 41-52, since p41-60 did not compete. Because amino acids 21-32 were not present on this peptide and because residues 37-41 are not well conserved, it seemed plausible that the HPD sequence was responsible for this competition. It was reasoned that the position of the conserved sequence within a competing peptide might be important. The 10-mer X(3)YHPDX(3) containing the candidate sequence nestled in the center was slightly better in competition experiments than YHPDX ( Fig. 3and Table 1). Thus, amino acids 34-36 of the J-domain, HPD, appear necessary but not sufficient for full stimulation of Hsp70 ATPase activity.


Figure 3: HPD peptide competition ATPase assays. Increasing amounts of peptides YHPD, YHPDX, and X(3)YHPDX(3) were added to samples containing 0.5 µM SSA1 and 1.0 µM YDJ1. Samples were incubated for 15 min at 30 °C, after which [alpha-P]ADP formation was assessed. An aliquot from each sample was removed for separation by thin layer chromatography and quantitation. Results were normalized for total counts in each sample, and the nonstimulated SSA1 activity was subtracted. The 4-mer was unable to compete with YDJ1 for interaction with SSA1. Somewhat longer HPD-containing peptides, however, could interact. Inclusion of a 100 molar excess of YHPDX reduced the YDJ1-stimulated SSA1 ATPase activity by 12%. Likewise, the 10-mer X(3)YHPDX(3) reduced the rate of ADP hydrolysis by 30%.



Previous data from this laboratory demonstrated that YDJ1 is farnesylated (Caplan et al., 1992b) and that Hsp70 is most likely to be YDJ1's partner in the yeast cytosol (Cyr and Douglas, 1994). Although farnesylation increases YDJ1 association with a membrane fraction following heat shock, this modification is known to mediate specific protein-protein interactions (Marshall, 1993). To test the possibility that COOH-terminal farnesylation of YDJ1 confers specificity of interaction with SSA1, two peptides corresponding to the COOH-terminal sequence were used in competition experiments. pSASQ contains the COOH-terminal 13 amino acids encoded by the nucleotide sequence, with the exception that amino acid 406 (the C of the CaaX box) is changed to serine. This substitution results in a TS phenotype (Caplan et al., 1992b) and defective transport of polypeptide precursors into organelles in vivo (Caplan et al., 1992a). pC-farnesyl corresponds to the farnesylated and proteolytically processed COOH terminus of YDJ1. Neither peptide showed any detectable competition of YDJ1-stimulated Hsp70 ATPase activity, even at peptide:YDJ1 molar ratios of 100:1.

J-domain and Hsp70 Interact at a Site Distinct from That for Polypeptide Substrate Binding

Although p21-40 was observed to reduce the YDJ1-stimulated ATPase activity of Hsp70, this could result from the peptide being bound as substrate and not by competing off YDJ1 stimulation. Different polypeptide substrates of Hsp70 have been observed to reduce ATPase activity, presumably by forming a stable complex, or to increase ATPase activity. (^3)We addressed whether p21-40 could compete with CMLA, a known synthetic substrate of Hsp70, for binding and also whether p21-40 could compete off the YDJ1-stimulated release of bound CMLA (Fig. 4). 0.0, 10.0, and 100.0 molar ratios of p1-20 and p21-40 were added to reactions containing 1.0 µMI-CMLA and 0.5 µM SSA1 with or without 1.0 µM YDJ1. After incubation, samples were separated by nondenaturing electrophoresis, and SSA1-bound CMLA was visualized by autoradiography and quantitated by densitometry. In these studies, p21-40 at molar ratios well above those that inhibit YDJ1-stimulated ATPase activity did not compete with I-CMLA for binding to the Hsp70 substrate site. Although 10 µM p1-20, 100 µM p1-20, and 10 µM p21-40 seemed to reduce Hsp70-bound CMLA (lanes 3, 5, and 7), this result was small and not always reproducible. Moreover, there was no further decrease of CMLA-SSA1 complex formation as the p21-40 concentration was increased to 100 µM (lane 9). This consistency in complex formation is not mirrored by constancy of CMLA release. Ten µM p1-20 had essentially no effect upon release (lane 4), although increasing the concentration of peptide to 100 µM did stabilize the CMLA-SSA1 complex (lane 6). Significantly, as little as 10.0 µM competing peptide p21-40 effectively blocked release of bound substrate (lane 8), and a large majority of CMLA remained bound to SSA when p21-40 was increased to 100.0 µM (lane 10). These results clearly indicate that p21-40 interacts specifically with SSA1 to compete off substrate release but does not affect substrate binding. They also demonstrate that YDJ1 must interact with SSA1 at a site distinct from that of polypeptide substrate binding. YDJ1 stimulates substrate release by a mechanism that does not include displacement of polypeptide substrate from Hsp70.


Figure 4: Peptide competition gel shift experiments. Nondenaturing gel electrophoresis and autoradiography were used to evaluate I-CMLA-SSA1 complexes in the presence of J-domain peptides (top panel). The star () marks the position of the CMLA-SSA1 complex. 1.0 µM radioiodinated CMLA was incubated with 0.5 µM purified SSA1 in the presence of Mg-ATP, forming a I-CMLA-SSA1 complex (lane 1). Inclusion of 1.0 µM YDJ1 stimulates release of CMLA from SSA1 (lane 2). J-domain peptides do not prevent formation of CMLA-SSA1 complex, as there is no significant decrease of complex with increasing peptide addition (lanes 3 and 5, 7, and 9). When added to samples containing YDJ1 as well, 10 µM p1-20 could not compete off the YDJ1-stimulated CMLA (lane 4), although 100 µM p1-20 could do so to some extent (lane 6). By contrast p21-40 appears to have a reproducible stabilizing effect on the complex at both 10 µM and 100 µM concentrations (lanes 8 and 10). These results were quantitated and confirmed by densitometry (bottom panel). Numbered lanes shown in the histogram correspond to those lanes scanned on the autoradiogram above. The amount of I-CMLA complex present in the absence of either peptide or YDJ1 (lane 1) was taken as 100% bound.



Characterization of JOY4

During the course of these experiments, Wall et al.(1994) reported that the NH(2)-terminal 108 residues of DnaJ containing the entire J-domain are both necessary and sufficient for interaction with DnaK. They also characterized the dnaJ259 mutant, which was deficient in both stimulation of DnaK activity and also in support of -phage replication. This mutant contained a histidine to glutamine change at residue 33, within the highly conserved HPD sequence. To examine the significance of this conserved region in the eukaryote, we created the analogous mutant in S. cerevisiae. Amino acid 34 was changed from histidine to glutamine with a base substitution using PCR-based site-directed mutagenesis, creating the allele ydj1Q34 (see ``Materials and Methods''). This allele was introduced into a ydj1 null background, resulting in JOY4. This strain was temperature-sensitive, exhibiting slow growth at 30 °C and no growth at 37 °C. The JOY4 doubling time in rich liquid media at 30 °C was 6 h, and there was no detectable growth in minimal liquid media (data not shown).

Characterization of ydj1Q34

To address directly the contribution of a single amino acid in the conserved HPD sequence to J-domain interaction with Hsp70, the ydj1Q34 allele was subcloned into an E. coli inducible expression vector and purified. Upon addition of up to 5.0 µM ydj1Q34 to 0.5 µM SSA1, there was essentially no increase in ATPase activity (Fig. 5). This is in contrast to the activity seen upon the addition of wild type YDJ1 protein, with which SSA1 ATPase activity achieved maximal stimulation by 1.0 µM.


Figure 5: Comparison of YDJ1 and ydj1Q34 stimulation of Hsp70 ATPase. To compare the ability of wild type YDJ1 and the mutant protein ydj1Q34 to stimulate SSA1, 0.5 µM purified SSA1 was incubated under assay conditions with either 0.5, 1.0, 2.0, or 5.0 µM ydj1Q34 or the same concentrations of ydj1Q34 and YDJ1. Samples were incubated for 15 min at 30 °C, after which a 2-µl aliquot was removed. [alpha-P]ADP and [alpha-P]ATP were separated by thin layer chromatography and quantitated. Values were normalized with respect to total counts in each sample. Because the ydj1Q34 preparation contained a small amount of contaminating ATPase, the values for ADP formation in control samples containing only the indicated concentrations of ydj1Q34 in reaction buffer were subtracted from each set of experimental samples. The mutated protein ydj1Q34 lacked the ability to stimulate Hsp70 even when present in 10-fold molar excess.



The ability of ydj1Q34 to stimulate substrate release and to compete with YDJ1 for substrate release was also examined. Ability to compete without ability to stimulate would indicate that binding of YDJ1 alone is not sufficient for the conformational change in SSA1 which results in peptide substrate release. Fig. 6shows that although a 2:1 molar ratio of YDJ1:SSA1 effects release of bound I-CMLA (lane 2), the same ratio of ydj1Q34 could not stimulate any release (lane 3). However, this inability does not stem from a total inability to bind to SSA1p. We observed that a 10-fold excess of ydj1Q34 could prevent YDJ1 stimulation of CMLA release from Hsp70 (lane 4).


Figure 6: ydj1Q34 gel shift experiments. 1.0 µM radiolabeled CMLA and 0.5 µM SSA1 were incubated under nondenaturing gel shift assay conditions alone and in the presence of either 1.0 µM YDJ1, 1.0 µM ydj1Q34, or 1.0 µM YDJ1 + 10.0 µM ydj1Q34. After a 15-min incubation at 30 °C, samples were separated on nondenaturing gels, which were then dried and exposed to x-ray film (top panel). After developing, the SSA1-CMLA complexes (as shown alongside the star) were quantitated by densitometry (bottom panel). Histogram bars correspond to gel lanes of the same number. The amount of I-CMLA-SSA1 complex in lane 1 was taken to be 100% bound. Although ydj1Q34 does not stimulate release of I-CMLA bound to SSA1 (lane 3), a 10-fold excess of ydj1Q34 (lane 4) can significantly reduce the amount of release effected by the wild type YDJ1 protein (lane 2).



These results indicate two possibilities: either that ydj1Q34 possesses a weaker affinity for Hsp70 or that ydj1Q34 possesses wild type affinity but that upon binding the mutant ydj1Q34 protein does not stimulate ATPase activity and substrate release. To distinguish between these two possibilities, we used peptide p21-40H34Q in competition experiments (Fig. 7). p21-40H34Q mimics the amino acid change in ydj1Q34 and is otherwise identical to p21-40. If ydj1Q34 affinity for SSA1 remains the same as that of the wild type YDJ1, then p21-40H34Q and p21-40 (wild type) should compete off the YDJ1-stimulated ATPase activity of SSA1 equally well. The addition of 50 µM p21-40 to a reaction mixture containing 0.5 µM SSA1 and 1.0 µM YDJ1 decreased maximal ATP hydrolysis by 72%; however, the addition of 50 µM p21-40H34Q achieved only a 35% reduction. These and the data in Fig. 6suggest that ydj1Q34 binds to SSA1 with less affinity than wild type YDJ1 and that the ydj1Q34-SSA1 interaction is not transduced into hydrolysis of ATP by SSA1 and release of bound polypeptide substrate. It appears that the conserved HPD of the J-domain is important to the binding of YDJ1 to SSA1 and is absolutely required for YDJ1 stimulation of SSA1 ATPase activity, which is in turn coupled to polypeptide binding and release.


Figure 7: pH34Q competition for Hsp70 interaction. SSA1 at 0.5 µM and YDJ1 at 1.0 µM were incubated in reaction buffer with 0.0, 10.0, 20.0, and 50.0 µM p21-40 (wild type (WT) sequence) or p21-40H34Q to determine whether they could reduce ATP hydrolysis equally well. Samples were incubated for 15 min at 30 °C, after which 2-µl aliquots were removed and spotted in duplicate onto polyethyleneimine-cellulose. After separation of [alpha-P]ADP and [alpha-P]ATP by thin layer chromatography, spots were visualized, excised, and counted. Plotted values were normalized for the number of total counts present in each sample and adjusted for the amount of nonstimulated SSA1 ATP hydrolysis. Although p21-40H34Q reduced YDJ1-stimulated ATPase activity to 65% of that in the absence of peptide, it could not compete off YDJ1 as effectively as the wild type sequence.




DISCUSSION

The result that YDJ1 interacts with SSA1 at a site distinct from that for peptide substrate binding is consistent with a current model proposing that in addition to stimulating Hsp70 ATPase activity, J homologues initially bind to some unfolded proteins and nascent polypeptides and recruit Hsp70 to its target substrates. DnaJ (Hendrick et al., 1993) and the yeast J homologues SIS1 (Zhong and Arndt, 1993) and YDJ1^3 associate with polysomes. DnaJ is known to initially bind and then recruit DnaK for binding to both the heat shock sigma factor, 32 (Gamer et al., 1992) and RepA protein (Wickner et al., 1992). Upon recruitment, the DnaK conformation is altered by interaction with DnaJ such that ATP hydrolysis is favored over ATP binding. Liberek et al. (1991b) have demonstrated using partial tryptic digests that DnaK undergoes different conformational changes in the presence of either ATP or DnaJ. In addition, wild type DnaJ can either prevent or quickly relax the ATP associated change in DnaK trypsin susceptibility, whereas the dnaJ259 mutant protein does not (Wall et al., 1994). If a J-protein acts to recruit Hsp70 to polypeptide substrates, then the J-protein effect on Hsp70 conformation must be concurrent with or precede binding of substrate peptide by Hsp70. The substrate binding site of Hsp70 therefore must be available to the peptide and not occupied by the J-protein.

In this study, the peptide p21-40 competes with YDJ1 for stimulation of SSA1 ATPase activity and CMLA release but does not prevent formation of the CMLA-SSA1 complex. This argues against any model that proposes that substrate release from Hsp70s results from direct displacement by J-proteins. It is possible, however, that J-protein interaction and peptide substrate binding may still be mutually exclusive because of differing conformations of Hsp70 for binding of either. Although p21-40 could not prevent binding of CMLA to SSA1 at concentrations that prevented release of bound CMLA, the 20-mer is unlikely to have had any effect on SSA1 conformation, since it could not alone stimulate SSA1 ATPase activity. Ydj1Q34 was able to interact with SSA1 to prevent YDJ1-stimulated release of CMLA in gel shift experiments; however, it too is unlikely to affect SSA1 conformation since it could not alone stimulate ATPase activity or peptide release. This is analogous to dnaJ259, which was shown to have reduced influence on DnaK conformation relative to wild type DnaJ. The conformational change in Hsp70 protein upon interaction with wild type J-proteins would result in two different populations of Hsp70 molecules, reflecting those that had interacted with J-proteins and those that had not. This may explain why we never observed complete reduction of SSA1 ATPase activity to basal levels in the presence of YDJ1 and a large excess of the competing peptide p21-40.

It is likely that other regions of the J-domain are also sites of interaction with Hsp70s. In our study, shorter HPD-containing peptides could not compete off YDJ1-stimulated Hsp70 ATPase activity, indicating that other residues must be necessary for YDJ1-Hsp70 binding. It was surprising that none of the other three J-domain peptides, p1-20, p41-60, and p61-80, exhibited any measurable effect on the YDJ1-stimulated increase in SSA1 ATPase activity, despite the presence of very highly conserved sequences throughout the J-domain spanned by these peptides. Recent publication of the the NMR structure for amino acids 2-108 of DnaJ suggests a model that accounts for the importance of both the HPD sequence in the interhelical hinge region and the selective pressure for sequence conservation along the rest of the J-domain. Two groups (Szyperski et al., 1994; Hill et al., 1995) found independently that in contrast to the predicted structure of two alpha-helices, the monomeric J-domain possesses four helices that interact strongly with one another to form a hydrophobic core. The two longer helices 2 and 3 associate with one another to present the conserved HPD in the interhelical loop. In this model, the sequence conservation in the helical regions of the J-domain preserves the precise interactions that determine the tertiary structure of the domain, which is necessary for presentation of the HPD sequence. While this manuscript was in review, several nonconserved positions within the J-domain were also identified as necessary for binding to Hsp70. These nonconserved residues serve to determine the specificity of J homologues for different Hsp70 molecules (Schlenstedt et al., 1995). Taken together, these data on the roles of conserved and nonconserved residues within the J-domain suggest that tertiary conformations are important for the presentation of specific residues necessary for recognition, binding, and stimulation. The 20-mer peptides p1-20, 41-60, and 61-80 are too short to attain these conformations. By contrast, p21-40 largely corresponds to a loop region. Because the J-domain is monomeric in solution, p21-40 cannot prevent YDJ1 stimulation of Hsp70 by disruption of the YDJ1 dimer.

That several nonconserved residues have been identified as necessary for J homologue binding to specific cognate Hsp70s suggests that the absolutely conserved HPD sequence is specifically required for stimulation of ATPase activity. This conclusion is supported by our demonstration that the ydj1Q34 mutant protein can prevent YDJ1-stimulated release of bound CMLA by Hsp70, despite its total lack of ability to stimulate either ATPase activity or substrate release on its own. The mutant protein was able to prevent CMLA release at lower ratios relative to YDJ1 than those required for competition by p21-40 peptide ( Fig. 4and Fig. 6and data not shown), thus suggesting that the full-length protein is capable of binding but not stimulating Hsp70. This ability of ydj1Q34 to bind Hsp70 nonproductively, as well as its solubility and purification characteristics, which are identical to those of the wild type YDJ1 protein, confirms that the mutant is not dysfunctional because of any misfolded structure.

It is noteworthy that amino acids 22-29 in the DnaJ from Clostridium acetobutylicum, KKAFRKLA (Behrens et al., 1993), are similar to a sequence of Raf kinase, RKTFLKLA, which may interact with -phosphate residues of ATP. (^4)Amino acids 23-30 of YDJ1, KKAYEKCA (Caplan and Douglas, 1991) and 22-29 of E. coli DnaJ, RKAYKRLA (Bardwell et al., 1986; Ohki et al. 1986) are less similar; however, it is tantalizing to speculate that this sequence present in helix 2 of the J-domain and represented in the competing peptide p21-40 may also have a role in regulating Hsp70 activity. If this is the case, then J-proteins would interact with Hsp70s at or near their catalytic ATPase domain.

It is now confirmed that the J-domain of DnaJ and a eukaryotic homologue, YDJ1, are necessary to effect a conformational change in Hsp70 leading to increased ATPase activity and peptide substrate release. What then, is the function of the remainder of the YDJ1 molecule, which shares other conserved domains with DnaJ? Szypersky et al.(1994) have shown that the glycine/phenylalanine-rich stretch immediately COOH-terminal to the J-domain of DnaJ is flexible in solution, possibly to allow proper orientation of the J-domain for interaction with DnaK. The zinc finger domain, containing four repeats of the motif CXXCXGXG, has an unknown function. Although DnaJ does function in DNA replication, there has been no demonstration of DNA binding capabilities. Moreover, this motif is conserved in the cytosolic protein YDJ1. Caplan et al. (1992a) have shown genetically that YDJ1 functions as a dimer; possibly this domain serves as a dimerization site. YDJ1 associates with membranes upon heat shock in a farnesylation-dependent manner (Caplan et al., 1992b); however, this farnesylation appears to be a signal for translocation upon heat shock and may not confer intrinsic affinity for membranes.

The zinc fingers might be analogous to the ``zinc butterflies'' described for protein kinase C and Raf kinase, which bind phospholipids and phorbol esters (Quest et al., 1992; Ghosh et al., 1994; Ghosh and Bell, 1994; Lehel et al., 1995). This region of protein kinase C has been suggested as a site for interaction with 14-3-3 proteins (Robinson et al., 1994). Alternatively, this domain may provide a structural motif for the recruitment of Hsp70. Finally, the COOH-terminal portion of YDJ1 is far less conserved between DnaJ and the other J homologues and ends with a farnesyl modification unique to YDJ1 among yeast homologues. Two plant dnaJ homologues, LDJ1 in Allium porrum (Bessoule, 1993) and ANJ1 in Atriplex numularia (Zhu et al., 1993) and one human homologue HDJ2 (Chellaiah et al., 1993) also contain a COOH-terminal farnesylation signal. ANJ1 in A. numularia has been show to be farnesylated and, like YDJ1, is necessary for translocation to membranes and survival at elevated temperatures. It is likely that the COOH-terminal region of YDJ1 is specialized for YDJ1's role as a cytoplasmic chaperone that also associates with organellar membranes to deliver protein substrates.


FOOTNOTES

*
This work was supported by National Institutes of Health Grant 5-RO1-AG11527-01-03 and American Heart Association Grant 92006620 (to M. G. D.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
Present address: Neurobiology Dept., Swiss Federal Institute of Technology, CH8093 Zürich, Switzerland.

To whom correspondence should be addressed: Sigma Diagnostics, 545 S. Ewing, St. Louis, MO 63103. Tel.: 800-521-8956; Fax: 314-531-2586.

(^1)
The abbreviations used are: Hsp(s), heat shock protein(s); Fmoc, N-(9-fluorenyl)methoxycarbonyl; HPLC, high performance liquid chromatography; DTT, dithiothreitol; MOPS, 3-(N-morpholino)propanesulfonic acid; PCR, polymerase chain reaction; CMLA, carboxymethyllactalbumin.

(^2)
J. Thissen, personal communication.

(^3)
J. Tsai, L. Estey, and M. G. Douglas, submitted for publication.

(^4)
S. Campbell-Burk, personal communication.


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