The Glycine-Phenylalanine-Rich Region Determines the Specificity of the Yeast Hsp40 Sis1

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted
	Citation Map

Services

	E-mail this article to a friend
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Yan, W.
	Articles by Craig, E. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Yan, W.
	Articles by Craig, E. A.

Previous Article | Next Article

Molecular and Cellular Biology, November 1999, p. 7751-7758, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

The Glycine-Phenylalanine-Rich Region Determines the Specificity of the Yeast Hsp40 Sis1

Wei Yan and Elizabeth A. Craig^*

Department of Biomolecular Chemistry, University of Wisconsin $---$ Madison, Madison, Wisconsin 53706

Received 14 June 1999/Returned for modification 28 July 1999/Accepted 10 August 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Hsp40s are ubiquitous, conserved proteins which function with molecular chaperones of the Hsp70 class. Sis1 is an essentialHsp40 of the cytosol of Saccharomyces cerevisiae, thought to berequired for initiation of translation. We carried out a geneticanalysis to determine the regions of Sis1 required to performits key function(s). A C-terminal truncation of Sis1, removing231 amino acids but retaining the N-terminal 121 amino acids encompassingthe J domain and the glycine-phenylalanine-rich (G-F) region,was able to rescue the inviability of a $Delta$ sis1 strain. The yeastcytosol contains other Hsp40s, including Ydj1. To determine whichregions carried the critical determinants of Sis1 function, weconstructed chimeric genes containing portions of SIS1 and YDJ1.A chimera containing the J domain of Sis1 and the G-F region ofYdj1 could not rescue the lethality of the $Delta$ sis1 strain. However,a chimera with the J domain of Ydj1 and the G/F region of Sis1could rescue the strain's lethality, indicating that the G-F regionis a unique region required for the essential function of Sis1.However, a J domain is also required, as mutants expected to causea disruption of the interaction of the J domain with Hsp70 areinviable. We conclude that the G-F region, previously thoughtonly to be a linker or spacer region between the J domain andC-terminal regions of Hsp40s, is a critical determinant of Sis1function.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Hsp70s and Hsp40s (DnaJs) are two families of molecular chaperones which work together in a variety of cellular processes,including protein translation, translocation, and folding, aswell as in the regulation of the biological activity of signallingmolecules (5). Hsp70s bind unfolded or partially folded polypeptides,preventing aggregation and assisting the folding of these polypeptidesubstrates (4, 14). The cycle of binding and release of substratepolypeptides to Hsp70 is nucleotide dependent. ATP-bound Hsp70has a low affinity for substrates, while ADP-bound Hsp70 has arelatively high affinity (30). Therefore, the Hsp40s, whichstimulate the weak intrinsic ATPase activity of Hsp70s, play criticalroles in regulating substrate binding (23). Some Hsp40s alsoprevent aggregation by binding unfolded polypeptide substratesand therefore can be considered molecular chaperones in theirown right (10). In some cases, Hsp40s may transfer bound substratesto Hsp70 (19).

Multiple Hsp40s have been discovered in both prokaryotic and eukaryotic cells. All contain a signature J domain of about 70amino acids. Genetic and biochemical evidence indicates that theJ domain of Hsp40s interacts with the ATPase domain of Hsp70 (9,18). The structures of the J domains of Escherichia coli DnaJand Hdj1, a mammalian Hsp40, have been solved by nuclear magneticresonance (NMR) (16, 25, 27). The tertiary structures ofthe two different J domains are remarkably similar even thoughthere is only 54% sequence similarity between them. Both consistof four $alpha$ -helices. Helix II and helix III are antiparallel. Hydrophobicresidues on the interior faces of helices I, II, and III forma hydrophobic core which stabilizes the structure. Amino acidson the outer surface of helices II and III and in the loop betweenthem, which contains the highly conserved HPD tripeptide, arethought to be important in determining the affinity and selectivityof the interaction between a particular J domain and its Hsp70partner (13, 25). Mutations within the HPD tripeptide leadto a loss of both J domain function and interaction with Hsp70(11, 12, 36, 37, 39).

The Hsp40 class of proteins is divided into three subgroups based on the presence of conserved domains in addition to theJ domain (9). Class I Hsp40s have a glycine-phenylalanine-rich(G-F) region adjacent to the N-terminal J domain, followed bya cysteine-rich region which forms a zinc finger motif and a poorlyconserved C-terminal region. DnaJ of E. coli and Ydj1 of Saccharomycescerevisiae are class I Hsp40s. Class II Hsp40s, which includeSis1 of S. cerevisiae and Hdj1 of mammalian cells, lack the zincfinger motif. Class III Hsp40s lack both the G-F region and thezinc finger motif. Thus, the J domain is the only conserved structureamong these Hsp40s. While the conserved J domain is involved ininteractions with Hsp70s, the polypeptide binding site(s) hasbeen located in the zinc finger and/or poorly conserved C-terminalregions of representatives of class I and II Hsp40s. So far, noclass III Hsp40 has been shown to bind unfolded proteins. Thefunction of the G-F regions of class I and II Hsp40s has not beenestablished. It has been proposed that the G-F region is a flexiblelinker between the J domain and other regions of the type I andII Hsp40s (34) but may be important for interactions with Hsp70s(17, 38).

In the yeast S. cerevisiae, 16 Hsp40s have been identified by their sequence similarities to E. coli DnaJ. Although they havenot all been analyzed, some have been localized to major cellularcompartments: three in the endoplasmic reticulum (ER) (Sec63,Scj1, and Jem1), three in the mitochondria (Mdj1, Mdj2, and Jac1),and at least four in the cytosol (Ydj1, Sis1, Zuo1, and Djp1)(10, 15, 35, 40, 41) (37a). This report focuses onthe yeast cytosolic Hsp40 Sis1. Sis1 and Ydj1, another yeast cytosolicHsp40, have similar biochemical properties in vitro. Both canstimulate the ATPase activity of the yeast cytosolic Hsp70 Ssa1,can bind unfolded polypeptides, and can function with Ssa1 torefold denatured luciferase (20). However, they appear to carryout different functions in vivo. Ydj1 has been implicated in thefolding of proteins and the translocation of proteins into organelles(1, 3, 6, 21). Sis1, on the other hand, appears tobe required for the initiation of translation (42). Overexpressionof YDJ1 cannot suppress the lethal phenotype of the sis1 disruptionmutant; overexpression of SIS1 can only suppress the slow-growthphenotype of the ydj1-null mutant at low temperatures (7, 22)and the translocation defect of a temperature-sensitive ydj1 mutant(6).

To understand the domain structure of Sis1 required for its essential function within the cell, we carried out a genetic analysis.The J domain and G-F region of Sis1 alone are sufficient to supportcell growth. A functional J domain is required to maintain cellviability, but the J domain of Ydj1 can substitute. However, theG-F region of Sis1 is specifically required, as the G-F regionof Ydj1 cannot substitute for it. We conclude that the uniquespecificity of some Hsp40s is determined by their G-Fregions.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Yeast strains and culturing methods. The yeast strains used in this study were as follows: PJ43-2B (MAT $alpha$ , trp1-1 ura3-1 leu2-3,112 his3-11,15 ade2-1 can1-100 GAL2⁺ met2- $Delta$ 1 lys2- $Delta$ 2), PJ53 (a/ $alpha$ , rp1-1/trp1-1 ura3-1/ura3-1leu2-3,112/leu2-3,112 his3-11,15/his3-11,15 ade2-1/ade2-1 can1-100/can1-100GAL2⁺/GAL2⁺ met2- $Delta$ 1/met2- $Delta$ 1 lys2- $Delta$ 2/lys2- $Delta$ 2), and WY26 (MAT $alpha$ , trp1-1 ura3-1leu2-3,112 his3-11,15 ade2-1 can1-100 GAL2⁺ met2- $Delta$ 1 lys2- $Delta$ 2 $Delta$ sis1::LEU2)/pYW17 (SIS1-YCP50).

The $Delta$ sis1::LEU2 mutation in the yeast strain WY26 used in this study contains the LEU2 gene in place of sequence $-$ 13 to +1,056bp of the SIS1 gene. A SmaI-NotI fragment containing the entireLEU2 gene was cloned into the BstZ17I site (13 bp upstream ofthe ATG of the SIS1 coding region) and the NotI site (introducedimmediately before the stop codon) of SIS1 to replace the entireSIS1 coding region. An EcoRI-SalI fragment from this constructcontaining the upstream and downstream noncoding regions of SIS1gene with an inserted LEU2 gene in place of the coding regionwas transformed into the yeast strain PJ53 to make a heterozygousdiploid $Delta$ sis1 strain by one-step gene replacement (28). Thisheterozygous diploid $Delta$ sis1 strain carrying a wild-type SIS1 genein YCp50 plasmid (pYW17) was sporulated and dissected to obtaina haploid $Delta$ sis1::LEU2 strain (WY26) whose survival is maintainedby the pYW17plasmid.

Yeast cultures were grown on either yeast extract-peptone-dextrose (YEPD) medium containing 2% glucose (31) or syntheticcomplete medium containing 5-fluoroorotic acid (5-FOA) (32).For drop test, cells were grown to an optical density at 600 nm(OD₆₀₀) of 0.5 to 1.0. About 0.4 OD₆₀₀ U of cells was resuspendedin 5 ml of sterile water, and a 1:10 serial dilution was prepared.Seven microliters of each dilution was spotted on YEPD or 5-FOAplates which were then incubated at the temperatures indicatedfor the number of days indicated (see Fig. 1 and 5). To preparecell lysates to analyze protein expression, about 1.5 OD₆₀₀ Uof cells was resuspended in 100 µl of 2× sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) sample buffer to make cell lysatesby beating with glass beads (2), and 12 µl of lysates was subjectedto electrophoresis and immunoblot with the indicatedantibodies.

PCR mutagenesis of SIS1 gene. A BamHI-SalI fragment of the SIS1 gene from plasmid CB371 (a generous gift from Kim Ardnt's lab) was cloned into YCp50 andused as a wild-type plasmid (pYW17, SIS1-YCP50). This fragmentwas also cloned into plasmid pRS314 (33) to be used as the backboneplasmid (pYW65, SIS1-pRS314) to construct sis1 mutants. An error-pronePCR was carried out in buffer A (10 mM Tris-HCl [pH 9], 1.5 mMMgCl₂, 25 mM KCl, and 0.1 mg of gelatin per ml) to synthesizea NsiI-SalI fragment of the SIS1 gene. This mutant PCR fragmentwas cloned into the pYW65 plasmid to replace the wild-type NsiI-SalIfragment and was transformed into the $Delta$ sis1 strain WY26 whichcarries SIS1-YCP50. Transformants were screened for temperature-sensitivealleles of the SIS1 gene. Three mutants which grew slightly moreslowly than the wild-type strain at 38.5°C were obtained fromthis screen. Sequencing of these mutated genes indicated thatthey encode three C-terminal truncated fragments of Sis1 containingthe first 297, 262, and 206 amino acids,respectively.

To construct truncations 1-68, 1-121, and 1-172, a NotI site was introduced by PCR immediately after amino acid 68, 121, or172, respectively. Taking advantage of another NotI site whichwas introduced immediately before the stop codon (see above),NotI fragments containing amino acids 69 to 352, 122 to 352, or173 to 352 of Sis1 were removed to construct the truncations 1-68,1-121, and 1-172, respectively. Consequently, truncations 1-68and 1-172 encode the first 68 and 172 amino acids of Sis1, respectively,plus two extra amino acids (Gly and Arg) at the C terminus, andtruncation 1-121 (SS) encodes the first 121 amino acid of Sis1plus an Arg residue at the C terminus. A similar strategy wasused to construct the internal deletion $Delta$ 71-121; a XhoI site wasintroduced immediately prior to amino acid 122. Then a XhoI fragment(from the native XhoI site of the SIS1 gene at codon 69 to thisintroduced XhoI site) containing amino acids 71 to 121 was removedby molecular cloning to construct a Sis1 protein carrying an internaldeletion of the entire G-Fregion.

Two-point mutants of SIS1, H34Q, and HPD34-36AAA were constructed by site-directed PCR mutagenesis and were cloned into thepRS314 plasmid. The mutated sequences were synthesized in theoligonucleotide primers and were incorporated into the contextof the SIS1gene.

Construction of Sis1-Ydj1 chimeras. A Ydj1 truncation which encodes the first 104 amino acids of YDJ1 (YY) was kindly provided by Jill Johnson of this laboratory.Based on the YY construct and the SS (1-121) construct describedabove, chimeric genes encoding the J domain of Sis1 and the G-Fregion of Ydj1 (SY) and the J domain of Ydj1 and the G-F regionof Sis1 (YS) were constructed. To create these chimeras, a BclIsite was introduced into YDJ1 gene (at the end of the J domain)without changing the amino acid sequence by substituting the Cresidue (+200 bp, A of ATG is counted as 1) with T through PCRto allow swapping the G-F region between SS (containing a nativeBclI site at the analogous position) and YY at the BclI site.To compare expression levels of YS and YY constructs using antibodyagainst the same epitope, an NcoI site was introduced by PCR atthe ATG of either YS or YY to allow addition of an Xpress andpolyhistidine tag (XbaI-NcoI fragment of the pRSET B vector; InvitrogenCo., Carlsbad, Calif.) to the N terminus of the YS or YY codingregion (encompassed in an NcoI-SalI fragment). This N-terminallytagged YS or YY (XbaI-NcoI-SalI fragment) region was then clonedinto the SpeI and SalI sites of the p414GPD vector under the controlof the glyceraldehyde-3-phosphate dehydrogenase (GPD) promoter(24). To express the N-terminally tagged YS construction underthe control of different promoters, such as the promoters of translationelongation factor 1 $alpha$ (TEF) and alcohol dehydrogenase 1 (ADH),a XbaI-SalI fragment from the above YS-p414GPDHisB construct wasmoved into p414TEF or p414ADH vectors at the SpeI and SalI sites.Similarly, a XbaI-SalI fragment from the YY-p414GPDHisB was clonedinto the SpeI-SalI site of the multicopy 2µm version of the GPDvector, p424GPD, to overexpress the N-terminally taggedYY.

To construct the YYS fusion, an EcoRV site was introduced by PCR into the SIS1 gene close to the end of the G-F region, therebyreplacing asparagine 113 with aspartic acid. This construct canrescue the lethal phenotype of the $Delta$ sis1 strain as well as thewild-type SIS1 (data not shown). Using this introduced EcoRV site,the glycine-methionine-rich (G-M) C-terminal region of Sis1 (EcoRV-SalIfragment of this SIS1 construct) was fused to the C terminus ofthe Ydj1 G-F region (a SacI-EcoRV fragment of YDJ1 containingthe promoter, J domain, and G-F region of Ydj1) to make a YYSfusion. To make the truncated fusion YYS-292, YYS-262 and YYS-206,the wild-type parts of the YYS construction, were replaced withthe NsiI-SalI fragments of SIS1 containing these sis1 truncationmutations.

Protein purification and antibody generation. Ydj1 was purified as described previously from a T7 expression construct in E. coli (43). Sis1, a generous gift from TaraBeck of this laboratory, was expressed from a T7 expression construct(pET11a-SIS1) in E. coli and was purified by chromatographic separationswith Q-Sepharose and hydroxyapatite. Purified Ydj1 and Sis1 wereused as immunogens to raise the count of polyclonal antibodiesinrabbits.

Quantitation of protein expression by immunoblot. Yeast lysates from wild-type strain PJ43-2B were prepared as described previously (26). Serial dilutions of purified Ydj1and Sis1 proteins were used as standards to determine the relativeprotein levels in the lysate. The cell lysate and purified proteinswere run on SDS-PAGE, were transferred to nitrocellulose (Hybond-C;Amersham Corp., Arlington Heights, Ill.), and were immunoblottedfor Ydj1 and Sis1 using the ECL detection kit (Amersham). Exposedfilm (BioMax-AR; Eastman Kodak Co., Rochester, N.Y.) was densitometricallyanalyzed using Ofoto (Light Source Computer Images, Inc.) andScan Analysis (Biosoft) software packages. Quantification of thecellular amount of Ydj1 or Sis1 in the cell lysate was achievedby comparison of the densitometric signals from the serial dilutionsof purified proteins to those from the celllysate.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Analysis of domains of Sis1 required for essential functions. To determine the sequences of Sis1 which play critical roles in its function, a series of C-terminal truncation mutants ofSIS1 were isolated (Fig. 1A and Materials and Methods). Theseconstructs were transformed into strain WY26, which contains acomplete deletion of the SIS1 coding region on the chromosome( $Delta$ sis1::LEU2) and carries a wild-type SIS1 gene on a low-copy-numbercentromeric plasmid harboring the URA3 gene (SIS1-YCp50) to allowcell viability. To test whether these Sis1 truncations could substitutefor the wild-type Sis1, the transformants were spotted onto platescontaining 5-FOA to select for cells having lost the URA3-basedplasmid carrying the wild-type SIS1 gene (32). As can be seenin Fig. 1A, all of the truncations rescued the $Delta$ sis1 strain on5-FOA plates with the exception of the shortest truncation, containingthe first 68 amino acids of the protein. This 68-amino-acid fragmentencompassing only the J domain is expressed as a stable protein(data not shown). The ability of all but one of the constructsto rescue indicates that much of the C terminus of Sis1 can bedeleted, and the remaining fragments still retain sufficient activityto support growth.

View larger version (27K):
[in this window]
[in a new window]

FIG. 1. Growth phenotype of sis1 truncation mutants. (A) Diagram of Sis1 truncations used in this study and their ability to rescue the lethal phenotype of the $Delta$ sis1 strain. All of the sis1-truncated mutants were cloned into the pRS314 plasmid and transformed into the strain WY26. Transformed cells were grown and spotted onto 5-FOA plates (see Materials and Methods) and were incubated at 30°C for 3 days. (B) Immunodetection of mutant Sis1 proteins. Cells surviving on the 5-FOA plates shown in A were grown in YEPD medium. Cell lysates were prepared as described in Materials and Methods and were subjected to SDS-PAGE and immunoblotted using a Sis1-specific antibody. (C) Cell cultures used in panel B were diluted and spotted on YEPD plates. Plates were incubated at the indicated temperatures for 2 days.

Those transformants which were viable on 5-FOA plates were analyzed by immunoblotting to ensure that the observed growth wascaused by truncated Sis1 proteins rather than by the presenceof any full-length Sis1 protein resulting from plasmid recombination(Fig. 1B). All truncation mutants showed bands of the expectedsize and lacked detectable levels of the wild-type protein. Thesecells were also tested for their ability to grow at a varietyof temperatures on nutrient-rich media (Fig. 1C). Strains containingtruncations 1-297, 1-262, 1-206, and 1-171, all of which lackpart or all of the C-terminal region, grew as well as the wild-typestrain at 30°C, and nearly as well as the wild type at 37°C. Theseresults suggest that the C-terminal region (amino acids 172 to353) of Sis1 may not play an essential role for cell survival,at least under normal laboratory conditions. Interestingly, thestrain containing a truncated Sis1 (1-121), retaining only theJ domain and the G-F region, allowed growth of the $Delta$ sis1 strainat 30 and 37°C, even though such cells grew somewhat more slowlythan the wild type. Therefore, we conclude that the J domain andthe G-F region of Sis1 are sufficient to carry out the essentialfunction of Sis1 at optimal growthtemperatures.

The G-F region of Sis1 is specifically required for its essential function. The lethal phenotype of the $Delta$ sis1 strain can be suppressed by a fragment containing the J domain and the G-F region of Sis1(Fig. 1C) but not by overexpression of Ydj1 (22) (data not shown).We investigated why Ydj1, which also contains a similar J domainand G-F region, cannot substitute for the absence of Sis1. Wereasoned that differential localization caused by the farnesylationsignal at the C-terminal end of Ydj1 which results in a portionof Ydj1 being associated with the membrane might be responsible(8). A ydj1 mutant, ydj1-C406S, in which the farnesylationsignal CASQ has been changed to SASQ has been shown to have reducedmembrane association (8). To test if the inability to rescue $Delta$ sis1 was due to farnesylation, ydj1-C406S (a gift from AvromJ. Caplan) was transformed into the $Delta$ sis1 strain. This ydj1 mutantwas unable to support cell growth (data not shown), suggestingthe targeting of the membrane of Ydj1 caused by farnesylationdoes not prevent Ydj1 from substituting forSis1.

We then tested if the J domain and G-F region of Ydj1 lacking the C-terminal regions could suppress the lethality of the $Delta$ sis1strain. The Ydj1 truncation containing only the J domain and theG-F region (YY, amino acids 1 to 104) was transformed into the $Delta$ sis1 strain (Fig. 2A). The YY truncation did not rescue the $Delta$ sis1strain. This YY construction made functional protein as it rescuedthe slow-growth phenotype of the $Delta$ ydj1 strain (16a). These resultssuggest that a unique structure within the J domain and/or theG-F region of Sis1, which cannot be replaced by the analogousdomains of Ydj1, is required to rescue the lethality of the $Delta$ sis1strain.

View larger version (36K):
[in this window]
[in a new window]

FIG. 2. Evidence for the importance of the G-F region of Sis1. (A) Truncated fusion constructs containing various combinations of the J domain and G-F region from either Ydj1 or Sis1 are shown in the diagram. The capitalized S or Y stands for domains from Sis1 and Ydj1, respectively. The s or y in parentheses indicates the individual promoter of each construct as being from either SIS1 or YDJ1, respectively. Cell cultures were diluted, spotted on 5-FOA plates, and incubated at 30°C for 4 days. (B) The YS or YY construct was cloned into either a low copy (CEN) or multiple-copy (2µm) plasmid under the control of the GPD, TEF, or ADH promoters to express the proteins tagged with Xpress epitope at different levels. Drop tests were performed as described in panel A using cells carrying these constructs. (C) Cell lysates from cells shown in panel B were separated by SDS-PAGE and were immunoblotted by using the anti-Xpress antibody.

To further dissect whether the J domain or the G-F region from Sis1 is important for the essential function, two fusion proteinswere constructed: one in which the J domain from Sis1 was fusedto the G-F region of Ydj1 (SY) and one in which the J domain fromYdj1 was fused to the G-F region of Sis1 (YS) (Fig. 2A). Thesetwo fusion constructions (YS and SY) were transformed in the $Delta$ sis1strain to test their ability to provide Sis1 function. YS wasable to rescue as well as SS, while neither SY nor YY permittedgrowth (Fig. 2A). This result suggests that it is the G-F regionfrom Sis1 which is specifically required for that protein's essentialfunction and that the J domain is not responsible for the functionalspecificity.

Differences in the extent of lethality suppression by the chimeric proteins could possibility be attributed to different expressionlevels. To eliminate this possibility, we wanted to compare thelevels of chimeric proteins in the transformants. Unfortunately,available antibodies against either Sis1 or Ydj1 do not recognizethe YS-YY pair equally and thus could not be used for this purpose.To circumvent this problem, the N termini of both YS and YY weretagged with an Xpress epitope (Invitrogen Co.) so that proteinexpression levels could be detected using anti-Xpress antibodyfor both proteins without epitope bias. The N-terminally taggedYS and YY were cloned into either low-copy-number (CEN) or multiple-copy(2-µm) plasmids under control of the GPD, TEF, or ADH promotersto allow differential expression levels of each construction.All YS constructs were able to rescue growth of $Delta$ sis1 cells (Fig.2B). However, YY was unable to rescue even when expressed at ahigher level than YS (compare lanes 3 and 5 in Fig. 2C). We concludethat the differential abilities of YS and YY to sustain growthof $Delta$ sis1 cells represent a functional difference between the twoproteins and not merely different levels ofexpression.

Since overexpression of Sis1 partly suppresses the slow-growth phenotype of $Delta$ ydj1 cells, but overexpression of Ydj1 does notallow growth of $Delta$ sis1 cells at any temperature (7, 22), wewanted to compare the normal levels of expression of these twoHsp40s in wild-type cells. The relative amounts of Ydj1 and Sis1were determined by immunoblot analysis by using serial dilutionsof cell extracts, purified Ydj1, and purified Sis1 as describedin Materials and Methods. Ydj1 and Sis1 were detected by immunoblotanalysis using antibodies specific to Ydj1 or Sis1, respectively.By comparing the signal from cell extracts with that from purifiedproteins, we determined the relative amounts of Ydj1 and Sis1in cell extracts. The results of one experiment are shown in Fig.3. From the results of a number of experiments, we calculatedthat Ydj1 is between 10 and 15 times more abundant than Sis1 insidethe cell. The fact that the expression of Ydj1 is higher thanthe expression of Sis1 in vivo, together with the fact that theloss of the farnesylation signal does not affect the rescue ofthe $Delta$ sis1 strain, supports the idea that Sis1 is functionallydistinct from Ydj1.

View larger version (28K):
[in this window]
[in a new window]

FIG. 3. Determination of the relative levels of Sis1 and Ydj1 in wild-type cells. Wild-type cells (PJ43-2B) were grown at 30°C in YEPD media to an OD₆₀₀ of 0.5. Approximately 0.3 OD₆₀₀ U of cells was collected, and 200-µl cell lysates were made from these cells. Ten microliters of these cell lysates and the indicated amounts of purified Sis1 and Ydj1 were run on SDS-PAGE and immunoblotted with anti-Sis1 and anti-Ydj1 antibodies. Immunoblot signals from cell lysates were compared with those from the predetermined amounts of Sis1 or Ydj1. The cell lysate was calculated to contain about 19 fmol of Sis1 and 285 fmol of Ydj1.

J domain function is required for the rescue of the $Delta$ sis1 strain. Since constructs containing the J domains from either Sis1 or Ydj1 are equally capable of rescuing a SIS1 deletion, we testedwhether J domain function is required for Sis1 activity. Two differentpoint mutations, H34Q and HPD34-36AAA, were introduced into theregion of SIS1 encoding the highly conserved HPD loop region.Similar mutations in several Hsp40 homologues such, as DnaJ, Ydj1,Sec63, and the large T antigen of simian virus 40, have been shownto disrupt the J domain functions (11, 12, 36, 37, 39).Plasmids containing H34Q or HPD34-36AAA in the context of eitherthe SS truncation or full-length Sis1 were transformed into the $Delta$ sis1 strain. None of the constructs were able to rescue the lethalityof the $Delta$ sis1 strain (Fig. 4), even though the mutant genes expressedstable proteins (data not shown). We conclude that J domain functionis required for Sis1 activity.

View larger version (17K):
[in this window]
[in a new window]

FIG. 4. Amino acid changes in the HPD loop disrupt Sis1 function. Diagram of sis1 point mutations H34Q (single star) and HPD34-36AAA (triple stars) in truncated (amino acids 1 to 121) or full-length Sis1 (WT). WY26 cells containing these mutant constructs were diluted and spotted on 5-FOA plates; the plates were incubated at 30°C for 2 days (truncation constructs) and 3 days (full-length constructs), respectively.

Function of the G-F region is redundant to the functions of the G-M and C-terminal regions. Having determined that the essential Sis1 function requires a functional J domain and G-F region, we wanted to investigatethe roles of the G-M and the C-terminal regions for Sis1 function.Since the N-terminal J domain is absolutely required for Sis1function, we made a deletion mutant in which the segment encodingthe G-F region was deleted, but the reading frame was maintained,and we tested the ability of this deletion mutant to support cellgrowth. This construct (S_S) rescued the $Delta$ sis1 strain as wellas wild-type Sis1 (Fig. 5A). This rescue indicates that the G-Mregion and the C-terminal region from Sis1 can substitute forthe G-F region of Sis1 to maintain cell survival in the absenceof wild-type Sis1. Consistent with this result, a chimeric fusionprotein, YYS, in which the J domain and the G-F region from Ydj1were fused to the G-M and C-terminal regions of Sis1, efficientlyrescued growth of the $Delta$ sis1 strain (Fig. 5A).

View larger version (49K):
[in this window]
[in a new window]

FIG. 5. The G-F region is dispensable in the context of the full-length protein. (A) Diagram of the G-F region-deleted sis1 mutant SXS and YYS chimeric fusion. Cells carrying these constructs were created for drop test on 5-FOA plates and were incubated at 30°C for 3 days. (B) Full-length and truncated YYS chimeric fusions are shown in the diagram. A similar drop test was performed with cells containing these constructs, and cells were spotted onto YEPD plates which were incubated at the indicated temperatures for 3 days.

The above results suggest a functional redundancy between the G-F region and the C-terminal 231 amino acids of Sis1. To investigatewhich sequences within this C-terminal 231 amino acids are minimallyrequired to duplicate the function of the G-F region, we introducedour sis1 C-terminal truncated mutations into the YYS chimericconstruct (Fig. 5B). Among the four truncated fusion genes, onlyYYS-206, YYS-262, and YYS-297 expressed stable proteins (datanot shown). As shown in Fig. 5B, these three truncated fusionproteins each allowed growth of the $Delta$ sis1 strain. The smallesttruncation, YYS-206, which removes amino acids 207 to 352 of theC terminus, allowed wild-type growth rates, while growth of transformantscarrying the longer fusions grew more slowly at 37°C. We concludethat the region from amino acid 122 to 206, which includes theG-M region and part of the C-terminal region, is redundant withthe G-F region for the essential function ofSis1.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study, we have analyzed the domains of Sis1 needed for its essential house-keeping roles. Analysis of mutants encodingamino acid substitutions showed the Sis1 J domain to be essential,as is the case with many Hsp40s which have been tested. Our datashowing that the J domain of Sis1 plays a critical role is consistentwith the previously published observation that a 22-amino-aciddeletion within the J domain of Sis1 which includes the conservedHPD sequence resulted in a lethal phenotype (22). Since theJ domain has been shown to be the interactive site with the ATPasedomain of Hsp70s, these results suggest that the site of interactionof Sis1 with an Hsp70 is essential for its in vivo function. Althoughthe J domain is critical for Sis1 to support cell growth, it isnot necessary that the J domain be from Sis1. The J domain fromYdj1 can provide the same essential function, indicating thatthe J domain structures of these two cytosolic Hsp40s are functionallysimilar.

As is the case with the J domains of cytosolic Ydj1 and Sis1, the J domains of two ER Hsp40s, Sec63 and Scj1, were found tobe interchangeable. However, the J domain of Sis1 could not substitutefor the J domain of Sec63 (29). Therefore, it was proposed thatthe specificity of J domain interaction with Hsp70s is determinedby the amino acids on the outside of helices II and III of theJ domain, as they were very similar between these two Hsp40s ofthe ER (9, 25, 29). The Sis1 J domain was able to substituteif three amino acids on the surfaces of helix II or III were alteredto more closely resemble those of the ER J domains (29). Aftermodeling structures of Sis1 and Ydj1, we compared the amino acidson the outer surfaces of Sis1 and Ydj1 helices II and III. Wefound that the sequences of Sis1 and Ydj1 at these locations aremore similar to each other than to other Hsp40s (Fig. 6A). Whetherthese similarities between the Hsp40s of the same cellular compartment(Sec63/Scj1 and Sis1/Ydj1) are simply the result of the concertedevolution of Hsp70s and Hsp40s that function together or whetherthese similarities play a more critical role is not known at thistime.

View larger version (53K):
[in this window]
[in a new window]

FIG. 6. Sequence alignment of the J domains and G-F region. (A) Alignment of the sequences of the J domains of DnaJ, Hdj1, and Hsp40s of S. cerevisiae carried out by the Jotun-Hein method using MegAlign software of the DNA* program package (DNASTAR Inc., Madison, Wis.). Assignments of the helices was based on the NMR structures of Hdj1 (1HDJ) and DnaJ (1XBL) in the PDB from the Brookhaven National Laboratory. The asterisks indicate residues predicted to be on the outside of helix II and III. The residues of Ydj1 and Sis1 were marked with asterisks based on the predicted structures of the proteins modeled from the DnaJ structure using SYBYL molecular modeling software (Tripos Inc., St. Louis, Mo.). The three amino acids of Sis1 which, when replaced with the corresponding residues of Sec63, enable this J domain to substitute for the J domain of Sec63 are underlined. (B) The entire amino acid sequences of Sis1 and Ydj1 were aligned and compared by the same alignment method described for panel A. Only the alignment of the G-F region is shown.

While the J domain is critical and interchangeable between Sis1 and Ydj1, our results indicate that it is the G-F region thatdifferentiates Sis1 from Ydj1. The minimal 121-amino-acid fragmentof Sis1 containing only the G-F region and the J domain allowsnearly wild-type growth rates at 30°C. The G-F region of Sis1cannot be replaced by the G-F region of Ydj1, even when such afusion is expressed at levels higher than the analogous Sis1 fragment.This is a surprising result, as no specific role has been assignedto the G-F region. It has been suggested that the G-F region servesas a linker or spacer region between the J domain and the moreC-terminal regions of type I and II Hsp40s (17, 34). However,our results show that in the case of Sis1 the G-F region playsa much more fundamental role in the absence of C-terminal sequences,as it is specificallyrequired.

Recently published results suggest that the interaction of the J domain of Sec63 with the ER Hsp70 BiP broadens the rangeof peptides which stably bind to BiP and may determine the peptidebinding specificity of BiP (23). The G-F region may affect substratebinding of an Hsp70 by directly contacting Hsp70 or by regulatingthe conformation of the J domain. Recently Huang et al. showedthat the NMR structure of the J domain in DnaJ is affected bythe G-F region (16). It is possible that different Hsp40 partnersare able to differentially affect the specificity of Hsp70 interactionwith substrates by causing slightly altered conformations whichin turn affect substrate binding affinities. In this regard, itis interesting that the only defect observed for a DnaJ mutantprotein deleted for the G-F region was a defect in the targetingof the $sigma$ ³² protein substrate to Hsp70/DnaK (38).

Previously reported data suggests that both Ydj1 and Sis1 may function with the cytosolic chaperone Ssa. Both are able tostimulate its ATPase activity. Both Sis1 and Ssa are involvedin initiation of translation (15a, 42), while Ydj1 and Ssaplay roles in protein translocation and folding (1, 3, 6,21). Specificity of those roles in which Ssa functions couldbe determined by the Hsp40 partner. Such specificity could beconveyed by structural difference between Sis1 and Ydj1 withinthe G-F region. Comparison of the G-F sequences between thesetwo Hsp40s indicates that there are two stretches of sequences(of 12 and 11 amino acids, respectively) in the Sis1 G-F regionwhich are absent in the Ydj1 G-F region (Fig. 6B). These two extrastretches, which contain amino acids other than glycine and phenylalanine,might be responsible for the functional difference between theG-F regions of these twoHsp40s.

While the G-F region in conjunction with the J domain is sufficient to supply essential Sis1 function, the role of the G-Fregion of Sis1 can be carried out by more C-terminal sequences,as indicated by the ability of a protein containing a deletionof the G-F region or replacement of the Sis1 G-F region with theYdj1 G-F region to allow growth of $Delta$ sis1 cells. This functionallyredundant region was narrowed down to the segment between aminoacids 122 and 206. This region includes the G-M region, whichis encompassed within amino acids 122 to 171, and part of themore C-terminal region. Since both the G-F and G-M regions arerich in glycine, we suspect that the G-M region itself is sufficient.However, we were unable to test this idea directly, as the fusionprotein containing the J domain and G-F region of Ydj1 linkeddirectly to amino acids 122 to 171 of Sis1 wasunstable.

The function of the most C-terminal segment of Sis1 remains unclear. Cells containing a truncated Sis1 in which the entireregion between amino acids 207 and 352 has been deleted grow aswell as wild-type cells at both 30 and 37°C (as demonstrated bythe growth of truncation 1-206 shown in Fig. 1C and the growthof YYS-206 shown in Fig. 5B). However, removing part of the sequencefrom amino acid 207 to 352, as indicated by truncation YYS-262and truncations 1-297 and YYS-297, resulted in a slow growth at37°C (Fig. 1C, 5B). The growth defect caused by these truncationsis consistent with previously published results. Four sis1 mutants,including the mutant sis1-85 which has been used for all the geneticanalysis of Sis1 function, each having a 22-amino-acid deletionwithin this region, have either lethal or severe temperature-sensitivephenotypes (22). It is possible that the four internal deletionsas well as our partial truncations within this region from aminoacid 207 to 353 may produce structural alterations which affectthe ability of Sis1 to function normally, while deletion of theentire region is notproblematic.

In any case, our analysis of the deletions indicates that the C-terminal region is not required for robust growth under theconditions tested. Interestingly, the C-terminal region of Sis1containing amino acids 171 to 353 of Sis1 is able to bind unfoldedproteins (20). Together with the fact that the 1-172 truncationis able to perform the critical functions of Sis1, this resultsuggests that the ability to bind unfolded proteins is not anessential aspect of Sis1 function. Although it is still formallypossible that the G-F region can bind unfolded polypeptides, toour knowledge no indication of such a functionexists.

In summary, we suggest that the J domain and G-F region of Hsp40s of classes I and II may be sufficient for the basic functionsof DnaJs in vivo, while the more C-terminal regions are importantunder suboptimal growth conditions (for example, at the upperlimits of the temperature range allowing growth). This idea issupported by the data presented here. In addition, a Ydj1 truncationcontaining only the J domain and the G-F supports normal growthrates of a $Delta$ ydj1 strain at 30°C (16a). A similar truncation ofDnaJ also permits $lambda$ phage replication, albeit at a reduced efficiency(38). The challenge will be to determine the mechanistic roleof the G-F region in determining the specificity of itsfunction.

	ACKNOWLEDGMENTS

We thank J. Johnson, C. Pfund, and N. Lopez for critical reading of the manuscript, Tara Beck for providing antibodies toSis1 and Ydj1 and purified Sis1 and Ydj1 proteins, A. Caplan forproviding ydj1 mutant C406S, J. Johnson for providing the Ydj1truncation, and K. Arndt for providing a wild-type SIS1plasmid.

This work was supported by NIH grant 5RO1 GM31107 to E.A.C.

	FOOTNOTES

^* Corresponding author. Mailing address: 1300 University Ave., Department of Biomolecular Chemistry, University of Wisconsin $---$ Madison,Madison, WI 53706. Phone: (608) 263-7105. Fax: (608) 262-5253.E-mail: ecraig{at}facstaff.wisc.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Atencio, D. P., and M. P. Yaffe. 1992. MAS5, a yeast homolog of DnaJ involved in mitochondrial protein import. Mol. Cell. Biol. 12:283-291[Abstract/Free Full Text].

2. Ausubel, F., R. Brent, R. Kingston, D. Moore, J. G. Seidman, J. Smith, and K. Struhl. 1997. Current protocols in molecular biology. John Wiley and Sons, New York, N.Y.

3. Becker, J., W. Walter, W. Yan, and E. A. Craig. 1996. Functional interaction of cytosolic Hsp70 and DnaJ-related protein, Ydj1p, in protein translocation in vivo. Mol. Cell. Biol. 16:4378-4386[Abstract/Free Full Text].

4. Buchberger, A., J. Reinstein, and B. Bukau. 1999. The DnaK chaperone system: mechanism and comparison with other Hsp70 systems, p. 609-635. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.

5. Bukau, B., F. X. Schmid, and J. Buchner. 1999. Assisted protein folding, p. 3-10. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.

6. Caplan, A. J., D. M. Cyr, and M. G. Douglas. 1992. YDJ1p facilitates polypeptide translocation across different intracellular membranes by a conserved mechanism. Cell 71:1143-1155[Medline].

7. Caplan, A. J., and M. G. Douglas. 1991. Characterization of YDJ1: a yeast homologue of the bacterial DnaJ protein. J. Cell Biol. 114:609-621[Abstract/Free Full Text].

8. Caplan, A. J., J. Tsai, P. J. Casey, and M. G. Douglas. 1992. Farnesylation of YDJ1p is required for function at elevated growth temperatures in S. cerevisiae. J. Biol. Chem. 267:18890-18895[Abstract/Free Full Text].

9. Cheetham, M., and A. Caplan. 1998. Structure, function and evolution of DnaJ: conservation and adaption of chaperone function. Cell Stress Chaperones 3:28-36. [Medline]

10. Craig, E., W. Yan, and P. James. 1999. Genetic dissection of the Hsp70 chaperone system of yeast, p. 139-162. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.

11. Dey, B., A. J. Caplan, and F. Boschelli. 1996. The Ydj1 molecular chaperone facilitates formation of active p60^v-src in yeast. Mol. Biol. Cell 7:91-100[Abstract].

12. Feldheim, D., J. Rothblatt, and R. Schekman. 1992. Topology and functional domains of Sec63p, an endoplasmic reticulum membrane protein required for secretory protein translocation. Mol. Cell. Biol. 12:3288-3296[Abstract/Free Full Text].

13. Greene, M., K. Maskos, and S. Landry. 1998. Role of the J-domain in the cooperation of Hsp40 with Hsp70. Proc. Natl. Acad. Sci. USA 95:6108-6113[Abstract/Free Full Text].

14. Hartl, F. U. 1996. Molecular chaperones in cellular protein folding. Nature 381:571-580[Medline].

15. Hettema, E. H., C. C. M. Ruigrok, M. G. Koerkamp, M. v. d. Berg, H. F. Tabak, B. Distel, and I. Braakman. 1998. The cytosolic DnaJ-like protein Djp1p is involved specifically in peroxisomal protein import. J. Cell Biol. 142:421-434[Abstract/Free Full Text].

15a. Horton, L., and J. Hensold. Personal communication.

16. Huang, K., J. M. Flanagan, and J. H. Prestegard. 1999. The influence of C-terminal extension on the structure of the "J-domain" in E. coli DnaJ. Protein Sci. 8:203-214[Medline].

16a. Johnson, J., and E. Craig. Unpublished data.

17. Karzai, A. W., and R. McMacken. 1996. A bipartite signaling mechanism involved in DnaJ-mediated activation of the Escherichia coli DnaK protein. J. Biol. Chem. 271:11236-11246[Abstract/Free Full Text].

18. Kelley, W. L. 1998. The J-domain family and the recruitment of chaperone power. Trends Biochem. 23:222-227[Medline].

19. Laufen, T., M. Mayer, C. Beisel, D. Klostermeier, A. Mogk, J. Reinstein, and B. Bukau. 1999. Mechanism of regulation of Hsp70 chaperones by DnaJ co-chaperones. Proc. Natl. Acad. Sci. USA 96:5452-5457[Abstract/Free Full Text].

20. Lu, Z., and D. Cyr. 1998. Protein folding activity of Hsp70 is modified differently by the Hsp40 co-chaperones Sis1 and Ydj1. J. Biol. Chem. 273:27824-27830[Abstract/Free Full Text].

21. Lu, Z., and D. M. Cyr. 1998. The conserved carboxyl terminus and zinc finger-like domain of the co-chaperone Ydj1 assist Hsp70 in protein folding. J. Biol. Chem. 273:5970-5978[Abstract/Free Full Text].

22. Luke, M., A. Suttin, and K. Arndt. 1991. Characterization of SIS1, a Saccharomyces cerevisiae homologue of bacterial dnaJ proteins. J. Cell Biol. 114:623-638[Abstract/Free Full Text].

23. Misselwitz, B., O. Staeck, and T. Rapoport. 1998. J proteins catalytically activate Hsp70 molecules to trap a wide range of peptide sequences. Mol. Cell 2:593-603[Medline].

24. Mumberg, D., R. Muller, and M. Funk. 1995. Yeast vectors for the controlled expression of heterologous proteins in different genetic backgrounds. Gene 156:119-122[Medline].

25. Pellecchia, M., T. Szyperski, D. Wall, C. Georgopoulos, and K. Wuthrich. 1996. NMR structure of the J-domain and the Gly/Phe-rich region of the Escherichia coli DnaJ chaperone. J. Mol. Biol. 260:236-250[Medline].

26. Pfund, C., N. Lopez-Hoyo, T. Ziegelhoffer, B. A. Schilke, P. Lopez-Buesa, W. A. Walter, M. Wiedmann, and E. A. Craig. 1998. The molecular chaperone SSB from S. cerevisiae is a component of the ribosome-nascent chain complex. EMBO J. 17:3981-3989[Medline].

27. Qian, Y. Q., D. Patel, F. U. Hartl, and D. J. McColl. 1996. Nuclear magnetic resonance solution structure of the human Hsp40 (HDJ-1) J-domain. J. Mol. Biol. 260:224-235[Medline].

28. Rothstein, R. 1991. Targeting, disruption, replacement and allele rescue: intergrative DNA transformation in yeast. Methods Enzymol. 194:281-301[Medline].

29. Schlenstedt, G., S. Harris, B. Risse, R. Lill, and P. A. Silver. 1995. A yeast DnaJ homologue, Scj1p, can function in the endoplasmic reticulum with BiP/Kar2p via a conserved domain that specifies interactions with Hsp70s. J. Cell Biol. 129:979-988[Abstract/Free Full Text].

30. Schmid, D., A. Baici, H. Gehring, and P. Christen. 1994. Kinetics of molecular chaperone action. Science 263:971-973[Abstract/Free Full Text].

31. Sherman, F., G. R. Fink, and J. B. Hicks. 1986. Laboratory course manual for methods in yeast genetics. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

32. Sikorski, R. S., and J. D. Boeke. 1991. In vitro mutagenesis and plasmid shuffling: from cloned gene to mutant yeast. Methods Enzymol. 194:302-318[Medline].

33. Sikorski, R. S., and P. Hieter. 1989. A system of shuttle vectors and yeast host strains designed for efficient manipulation of DNA in Saccharomyces cerevisiae. Genetics 122:19-27[Abstract/Free Full Text].

34. Silver, P. A., and J. Way. 1993. Eukaryotic DnaJ homologs and the specificity of Hsp70 activity. Cell 74:5-6[Medline].

35. Strain, J., C. R. Lorenz, J. Bode, S. Garland, G. A. Smolen, D. T. Ta, L. E. Vickery, and V. C. Culotta. 1998. Suppressors of superoxide dismutase (SOD1) deficiency in Saccharomyces cerevisiae. J. Biol. Chem. 273:31138-31144[Abstract/Free Full Text].

36. Suh, W.-C., W. Burkholder, C. Z. Lu, X. Zhao, M. Gottesman, and C. Gross. 1998. Interaction of the Hsp70 molecular chaperone, DnaK, with its cochaperone DnaJ. Proc. Natl. Acad. Sci. USA 95:15223-15228[Abstract/Free Full Text].

37. Tsai, J., and M. G. Douglas. 1996. A conserved HPD sequence of the J-domain is necessary for YDJ1 stimulation of Hsp70 ATPase activity at a site distinct from substrate binding. J. Biol. Chem. 271:9347-9354[Abstract/Free Full Text].

37a. Voisine, C., and E. Craig. Unpublished results.

38. Wall, D., M. Zylicz, and C. Georgopoulos. 1995. The conserved G/F motif of the DnaJ chaperone is necessary for the activation of the substrate binding properties of the DnaK chaperone. J. Biol. Chem. 270:2139-2144[Abstract/Free Full Text].

39. Wall, D., M. Zylicz, and C. Georgopoulos. 1994. The NH₂-terminal 108 amino acids of the Escherichia coli DnaJ protein stimulate the ATPase activity of DnaK and are sufficient for lambda replication. J. Biol. Chem. 269:5446-5451[Abstract/Free Full Text].

40. Westermann, B., and W. Neupert. 1997. Mdj2p, a novel DnaJ homolog in the mitochondrial inner membrane of the yeast. J. Mol. Biol. 272:477-483[Medline].

41. Yan, W., B. Schilke, C. Pfund, W. Walter, S. Kim, and E. A. Craig. 1998. Zuotin, a ribosome-associated DnaJ molecular chaperone. EMBO J. 17:4809-4817[Medline].

42. Zhong, T., and K. T. Arndt. 1993. The yeast SIS1 protein, a DnaJ homolog, is required for initiation of translation. Cell 73:1175-1186[Medline].

43. Ziegelhoffer, T., P. Lopez-Buesa, and E. A. Craig. 1995. The dissociation of ATP from hsp70 of Saccharomyces cerevisiae is stimulated by both Ydj1p and peptide substrates. J. Biol. Chem. 270:10412-10419[Abstract/Free Full Text].

This article has been cited by other articles:

Sahi, C., Lee, T., Inada, M., Pleiss, J. A., Craig, E. A. (2010). Cwc23, an Essential J Protein Critical for Pre-mRNA Splicing with a Dispensable J Domain. Mol. Cell. Biol. 30: 33-42 [Abstract] [Full Text]
Flom, G. A., Lemieszek, M., Fortunato, E. A., Johnson, J. L. (2008). Farnesylation of Ydj1 Is Required for In Vivo Interaction with Hsp90 Client Proteins. Mol. Biol. Cell 19: 5249-5258 [Abstract] [Full Text]
Bagriantsev, S. N., Gracheva, E. O., Richmond, J. E., Liebman, S. W. (2008). Variant-specific [PSI+] Infection Is Transmitted by Sup35 Polymers within [PSI+] Aggregates with Heterogeneous Protein Composition. Mol. Biol. Cell 19: 2433-2443 [Abstract] [Full Text]
Sahi, C., Craig, E. A. (2007). Network of general and specialty J protein chaperones of the yeast cytosol. Proc. Natl. Acad. Sci. USA 104: 7163-7168 [Abstract] [Full Text]
Cintron, N. S., Toft, D. (2006). Defining the Requirements for Hsp40 and Hsp70 in the Hsp90 Chaperone Pathway. J. Biol. Chem. 281: 26235-26244 [Abstract] [Full Text]
Nevoigt, E., Kohnke, J., Fischer, C. R., Alper, H., Stahl, U., Stephanopoulos, G. (2006). Engineering of Promoter Replacement Cassettes for Fine-Tuning of Gene Expression in Saccharomyces cerevisiae. Appl. Environ. Microbiol. 72: 5266-5273 [Abstract] [Full Text]
Cajo, G. C., Horne, B. E., Kelley, W. L., Schwager, F., Georgopoulos, C., Genevaux, P. (2006). The Role of the DIF Motif of the DnaJ (Hsp40) Co-chaperone in the Regulation of the DnaK (Hsp70) Chaperone Cycle. J. Biol. Chem. 281: 12436-12444 [Abstract] [Full Text]
Borges, J. C., Fischer, H., Craievich, A. F., Ramos, C. H. I. (2005). Low Resolution Structural Study of Two Human HSP40 Chaperones in Solution: DJA1 FROM SUBFAMILY A AND DJB4 FROM SUBFAMILY B HAVE DIFFERENT QUATERNARY STRUCTURES. J. Biol. Chem. 280: 13671-13681 [Abstract] [Full Text]
Aron, R., Lopez, N., Walter, W., Craig, E. A., Johnson, J. (2005). In Vivo Bipartite Interaction Between the Hsp40 Sis1 and Hsp70 in Saccharomyces cerevisiae. Genetics 169: 1873-1882 [Abstract] [Full Text]
Silberg, J. J., Tapley, T. L., Hoff, K. G., Vickery, L. E. (2004). Regulation of the HscA ATPase Reaction Cycle by the Co-chaperone HscB and the Iron-Sulfur Cluster Assembly Protein IscU. J. Biol. Chem. 279: 53924-53931 [Abstract] [Full Text]
Borkovich, K. A., Alex, L. A., Yarden, O., Freitag, M., Turner, G. E., Read, N. D., Seiler, S., Bell-Pedersen, D., Paietta, J., Plesofsky, N., Plamann, M., Goodrich-Tanrikulu, M., Schulte, U., Mannhaupt, G., Nargang, F. E., Radford, A., Selitrennikoff, C., Galagan, J. E., Dunlap, J. C., Loros, J. J., Catcheside, D., Inoue, H., Aramayo, R., Polymenis, M., Selker, E. U., Sachs, M. S., Marzluf, G. A., Paulsen, I., Davis, R., Ebbole, D. J., Zelter, A., Kalkman, E. R., O'Rourke, R., Bowring, F., Yeadon, J., Ishii, C., Suzuki, K., Sakai, W., Pratt, R. (2004). Lessons from the Genome Sequence of Neurospora crassa: Tracing the Path from Genomic Blueprint to Multicellular Organism. Microbiol. Mol. Biol. Rev. 68: 1-108 [Abstract] [Full Text]
Fan, C.-Y., Lee, S., Ren, H.-Y., Cyr, D. M. (2004). Exchangeable Chaperone Modules Contribute to Specification of Type I and Type II Hsp40 Cellular Function. Mol. Biol. Cell 15: 761-773 [Abstract] [Full Text]
Lopez, N., Aron, R., Craig, E. A. (2003). Specificity of Class II Hsp40 Sis1 in Maintenance of Yeast Prion [RNQ+]. Mol. Biol. Cell 14: 1172-1181 [Abstract] [Full Text]
Kabani, M., Beckerich, J.-M., Brodsky, J. L. (2002). Nucleotide Exchange Factor for the Yeast Hsp70 Molecular Chaperone Ssa1p. Mol. Cell. Biol. 22: 4677-4689 [Abstract] [Full Text]
Kryndushkin, D. S., Smirnov, V. N., Ter-Avanesyan, M. D., Kushnirov, V. V. (2002). Increased Expression of Hsp40 Chaperones, Transcriptional Factors, and Ribosomal Protein Rpp0 Can Cure Yeast Prions. J. Biol. Chem. 277: 23702-23708 [Abstract] [Full Text]
Lee, S., Fan, C. Y., Younger, J. M., Ren, H., Cyr, D. M. (2002). Identification of Essential Residues in the Type II Hsp40 Sis1 That Function in Polypeptide Binding. J. Biol. Chem. 277: 21675-21682 [Abstract] [Full Text]
Hundley, H., Eisenman, H., Walter, W., Evans, T., Hotokezaka, Y., Wiedmann, M., Craig, E. (2002). The in vivo function of the ribosome-associated Hsp70, Ssz1, does not require its putative peptide-binding domain. Proc. Natl. Acad. Sci. USA 99: 4203-4208 [Abstract] [Full Text]
Lau, P. P., Villanueva, H., Kobayashi, K., Nakamuta, M., Chang, B. H.-J., Chan, L. (2001). A DnaJ Protein, Apobec-1-binding Protein-2, Modulates Apolipoprotein B mRNA Editing. J. Biol. Chem. 276: 46445-46452 [Abstract] [Full Text]
Salmon, D., Montero-Lomeli, M., Goldenberg, S. (2001). A DnaJ-like Protein Homologous to the Yeast Co-chaperone Sis1 (TcJ6p) Is Involved in Initiation of Translation in Trypanosoma cruzi. J. Biol. Chem. 276: 43970-43979 [Abstract] [Full Text]
Johnson, J. L., Craig, E. A. (2001). An Essential Role for the Substrate-Binding Region of Hsp40s in Saccharomyces cerevisiae. JCB 152: 851-856 [Abstract] [Full Text]
Voisine, C., Cheng, Y. C., Ohlson, M., Schilke, B., Hoff, K., Beinert, H., Marszalek, J., Craig, E. A. (2001). Jac1, a mitochondrial J-type chaperone, is involved in the biogenesis of Fe/S clusters in Saccharomyces cerevisiae. Proc. Natl. Acad. Sci. USA 98: 1483-1488 [Abstract] [Full Text]
Sullivan, C. S., Tremblay, J. D., Fewell, S. W., Lewis, J. A., Brodsky, J. L., Pipas, J. M. (2000). Species-Specific Elements in the Large T-Antigen J Domain Are Required for Cellular Transformation and DNA Replication by Simian Virus 40. Mol. Cell. Biol. 20: 5749-5757 [Abstract] [Full Text]
Johnson, J. L., Craig, E. A. (2000). A Role for the Hsp40 Ydj1 in Repression of Basal Steroid Receptor Activity in Yeast. Mol. Cell. Biol. 20: 3027-3036 [Abstract] [Full Text]
Horton, L. E., James, P., Craig, E. A., Hensold, J. O. (2001). The Yeast hsp70 Homologue Ssa Is Required for Translation and Interacts with Sis1 and Pab1 on Translating Ribosomes. J. Biol. Chem. 276: 14426-14433 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted
	Citation Map

Services

	E-mail this article to a friend
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Yan, W.
	Articles by Craig, E. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Yan, W.
	Articles by Craig, E. A.

1.	Atencio, D. P., and M. P. Yaffe. 1992. MAS5, a yeast homolog of DnaJ involved in mitochondrial protein import. Mol. Cell. Biol. 12:283-291[Abstract/Free Full Text].
2.	Ausubel, F., R. Brent, R. Kingston, D. Moore, J. G. Seidman, J. Smith, and K. Struhl. 1997. Current protocols in molecular biology. John Wiley and Sons, New York, N.Y.
3.	Becker, J., W. Walter, W. Yan, and E. A. Craig. 1996. Functional interaction of cytosolic Hsp70 and DnaJ-related protein, Ydj1p, in protein translocation in vivo. Mol. Cell. Biol. 16:4378-4386[Abstract/Free Full Text].
4.	Buchberger, A., J. Reinstein, and B. Bukau. 1999. The DnaK chaperone system: mechanism and comparison with other Hsp70 systems, p. 609-635. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.
5.	Bukau, B., F. X. Schmid, and J. Buchner. 1999. Assisted protein folding, p. 3-10. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.
6.	Caplan, A. J., D. M. Cyr, and M. G. Douglas. 1992. YDJ1p facilitates polypeptide translocation across different intracellular membranes by a conserved mechanism. Cell 71:1143-1155[Medline].
7.	Caplan, A. J., and M. G. Douglas. 1991. Characterization of YDJ1: a yeast homologue of the bacterial DnaJ protein. J. Cell Biol. 114:609-621[Abstract/Free Full Text].
8.	Caplan, A. J., J. Tsai, P. J. Casey, and M. G. Douglas. 1992. Farnesylation of YDJ1p is required for function at elevated growth temperatures in S. cerevisiae. J. Biol. Chem. 267:18890-18895[Abstract/Free Full Text].
9.	Cheetham, M., and A. Caplan. 1998. Structure, function and evolution of DnaJ: conservation and adaption of chaperone function. Cell Stress Chaperones 3:28-36. [Medline]
10.	Craig, E., W. Yan, and P. James. 1999. Genetic dissection of the Hsp70 chaperone system of yeast, p. 139-162. In B. Bukau (ed.), Molecular chaperones and folding catalysts: regulation, cellular function and mechanisms. Harwood Academic Publishers, Amsterdam, The Netherlands.
11.	Dey, B., A. J. Caplan, and F. Boschelli. 1996. The Ydj1 molecular chaperone facilitates formation of active p60^v-src in yeast. Mol. Biol. Cell 7:91-100[Abstract].
12.	Feldheim, D., J. Rothblatt, and R. Schekman. 1992. Topology and functional domains of Sec63p, an endoplasmic reticulum membrane protein required for secretory protein translocation. Mol. Cell. Biol. 12:3288-3296[Abstract/Free Full Text].
13.	Greene, M., K. Maskos, and S. Landry. 1998. Role of the J-domain in the cooperation of Hsp40 with Hsp70. Proc. Natl. Acad. Sci. USA 95:6108-6113[Abstract/Free Full Text].
14.	Hartl, F. U. 1996. Molecular chaperones in cellular protein folding. Nature 381:571-580[Medline].
15.	Hettema, E. H., C. C. M. Ruigrok, M. G. Koerkamp, M. v. d. Berg, H. F. Tabak, B. Distel, and I. Braakman. 1998. The cytosolic DnaJ-like protein Djp1p is involved specifically in peroxisomal protein import. J. Cell Biol. 142:421-434[Abstract/Free Full Text].
15a.	Horton, L., and J. Hensold. Personal communication.
16.	Huang, K., J. M. Flanagan, and J. H. Prestegard. 1999. The influence of C-terminal extension on the structure of the "J-domain" in E. coli DnaJ. Protein Sci. 8:203-214[Medline].
16a.	Johnson, J., and E. Craig. Unpublished data.
17.	Karzai, A. W., and R. McMacken. 1996. A bipartite signaling mechanism involved in DnaJ-mediated activation of the Escherichia coli DnaK protein. J. Biol. Chem. 271:11236-11246[Abstract/Free Full Text].
18.	Kelley, W. L. 1998. The J-domain family and the recruitment of chaperone power. Trends Biochem. 23:222-227[Medline].
19.	Laufen, T., M. Mayer, C. Beisel, D. Klostermeier, A. Mogk, J. Reinstein, and B. Bukau. 1999. Mechanism of regulation of Hsp70 chaperones by DnaJ co-chaperones. Proc. Natl. Acad. Sci. USA 96:5452-5457[Abstract/Free Full Text].
20.	Lu, Z., and D. Cyr. 1998. Protein folding activity of Hsp70 is modified differently by the Hsp40 co-chaperones Sis1 and Ydj1. J. Biol. Chem. 273:27824-27830[Abstract/Free Full Text].
21.	Lu, Z., and D. M. Cyr. 1998. The conserved carboxyl terminus and zinc finger-like domain of the co-chaperone Ydj1 assist Hsp70 in protein folding. J. Biol. Chem. 273:5970-5978[Abstract/Free Full Text].
22.	Luke, M., A. Suttin, and K. Arndt. 1991. Characterization of SIS1, a Saccharomyces cerevisiae homologue of bacterial dnaJ proteins. J. Cell Biol. 114:623-638[Abstract/Free Full Text].
23.	Misselwitz, B., O. Staeck, and T. Rapoport. 1998. J proteins catalytically activate Hsp70 molecules to trap a wide range of peptide sequences. Mol. Cell 2:593-603[Medline].
24.	Mumberg, D., R. Muller, and M. Funk. 1995. Yeast vectors for the controlled expression of heterologous proteins in different genetic backgrounds. Gene 156:119-122[Medline].
25.	Pellecchia, M., T. Szyperski, D. Wall, C. Georgopoulos, and K. Wuthrich. 1996. NMR structure of the J-domain and the Gly/Phe-rich region of the Escherichia coli DnaJ chaperone. J. Mol. Biol. 260:236-250[Medline].
26.	Pfund, C., N. Lopez-Hoyo, T. Ziegelhoffer, B. A. Schilke, P. Lopez-Buesa, W. A. Walter, M. Wiedmann, and E. A. Craig. 1998. The molecular chaperone SSB from S. cerevisiae is a component of the ribosome-nascent chain complex. EMBO J. 17:3981-3989[Medline].
27.	Qian, Y. Q., D. Patel, F. U. Hartl, and D. J. McColl. 1996. Nuclear magnetic resonance solution structure of the human Hsp40 (HDJ-1) J-domain. J. Mol. Biol. 260:224-235[Medline].
28.	Rothstein, R. 1991. Targeting, disruption, replacement and allele rescue: intergrative DNA transformation in yeast. Methods Enzymol. 194:281-301[Medline].
29.	Schlenstedt, G., S. Harris, B. Risse, R. Lill, and P. A. Silver. 1995. A yeast DnaJ homologue, Scj1p, can function in the endoplasmic reticulum with BiP/Kar2p via a conserved domain that specifies interactions with Hsp70s. J. Cell Biol. 129:979-988[Abstract/Free Full Text].
30.	Schmid, D., A. Baici, H. Gehring, and P. Christen. 1994. Kinetics of molecular chaperone action. Science 263:971-973[Abstract/Free Full Text].
31.	Sherman, F., G. R. Fink, and J. B. Hicks. 1986. Laboratory course manual for methods in yeast genetics. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
32.	Sikorski, R. S., and J. D. Boeke. 1991. In vitro mutagenesis and plasmid shuffling: from cloned gene to mutant yeast. Methods Enzymol. 194:302-318[Medline].
33.	Sikorski, R. S., and P. Hieter. 1989. A system of shuttle vectors and yeast host strains designed for efficient manipulation of DNA in Saccharomyces cerevisiae. Genetics 122:19-27[Abstract/Free Full Text].
34.	Silver, P. A., and J. Way. 1993. Eukaryotic DnaJ homologs and the specificity of Hsp70 activity. Cell 74:5-6[Medline].
35.	Strain, J., C. R. Lorenz, J. Bode, S. Garland, G. A. Smolen, D. T. Ta, L. E. Vickery, and V. C. Culotta. 1998. Suppressors of superoxide dismutase (SOD1) deficiency in Saccharomyces cerevisiae. J. Biol. Chem. 273:31138-31144[Abstract/Free Full Text].
36.	Suh, W.-C., W. Burkholder, C. Z. Lu, X. Zhao, M. Gottesman, and C. Gross. 1998. Interaction of the Hsp70 molecular chaperone, DnaK, with its cochaperone DnaJ. Proc. Natl. Acad. Sci. USA 95:15223-15228[Abstract/Free Full Text].
37.	Tsai, J., and M. G. Douglas. 1996. A conserved HPD sequence of the J-domain is necessary for YDJ1 stimulation of Hsp70 ATPase activity at a site distinct from substrate binding. J. Biol. Chem. 271:9347-9354[Abstract/Free Full Text].
37a.	Voisine, C., and E. Craig. Unpublished results.
38.	Wall, D., M. Zylicz, and C. Georgopoulos. 1995. The conserved G/F motif of the DnaJ chaperone is necessary for the activation of the substrate binding properties of the DnaK chaperone. J. Biol. Chem. 270:2139-2144[Abstract/Free Full Text].
39.	Wall, D., M. Zylicz, and C. Georgopoulos. 1994. The NH₂-terminal 108 amino acids of the Escherichia coli DnaJ protein stimulate the ATPase activity of DnaK and are sufficient for lambda replication. J. Biol. Chem. 269:5446-5451[Abstract/Free Full Text].
40.	Westermann, B., and W. Neupert. 1997. Mdj2p, a novel DnaJ homolog in the mitochondrial inner membrane of the yeast. J. Mol. Biol. 272:477-483[Medline].
41.	Yan, W., B. Schilke, C. Pfund, W. Walter, S. Kim, and E. A. Craig. 1998. Zuotin, a ribosome-associated DnaJ molecular chaperone. EMBO J. 17:4809-4817[Medline].
42.	Zhong, T., and K. T. Arndt. 1993. The yeast SIS1 protein, a DnaJ homolog, is required for initiation of translation. Cell 73:1175-1186[Medline].
43.	Ziegelhoffer, T., P. Lopez-Buesa, and E. A. Craig. 1995. The dissociation of ATP from hsp70 of Saccharomyces cerevisiae is stimulated by both Ydj1p and peptide substrates. J. Biol. Chem. 270:10412-10419[Abstract/Free Full Text].