The Lumenal Domain of Sec63p Stimulates the ATPase Activity of BiP and Mediates BiP Recruitment to the Translocon in Saccharomyces cerevisiae

We studied the molecular nature of the interaction between the integral membrane protein Sec63p and the lumenal Hsp70 BiP to elucidate their role in the process of precursor transit into the ER of Saccharomyces cerevisiae. A lumenal stretch of Sec63p with homology to the Escherichia coli protein DnaJ is the likely region of interface between Sec63p and BiP. This domain, purified as a fusion protein (63Jp) with glutathione S–transferase (GST), mediated a stable ATP-dependent binding interaction between 63Jp and BiP and stimulated the ATPase activity of BiP. The interaction was highly selective because only BiP was retained on immobilized 63Jp when detergent-solubilized microsomes were mixed with ATP and the fusion protein. GST alone was inactive in these assays. Additionally, a GST fusion containing a point mutation in the lumenal domain of Sec63p did not interact with BiP. Finally, we found that the soluble Sec63p lumenal domain inhibited efficient precursor import into proteoliposomes reconstituted so as to incorporate both BiP and the fusion protein. We conclude that the lumenal domain of Sec63p is sufficient to mediate enzymatic interaction with BiP and that this interaction positioned at the translocation apparatus or translocon at the lumenal face of the ER is vital for protein translocation into the ER.     

Mutation of the ATP-binding pocket of SSA1 indicates that a functional interaction between Ssa1p and Ydj1p is required for post-translational translocation into the yeast endoplasmic reticulum

The translocation of proteins across the yeast ER membrane requires ATP hydrolysis and the action of DnaK (hsp70) and DnaJ homologues. In Saccharomyces cerevisiae the cytosolic hsp70s that promote post-translational translocation are the products of the Ssa gene family. Ssa1p maintains secretory precursors in a translocation-competent state and interacts with Ydj1p, a DnaJ homologue. Although it has been proposed that Ydj1p stimulates the ATPase activity of Ssa1p to release preproteins and engineer translocation, support for this model is incomplete. To this end, mutations in the ATP-binding pocket of SSA1 were constructed and examined both in vivo and in vitro. Expression of the mutant Ssa1p's slows wild-type cell growth, is insufficient to support life in the absence of functional Ssa1p, and results in a dominant effect on post-translational translocation. The ATPase activity of the purified mutant proteins was not enhanced by Ydj1p and the mutant proteins could not bind an unfolded polypeptide substrate. Our data suggest that a productive interaction between Ssa1p and Ydj1p is required to promote protein translocation.     

The Human DnaJ Homologue dj2 Facilitates Mitochondrial Protein Import and Luciferase Refolding

DnaJ homologues function in cooperation with hsp70 family members in various cellular processes including intracellular protein trafficking and folding. Three human DnaJ homologues present in the cytosol have been identified: dj1 (hsp40/hdj-1), dj2 (HSDJ/hdj-2), and neuronal tissue-specific hsj1. dj1 is thought to be engaged in folding of nascent polypeptides, whereas functions of the other DnaJ homologues remain to be elucidated. To investigate roles of dj2 and dj1, we developed a system of chaperone depletion from and readdition to rabbit reticulocyte lysates. Using this system, we found that heat shock cognate 70 protein (hsc70) and dj2, but not dj1, are involved in mitochondrial import of preornithine transcarbamylase. Bacterial DnaJ could replace mammalian dj2 in mitochondrial protein import. We also tested the effects of these DnaJ homologues on folding of guanidine-denatured firefly luciferase. Unexpectedly, dj2, but not dj1, together with hsc70 refolded the protein efficiently. We propose that dj2 is the functional partner DnaJ homologue of hsc70 in the mammalian cytosol. Bacterial DnaJ protein could replace mammalian dj2 in the refolding of luciferase. Thus, the cytosolic chaperone system for mitochondrial protein import and for protein folding is highly conserved, involving DnaK and DnaJ in bacteria, Ssa1–4p and Ydj1p in yeast, and hsc70 and dj2 in mammals.     

Interaction between BiP and Sec63p is required for the completion of protein translocation into the ER of Saccharomyces cerevisiae

To clarify the roles of Kar2p (BiP) and Sec63p in translocation across the ER membrane in Saccharomyces cerevisiae, we have utilized mutant alleles of the essential genes that encode these proteins: kar2-203 and sec63-1. Sanders et al. (Sanders, S. L., K. M. Whitfield, J. P. Vogel, M. D. Rose, and R. W. Schekman. 1992. Cell. 69:353-365) showed that the translocation defect of the kar2-203 mutant lies in the inability of the precursor protein to complete its transit across the membrane, suggesting that the lumenal hsp70 homologue Kar2p (BiP) binds the transiting polypeptide in order to facilitate its passage through the pore. We now show that mutation of a conserved residue (A181-->T) (Nelson, M. K., T. Kurihara, and P. Silver. 1993. Genetics. 134:159- 173) in the lumenal DnaJ box of Sec63p (sec63-1) results in an in vitro phenotype that mimics the precursor stalling defect of kar2-203. We demonstrate by several criteria that this phenotype results specifically from a defect in the lumenal interaction between Sec63p and BiP: Neither a sec62-1 mutant nor a mutation in the cytosolically exposed domain of Sec63p causes precursor stalling, and interaction of the sec63-1 mutant with the membranebound components of the translocation apparatus is unimpaired. Additionally, dominant KAR2 suppressors of sec63-1 partially relieve the stalling defect. Thus, proper interaction between BiP and Sec63p is necessary to allow the precursor polypeptide to complete its transit across the membrane.     

A yeast DnaJ homologue, Scj1p, can function in the endoplasmic reticulum with BiP/Kar2p via a conserved domain that specifies interactions with Hsp70s

Eukaryotic cells contain multiple Hsp70 proteins and DnaJ homologues. The partnership between a given Hsp70 and its interacting DnaJ could, in principle, be determined by their cellular colocalization or by specific protein-protein interactions. The yeast SCJ1 gene encodes one of several homologues of the bacterial chaperone DnaJ. We show that Scj1p is located in the lumen of the endoplasmic reticulum (ER), where it can function with Kar2p (the ER-lumenal BiP/Hsp70 of yeast). The region common to all DnaJ homologues (termed the J domain) from Scj1p can be swapped for a similar region in Sec63p, which is known to interact with Kar2p in the ER lumen, to form a functional transmembrane protein component of the secretory machinery. Thus, Kar2p can interact with two different DnaJ proteins. On the other hand, J domains from two other non-ER DnaJs, Sis1p and Mdj1p, do not function when swapped into Sec63p. However, only three amino acid changes in the Sis1p J domain render the Sec63 fusion protein fully functional in the ER lumen. These results indicate that the choice of an Hsp70 partner by a given DnaJ homologue is specified by the J domain.     

Effect of molecular chaperones on the expression of Candida antarctica lipase B in Pichia pastoris

One of the reasons for limited heterologous protein secretion in Pichia pastoris is the suboptimal folding conditions inside the cell. The Hsp70 and Hsp40 chaperone families in the cytoplasm or the ER regulate the folding and secretion of heterologous proteins. Here, we have studied the effect of chaperones Ydj1p, Ssa1p, Sec63p and Kar2p on the secretory expression of Candida antarctica lipase B (CalB) protein. Expression of CalB in P. pastoris resulted in the induction of Kar2p secretion into the medium surpassing the retrieval capacity of the cell. Individual overexpression of Ydj1p, Ssa1p and Sec63p in recombinant P. pastoris increased CalB expression level by 1.6-, 1.4- and 1.4-fold respectively compared to the control strain harboring only the CalB gene. However, overexpression of Kar2p had a negative effect on the expression of CalB. Moreover, Western blot analysis indicated accumulation and secretion of Kar2p in the ER, Golgi and extracellular medium in the chaperone coexpression strains. When expressed in combinations such as Ydj1p–Ssa1p, Ydj1p–Sec63p, Kar2p–Ssa1p, Kar2p–Sec63p, the expression level of CalB was increased by 2.5-, 1.5-, 1.5- and 1.5-fold respectively. Contrastingly, the Kar2p–Ydj1p combination resulted in decreased CalB secretion in the supernatant. From these results, we conclude that overexpression of Kar2p is not required for the secretion of CalB. Also, our work confirmed the synergistic effect of Ssa1p and Ydj1p chaperones in the expression of CalB.     

Genetic interactions between KAR2 and SEC63, encoding eukaryotic homologues of DnaK and DnaJ in the endoplasmic reticulum.

KAR2 encodes the yeast homologue of mammalian BiP, the endoplasmic reticulum (ER) resident member of the HSP70 family. Kar2p has been shown to be required for the translocation of proteins across the ER membrane as well as nuclear fusion. Sec63, an ER integral membrane protein that shares homology with the Escherichia coli DnaJ protein, is also required for translocation. In this paper we describe several specific genetic interactions between these two proteins, Kar2p and Sec63p. First, temperature-sensitive mutations in KAR2 and SEC63 form synthetic lethal combinations. Second, dominant mutations in KAR2 are allele-specific suppressors for the temperature-sensitive growth and translocation defect of sec63-1. Third, the sec63-1, unlike other translocation defective mutations, results in the induction of KAR2 mRNA levels. Taken together, these genetic interactions suggest that Kar2p and Sec63p interact in vivo in a manner similar to that of the E. coli HSP70, DnaK, and DnaJ. We propose that the interaction between these two proteins is critical to their function in protein translocation.     

Topology and functional domains of Sec63p, an endoplasmic reticulum membrane protein required for secretory protein translocation.

SEC63 encodes a protein required for secretory protein translocation into the endoplasmic reticulum (ER) of Saccharomyces cerevisiae (J. A. Rothblatt, R. J. Deshaies, S. L. Sanders, G. Daum, and R. Schekman, J. Cell Biol. 109:2641-2652, 1989). Antibody directed against a recombinant form of the protein detects a 73-kDa polypeptide which, by immunofluorescence microscopy, is localized to the nuclear envelope-ER network. Cell fractionation and protease protection experiments confirm the prediction that Sec63p is an integral membrane protein. A series of SEC63-SUC2 fusion genes was created to assess the topology of Sec63p within the ER membrane. The largest hybrid proteins are unglycosylated, suggesting that the carboxyl terminus of Sec63p faces the cytosol. Invertase fusion to a loop in Sec63p that is flanked by two putative transmembrane domains produces an extensively glycosylated hybrid protein. This loop, which is homologous to the amino terminus of the Escherichia coli heat shock protein, DnaJ, is likely to face the ER lumen. By analogy to the interaction of the DnaJ and Hsp70-like DnaK proteins in E. coli, the DnaJ loop of Sec63p may recruit luminal Hsp70 (BiP/GRP78/Kar2p) to the translocation apparatus. Mutations in two highly conserved positions of the DnaJ loop and short deletions of the carboxyl terminus inactivate Sec63p activity. Sec63p associates with several other proteins, including Sec61p, a 31.5-kDa glycoprotein, and a 23-kDa protein, and together with these proteins may constitute part of the polypeptide translocation apparatus. A nonfunctional DnaJ domain mutant allele does not interfere with the formation of the Sec63p/Sec61p/gp31.5/p23 complex.     

Reconstitution of protein translocation from solubilized yeast membranes reveals topologically distinct roles for BiP and cytosolic Hsc70

We reconstituted prepro-alpha-factor translocation and signal peptide processing using a yeast microsomal detergent soluble fraction formed into vesicles with soybean phospholipids. Reconstituted translocation required ATP, and was deficient when sec63 and kar2 (BiP) mutant cells were used as a source of membranes. Normal translocation was observed with vesicles reconstituted from a mixture of pure wild-type yeast BiP and a soluble fraction of kar2 mutant membranes. Two other heat-shock cognate (hsc) 70 homologs, yeast cytosolic hsc70 (Ssalp) and E. coli dnaK protein did not replace BiP. Conversely, BiP was not active under conditions where translocation into native ER vesicles required cytosolic hsc70. We conclude that cytosolic hsc70 and BiP serve noninterchangeable roles in polypeptide translocation, possibly because distinct, asymmetrically oriented membrane proteins are required to recruit each protein to opposing surfaces of the ER membrane.     

Role of Human Sec63 in Modulating the Steady-State Levels of Multi-Spanning Membrane Proteins

The Sec61 translocon of the endoplasmic reticulum (ER) membrane forms an aqueous pore, allowing polypeptides to be transferred across or integrated into membranes. Protein translocation into the ER can occur co- and posttranslationally. In yeast, posttranslational translocation involves the heptameric translocase complex including its Sec62p and Sec63p subunits. The mammalian ER membrane contains orthologs of yeast Sec62p and Sec63p, but their function is poorly understood. Here, we analyzed the effects of excess and deficit Sec63 on various ER cargoes using human cell culture systems. The overexpression of Sec63 reduces the steady-state levels of viral and cellular multi-spanning membrane proteins in a cotranslational mode, while soluble and single-spanning ER reporters are not affected. Consistent with this, the knock-down of Sec63 increases the steady-state pools of polytopic ER proteins, suggesting a substrate-specific and regulatory function of Sec63 in ER import. Overexpressed Sec63 exerts its down-regulating activity on polytopic protein levels independent of its Sec62-interacting motif, indicating that it may not act in conjunction with Sec62 in human cells. The specific action of Sec63 is further sustained by our observations that the up-regulation of either Sec62 or two other ER proteins with lumenal J domains, like ERdj1 and ERdj4, does not compromise the steady-state level of a multi-spanning membrane reporter. A J domain-specific mutation of Sec63, proposed to weaken its interaction with the ER resident BiP chaperone, reduces the down-regulating capacity of excess Sec63, suggesting an involvement of BiP in this process. Together, these results suggest that Sec63 may perform a substrate-selective quantity control function during cotranslational ER import.     

Roles of cytosolic Hsp70 and Hsp40 molecular chaperones in post-translational translocation of presecretory proteins into the endoplasmic reticulum

Hsp70 molecular chaperones and their co-chaperones work together in various cellular compartments to guide the folding of proteins and to aid the translocation of proteins across membranes. Hsp70s stimulate protein folding by binding exposed hydrophobic sequences thereby preventing irreversible aggregation. Hsp40s stimulate the ATPase activity of Hsp70s and target unfolded proteins to Hsp70s. Genetic and biochemical evidence supports a role for cytosolic Hsp70s and Hsp40s in the post-translational translocation of precursor proteins into endoplasmic reticulum and mitochondria. To gain mechanistic insight, we measured the effects of Saccharomyces cerevisiae Ssa1p (Hsp70) and Ydj1p (Hsp40) on the translocation of histidine-tagged prepro-alpha-factor (ppalphaF6H) into microsomes. Radiolabeled ppalphaF6H was affinity purified from wheat germ translation reactions (or Escherichia coli) to remove endogenous chaperones. We demonstrated that either Ssa1p or Ydj1p stimulates post-translational translocation by preventing ppalphaF6H aggregation. The binding and/or hydrolysis of ATP by Ssa1p were required to maintain the translocation competence of ppalphaF6H. To clarify the contributions of membrane-bound and cytosolic Ydj1p, we compared the efficiency of chaperone-dependent translocation into wild-type and Ydj1p-deficient microsomes. Neither soluble nor membrane-bound Ydj1p was essential for post-translational protein translocation. The ability of Ssa1p, Ydj1p, or both chaperones to restore the translocation competence of aggregated ppalphaF6H was negligible.     

A Sec63p-BiP complex from yeast is required for protein translocation in a reconstituted proteoliposome

Reconstituted proteoliposomes derived from solubilized yeast microsomes are able to translocate a secreted yeast mating pheromone precursor (Brodsky, J. L., S. Hamamoto, D. Feldheim, and R. Schekman. 1993. J. Cell Biol. 120:95-107). Reconstituted proteoliposomes prepared from strains with mutations in the SEC63 or KAR2 genes are defective for translocation; the kar2 defect can be overcome by the addition of purified BiP (encoded by the KAR2 gene). We now show that addition of BiP to wild-type reconstituted vesicles increases their translocation efficiency three-fold. To identify other ER components that are required for translocation, we purified a microsomal membrane protein complex that contains Sec63p. We found that the complex also includes BiP, Sec66p (gp31.5), and Sec67p (p23). The Sec63p complex restores translocation activity to reconstituted vesicles that are prepared from a sec63-1 strain, or from cells in which the SEC66 or SEC67 genes are disrupted. BiP dissociates from the complex when the purification is performed in the presence of ATP gamma S or when the starting membranes are from yeast containing the sec63-1 mutation. We conclude that the purified Sec63p complex is active and required for protein translocation, and that the association of BiP with the complex may be regulated in vivo.     

Nucleotide exchange factor for the yeast Hsp70 molecular chaperone Ssa1p

We report on the identification of Fes1p (yBR101cp) as a cytosolic homologue of Sls1p, an endoplasmic reticulum (ER) protein previously shown to act as a nucleotide exchange factor for yeast BiP (M. Kabani, J.-M. Beckerich, and C. Gaillardin, Mol. Cell. Biol. 20:6923-6934, 2000). We found that Fes1p associates preferentially to the ADP-bound form of the cytosolic Hsp70 molecular chaperone Ssa1p and promotes nucleotide release. Fes1p activity was shown to be compartment and species specific since Sls1p and Escherichia coli GrpE could not substitute for Fes1p. Surprisingly, whereas Sls1p stimulated the ATPase activity of BiP in cooperation with luminal J proteins, Fes1p was shown to inhibit the Ydj1p-mediated activation of Ssa1p ATPase activity in steady-state and single-turnover assays. Disruption of FES1 in several wild-type backgrounds conferred a strong thermosensitive phenotype but partially rescued ydj1-151 thermosensitivity. The Delta fes1 strain was proficient for posttranslational protein translocation, as well as for the ER-associated degradation of two substrates. However, the Delta fes1 mutant showed increased cycloheximide sensitivity and a general translational defect, suggesting that Fes1p acts during protein translation, a process in which Ssa1p and Ydj1p are known to be involved. In support of this hypothesis, Fes1p was found to be associated with ribosomes.     

Co-chaperone Specificity in Gating of the Polypeptide Conducting Channel in the Membrane of the Human Endoplasmic Reticulum

In mammalian cells, signal peptide-dependent protein transport into the endoplasmic reticulum (ER) is mediated by a dynamic polypeptide-conducting channel, the heterotrimeric Sec61 complex. Previous work has characterized the Sec61 complex as a potential ER Ca²⁺ leak channel in HeLa cells and identified ER lumenal molecular chaperone immunoglobulin heavy-chain-binding protein (BiP) as limiting Ca²⁺ leakage via the open Sec61 channel by facilitating channel closing. This BiP activity involves binding of BiP to the ER lumenal loop 7 of Sec61α in the vicinity of tyrosine 344. Of note, the Y344H mutation destroys the BiP binding site and causes pancreatic β-cell apoptosis and diabetes in mice. Here, we systematically depleted HeLa cells of the BiP co-chaperones by siRNA-mediated gene silencing and used live cell Ca²⁺ imaging to monitor the effects on ER Ca²⁺ leakage. Depletion of either one of the ER lumenal BiP co-chaperones, ERj3 and ERj6, but not the ER membrane-resident co-chaperones (such as Sec63 protein, which assists BiP in Sec61 channel opening) led to increased Ca²⁺ leakage via Sec6 complex, thereby phenocopying the effect of BiP depletion. Thus, BiP facilitates Sec61 channel closure (i.e. limits ER Ca²⁺ leakage) via the Sec61 channel with the help of ERj3 and ERj6. Interestingly, deletion of ERj6 causes pancreatic β-cell failure and diabetes in mice and humans. We suggest that co-chaperone-controlled gating of the Sec61 channel by BiP is particularly important for cells, which are highly active in protein secretion, and that breakdown of this regulatory mechanism can cause apoptosis and disease.     

Sec61p and BiP directly facilitate polypeptide translocation into the ER.

Secretory proteins are segregated from cytosolic proteins by their translocation into the endoplasmic reticulum (ER). A modified secretory protein trapped during translocation across the ER membrane can be crosslinked to two previously identified proteins, Sec61p and BiP (Kar2p). The dependence of this cross-linking upon proteins and small molecules was examined. Mutations in SEC62 and SEC63 decrease the ability of Sec61p to be cross-linked to the secretory polypeptide trapped in translocation. ATP is also required for interaction of Sec61p with the secretory protein. Three kar2 alleles display defective translocation in vitro. Two of these alleles also decrease the ability of Sec61p to be cross-linked to the secretory protein. The third allele, while exhibiting a severe translocation defect, does not affect the interaction of Sec61p with the secretory protein. These results suggest that Sec61p is directly involved in translocation and that BiP acts at two stages of the translocation cycle.     

Sec63p and Kar2p are required for the translocation of SRP-dependent precursors into the yeast endoplasmic reticulum in vivo

The translocation of secretory polypeptides into the endoplasmic reticulum (ER) occurs at the translocon, a pore-forming structure that orchestrates the transport and maturation of polypeptides at the ER membrane. In yeast, targeting of secretory precursors to the translocon can occur by two distinct pathways that are distinguished by their dependence upon the signal recognition particle (SRP). The SRP-dependent pathway requires SRP and its membrane-bound receptor, whereas the SRP-independent pathway requires a separate receptor complex consisting of Sec62p, Sec63p, Sec71p, Sec72p plus lumenal Kar2p/BiP. Here we demonstrate that Sec63p and Kar2p are also required for the SRP-dependent targeting pathway in vivo. Furthermore, we demonstrate multiple roles for Sec63p, at least one of which is exclusive to the SRP-independent pathway.     

BiP acts as a molecular ratchet during posttranslational transport of prepro-alpha factor across the ER membrane.

We have addressed the mechanism by which proteins are posttranslationally transported across the membrane of the yeast endoplasmic reticulum (ER). We demonstrate that BiP (Kar2p), a member of the Hsp70 family resident in the ER lumen, acts as a molecular ratchet during translocation of the secretory protein prepro-alpha factor through the channel formed by the Sec complex. Multiple BiP molecules associate with each translocation substrate following interaction with the J domain of the Sec63p component of the Sec complex. Bound BiP minimizes passive backward movements of the substrate through the channel, and BiP's subsequent dissociation results in a free polypeptide in the ER lumen. Antibodies against the substrate can replace BiP, indicating that a Brownian ratchet is sufficient to achieve translocation.     

N-Ethylmaleimide-modified Hsp70 inhibits protein folding.

Hsp70 molecular chaperones facilitate protein folding and translocation by binding to hydrophobic regions of nascent or unfolded proteins, thereby preventing their aggregation. N-Ethylmaleimide (NEM) inhibits the ATPase and protein translocation-stimulating activities of the yeast Hsp70 Ssa1p by modifying its three cysteine residues, which are located in its ATPase domain. NEM alters the conformation of Ssa1p and disrupts the coupling between its nucleotide- and polypeptide-binding domains. Ssa1p and the yeast DnaJ homolog Ydj1p constitute a protein folding machinery of the yeast cytosol. Using firefly luciferase as a model protein to study chaperone-dependent protein refolding, we have found that NEM also inhibits the protein folding activity of Ssa1p. Interestingly, the NEM-modified protein (NEM-Ssa1p) is a potent inhibitor of protein folding. NEM-Ssa1p can prevent the aggregation of luciferase and stimulate the ATPase activity of Ssa1p suggesting that it acts as an inhibitor by binding to nonnative forms of luciferase and by competing with them for the polypeptide binding site of Ssa1p. NEM-Ssa1p inhibits Ssa1p/Ydj1p-dependent protein refolding at different stages indicating that the chaperones bind and release nonnative forms of luciferase multiple times before folding is completed.     

The Mammalian Hsp40 ERdj3 Requires Its Hsp70 Interaction and Substrate-binding Properties to Complement Various Yeast Hsp40-dependent Functions

Heat shock proteins of 70 kDa (Hsp70s) and their J domain-containing Hsp40 cofactors are highly conserved chaperone pairs that facilitate a large number of cellular processes. The observation that each Hsp70 partners with many J domain-containing proteins (JDPs) has led to the hypothesis that Hsp70 function is dictated by cognate JDPs. If this is true, one might expect highly divergent Hsp70-JDP pairs to be unable to function in vivo. However, we discovered that, when a yeast cytosolic JDP, Ydj1, was targeted to the mammalian endoplasmic reticulum (ER), it interacted with the ER-lumenal Hsp70, BiP, and bound to BiP substrates. Conversely, when a mammalian ER-lumenal JDP, ERdj3, was directed to the yeast cytosol, it rescued the temperature-sensitive growth phenotype of yeast-containing mutant alleles in two cytosolic JDPs, HLJ1 and YDJ1, and activated the ATP hydrolysis rate of Ssa1, the yeast cytosolic Hsp70 that partners with Hlj1 and Ydj1. Surprisingly, ERdj3 mutants that were compromised for substrate binding were unable to rescue the hlj1ydj1 growth defect even though they stimulated the ATPase activity of Ssa1. Yet, J domain mutants of ERdj3 that were defective for interaction with Ssa1 restored the growth of hlj1ydj1 yeast. Taken together, these data suggest that the substrate binding properties of certain JDPs, not simply the formation of unique Hsp70-JDP pairs, are critical to specify in vivo function.     

Identification and characterization of a novel endoplasmic reticulum (ER) DnaJ homologue, which stimulates ATPase activity of BiP in vitro and is induced by ER stress

The activity of Hsp70 proteins is regulated by accessory proteins, which include members of the DnaJ-like protein family. Characterized by the presence of a highly conserved 70-amino acid J domain, DnaJ homologues activate the ATPase activity of Hsp70 proteins and stabilize their interaction with unfolded substrates. DnaJ homologues have been identified in most organelles where they are involved in nearly all aspects of protein synthesis and folding. Within the endoplasmic reticulum (ER), DnaJ homologues have also been shown to assist in the translocation, secretion, retro-translocation, and ER-associated degradation (ERAD) of secretory pathway proteins. By using bioinformatic methods, we identified a novel mammalian DnaJ homologue, ERdj4. It is the first ER-localized type II DnaJ homologue to be reported. The signal sequence of ERdj4 remains uncleaved and serves as a membrane anchor, orienting its J domain into the ER lumen. ERdj4 co-localized with GRP94 in the ER and associated with BiP in vivo when they were co-expressed in COS-1 cells. In vitro experiments demonstrated that the J domain of ERdj4 stimulated the ATPase activity of BiP in a concentration-dependent manner. However, mutation of the hallmark tripeptide HPD (His --> Gln) in the J domain totally abolished this activation. ERdj4 mRNA expression was detected in all human tissues examined but showed the highest level of the expression in the liver, kidney, and placenta. We found that ERdj4 was highly induced at both the mRNA and protein level in response to ER stress, indicating that this protein might be involved in either protein folding or ER-associated degradation.