Sds22p is a subunit of a stable isolatable form of protein phosphatase 1 (Glc7p) from Saccharomyces cerevisiae

Protein phosphatase 1 (PP1) is one of the major protein phosphatases in eukaryotic cells. PP1 activity is believed to be controlled by the interaction of PP1 catalytic subunit with various regulatory subunits. The essential gene GLC7 encodes the PP1 catalytic subunit in Saccharomyces cerevisiae. In this study, full-length GLC7(1-312), C-terminal deletion mutants, and C-terminally poly-his tagged mutants were constructed and expressed in a GLC7 knockout strain of S. cerevisiae. Viability studies of the GLC7 knockout strains carrying the plasmids expressing GLC7 C-terminal deletion mutants and their tagged forms showed that the mutants 1-295 and 1-304 were functional, whereas the mutant 1-245 was not. The C-terminally poly-his tagged Glc7p with and without an N-terminal hemagglutinin (HA) tag was partially purified by immobilized Ni(2+) affinity chromatography and further analyzed by gel filtration and ion exchange chromatography. Phosphatase activity assays, SDS-PAGE, and Western blot analyses of the chromatographic fractions suggested that the Glc7p associated with regulatory subunits in vivo. A 40-kDa protein was copurified with tagged Glc7p through several chromatographic procedures. Monoclonal antibody against the HA tag coimmunoprecipitated the tagged Glc7p and the 40-kDa protein. This protein was further purified by a reverse phase HPLC column. Analysis by CNBr digestion, peptide sequencing, and electrospray mass spectrometry showed that this 40-kDa protein is Sds22p, one of the proteins proposed to be a regulatory subunit of Glc7. These results demonstrate that Sds22p forms a complex with Glc7p and that Sds22p:Glc7p is a stable isolatable form of yeast PP1.     

Autocatalytic activation of influenza hemagglutinin

Enveloped viruses contain surface proteins that mediate fusion between the viral and target cell membranes following an activating stimulus. Acidic pH induces the influenza virus fusion protein hemagglutinin (HA) via irreversible refolding of a trimeric conformational state leading to exposure of hydrophobic fusion peptides on each trimer subunit. Herein, we show that cells expressing fowl plague virus HA demonstrate discrete switching behavior with respect to the HA conformational change. Partially activated states do not exist at the scale of the cell, activation of HA leads to aggregation of cell surface trimers, and newly synthesized HA refold spontaneously in the presence of previously activated HA. These observations imply a feedback mechanism involving self-catalyzed refolding of HA and thus suggest a mechanism similar to the autocatalytic refolding and aggregation of prions.     

Identification of Regions Involved in Substrate Binding and Dimer Stabilization within the Central Domains of Yeast Hsp40 Sis1

Protein folding, refolding and degradation are essential for cellular life and are regulated by protein homeostatic processes such those that involve the molecular chaperone DnaK/Hsp70 and its co-chaperone DnaJ. Hsp70 action is initiated when proteins from the DnaJ family bind an unfolded protein for delivery purposes. In eukaryotes, the DnaJ family can be divided into two main groups, Type I and Type II, represented by yeast cytosolic Ydj1 and Sis1, respectively. Although sharing some unique features both members of the DnaJ family, Ydj1 and Sis1 are structurally and functionally distinct as deemed by previous studies, including the observation that their central domains carry the structural and functional information even in switched chimeras. In this study, we combined several biophysical tools for evaluating the stability of Sis1 and mutants that had the central domains (named Gly/Met rich domain and C-terminal Domain I) deleted or switched to those of Ydj1 to gain insight into the role of these regions in the structure and function of Sis1. The mutants retained some functions similar to full length wild-type Sis1, however they were defective in others. We found that: 1) Sis1 unfolds in at least two steps as follows: folded dimer to partially folded monomer and then to an unfolded monomer. 2) The Gly/Met rich domain had intrinsically disordered characteristics and its deletion had no effect on the conformational stability of the protein. 3) The deletion of the C-terminal Domain I perturbed the stability of the dimer. 4) Exchanging the central domains perturbed the conformational stability of the protein. Altogether, our results suggest the existence of two similar subdomains in the C-terminal domain of DnaJ that could be important for stabilizing each other in order to maintain a folded substrate-binding site as well as the dimeric state of the protein.     

Mouse Hsp25, a small shock protein. The role of its C-terminal extension in oligomerization and chaperone action.

Under conditions of cellular stress, small heat shock proteins (sHsps), e.g. Hsp25, stabilize unfolding proteins and prevent their precipitation from solution. 1H NMR spectroscopy has shown that mammalian sHsps possess short, polar and highly flexible C-terminal extensions. A mutant of mouse Hsp25 without this extension has been constructed. CD spectroscopy reveals some differences in secondary and tertiary structure between this mutant and the wild-type protein but analytical ultracentrifugation and electron microscopy show that the proteins have very similar oligomeric masses and quaternary structures. The mutant shows chaperone ability comparable to that of wild-type Hsp25 in a thermal aggregation assay using citrate synthase, but does not stabilize alpha-lactalbumin against precipitation following reduction with dithiothreitol. The accessible hydrophobic surface of the mutant protein is less than that of the wild-type protein and the mutant is also less stable at elevated temperature. 1H NMR spectroscopy reveals that deletion of the C-terminal extension of Hsp25 leads to induction of extra C-terminal flexibility in the molecule. Monitoring complex formation between Hsp25 and dithiothreitol-reduced alpha-lactalbumin by 1H NMR spectroscopy indicates that the C-terminal extension of Hsp25 retains its flexibility during this interaction. Overall, these data suggest that a highly flexible C-terminal extension in mammalian sHsps is required for full chaperone activity.     

Molecular Chaperones and Mitochondrial Protein Folding

Precursor proteins destined for the mitochondrial matrix traverse inner and outer organelle membranes in an extended conformation. Translocation events are therefore integrally coupled to the processes of protein unfolding in the cytosol and protein refolding in the matrix. To successfully import proteins from the cytoplasm into mitochondria, cells have recruited a variety of molecular chaperone systems and folding catalysts. Within the organelles, mitochondrial Hsp70 (mt-Hsp70) is a major player in this process and exerts multiple functions. First, mt-Hsp70 binds together with cohort proteins to incoming polypeptide chains, thus conferring unidirectionality on the translocation process, and then assists in their refolding. A subset of imported proteins requires additional assistance by chaperonins of the Hsp60/Hsp10 family. Protein folding occurs within the cavity of these cylindrical complexes. A productive interaction of precursor proteins with molecular chaperones in the matrix is not only crucial for correct refolding and assembly, but also for processing of presequences, intramitochondrial sorting, and degradation of proteins. This review focuses on the role of mt-Hsp70 and Hsp60/Hsp10 in protein folding in the mitochondrial matrix and discusses recent findings on their molecular mechanism of action.     

Functional Rescue of Mutant Human Cystathionine ��-Synthase by Manipulation of Hsp26 and Hsp70 Levels in Saccharomyces cerevisiae

Many human diseases are caused by missense substitutions that result in misfolded proteins that lack biological function. Here we express a mutant form of the human cystathionine β-synthase protein, I278T, in Saccharomyces cerevisiae and show that it is possible to dramatically restore protein stability and enzymatic function by manipulation of the cellular chaperone environment. We demonstrate that Hsp70 and Hsp26 bind specifically to I278T but that these chaperones have opposite biological effects. Ethanol treatment induces Hsp70 and causes increased activity and steady-state levels of I278T. Deletion of the SSA2 gene, which encodes a cytoplasmic isoform of Hsp70, eliminates the ability of ethanol to restore function, indicating that Hsp70 plays a positive role in proper I278T folding. In contrast, deletion of HSP26 results in increased I278T protein and activity, whereas overexpression of Hsp26 results in reduced I278T protein. The Hsp26-I278T complex is degraded via a ubiquitin/proteosome-dependent mechanism. Based on these results we propose a novel model in which the ratio of Hsp70 and Hsp26 determines whether misfolded proteins will either be refolded or degraded.Cells have evolved quality control systems for misfolded proteins, consisting of molecular chaperones (heat shock proteins) and proteases. These molecules help prevent misfolding and aggregation by either promoting refolding or by degrading misfolded protein molecules (1). In eukaryotic cells, the Hsp70 system plays a critical role in mediating protein folding. Hsp70 protein interacts with misfolded polypeptides along with co-chaperones and promotes refolding by repeated cycles of binding and release requiring the hydrolysis of ATP (2). Small heat shock proteins (sHsp)² are small molecular weight chaperones that bind non-native proteins in an oligomeric complex and whose function is poorly understood (3). In mammalian cells, the sHsp family includes the α-crystallins, whose orthologue in Saccharomyces cerevisiae is Hsp26. Studies suggest that Hsp26 binding to misfolded protein aggregates is a prerequisite for effective disaggregation and refolding by Hsp70 and Hsp104 (4, 5).Misfolded proteins can result from missense substitutions such as those found in a variety of recessive genetic diseases, including cystathionine β-synthase (CBS) deficiency. CBS is a key enzyme in the trans-sulfuration pathway that converts homocysteine to cysteine (6). Individuals with CBS deficiency have extremely elevated levels of plasma total homocysteine, resulting in a variety of symptoms, including dislocated lenses, osteoporosis, mental retardation, and a greatly increased risk of thrombosis (7). Approximately 80% of the mutations found in CBS-deficient patients are point mutations that are predicted to cause missense substitutions in the CBS protein (8). The most common mutation found in CBS-deficient patients, an isoleucine to threonine substitution at amino acid position 278 (I278T), has been observed in nearly one-quarter of all CBS-deficient patients. Based on the crystal structure of the catalytic core of CBS, this mutation is located in a β-sheet more than 10 Å distant from the catalytic pyridoxal phosphate and does not directly affect the catalytic binding pocket or the dimer interface (9).Previously, our lab has developed a yeast bioassay for human CBS in which yeast expressing functional human CBS can grow in media lacking cysteine, whereas yeast expressing mutant CBS cannot (10). We have used this assay to characterize the functional effects of many different CBS missense alleles, including I278T (7, 11). However, an unexpected finding was that it was possible to restore function to I278T and a number of other CBS missense mutations by either truncation or the addition of a second missense mutation in the C-terminal regulatory domain (12, 13). The ability to restore function by a cis-acting second mutation suggested to us that it might be possible to restore function in trans via either interaction of mutant CBS with a small molecule (i.e. drug) or a mutation in another yeast gene. In a previous study, we found that small osmolyte chemical chaperones could restore function to mutant CBS presumably by directly stabilizing the mutant CBS protein (14).In this study we report on the surprising finding that exposure of yeast to ethanol can restore function of I278T CBS by altering the ratio of the molecular chaperones Hsp26 and Hsp70. We demonstrate Hsp70 binding promotes I278T folding and activity, whereas Hsp26 binding promotes I278T degradation via the proteosome. By manipulating the levels of Hsp26 and Hsp70, we are able to show that I278T CBS protein can have enzymatic activity restored to near wild-type levels of activity. Our findings suggest a novel function for sHsps.     

The C-terminal extension of Saccharomyces cerevisiae Hsp104 plays a role in oligomer assembly

The Saccharomyces cerevisiae protein Hsp104, a member of the Hsp100/Clp AAA+ family of ATPases, and its orthologues in plants (Hsp101) and bacteria (ClpB) function to disaggregate and refold thermally denatured proteins following heat shock and play important roles in thermotolerance. The primary sequences of fungal Hsp104's contain a largely acidic C-terminal extension not present in bacterial ClpB's. In this work, deletion mutants were used to determine the role this extension plays in Hsp104 structure and function. Elimination of the C-terminal tetrapeptide DDLD diminishes binding of the tetratricopeptide repeat domain cochaperone Cpr7 but is dispensable for Hsp104-mediated thermotolerance. The acidic region of the extension is also dispensable for thermotolerance and for the stimulation of Hsp104 ATPase activity by poly-l-lysine, but its truncation results in an oligomerization defect and reduced ATPase activity in vitro. Finally, sequence alignments reveal that the C-terminal extension contains a sequence (VLPNH) that is conserved in fungal Hsp104's but not in other orthologues. Hsp104 lacking the entire C-terminal extension including the VLPNH region does not assemble and has very low ATPase activity. In the presence of a molecular crowding agent the ATPase activities of mutants with longer truncations are partially restored possibly through enhanced oligomer formation. However, elimination of the whole C-terminal extension results in an Hsp104 molecule which is unable to assemble and becomes aggregation prone at high temperature, highlighting a novel structural role for this region.     

HBP21: A Novel Member of TPR Motif Family, as a Potential Chaperone of Heat Shock Protein 70 in Proliferative Vitreoretinopathy (PVR) and Breast Cancer

A large number of tetratricopeptide repeat (TPR)-containing proteins have been shown to interact with the C-terminal domain of the 70 kDa heat-shock protein (Hsp70), especially those with three consecutive TPR motifs. The TPR motifs in these proteins are necessary and sufficient for mediating the interaction with Hsp70. Here, we investigate HBP21, a novel human protein of unknown function having three tandem TPR motifs predicted by computational sequence analysis. We confirmed the high expression of HBP21 in breast cancer and proliferative vitreoretinopathy (PVR) proliferative membrane and examined whether HBP21 could interact with Hsp70 using a yeast two-hybrid system and glutathione S-transferase pull-down assay. Previous studies have demonstrated the importance of Hsp70 C-terminal residues EEVD and PTIEEVD for interaction with TPR-containing proteins. Here, we tested an assortment of truncation and amino acid substitution mutants of Hsp70 to determine their ability to bind to HBP21 using a yeast two-hybrid system. The newly discovered interaction between HBP21 and Hsp70 along with observations from other studies leads to our hypothesis that HBP21 may be involved in the inhibition of progression and metastasis of tumor cells. Qinghuai Liu and Juanyu Gao have contributed equally to this work.     

The sunflower plastidial ω3-fatty acid desaturase (HaFAD7) contains the signalling determinants required for targeting to, and retention in, the endoplasmic reticulum membrane in yeast but requires co-expressed ferredoxin for activity

Although plant plastidial ω3-desaturases are closely related to microsomal desaturases, heterologous expression in yeast of the Helianthus annuus FAD7 ω3-desaturase showed low activity in contrast to similar expression of microsomal FAD3 ω3-desaturases. However, the removal of the plastidial transit peptide and the incorporation of a KKNL motif to the C-terminus of HaFAD7 increased the activity by 10-fold compared to the native protein. N-terminal fusion of transmembrane-domains from either the yeast microsomal ELO3, (a type III signal anchor domain), or FAE1, an endoplasmic reticulum membrane anchoring domain, resulted in moderate increases in enzyme activity (5- and 7-fold, respectively), suggesting that the first, most hydrophobic transmembrane domain of HaFAD7 is sufficient to direct targeting to, and insertion into, the endoplasmic reticulum membrane. Furthermore, fusing a hemagglutinin (HA) epitope tag upstream of an endogenous C-terminal KEK motif resulted in a significant loss of activity compared to the un-tagged construct, indicating that the endogenous KEK C-terminal di-lysine motif is capable of directing in yeast the ER-retention of this normally plastidial-located protein. Western blotting analysis of constructs with internal HA epitope revealed that in whole cell extracts, with the exception of the one bound to C-terminal, it did not display a reduced level of protein accumulation. Whilst ferredoxin was shown to be required for HaFAD7 activity in yeast, it appears not necessary for protein stability and accumulation of this plastidial desaturase in the endoplasmic reticulum.     

Role of the DnaK and HscA homologs of Hsp70 chaperones in protein folding in E.coli.

Folding of newly synthesized cytosolic proteins has been proposed to require assistance by Hsp70 chaperones. We investigated whether two Hsp70 homologs of Escherichia coli, DnaK and HscA, have this role in vivo. Double mutants lacking dnaK and hscA were viable and lacked defects in protein folding at intermediate temperature. After heat shock, a subpopulation of pre-existing proteins slowly aggregated in mutants lacking DnaK, but not HscA, whereas the bulk of newly synthesized proteins displayed wild-type solubility. For thermolabile firefly luciferase, DnaK was dispensable for de novo folding at 30 degrees C, but essential for aggregation prevention during heat shock and subsequent refolding. DnaK and HscA are thus not strictly essential for folding of newly synthesized proteins. DnaK instead has functions in refolding of misfolded proteins that are essential under stress.     

Hydrophilic residues 526 KNDAAD 531 in the flexible C-terminal region of the chaperonin GroEL are critical for substrate protein folding within the central cavity

The final 23 residues in the C-terminal region of Escherichia coli GroEL are invisible in crystallographic analyses due to high flexibility. To probe the functional role of these residues in the chaperonin mechanism, we generated and characterized C-terminal truncated, double ring, and single ring mutants of GroEL. The ability to assist the refolding of substrate proteins rhodanese and malate dehydrogenase decreased suddenly when 23 amino acids were truncated, indicating that a sudden change in the environment within the central cavity had occurred. From further experiments and analyses of the hydropathy of the C-terminal region, we focused on the hydrophilicity of the sequence region (26 KNDAAD 531 and generated two GroEL mutants where these residues were changed to a neutral hydropathy sequence (526 GGGAAG 531) and a hydrophobic sequence (526 IGIAAI 531), respectively. Very interestingly, the two mutants were found to be defective in function both in vitro and in vivo. Deterioration of function was not observed in mutants where this region was replaced by a scrambled (526 NKADDA 531) or homologous (526 RQEGGE 531) sequence, indicating that the hydrophilicity of this sequence was important. These results highlight the importance of the hydrophilic nature of 526 KNDAAD 531 residues in the flexible C-terminal region for proper protein folding within the central cavity of GroEL.     

Sorting of soluble ER proteins in yeast.

In animal cells, luminal endoplasmic reticulum (ER) proteins are prevented from being secreted by a sorting system that recognizes the C-terminal sequence KDEL. We show that yeast has a similar sorting system, but it recognizes HDEL, rather than KDEL: derivatives of the enzyme invertase that bear the HDEL signal fail to be secreted. An invertase fusion protein that is retained in the cells is partially modified by outer-chain mannosyl transferases, which reside in the Golgi element. This supports the view, based on studies in animal cells, that ER targeting is achieved by continuous retrieval of proteins from the Golgi. We have used an invertase fusion gene to screen for mutants that are defective in this sorting system. Over 60 mutants were obtained; eight of these are alleles of a single gene, erd1. The mutant strains grow normally at 30 degrees C, but instead of retaining the fusion protein in the cells, they secrete it.     

The type I Hsp40 zinc finger-like region is required for Hsp70 to capture non-native polypeptides from Ydj1

The cytosolic yeast Hsp40 Ydj1 contains a conserved zinc finger-like region (ZFLR), which has two zinc-binding domains (ZBD), that helps regulate and specify Hsp70 function. To investigate the mechanism for Ydj1 ZFLR action, ZBDI and ZBDII mutants were constructed and characterized. ZBDII mutants exhibited temperature-sensitive growth defects, but yeast tolerated mutation of ZBDI. However, ZBDI and ZBDII mutants were defective at facilitating androgen receptor (AR) folding. Defective AR folding was associated with the accumulation of complexes between AR and Ydj1 ZFLR mutants and a reduction in Hsp70.AR complex formation. Purified Ydj1 ZBDI and ZBDII mutants could bind non-native polypeptides but could not deliver luciferase to Hsp70 and were defective at luciferase refolding. Interestingly, the ability of Ydj1 to synergize with Hsp70 to suppress thermally induced protein aggregation was blocked by mutation of ZBDII, but not ZBDI. Hence, ZBDII is required for yeast to survive heat stress because it is essential for Ydj1 to cooperate with Hsp70 to suppress protein aggregation. On the other hand, protein folding is dependent upon the action of both ZBDI and ZBDII because each is required for Hsp70 to capture non-native polypeptides from Ydj1.     

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 proteasome activator PA28 functions in collaboration with Hsp90 in vivo

We have previously shown that the proteasome activator PA28 is essential to Hsp90-dependent protein refolding in vitro, where PA28 mediates transfer of the Hsp90-bound substrate protein to the Hsc70/Hsp40 chaperone machine for its correct refolding. This observation suggests that PA28 may also collaborate with Hsp90 in cells. To examine this possibility, here we have used double-stranded RNA interference (RNAi) against PA28 in Caenorhabditis elegans mutants of daf-21, which encodes Hsp90. We show that C. elegans PA28 facilitates Hsp90-initiated protein refolding, albeit with an activity lower than that of mouse PA28 proteins. RNAi-mediated knockdown of PA28 significantly suppresses the Daf-c (dauer formation constitutive) phenotype of the daf-21 mutant, but it has no affect on the distinct defects of this mutant in sensing odorants. Taking these results together, we conclude that PA28 is likely to function in collaboration with Hsp90 in vivo.     

Isolation and Characterization of Prototrophic Mutants of Escherichia coli Unable to Support the Intracellular Growth of T7

Mutants of E. coli B/1 were isolated which grew normally but did not permit the intracellular growth of bacteriophage T7. Two classes of mutants were studied in detail (tsnB(-) and tsnC(-)). These strains adsorbed T7 normally and were killed by the infection. Synthesis of T7 RNA and of early and late classes of T7 proteins occurred normally after infection. In T7-infected tsnB(-) cells, T7 DNA synthesis stopped prematurely shortly after its onset, suggesting that the tsnB function affects a step in the late phase of T7 DNA replication. Mutants of T7 were isolated (T7beta) which could grow on tsnB(-) cells. In T7-infected tsnC(-) cells, T7 DNA synthesis was completely blocked, suggesting that the tsnC function affects a step in an early phase of T7 DNA replication.     

Mitochondrial Hsp60, resistance to oxidative stress,and the labile iron pool are closely connected in Saccharomyces cerevisiae

In the present study, we have analyzed the role of the molecular chaperone Hsp60 in protection of Saccharomyces cerevisiae against oxidative damage. We constructed mutant strains in which the levels of Hsp60 protein, compared with wild-type cells, were four times greater, and the addition of doxycycline gradually reduces them to 20% of wild-type. Under oxidative-stress conditions, the progressive decrease in Hsp60 levels in these mutants resulted in reduced cell viability and an increase in both cell peroxide species and protein carbonyl content. Protection of Fe/S-containing enzymes from oxidative inactivation was found to be dose-dependent with respect to Hsp60 levels. As these enzymes release their iron ions under oxidative-stress conditions, the intracellular labile iron pool, monitored with calcein, was higher in cells with reduced Hsp60 levels. Consistently, the iron chelator deferoxamine protected low Hsp60-expressing cells from both oxidant-induced death and protein oxidation. These results indicate that the role of Hsp60 in oxidative-stress defense is explained by protection of several Fe/S proteins, which prevent the release of iron ions and thereby avert further damage.     

Genetic evidence for a functional relationship between Hsp104 and Hsp70.

The phenotypes of single Hsp104 and Hsp70 mutants of the budding yeast Saccharomyces cerevisiae provide no clue that these proteins are functionally related. Mutation of the HSP104 gene severely reduces the ability of cells to survive short exposures to extreme temperatures (thermotolerance) but has no effect on growth rates. On the other hand, mutations in the genes that encode Hsp70 proteins have significant effects on growth rates but do not reduce thermotolerance. The absence of a thermotolerance defect in S. cerevisiae Hsp70 mutants is puzzling, since the protein clearly plays an important role in thermotolerance in a variety of other organisms. In this report, examination of the phenotypes of combined Hsp104 and Hsp70 mutants uncovers similarities in the functions of Hsp104 and Hsp70 not previously apparent. In the absence of the Hsp104 protein, Hsp70 is very important for thermotolerance in S. cerevisiae, particularly at very early times after a temperature upshift. Similarly, Hsp104 plays a substantial role in vegetative growth under conditions of decreased Hsp70 protein levels. These results suggest a close functional relationship between Hsp104 and Hsp70.