The DnaK chaperone is necessary for alpha-complementation of beta-galactosidase in Escherichia coli

We show here the involvement of the molecular chaperone DnaK from Escherichia coli in the in vivo alpha-complementation of the beta-galactosidase. In the dnaK756(Ts) mutant, alpha-complementation occurs when the organisms are grown at 30 degrees C but not at 37 or 40 degrees C, although these temperatures are permissive for bacterial growth. Plasmid-driven expression of wild-type dnaK restores the alpha-complementation in the mutant but also stimulates it in a dnaK(+) strain. In a mutant which contains a disrupted dnaK gene (DeltadnaK52::Cm(r)), alpha-complementation is also impaired, even at 30 degrees C. This observation provides an easy and original phenotype to detect subtle functional changes in a protein such as the DnaK756 chaperone, within the physiologically relevant temperature.     

Viability of rep recA mutants depends on their capacity to cope with spontaneous oxidative damage and on the DnaK chaperone protein

Replication arrests due to the lack or the inhibition of replicative helicases are processed by recombination proteins. Consequently, cells deficient in the Rep helicase, in which replication pauses are frequent, require the RecBCD recombination complex for growth. rep recA mutants are viable and display no growth defect at 37 or 42 degrees C. The putative role of chaperone proteins in rep and rep recA mutants was investigated by testing the effects of dnaK mutations. dnaK756 and dnaK306 mutations, which allow growth of otherwise wild-type Escherichia coli cells at 40 degrees C, are lethal in rep recA mutants at this temperature. Furthermore, they affect the growth of rep mutants, and to a lesser extent, that of recA mutants. We conclude that both rep and recA mutants require DnaK for optimal growth, leading to low viability of the triple (rep recA dnaK) mutant. rep recA mutant cells form colonies at low efficiency when grown to exponential phase at 30 degrees C. Although the plating defect is not observed at a high temperature, it is not suppressed by overexpression of heat shock proteins at 30 degrees C. The plating defect of rep recA mutant cells is suppressed by the presence of catalase in the plates. The cryosensitivity of rep recA mutants therefore results from an increased sensitivity to oxidative damage upon propagation at low temperatures.     

Escherichia coli dnaK null mutants are inviable at high temperature.

DnaK, a major Escherichia coli heat shock protein, is homologous to major heat shock proteins (Hsp70s) of Drosophila melanogaster and humans. Null mutations of the dnaK gene, both insertions and a deletion, were constructed in vitro and substituted for dnaK+ in the E. coli genome by homologous recombination in a recB recC sbcB strain. Cells carrying these dnaK null mutations grew slowly at low temperatures (30 and 37 degrees C) and could not form colonies at a high temperature (42 degrees C); furthermore, they also formed long filaments at 42 degrees C. The shift of the mutants to a high temperature evidently resulted in a loss of cell viability rather than simply an inhibition of growth since cells that had been incubated at 42 degrees C for 2 h were no longer capable of forming colonies at 30 degrees C. The introduction of a plasmid carrying the dnaK+ gene into these mutants restored normal cell growth and cell division at 42 degrees C. These null mutants showed a high basal level of synthesis of heat shock proteins except for DnaK, which was completely absent. In addition, the synthesis of heat shock proteins after induction in these dnaK null mutants was prolonged compared with that in a dnaK+ strain. The well-characterized dnaK756 mutation causes similar phenotypes, suggesting that they are caused by a loss rather than an alteration of DnaK function. The filamentation observed when dnaK mutations were incubated at a high temperature was not suppressed by sulA or sulB mutations, which suppress SOS-induced filamentation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Roles of the Escherichia coli Small Heat Shock Proteins IbpA and IbpB in Thermal Stress Management: Comparison with ClpA, ClpB, and HtpG In Vivo

We have constructed an Escherichia coli strain lacking the small heat shock proteins IbpA and IbpB and compared its growth and viability at high temperatures to those of isogenic cells containing null mutations in the clpA, clpB, or htpG gene. All mutants exhibited growth defects at 46°C, but not at lower temperatures. However, the clpA, htpG, and ibp null mutations did not reduce cell viability at 50°C. When cultures were allowed to recover from transient exposure to 50°C, all mutations except Δibp led to suboptimal growth as the recovery temperature was raised. Deletion of the heat shock genes clpB and htpG resulted in growth defects at 42°C when combined with the dnaK756 or groES30 alleles, while the Δibp mutation had a detrimental effect only on the growth of dnaK756 mutants. Neither the overexpression of these heat shock proteins nor that of ClpA could restore the growth of dnaK756 or groES30 cells at high temperatures. Whereas increased levels of host protein aggregation were observed in dnaK756 and groES30 mutants at 46°C compared to wild-type cells, none of the null mutations had a similar effect. These results show that the highly conserved E. coli small heat shock proteins are dispensable and that their deletion results in only modest effects on growth and viability at high temperatures. Our data also suggest that ClpB, HtpG, and IbpA and -B cooperate with the major E. coli chaperone systems in vivo.     

Involvement of the chaperonin dnaK in the rapid degradation of a mutant protein in Escherichia coli.

The ability of Escherichia coli rapidly to degrade abnormal proteins is inhibited by mutations affecting any of several heat shock proteins (hsps). We therefore tested whether a short-lived mutant protein might become associated with hsps as part of its degradation. At 30 degrees C, the non-secreted mutant form of alkaline phosphatase, phoA61, is relatively stable, and very little phoA61 is found associated with the hsp dnaK. However, raising the temperature to 37 degrees C or 41 degrees C stimulated the degradation of this protein, and up to 30% of cellular phoA61 became associated with dnaK, as shown by immunoprecipitation and Western blot analysis. Also found in complexes with phoA61 were the hsps, protease La and grpE (but no groEL, or groES). The rapid degradation of phoA61 at 37 degrees C and 41 degrees C is in part by protease La, since it decreased by 50% in lon mutants. This process also requires dnaK, since deletion of this gene prevented phoA61 degradation almost completely (unless a wild-type dnaK gene was introduced). In contrast, the missense mutation, dnaK756, enhanced phoA61 degradation. The dnaK756 protein also was associated with phoA61, but this complex, unlike that containing wild-type dnaK could not be dissociated by ATP addition. Furthermore, in a grpE mutant, the degradation of phoA61 and the amount associated with dnaK increased, while in a dnaJ mutant, phoA61 degradation and its association with dnaK decreased. Thus, complex formation with dnaK appears essential for phoA61 degradation by protease La and some other cell proteases, and a failure of the dnaK to dissociate normally may accelerate proteolytic attack.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chaperone Hsp31 contributes to acid resistance in stationary-phase Escherichia coli

Hsp31, the product of the sigmaS - and sigmaD -dependent hchA gene, is a heat-inducible chaperone implicated in the management of protein misfolding at high temperatures. We show here that Hsp31 plays an important role in the acid resistance of starved Escherichia coli but that it has little influence on oxidative-stress survival.     

Self-association and chaperone activity of Hsp27 are thermally activated

The small heat shock protein 27 (Hsp27) is an oligomeric, molecular chaperone in vitro. This chaperone activity and other physiological roles attributed to Hsp27 have been reported to depend on the state of self-association. In the present work, we have used sedimentation velocity experiments to demonstrate that the self-association of Hsp27 is independent of pH and ionic strength but increases significantly as the temperature is increased from 10 to 40 degrees C. The largest oligomers formed at 10 degrees C are approximately 8-12 mer, whereas at 40 degrees C oligomers as large as 22-30 mer are observed. Similarly, the chaperone activity of Hsp27 as indicated by its ability to inhibit dithiothreitol-induced insulin aggregation also increases with increased temperature, with a particularly sharp increase in activity as temperature is increased from 34 to 43 degrees C. Similar studies of an Hsp27 triple variant that mimics the behavior of the phosphorylated protein establish that this protein has greatly diminished chaperone activity that responds minimally to increased temperature. We conclude that Hsp27 can exploit a large number of oligomerization states and that the range of oligomer size and the magnitude of chaperone activity increase significantly as temperature is increased over the range that is relevant to the physiological heat shock response.     

Phosphorylation of glutaminyl-tRNA synthetase and threonyl-tRNA synthetase by the gene products of dnaK and dnaJ in Escherichia coli K-12 cells

In Escherichia coli K-12, the heat shock protein DnaK and DnaJ participate in phosphorylation of both glutaminyl-tRNA synthetase and threonyl-tRNA synthetase since when cellular proteins extracted from the dnaK7(Ts), dnaK756(Ts) and dnaJ259(Ts) mutant cells labeled with 32Pi at 42 degrees C were analyzed by two-dimensional gel electrophoresis, no phosphorylation of glutaminyl-tRNA synthetase and threonyl-tRNA synthetase was observed while phosphorylation of both aminoacyl-tRNA synthetases was detected in the samples extracted from wild-type cells.     

The role of DnaK/DnaJ and GroEL/GroES systems in the removal of endogenous proteins aggregated by heat-shock from Escherichia coli cells

The submission of Escherichia coli cells to heat-shock (45 degrees C, 15 min) caused the intracellular aggregation of endogenous proteins. In the wt cells the aggregates (the S fraction) disappeared 10 min after transfer to 37 degrees C. In contrast, the S fraction in the dnaK and dnaJ mutant strains was stable during approximately one generation time (45 min). This demonstrated that neither the renaturation nor the degradation of the denatured proteins was possible in the absence of DnaK and DnaJ. The groEL44 and groES619 mutations stabilised the aggregates to a lesser extent. It was shown by the use of cloned genes, dnaK/dnaJ or groEL/groES, producing the corresponding proteins in about 4-fold excess, that the appearance of the S fraction in the wt strain resulted from a transiently insufficient supply of the heat-shock proteins. Overproduction of the GroEL/GroES proteins in dnaK756 or dnaJ259 background prevented the aggregation, however, overproduction of the DnaK/DnaJ proteins did not prevent the aggregation in the groEL44 or groES619 mutant cells although it accelerated the disappearance of the aggregates. The properties of the aggregated proteins are discussed from the point of view of their competence to renaturation/degradation by the heat-shock system.     

Cellular defects caused by deletion of the Escherichia coli dnaK gene indicate roles for heat shock protein in normal metabolism.

DnaK is a major heat shock protein of Escherichia coli and has been previously reported to be essential for growth at high temperatures. We systematically investigated the role of DnaK in cellular metabolism at a wide range of growth temperatures by analyzing cellular defects caused by deletion of the dnaK gene (delta dnaK52). At intermediate temperatures (30 degrees C), introduction of the delta dnaK52 allele into wild-type cells caused severe defects in cell division, slow growth, and poor viability of the cells. delta dnaK52 mutants were genetically unstable at 30 degrees C and frequently acquired secondary mutations. At high (42 degrees C) and low (11 and 16 degrees C) temperatures the delta dnaK52 allele could only be introduced into the subpopulation of wild-type cells that had duplicated the dnaK region of their chromosome. delta dnaK52 mutants isolated at 30 degrees C were cold sensitive as well as temperature sensitive for growth. Cell division defects of delta dnaK52 mutants at 30 degrees C were largely suppressed by overproduction of the FtsZ protein, which is normally required for septation during cell division; however, slow growth and poor viability at 30 degrees C and cold sensitivity and temperature sensitivity of growth were not suppressed, indicating that delta dnaK52 mutants had additional defective cellular functions besides cell division.     

Hsp31 Is a Stress Response Chaperone That Intervenes in the Protein Misfolding Process

The Saccharomyces cerevisiae heat shock protein Hsp31 is a stress-inducible homodimeric protein that is involved in diauxic shift reprogramming and has glyoxalase activity. We show that substoichiometric concentrations of Hsp31 can abrogate aggregation of a broad array of substrates in vitro. Hsp31 also modulates the aggregation of α-synuclein (αSyn), a target of the chaperone activity of human DJ-1, an Hsp31 homolog. We demonstrate that Hsp31 is able to suppress the in vitro fibrillization or aggregation of αSyn, citrate synthase and insulin. Chaperone activity was also observed in vivo because constitutive overexpression of Hsp31 reduced the incidence of αSyn cytoplasmic foci, and yeast cells were rescued from αSyn-generated proteotoxicity upon Hsp31 overexpression. Moreover, we showed that Hsp31 protein levels are increased by H₂O₂, in the diauxic phase of normal growth conditions, and in cells under αSyn-mediated proteotoxic stress. We show that Hsp31 chaperone activity and not the methylglyoxalase activity or the autophagy pathway drives the protective effects. We also demonstrate reduced aggregation of the Sup35 prion domain, PrD-Sup35, as visualized by fluorescent protein fusions. In addition, Hsp31 acts on its substrates prior to the formation of large aggregates because Hsp31 does not mutually localize with prion aggregates, and it prevents the formation of detectable in vitro αSyn fibrils. These studies establish that the protective role of Hsp31 against cellular stress is achieved by chaperone activity that intervenes early in the protein misfolding process and is effective on a wide spectrum of substrate proteins, including αSyn and prion proteins.     

The Yeast AAA+ Chaperone Hsp104 Is Part of a Network That Links the Actin Cytoskeleton with the Inheritance of Damaged Proteins

The yeast AAA⁺ chaperone Hsp104 is essential for the development of thermotolerance and for the inheritance of prions. Recently, Hsp104, together with the actin cytoskeleton, has been implicated in the asymmetric distribution of carbonylated proteins. Here, we investigated the interplay between Hsp104 and actin by using a dominant-negative variant of Hsp104 (HAP/ClpP) that degrades substrate proteins instead of remodeling them. Coexpression of HAP/ClpP causes defects in morphology and the actin cytoskeleton. Taking a candidate approach, we identified Spa2, a member of the polarisome complex, as an Hsp104 substrate. Furthermore, we provided genetic evidence that links Spa2 and Hsp104 to Hof1, a member of the cytokinesis machinery. Spa2 and Hof1 knockout cells are affected in the asymmetric distribution of damaged proteins, suggesting that Hsp104, Spa2, and Hof1 are members of a network controlling the inheritance of carbonylated proteins.The ensemble of molecular chaperones and proteases constitutes the cellular system that repairs and eliminates misfolded proteins. The activity of this system ensures not only the recovery of cells from protein-damaging stress conditions, but also the maintenance of protein homeostasis under normal growth conditions. The concomitant involvement of members of the Hsp70 and Hsp90 chaperone families in stress-related, regulatory, and housekeeping functions allows the integration of environmental stimuli into regulatory networks (4, 24, 39, 40). However, it has remained unclear whether other chaperones are also involved in regulatory processes.One chaperone which so far has been connected only to stress-related protein quality functions is the oligomeric AAA⁺ chaperone Hsp104 of Saccharomyces cerevisiae. Hsp104 is essential for the development of thermotolerance by reactivating aggregated proteins after severe stress conditions and for prion propagation by severing prion fibrils (31). Yeast cells, when grown at 30°C, harbor approximately 5,000 copies of Hsp104 hexamers per cell, a number that is minor compared to other cytosolic chaperone machineries (e.g., Hsp70 and Hsp90) that are involved in general protein-folding events (10). The known cellular functions of Hsp104, however, cannot provide a rationale for the determined Hsp104 levels, since protein aggregation is hardly detectable in yeast cells at 30°C even in mutant cells lacking Hsp104 function. Furthermore, yeast prions occur de novo at a very low rate of 10⁻⁶ per cell. In consequence, both well-characterized Hsp104 activities are barely required at 30°C, suggesting that Hsp104 has additional, so far unknown housekeeping functions. On the other hand, an S. cerevisiae hsp104 knockout exhibits no obvious phenotype at 30°C (27), giving no clues to a potential involvement of Hsp104 in other cellular processes.Recently, Hsp104 was demonstrated to influence the asymmetric distribution of oxidatively damaged (carbonylated) proteins (8). It remained unclear whether the role of Hsp104 in this process relies on its known activities in protein quality control or on an unknown involvement in other cellular processes. Here, we provide evidence that Hsp104 is part of a network that controls the inheritance of damaged proteins under physiological growth conditions.     

The dnaK protein modulates the heat-shock response of Escherichia coli

E. coli bacteria respond to a sudden upward shift in temperature by transiently overproducing a small subset of their proteins, one of which is the product of the dnaK gene. Mutations in dnaK have been previously shown to affect both DNA and RNA synthesis in E. coli. Bacteria carrying the dnaK756 mutation fail to turn off the heat-shock response at 43 degrees C. Instead, they continue to synthesize the heat-shock proteins in large amounts and underproduce other proteins. Both reversion and P1 transduction analyses have shown that the failure to turn off the heat-shock response is the result of the dnaK756 mutation. In addition, bacteria that overproduce the dnaK protein at all temperatures undergo a drastically reduced heat-shock response at high temperature. We conclude that the dnaK protein is an inhibitor of the heat-shock response in E. coli.     

The cytoplasmic chaperone hsp104 is required for conformational repair of heat-denatured proteins in the yeast endoplasmic reticulum

Severe heat stress causes protein denaturation in various cellular compartments. If Saccharomyces cerevisiae cells grown at 24 degrees C are preconditioned at 37 degrees C, proteins denatured by subsequent exposure to 48-50 degrees C can be renatured when the cells are allowed to recover at 24 degrees C. Conformational repair of vital proteins is essential for survival, because gene expression is transiently blocked after the thermal insult. Refolding of cytoplasmic proteins requires the Hsp104 chaperone, and refolding of lumenal endoplasmic reticulum (ER) proteins requires the Hsp70 homologue Lhs1p. We show here that conformational repair of heat-damaged glycoproteins in the ER of living yeast cells required functional Hsp104. A heterologous enzyme and a number of natural yeast proteins, previously translocated and folded in the ER and thereafter denatured by severe heat stress, failed to be refolded to active and secretion-competent structures in the absence of Hsp104 or when an ATP-binding site of Hsp104 was mutated. During recovery at 24 degrees C, the misfolded proteins persisted in the ER, although the secretory apparatus was fully functional. Hsp104 appears to control conformational repair of heat-damaged proteins even beyond the ER membrane.     

The molecular chaperone Hsp78 confers compartment-specific thermotolerance to mitochondria

Hsp78, a member of the family of Clp/Hsp100 proteins, exerts chaperone functions in mitochondria of S. cerevisiae which overlap with those of mitochondrial Hsp70. In the present study, the role of Hsp78 under extreme stress was analyzed. Whereas deletion of HSP78 does not affect cell growth at temperatures up to 39 decrees C and cellular thermotolerance at 50 degrees C, Hsp78 is crucial for maintenance of respiratory competence and for mitochondrial genome integrity under severe temperature stress (mitochondrial thermotolerance). Mitochondrial protein synthesis is identified as a thermosensitive process. Reactivation of mitochondrial protein synthesis after heat stress depends on the presence of Hsp78, though Hsp78 does not confer protection against heat-inactivation to this process. Hsp78 appears to act in concert with other mitochondrial chaperone proteins since a conditioning pretreatment of the cells to induce the cellular heat shock response is required to maintain mitochondrial functions under severe temperature stress. When expressed in the cytosol, Hsp78 can substitute for the homologous heat shock protein Hsp104 in mediating cellular thermotolerance, suggesting a conserved mode of action of the two proteins. Thus, proteins of the Clp/Hsp100-family located in the cytosol and within mitochondria confer compartment-specific protection against heat damage to the cell.     

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.     

Severe oxidative stress causes inactivation of DnaK and activation of the redox-regulated chaperone Hsp33

DnaK/DnaJ/GrpE constitutes the primary chaperone machinery in E. coli that functions to protect proteins against heat-induced protein aggregation. Surprisingly, upon exposure of cells to reactive oxygen species at elevated temperature, proteins are no longer protected by the DnaK system. Instead, they bind now to the redox-regulated chaperone Hsp33, which is activated by the same conditions that inactivate DnaK. The inactivation of DnaK seems to be induced by the dramatic decrease in intracellular ATP levels that occurs upon exposure of cells to reactive oxygen species. This appears to render DnaK's N-terminal ATPase domain nucleotide depleted and thermolabile. DnaK's N terminus reversibly unfolds in vivo, and DnaK loses its ability to protect proteins against stress-induced aggregation. Now, the ATP-independent chaperone holdase Hsp33 binds to a large number of cellular proteins and prevents their irreversible aggregation. Upon return to nonstress conditions, Hsp33 becomes inactivated while DnaK reactivates and resumes its task to support protein folding.