The heat-shock DnaK protein is required for plasmid R1 replication and it is dispensable for plasmid ColE1 replication.

Plasmid R1 replication in vitro is inactive in extracts prepared from a dnaK756 strain but is restored to normal levels upon addition of purified DnaK protein. Replication of R1 in extracts of a dnaKwt strain can be specifically inhibited with polyclonal antibodies against DnaK. RepA-dependent replication of R1 in dnaK756 extracts supplemented with DnaKwt protein at maximum concentration is partially inhibited by rifampicin and it is severely inhibited at sub-optimal concentrations of DnaK protein. The copy number of a run-away R1 vector is reduced in a dnaK756 background at 30 degrees C and at 42 degrees C the amplification of the run-away R1 vector is prevented. However a runaway R1 vector containing dnaK gene allows the amplification of the plasmid at high temperature. These data indicate that DnaK is required for both in vitro and in vivo replication of plasmid R1 and show a partial compensation for the low level of DnaK by RNA polymerase. In contrast ColE1 replication is not affected by DnaK as indicated by the fact that ColE1 replicates with the same efficiency in extracts from dnaKwt and dnaK756 strains.     

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.     

DnaK mutants defective in ATPase activity are defective in negative regulation of the heat shock response: expression of mutant DnaK proteins results in filamentation.

Site-directed mutagenesis has previously been used to construct Escherichia coli dnaK mutants encoding proteins that are altered at the site of in vitro phosphorylation (J. S. McCarty and G. C. Walker, Proc. Natl. Acad. Sci. USA 88:9513-9517, 1991). These mutants are unable to autophosphorylate and are severely defective in ATP hydrolysis. These mutant dnaK genes were placed under the control of the lac promoter and were found not to complement the deficiencies of a delta dnaK mutant in negative regulation of the heat shock response. A decrease in the expression of DnaK and DnaJ below their normal levels at 30 degrees C was found to result in increased expression of GroEL. The implications of these results for DnaK's role in the negative regulation of the heat shock response are discussed. Evidence is also presented indicating the existence of a 70-kDa protein present in a delta dnaK52 mutant that cross-reacts with antibodies raised against DnaK. Derivatives of the dnaK+ E. coli strain MC4100 expressing the mutant DnaK proteins filamented severely at temperatures equal to or greater than 34 degrees C. In the dnaK+ E. coli strain W3110, expression of these mutant proteins caused extreme filamentation even at 30 degrees C. Together with other observations, these results suggest that DnaK may play a direct role in the septation pathway, perhaps via an interaction with FtsZ. Although delta dnaK52 derivatives of strain MC4100 filament extensively, a level of underexpression of DnaK and DnaJ that results in increased expression of the other heat shock proteins did not result in filamentation. The delta dnaK52 allele could be transduced successfully, at temperatures of up to 45 degrees C, into strains carrying a plasmid expressing dnaK+ dnaJ+, although the yield of transductants decreased above 37 degrees C. In contrast, with a strain that did not carry a plasmid expressing dnaK+ dnaJ+, the yield of delta dnaK52 transductants decreased extremely sharply between 39 and 40 degrees C, suggesting that DnaK and DnaJ play one or more roles critical for growth at temperatures of 40 degrees C or greater.     

DnaK-facilitated ribosome assembly in Escherichia coli revisited

Assembly helpers exist for the formation of ribosomal subunits. Such a function has been suggested for the DnaK system of chaperones (DnaK, DnaJ, GrpE). Here we show that 50S and 30S ribosomal subunits from an Escherichia coli dnaK-null mutant (containing a disrupted dnaK gene) grown at 30 degrees C are physically and functionally identical to wild-type ribosomes. Furthermore, ribosomal components derived from mutant 30S and 50S subunits are fully competent for in vitro reconstitution of active ribosomal subunits. On the other hand, the DnaK chaperone system cannot circumvent the necessary heat-dependent activation step for the in vitro reconstitution of fully active 30S ribosomal subunits. It is therefore questionable whether the requirement for DnaK observed during in vivo ribosome assembly above 37 degrees C implicates a direct or indirect role for DnaK in this process.     

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)     

Functional defects of the DnaK756 mutant chaperone of Escherichia coli indicate distinct roles for amino- and carboxyl-terminal residues in substrate and co-chaperone interaction and interdomain communication

The first discovery of an Hsp70 chaperone gene was the isolation of an Escherichia coli mutant, dnaK756, which rendered the cells resistant to lytic infection with bacteriophage lambda. The DnaK756 mutant protein has since been used to establish many of the cellular roles and biochemical properties of DnaK. DnaK756 has three glycine-to-aspartate substitutions at residues 32, 455, and 468, which were reported to result in defects in intrinsic and GrpE-stimulated ATPase activities, substrate binding, stability of the substrate-binding domain, interdomain communication, and, consequently, defects in chaperone activity. To dissect the effects of the different amino acid substitutions in DnaK756, we analyzed two DnaK variants carrying only the amino-terminal (residue 32) or the two carboxyl-terminal (residues 455 and 468) substitutions. The amino-terminal substitution interfered with the GrpE-stimulated ATPase activity. The carboxyl-terminal mutations (i) affected stability and function of the substrate-binding domain, (ii) caused a 10-fold elevated ATP hydrolysis rate, but (iii) did not severely affect domain coupling. Surprisingly, DnaK chaperone activity was more severely compromised by the amino-terminal than by the carboxyl-terminal amino acid substitutions both in vivo and in vitro. In the in vitro refolding of denatured firefly luciferase, the defect of the DnaK variant carrying the amino-terminal substitution results from its inability to release, upon GrpE-mediated nucleotide exchange, bound luciferase in a folding competent state. Our results indicate that the DnaK-DnaJ-GrpE chaperone system can tolerate suboptimal substrate binding, whereas the tight kinetic control of substrate dissociation by GrpE is essential.     

Escherichia coli DnaK and GrpE heat shock proteins interact both in vivo and in vitro.

Previous studies have demonstrated that the Escherichia coli dnaK and grpE genes code for heat shock proteins. Both the Dnak and GrpE proteins are necessary for bacteriophage lambda DNA replication and for E. coli growth at all temperatures. Through a series of genetic and biochemical experiments, we have shown that these heat shock proteins functionally interact both in vivo and in vitro. The genetic evidence is based on the isolation of mutations in the dnaK gene, such as dnaK9 and dnaK90, which suppress the Tr- phenotype of bacteria carrying the grpE280 mutation. Coimmunoprecipitation of DnaK+ and GrpE+ proteins from cell lysates with anti-DnaK antibodies demonstrated their interaction in vitro. In addition, the DnaK756 and GrpE280 mutant proteins did not coimmunoprecipitate efficiently with the GrpE+ and DnaK+ proteins, respectively, suggesting that interaction between the DnaK and GrpE proteins is necessary for E. coli growth, at least at temperatures above 43 degrees C. Using this assay, we found that one of the dnaK suppressor mutations, dnaK9, reinstated a protein-protein interaction between the suppressor DnaK9 and GrpE280 proteins.     

The in vivo and in vitro characterization of DnaK from Agrobacterium tumefaciens RUOR

Molecular chaperones of the heat shock protein 70 family (Hsp70; also called DnaK in prokaryotes) play an important role in the folding and functioning of cellular protein machinery. The dnaK gene from the plant pathogen Agrobacterium tumefaciens RUOR was amplified using the polymerase chain reaction and the DnaK protein (Agt DnaK) was over-produced as a His-tagged protein in Escherichia coli. The Agt DnaK amino acid sequence was 96% identical to the A. tumefaciens C58 DnaK sequence and 65% identical to the E. coli DnaK sequence. Agt DnaK was shown to be able to functionally replace E. coli DnaK in vivo using complementation assays with an E. coli dnaK756 mutant strain and a dnaK52 deletion strain. Over-production and purification of Agt DnaK was successful, and allowed for further characterization of the protein. Kinetic analysis of the basal ATPase activity of purified Agt DnaK revealed a Vmax of 1.3 nmol phosphate released per minute per milligram DnaK, and a Km of 62 microM ATP. Thus, this is the first study to provide both in vivo and in vitro evidence that Agt DnaK has the properties of a molecular chaperone of the Hsp70 family.     

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.     

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)     

Authentic precursors to ribosomal subunits accumulate in Escherichia coli in the absence of functional DnaK chaperone

Escherichia coli dnaK-ts mutants are defective in the late stages of ribosome biogenesis at high temperature. Here, we show that the 21S, 32S and 45S ribosomal particles that accumulate in the dnaK756-ts mutant at 44 degrees C contain unprocessed forms of their 16S and 23S rRNAs (partially processed in the case of 45S particles). Their 5S rRNA stoichiometry and ribosomal protein composition are typical of the genuine ribosomal precursors found in a wild-type (dnaK+) strain. Despite the lack of a functional DnaK, a very slow maturation of these 21S, 32S and 45S particles to structurally and functionally normal 30S and 50S ribosomal subunits still occurs at high temperature. This conversion is accompanied by the processing of p16S and p23S rRNAs to their mature forms. We conclude that: (i) 21S, 32S and 45S particles are not dead-end particles, but true precursors to active ribosomes (21S particles are converted to 30S subunits, and 32S and 45S to 50S subunits); (ii) DnaK is not absolutely necessary for ribosome biogenesis, but accelerates the late steps of this process considerably at high temperature; and (iii) 23S rRNA processing depends on the stage reached in the stepwise assembly of the 50S subunit, not directly on DnaK.     

Delta dnaK52 mutants of Escherichia coli have defects in chromosome segregation and plasmid maintenance at normal growth temperatures.

Major heat shock proteins, such as the Escherichia coli DnaK protein, not only are required for cell growth after heat shock but seem to possess important functions in cellular metabolism at normal growth temperatures as well. E. coli delta dnaK52 mutants have severe cellular defects at 30 degrees C, one of which is in cell division (B. Bukau and G. C. Walker, J. Bacteriol, 171:2337-2346, 1989). Here we show that at 30 degrees C, delta dnaK52 mutants have defects in chromosome segregation and in maintenance of low-copy-number plasmids. Fluorescence microscopic analysis revealed that chromosomes were frequently lacking at peripheries of cell filaments of delta dnaK52 mutants and clustered at other locations. In other parts of the cell filaments, chromosomes were apparently normally distributed and they were also present in most of the small cells found in populations of delta dnaK52 cells. These defects might be at the level of DNA replication, since delta dnaK52 mutants have a threshold lower rate of DNA synthesis than wild-type cells. Chromosome segregation defects of delta dnaK52 mutants were also observed in an rnh dnaA mutant background, in which initiation of DNA replication is DnaA-oriC independent. We also found that low-copy-number P1 miniplasmids could not be stably maintained in delta dnaK52 mutants at 30 degrees C. delta par P1 miniplasmids that carry the P1-encoded rep functions required for their replication but lack the P1-encoded par functions required for faithful partitioning of the plasmids during cell division were also unstable in delta dnaK52 mutants. Taken together, our results indicate important, although not absolutely essential, functions for DnaK at 30 degrees C in one or more processes necessary for correct replication and/or partitioning of chromosomes and P1 miniplasmids. Furthermore, we found that P1 miniplasmids were also highly unstable in dnaJ259 mutants, indicating a role for the DnaJ heat shock protein in maintenance of these plasmids.     

Role of heat shock protein DnaK in osmotic adaptation of Escherichia coli.

Escherichia coli can adapt and recover growth at high osmolarity. Adaptation requires the deplasmolysis of cells previously plasmolyzed by the fast efflux of water promoted by osmotic upshift. Deplasmolysis is essentially ensured by a net osmo-dependent influx of K+. The cellular content of the heat shock protein DnaK is increased in response to osmotic upshift and does not decrease as long as osmolarity is high. The dnaK756(Ts) mutant, which fails to deplasmolyze and recover growth, does not take up K+ at high osmolarity; DnaK protein is required directly or indirectly for the maintenance of K+ transport at high osmolarity. The temperature-sensitive mutations dnaJ259 and grpE280 do not affect the osmoadaptation of E. coli at 30 degrees C.     

Identification of a gene, closely linked to dnaK, which is required for high-temperature growth of Escherichia coli.

We have constructed four deletion derivatives of the cloned dnaK gene. Plasmid pDD1, in which the last 10 amino acids of the DnaK protein have been replaced by three different amino acids derived from the pBR322 vector, was as effective as plasmid pKP31, from which it was derived, in restoring the ability of a dnaK null mutant, Escherichia coli BB1553, to plate lambda phage and to grow at high temperatures. The other three mutations, involving much larger deletions of the dnaK gene, did not restore the ability to plate lambda phage or the ability to grow at high temperatures. Plasmid pKUC2, which contains the whole dnaK gene and its promoters, was capable of restoring the ability of E. coli BB1553 to plate lambda phage but, surprisingly, it did not restore the ability to grow at high temperatures, even though it was shown that the DnaK protein was efficiently expressed in these cultures. By transposon mutagenesis and sub-cloning, we have shown the presence of a second gene in plasmid pKP31 which is required for high-temperature growth of E. coli BB1553. This gene, which we call htg A, is presumably also defective in the dnaK null mutant E. coli BB1553. We have also demonstrated that the inability of E. coli K756 to grow above 43.5 degrees C is complemented by sub-clones which contain the htg A gene, but not by plasmid pKUC2.     

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.     

Characterization of the dnaK multigene family in the Cyanobacterium Synechococcus sp. strain PCC7942

The cyanobacterium Synechococcus sp. strain PCC7942 has three dnaK homologues (dnaK1, dnaK2, and dnaK3), and a gene disruption experiment was carried out for each dnaK gene by inserting an antibiotic resistance marker. Our findings revealed that DnaK1 was not essential for normal growth, whereas DnaK2 and DnaK3 were essential. We also examined the effect of heat shock on the levels of these three DnaK and GroEL proteins and found a varied response to heat shock, with levels depending on each protein. The DnaK2 and GroEL proteins exhibited a typical heat shock response, that is, their synthesis increased upon temperature upshift. In contrast, the synthesis of DnaK1 and DnaK3 did not respond to heat shock; in fact, the level of DnaK1 protein decreased. We also analyzed the effect of overproduction of each DnaK protein in Escherichia coli cells using an inducible expression system. Overproduction of DnaK1 or DnaK2 resulted in defects in cell septation and formation of cell filaments. On the other hand, overproduction of DnaK3 did not result in filamentous cells; rather a swollen and twisted cell morphology was observed. When expressed in an E. coli dnaK756 mutant, dnaK2 could suppress the growth deficiency at the nonpermissive temperature, while dnaK1 and dnaK3 could not suppress this phenotype. On the contrary, overproduction of DnaK1 or DnaK3 resulted in growth inhibition at the permissive temperature. These results suggest that different types of Hsp70 in the same cellular compartment have specific functions in the cell.     

Mutations altering heat shock specific subunit of RNA polymerase suppress major cellular defects of E. coli mutants lacking the DnaK chaperone.

An Escherichia coli mutant lacking HSP70 function, delta dnaK52, is unable to grow at both high and low temperatures and, at intermediate temperature (30 degrees C), displays defects in major cellular processes such as cell division, chromosome segregation and regulation of heat shock gene expression that lead to poor growth and genetic instability of the cells. In an effort to understand the roles of molecular chaperones such as DnaK in cellular metabolism, we analyzed secondary mutations (sid) that suppress the growth defects of delta dnaK52 mutants at 30 degrees C and also permit growth at low temperature. Of the five suppressors we analyzed, four were of the sidB class and mapped within rpoH, which encodes the heat shock specific sigma subunit (sigma 32) of RNA polymerase. The sidB mutations affected four different regions of the sigma 32 protein and, in one case, resulted in a several fold reduction in the cellular concentration of sigma 32. Presence of any of the sidB mutations in delta dnaK52 mutants as well as in dnaK+ cells caused down-regulation of heat shock gene expression at 30 degrees C and decreased induction of the heat shock response after shift to 43.5 degrees C. These findings suggest that the physiologically most significant function of DnaK in the metabolism of unstressed cells is its function in heat shock gene regulation.