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.     

Complementation of an Escherichia coli DnaK defect by Hsc70-DnaK chimeric proteins

Escherichia coli DnaK and rat Hsc70 are members of the highly conserved 70-kDa heat shock protein (Hsp70) family that show strong sequence and structure similarities and comparable functional properties in terms of interactions with peptides and unfolded proteins and cooperation with cochaperones. We show here that, while the DnaK protein is, as expected, able to complement an E. coli dnaK mutant strain for growth at high temperatures and lambda phage propagation, Hsc70 protein is not. However, an Hsc70 in which the peptide-binding domain has been replaced by that of DnaK is able to complement this strain for both phenotypes, suggesting that the peptide-binding domain of DnaK is essential to fulfill the specific functions of this protein necessary for growth at high temperatures and for lambda phage replication. The implications of these findings on the functional specificities of the Hsp70s and the role of protein-protein interactions in the DnaK chaperone system are discussed.     

Functional similarities and differences of an archaeal Hsp70(DnaK) stress protein compared with its homologue from the bacterium Escherichia coli

Archaea are prokaryotes but some of their chaperoning systems resemble those of eukaryotes. Also, not all archaea possess the stress protein Hsp70(DnaK), in contrast with bacteria and eukaryotes, which possess it without any known exception. Further, the primary structure of the archaeal DnaK resembles more the bacterial than the eukaryotic homologues. The work reported here addresses two questions: Is the archaeal Hsp70 protein a chaperone, like its homologues in the other two phylogenetic domains? And, if so, is the chaperoning mechanism of bacterial or eukaryotic type? The data have shown that the DnaK protein of the archaeon Methanosarcina mazei functions efficiently as a chaperone in luciferase renaturation in vitro, and that it requires DnaJ, and the other bacterial-type chaperone, GrpE, to perform its function. The M. mazei DnaK chaperone activity was enhanced by interaction with the bacterial co-chaperone DnaJ, but not by the eukaryotic homologue HDJ-2. Both the bacterial GrpE and DnaJ stimulated the ATPase activity of the M. mazei DnaK. The M. mazei DnaK-dependent chaperoning pathway in vitro is similar to that of the bacterium Escherichia coli used for comparison. However, in vivo analyses indicate that there are also significant differences. The M. mazei dnaJ and grpE genes rescued E.coli mutants lacking these genes, but E.coli dnaK mutants were not complemented by the M. mazei dnaK gene. Thus, while the data from in vitro tests demonstrate functional similarities between the M. mazei and E.coli DnaK proteins, in vivo results indicate that, intracellularly, the chaperones from the two species differ.     

Structural and functional relationships in DnaK and DnaK756 heat-shock proteins from Escherichia coli.

The secondary structures of DnaK and the mutant DnaK756 heat-shock proteins from Escherichia coli have been investigated by Fourier transform infrared spectroscopy. The analysis of infrared data showed that DnaK and DnaK756 proteins have different secondary structures that are not affected by the presence of ATP or beta, gamma-methyleneadenosine 5'-triphosphate. The infrared data indicate also that the tertiary structures of DnaK and DnaK756 proteins are different and that DnaK protein undergoes conformational changes in its tertiary structure not only during binding of ATP but also during ATP hydrolysis. Using fluorescence spectroscopy of a single tryptophan located in the N-terminal domain of DnaK protein and fluorescence of 1,1'-bis(4-anilino)naphthalene-5,5'-disulfonic acid, which interacts with hydrophobic domains of DnaK protein, we were able to distinguish between two conformational states of DnaK protein. After binding of triphosphonucleotides, the C-terminal domain of DnaK protein changes in tertiary structure in such a way that fewer hydrophobic segments are exposed on the surface of the protein. After ATP hydrolysis, the number of hydrophobic segments on the surface of the protein is further reduced, and moreover the tertiary structure of the N-terminal domain of the protein changes. These data are discussed in terms of structural and functional relationships of both DnaK and DnaK756 proteins.     

All three J-domain proteins of the Escherichia coli DnaK chaperone machinery are DNA binding proteins

DnaJ, DjlA and CbpA are the J-domain proteins of DnaK, the major Hsp70 of Escherichia coli. CbpA was originally discovered as a DNA binding protein. Here, we show that DNA binding is a property of DnaJ and DjlA as well. Of special interest in this respect is DjlA, as this cytoplasmic protein is membrane bound and, as shown here, its affinity for DNA is extremely high. The finding that all the three J-proteins of DnaK are DNA binding proteins sheds new light on the cellular activity of these proteins.     

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.     

Mutations in the substrate binding domain of the Escherichia coli 70 kDa molecular chaperone, DnaK, which alter substrate affinity or interdomain coupling

In Escherichia coli, DnaK is essential for the replication of bacteriophage lambda DNA; this in vivo activity provides the basis of a screen for mutations affecting DnaK function. Mn PCR was used to introduce mutations into residues 405-468 of the C-terminal polypeptide-binding domain of DnaK. These mutant proteins were screened for the ability to propagate bacteriophage lambda in the background of a dnaK deficient cell line, BB1553. This initial screen identified several proteins which were mutant at multiple positions. The multiple mutants were further dissected into single mutants which remained negative for lambda propagation. Four of these single-site mutants were purified and assayed for biochemical functionality. Two single-site mutations, F426S and S427P, are localized in the peptide binding site and display weakened peptide binding affinity. This indicates that the crystallographically determined peptide binding site is also critical for in vivo lambda replication. Two other mutations, K414I and N451K, are located at the edge of the beta-sandwich domain near alpha-helix A. The K414I mutant binds peptide moderately well, yet displays defects in allosteric functions, including peptide-stimulated ATPase activity, ATP-induced changes in tryptophan fluorescence, ATP-induced peptide release, and elevated ATPase activity. The K414 position is close in tertiary structure to the linker region to the ATPase domain and reflects a specific area of the peptide-binding domain which is necessary for interdomain coupling. The mutant N451K displays defects in both peptide binding and allosteric interaction.     

Role of the chaperone DnaK in protein solubility and conformational quality in inclusion body-forming Escherichia coli cells

Misfolding-prone proteins produced in bacteria usually fail to adopt their native conformation and aggregate. In cells producing folding-reluctant protein species, folding modulators are supposed to be limiting, a fact that enhances protein deposition. Therefore, coproducing DnaK or other main chaperones along with the target protein has been a common approach to gain solubility, although with very inconsistent and often discouraging results. In an attempt to understand the reason for this inconsistency, the impact of exogenous DnaK (encoded in an accompanying plasmid) on two protein features observed as indicators of protein quality, namely solubility and functionality, has been analysed here through the specific fluorescence emission of a reporter Green Fluorescent Protein (GFP). Intriguingly, GFP solubility is strongly dependent on its own yield but poorly affected by DnaK levels. On the contrary, the specific fluorescence of both soluble and insoluble GFP populations is simultaneously modulated by the availability of DnaK, with a profile that is clearly dissimilar to that shown by protein solubility. Therefore, solubility, not being coincident with the biological activity of the target protein, might not be a robust indicator of protein quality.     

DnaK functions as a central hub in the E. coli chaperone network

Cellular chaperone networks prevent potentially toxic protein aggregation and ensure proteome integrity. Here, we used Escherichia coli as a model to understand the organization of these networks, focusing on the cooperation of the DnaK system with the upstream chaperone Trigger factor (TF) and the downstream GroEL. Quantitative proteomics revealed that DnaK interacts with at least ~700 mostly cytosolic proteins, including ~180 relatively aggregation-prone proteins that utilize DnaK extensively during and after initial folding. Upon deletion of TF, DnaK interacts increasingly with ribosomal and other small, basic proteins, while its association with large multidomain proteins is reduced. DnaK also functions prominently in stabilizing proteins for subsequent folding by GroEL. These proteins accumulate on DnaK upon GroEL depletion and are then degraded, thus defining DnaK as a central organizer of the chaperone network. Combined loss of DnaK and TF causes proteostasis collapse with disruption of GroEL function, defective ribosomal biogenesis, and extensive aggregation of large proteins.     

The Hsp70 chaperone machines of Escherichia coli: a paradigm for the repartition of chaperone functions

Molecular chaperones are highly conserved in all free-living organisms. There are many types of chaperones, and most are conveniently grouped into families. Genome sequencing has revealed that many organisms contain multiple members of both the DnaK (Hsp70) family and their partner J-domain protein (JDP) cochaperone, belonging to the DnaJ (Hsp40) family. Escherichia coli K-12 encodes three Hsp70 genes and six JDP genes. The coexistence of these chaperones in the same cytosol suggests that certain chaperone-cochaperone interactions are permitted, and that chaperone tasks and their regulation have become specialized over the course of evolution. Extensive genetic and biochemical analyses have greatly expanded knowledge of chaperone tasking in this organism. In particular, recent advances in structure determination have led to significant insights of the underlying complexities and functional elegance of the Hsp70 chaperone machine.     

Cooperative action of Escherichia coli ClpB protein and DnaK chaperone in the activation of a replication initiation protein

The Escherichia coli molecular chaperone protein ClpB is a member of the highly conserved Hsp100/Clp protein family. Previous studies have shown that the ClpB protein is needed for bacterial thermotolerance. Purified ClpB protein has been shown to reactivate chemically and heat-denatured proteins. In this work we demonstrate that the combined action of ClpB and the DnaK, DnaJ, and GrpE chaperones leads to the activation of DNA replication of the broad-host-range plasmid RK2. In contrast, ClpB is not needed for the activation of the oriC-dependent replication of E. coli. Using purified protein components we show that the ClpB/DnaK/DnaJ/GrpE synergistic action activates the plasmid RK2 replication initiation protein TrfA by converting inactive dimers to an active monomer form. In contrast, Hsp78/Ssc1/Mdj1/Mge1, the corresponding protein system from yeast mitochondria, cannot activate the TrfA replication protein. Our results demonstrate for the first time that the ClpB/DnaK/DnaJ/GrpE system is involved in protein monomerization and in the activation of a DNA replication factor.     

Escherichia coli HdeB is an acid stress chaperone

We cloned, expressed, and purified the hdeB gene product, which belongs to the hdeAB acid stress operon. We extracted HdeB from bacteria by the osmotic-shock procedure and purified it to homogeneity by ion-exchange chromatography and hydroxyapatite chromatography. Its identity was confirmed by mass spectrometry analysis. HdeB has a molecular mass of 10 kDa in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, which matches its expected molecular mass. We purified the acid stress chaperone HdeA in parallel in order to compare the two chaperones. The hdeA and hdeB mutants both display reduced viability upon acid stress, and only the HdeA/HdeB expression plasmid can restore their viability to close to the wild-type level, suggesting that both proteins are required for optimal protection of the bacterial periplasm against acid stress. Periplasmic extracts from both mutants aggregate at acidic pH, suggesting that HdeA and HdeB are required for protein solubilization. At pH 2, the aggregation of periplasmic extracts is prevented by the addition of HdeA, as previously reported, but is only slightly reduced by HdeB. At pH 3, however, HdeB is more efficient than HdeA in preventing periplasmic-protein aggregation. The solubilization of several model substrate proteins at acidic pH supports the hypothesis that, in vitro, HdeA plays a major role in protein solubilization at pH 2 and that both proteins are involved in protein solubilization at pH 3. Like HdeA, HdeB exposes hydrophobic surfaces at acidic pH, in accordance with the appearance of its chaperone properties at acidic pH. HdeB, like HdeA, dissociates from dimers at neutral pH into monomers at acidic pHs, but its dissociation is complete at pH 3 whereas that of HdeA is complete at a more acidic pH. Thus, we can conclude that Escherichia coli possesses two acid stress chaperones that prevent periplasmic-protein aggregation at acidic pH.     

Multicopy plasmid suppression of stationary phase chaperone toxicity in Escherichia coli by phosphogluconate dehydratase and the N-terminus of DnaK

Overproduction of DnaK in Escherichia coli results in a bacteriocidal effect. This effect is most acute in stationary phase cells. A selection scheme was developed to isolate multicopy suppressors from an E. coli plasmid expression library, which overcome the stationary phase toxicity of excess DnaK. Two suppressor plasmids were recovered which contained inserts of 1.85 kb and 2.69 kb, respectively. Rearranged and deleted plasmid derivatives were constructed and used to further localize the suppressors. DNA sequence analysis demonstrated that one suppressor encoded phosphogluconate dehydratase (Edd) while the other suppressor encoded the N-terminal 237 amino acids of DnaK itself (DnaK′). Strains bearing the suppressor plasmids constitutively overproduced proteins with apparent masses of 66 kDa (Edd) and 37 kDa (DnaK′) as determined by gel electrophoresis. Western blot analysis using polyclonal antisera specific for either Edd or DnaK confirmed the identity of these overproduced proteins. Suppression of DnaK toxicity was eliminated by the introduction of a + 1 frameshift mutation early in the respective coding regions of either of the two suppressors. These results suggest that suppressor gene translation plays a role in the mechanism of DnaK suppression.     

High-throughput screen for Escherichia coli heat shock protein 70 (Hsp70/DnaK): ATPase assay in low volume by exploiting energy transfer

Members of the heat shock protein 70 (Hsp70) family of molecular chaperones are emerging as potential therapeutic targets. Their ATPase activity has classically been measured using colorimetric phosphate detection reagents, such as quinaldine red (QR). Although such assays are suitable for 96-well plate formats, they typically lose sensitivity when attempted in lower volume due to path length and meniscus effects. These limitations and Hsp70's weak enzymatic activity have combined to create significant challenges in high-throughput screening. To overcome these difficulties, the authors have adopted an energy transfer strategy that was originally reported by Zuck et al. (Anal Biochem 2005;342:254-259). Briefly, white 384-well plates emit fluorescence when irradiated at 430 nm. In turn, this intrinsic fluorescence can be quenched by energy transfer with the QR-based chromophore. Using this more sensitive approach, the authors tested 55,400 compounds against DnaK, a prokaryotic member of the Hsp70 family. The assay performance was good (Z' ~0.6, coefficient of variation ~8%), and at least one promising new inhibitor was identified. In secondary assays, this compound specifically blocked stimulation of DnaK by its co-chaperone, DnaJ. Thus, this simple and inexpensive adaptation of a colorimetric method might be suitable for screening against Hsp70 family members.     

Interactions within the ClpB/DnaK bi-chaperone system from Escherichia coli

ClpB and DnaK form a bi-chaperone system that reactivates strongly aggregated proteins in vivo and in vitro. Previously observed interaction between purified ClpB and DnaK suggested that one of the chaperones might recruit its partner during substrate reactivation. We show that ClpB from Escherichia coli binds at the substrate binding site of DnaK and the interaction is supported by the N-terminal domain and the middle domain of ClpB. Moreover, the interaction between ClpB and DnaK depends on the nucleotide-state of DnaK: it is stimulated by ADP and inhibited by ATP. These observations indicate that DnaK recognizes selected structural motifs in ClpB as "pseudo-substrates" and that ClpB may compete with bona fide substrates of DnaK. We conclude that direct interaction between ClpB and DnaK does not mediate a substrate transfer between the chaperones, it may, however, play a role in the recruitment of the bi-chaperone system to specific recognition sites in aggregated particles.     

A physics-based approach of coarse-graining the cytoplasm of Escherichia coli (CGCYTO)

We have investigated protein stability in an environment of Escherichia coli cytoplasm using coarse-grained computer simulations. To coarse-grain a small slide of E. coli's cytoplasm consisting of over 16 million atoms, we have developed a self-assembled clustering algorithm (CGCYTO). CGCYTO uses the shape parameter and asphericity as well as a parameter λ (ranging from 0 to 1) that measures the covolume of a test protein and a macromolecule against the covolume of a test protein and a sphere of equal volume as that of a macromolecule for the criteria of coarse-graining a cytoplasmic model. A cutoff λ_c = 0.8 was chosen based on the size of a test protein and computational resources and it determined the resolution of a coarse-grained cytoplasm. We compared the results from a polydisperse cytoplasmic model (PD model) produced by CGCYTO with two other coarse-grained hard-sphere cytoplasmic models: 1), F70 model, macromolecules in the cytoplasm were modeled by homogeneous hard spheres with a radius of 55 Å, the size of Ficoll70 and 2), HS model, each macromolecule in the cytoplasm was modeled by a hard sphere of equal volume. It was found that the folding temperature T_f of a test protein (apoazurin) in a PD model is ～5° greater than that in a F70 model. In addition, the deviation of T_f in a PD model is twice as much as that in a HS model when an apoazurin is randomly placed at different voids formed by particle fluctuations in PD models.     

Physiological consequences of DnaK and DnaJ overproduction in Escherichia coli.

The physiological consequences of molecular chaperone overproduction in Escherichia coli are presented. Constitutive overproduction of DnaK from a multicopy plasmid containing large chromosomal fragments spanning the dnaK region resulted in plasmid instability. Co-overproduction of DnaJ with DnaK stabilized plasmid levels. To examine the effects of altered levels of DnaK and DnaJ in a more specific manner, an inducible expression system for dnaK and dnaJ was constructed and characterized. Differential rates of DnaK synthesis were determined by quantitative Western blot (immunoblot) analysis. Moderate levels of DnaK overproduction resulted in a defect in cell septation and formation of cell filaments, but co-overproduction of DnaJ overcame this effect. Further increases in the level of DnaK terminated culture growth despite increased levels of DnaJ. DnaK overproduction was found to be bacteriocidal, and this effect was also partially suppressed by DnaJ. The bacteriocidal effect was apparent only with cultures which were allowed to enter stationary phase, indicating that DnaK toxicity is growth phase dependent.