Phylogenetic analysis of the third hsp70 homolog in Escherichia coli; a novel member of the Hsc66 subfamily and its possible co-chaperone.

Novel members of the highly conserved protein family, Hsp70, have been found in the complete sequences of several genomes. To elucidate a phylogenetic relationship among Hsp70 proteins of Escherichia coli, we searched all open reading frames derived from 13 complete genomes for Hsp70/actin-related proteins by the single-linkage clustering method. Phylogenetic analysis of this superfamily revealed that E. coli possesses at least three Hsp70 homologs (DnaK, Hsc66 and Hsc62). We found that Hsc62, which is the product of hscC, is a new member of the Hsc66 subfamily, and is specific to E. coli. The analysis also suggested that YegD of E. coli is closely related to the actin family, which consists of the actin, FtsA and MreB subfamilies. A further database search revealed that two dnaJ homologs, ybeS and ybeV, were located on the opposite strand near hscC. Consequently, E. coli seems to have three gene clusters composed of DnaK and DnaJ homologs.     

Protein folding rates and thermodynamic stability are key determinants for interaction with the Hsp70 chaperone system

The Hsp70 family of molecular chaperones participates in vital cellular processes including the heat shock response and protein homeostasis. E. coli''s Hsp70, known as DnaK, works in concert with the DnaJ and GrpE co-chaperones (K/J/E chaperone system), and mediates cotranslational and post-translational protein folding in the cytoplasm. While the role of the K/J/E chaperones is well understood in the presence of large substrates unable to fold independently, it is not known if and how K/J/E modulates the folding of smaller proteins able to fold even in the absence of chaperones. Here, we combine experiments and computation to evaluate the significance of kinetic partitioning as a model to describe the interplay between protein folding and binding to the K/J/E chaperone system. First, we target three nonobligatory substrates, that is, proteins that do not require chaperones to fold. The experimentally observed chaperone association of these client proteins during folding is entirely consistent with predictions from kinetic partitioning. Next, we develop and validate a computational model (CHAMP70) that assumes kinetic partitioning of substrates between folding and interaction with K/J/E. CHAMP70 quantitatively predicts the experimentally measured interaction of RNase H^D as it refolds in the presence of various chaperones. CHAMP70 shows that substrates are posed to interact with K/J/E only if they are slow-folding proteins with a folding rate constant k_f <50 s⁻¹, and/or thermodynamically unstable proteins with a folding free energy ΔG⁰_UN ≥−2 kcal mol⁻¹. Hence, the K/J/E system is tuned to use specific protein folding rates and thermodynamic stabilities as substrate selection criteria.     

Probing the different chaperone activities of the bacterial HSP70-HSP40 system using a thermolabile luciferase substrate

During mild heat-stress, a native thermolabile polypeptide may partially unfold and transiently expose water-avoiding hydrophobic segments that readily tend to associate into a stable misfolded species, rich in intra-molecular non-native beta-sheet structures. When the concentration of the heat-unfolded intermediates is elevated, the exposed hydrophobic segments tend to associate with other molecules into large stable insoluble complexes, also called "aggregates." In mammalian cells, stress- and mutation-induced protein misfolding and aggregation may cause degenerative diseases and aging. Young cells, however, effectively counteract toxic protein misfolding with a potent network of molecular chaperones that bind hydrophobic surfaces and actively unfold otherwise stable misfolded and aggregated polypeptides. Here, we followed the behavior of a purified, initially mostly native thermolabile luciferase mutant, in the presence or absence of the Escherichia coli DnaK-DnaJ-GrpE chaperones and/or of ATP, at 22 °C or under mild heat-stress. We concomitantly measured luciferase enzymatic activity, Thioflavin-T fluorescence, and light-scattering to assess the effects of temperature and chaperones on the formation, respectively, of native, unfolded, misfolded, and/or of aggregated species. During mild heat-denaturation, DnaK-DnaJ-GrpE+ATP best maintained, although transiently, high luciferase activity and best prevented heat-induced misfolding and aggregation. In contrast, the ATP-less DnaK and DnaJ did not maintain optimal luciferase activity and were less effective at preventing luciferase misfolding and aggregation. We present a model accounting for the experimental data, where native, unfolded, misfolded, and aggregated species spontaneously inter-convert, and in which DnaK-DnaJ-GrpE+ATP specifically convert stable misfolded species into unstable unfolded intermediates.     

Construction of Escherichia coli dnaK-deletion mutant infected by lambdaDE3 for overexpression and purification of recombinant GrpE proteins

Escherichia coli is widely employed to produce recombinant proteins because this microorganism is simple to manipulate, inexpensive to culture, and of short duration to produce a recombinant protein. However, contamination of molecular chaperone DnaK during purification of the recombinant protein is sometimes a problem, since DnaK sometimes has a negative effect on subsequent experiments. Previously, several efforts have been done to remove the DnaK contaminants by several sequential chromatography or washing with some expensive chemicals such as ATP. Here, we developed a simple and inexpensive method to express and purify recombinant proteins based on an E. coli dnaK-deletion mutant. The E. coli ΔdnaK52 mutant was infected by λDE3 phage to overexpress desired recombinant proteins under the control of T7 promoter. Using this host cell, recombinant hexa histidine-tag fused GrpE, which is well known as a co-chaperone for DnaK and to strongly interact with DnaK, was overexpressed and purified by one-step nickel affinity chromatography. As a result, highly purified recombinant GrpE was obtained without washing with ATP. The purified recombinant GrpE showed a folded secondary structure and a dimeric structure as previous findings. In vitro ATPase activity assay and luciferase-refolding activity assay demonstrated that the recombinant GrpE worked together with DnaK. Thus, this developed method would be rapid and useful for expression and purification of recombinant proteins which is difficult to remove DnaK contaminants.     

A structure-based interpretation of E.coli GrpE thermodynamic properties

GrpE is the nucleotide exchange factor for the Escherichia coli molecular chaperone DnaK, the prokaryotic homologue of Hsp70. Thermodynamic properties of GrpE structural domains were characterized by examining a number of structural and point mutants using circular dichroism, differential scanning calorimetry and analytical ultracentrifugation. These structural domains are the long paired N-terminal helices, the central four-helix bundle, and the C-terminal compact beta-domains. We show that the central four-helix bundle (t(m) approximately 75 degrees C) provides a stable platform for the association of the long paired N-terminal helices (t(m) approximately 50 degrees C), which can then function as a temperature sensor. The stability of the N-terminal helices is linked to the presence of the C-terminal compact beta-domains of GrpE, providing a potential mechanism for coupling of DnaK-binding activity of GrpE with temperature. On the basis of our thermodynamic analysis of E.coli GrpE, we present a structure-based model for the melting properties of the nucleotide exchange factor, wherein the long paired helices function as a molecular thermocouple.     

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.     

DnaJ/Hsc70 chaperone complexes control the extracellular release of neurodegenerative‐associated proteins

It is now known that proteins associated with neurodegenerative disease can spread throughout the brain in a prionlike manner. However, the mechanisms regulating the trans‐synaptic spread propagation, including the neuronal release of these proteins, remain unknown. The interaction of neurodegenerative disease‐associated proteins with the molecular chaperone Hsc70 is well known, and we hypothesized that much like disaggregation, refolding, degradation, and even normal function, Hsc70 may dictate the extracellular fate of these proteins. Here, we show that several proteins, including TDP‐43, α‐synuclein, and the microtubule‐associated protein tau, can be driven out of the cell by an Hsc70 co‐chaperone, DnaJC5. In fact, DnaJC5 overexpression induced tau release in cells, neurons, and brain tissue, but only when activity of the chaperone Hsc70 was intact and when tau was able to associate with this chaperone. Moreover, release of tau from neurons was reduced in mice lacking the DnaJC5 gene and when the complement of DnaJs in the cell was altered. These results demonstrate that the dynamics of DnaJ/Hsc70 complexes are critically involved in the release of neurodegenerative disease proteins.     

Transient interactions of a slow-folding protein with the Hsp70 chaperone machinery

Most known proteins have at least one local Hsp70 chaperone binding site. Does this mean that all proteins interact with Hsp70 as they fold? This study makes an initial step to address the above question by examining the interaction of the E.coli Hsp70 chaperone (known as DnaK) and its co-chaperones DnaJ and GrpE with a slow-folding E.coli substrate, RNase H^D. Importantly, this protein is a nonobligatory client, and it is able to fold in vitro even in the absence of chaperones. We employ stopped-flow mixing, chromatography, and activity assays to analyze the kinetic perturbations induced by DnaK/DnaJ/GrpE (K/J/E) on the folding of RNase H^D. We find that K/J/E slows down RNase H^D''s apparent folding, consistent with the presence of transient chaperone-substrate interactions. However, kinetic retardation is moderate for this slow-folding client and it is expected to be even smaller for faster-folding substrates. Given that the interaction of folding-competent substrates such as RNase H^D with the K/J/E chaperones is relatively short-lived, it does not significantly interfere with the timely production of folded biologically active substrate. The above mode of action is important because it preserves K/J/E bioavailability, enabling this chaperone system to act primarily by assisting the folding of other misfolded and (or) aggregation-prone cellular proteins that are unable to fold independently. When refolding is carried out in the presence of K/J and absence of the nucleotide exchange factor GrpE, some of the substrate population becomes trapped as a chaperone-bound partially unfolded state.     

Conformational change of chaperone Hsc70 upon binding to a decapeptide: a circular dichroism study.

The conformation of bovine Hsc70, a 70-kDa heat shock cognate protein, and its conformational change upon binding to decapeptides, was studied by CD spectroscopy and secondary structure prediction (Chou, P.Y. & Fasman, G.D., 1974, Biochemistry 13, 222-245). The CD spectra were analyzed by the LINCOMB method, as well as by the convex constraint analysis (CCA) method (Perczel, A., Park, K., & Fasman, G.D., 1992, Anal. Biochem. 203, 83-93). The result of the CD analysis of Hsc70 (15% alpha-helix, 24% beta-sheet, 24% beta-turn, and 38% remainder) was very similar to the predicted secondary structure for the beta-sheet (24%) and the beta-turn (29%). However, there is disagreement between the alpha-helical content by CD analysis (15%) and the predicted structure (30%). In spite of the fact that the decapeptides contained a considerable amount of beta-sheet (22%), the interaction of the heat shock protein with the peptide resulted in an overall decrease in the content of beta-sheet conformation (-15%) of the complex. This may be due to induction of a molten globule state. The result of the CCA analysis indicated that the Hsc70 undergoes a conformational change upon binding the decapeptides.     

Hsc66 and Hsc20, a new heat shock cognate molecular chaperone system from Escherichia coli.

The hscA and hscB genes of Escherichia coli encode novel chaperone and co-chaperone proteins, designated Hsc66 and Hsc20, respectively. We have overproduced and purified Hsc66 and Hsc20 in high yield in E. coli and describe their initial characterization including absorbance, fluorescence, and circular dichroism spectra. Immunoblot analyses of E. coli cultures using antisera to Hsc66 and Hsc20 raised in rabbits establish that Hsc66 and Hsc20 are constitutively expressed at levels corresponding to cell concentration approximately 20 microM and approximately 10 microM, respectively. The levels do not change appreciably following heat shock (44 degrees C), but a small increase in Hsc20 is observed following a shift to 10 degrees C. Purified Hsc66 exhibits a low intrinsic ATPase activity (approximately 0.6 min-1 at 37 degrees C), and Hsc20 was found to stimulate this activity up to 3.8-fold with half-maximal stimulation at a concentration approximately 5 microM. These findings suggest that Hsc66 and Hsc20 comprise a molecular chaperone system similar to the prokaryotic DnaK/DnaJ and eukaryotic hsp70/hsp40 systems. Sequence differences between Hsc66 and Hsc20 compared to other members of this chaperone family, however, suggest that the Hsc66/Hsc20 system will display different peptide binding specificity and that it is likely to be subject to different regulatory mechanisms. The high level of constitutive expression and the lack of a major response to temperature changes suggest that Hsc66 and Hsc20 play an important cellular role(s) under non-stress conditions.     

The rpoD gene functions as a multicopy suppressor for mutations in the chaperones, CbpA, DnaJ and DnaK, in Escherichia coli

Abstract The CbpA protein is an analog of the DnaJ molecular chaperone of Escherichia coli . The dnaJ ⁻ cbpA ⁻ double-null mutant exhibits severe defects in cell growth, namely, a very narrow temperature range for growth. To gain insight into the functions of CbpA as well as DnaJ, we isolated a multicopy suppressor gene that permits this dnaJ ⁻ cbpA ⁻~ mutant to grow normally at low temperatures. The suppressor gene was identified as rpoD , the gene that encodes the major σ ⁷⁰. The biological implications of this finding are examined and discussed.     

The heat-sensitive Escherichia coli grpE280 phenotype: impaired interaction of GrpE(G122D) with DnaK

GrpE is the nucleotide-exchange factor of the DnaK chaperone system. Escherichia coli cells with the classical temperature-sensitive grpE280 phenotype do not grow under heat-shock conditions and have been found to carry the G122D point mutation in GrpE. To date, the molecular mechanism of this defect has not been investigated in detail. Here, we examined the structural and functional properties of isolated GrpE(G122D) in vitro. Similar to wild-type GrpE, GrpE(G122D) is an elongated dimer in solution. Compared to wild-type GrpE, GrpE(G122D) catalyzed the ADP/ATP exchange in DnaK only marginally and did not compete with wild-type GrpE in interacting with DnaK. In the presence of ADP, GrpE(G122D) in contrast to wild-type GrpE, did not form a complex with DnaK detectable by size-exclusion chromatography with on-line static light-scattering and differential refractometry. Apparently, GrpE(G122D) in the presence of ADP binds to DnaK only with much lower affinity than wild-type GrpE. GrpE(G122D) could not substitute for wild-type GrpE in the refolding of denatured proteins by the DnaK/DnaJ/GrpE chaperone system. In the crystal structure of a (Delta1-33)GrpE(G122D).DnaK-ATPase complex, which as yet is the only available structure of a GrpE variant, Asp122 does not interact directly with neighboring residues of GrpE or DnaK. The far-UV circular dichroism spectra of mutant and wild-type GrpE proved slightly different. Possibly, a discrete change in conformation impairs the formation of the complex with DnaK and renders GrpE(G122D) virtually inactive as a nucleotide exchange factor. In view of the drastically reduced ADP/ATP-exchange activity of GrpE(G122D), the heat sensitivity of grpE280 cells might be explained by the ensuing slowing of the chaperone cycle and the increased sequestering of target proteins by high-affinity, ADP-liganded DnaK, both effects being incompatible with efficient chaperone action required for cell growth.     

Crystallization and preliminary X-ray crystallographic properties of Hsc20, a J-motif co-chaperone protein from Escherichia coli.

Hsc20 is a 20-kDa auxiliary protein that functions with the molecular chaperone Hsc66 in Escherichia coli. Crystals of Hsc20 suitable for X-ray diffraction analysis were grown using the hanging drop vapor diffusion technique in polyethylene glycol 400 containing dioxane as an additive to slow growth. The crystals are monoclinic and belong to the space group C2 with unit cell dimensions a = 125.4 A, b = 71.9 A, c = 68.8 A, and beta = 97.0 degrees. The crystals diffract to a minimum d-spacing of approximately 2.5 A resolution, and a native data set was collected to 2.7 A. The results of a self-rotation function analysis revealed threefold symmetry, suggesting three molecules of Hsc20 in the asymmetric unit and, hence, 12 molecules in the unit cell; this corresponds to a Vm value of 2.6 A3/Da and a solvent content of approximately 53% in the crystals. Structure determination by isomorphous replacement is in progress.     

Structural and functional analysis of the Hsp70/Hsp40 chaperone system

As one of the most abundant and highly conserved molecular chaperones, the 70‐kDa heat shock proteins (Hsp70s) play a key role in maintaining cellular protein homeostasis (proteostasis), one of the most fundamental tasks for every living organism. In this role, Hsp70s are inextricably linked to many human diseases, most notably cancers and neurodegenerative diseases, and are increasingly recognized as important drug targets for developing novel therapeutics for these diseases. Hsp40s are a class of essential and universal partners for Hsp70s in almost all aspects of proteostasis. Thus, Hsp70s and Hsp40s together constitute one of the most important chaperone systems across all kingdoms of life. In recent years, we have witnessed significant progress in understanding the molecular mechanism of this chaperone system through structural and functional analysis. This review will focus on this recent progress, mainly from a structural perspective.     

Biochemical properties of Hsp70 chaperone system from Meiothermus ruber

The guanidine-hydrochloride (Gdn-HCl) and thermally induced unfolding of Hsp70 from Meiothermus ruber (Mru.Hsp70) were analysed using tryptophan fluorescence and 8-anilino-1-naphthalenesulfonic acid (ANS) binding. The ANS binding to Mru.Hsp70 showed both the increase in fluorescence intensity and a shift in emission maximum. Analysis of the unfolding profile of Mru.Hsp70 indicated that Gdn-HCl induced unfolding of Mru.Hsp70 occurred through intermediate species. The tryptophan and ANS fluorescence emission spectra revealed that ATP induced conformational change increased the thermal stability of Mru.Hsp70. The data obtained are similar to those of Escherichia coli DnaK. The ATP-ase activity of chaperones is fundamental for their biological activity. It this paper we demonstrate that, in contrast to Thermus thermophilus, both Mru.Hsp40 and Mru.Hsp22 co-chaperones affect the ATP-ase activity of Mru.Hsp70. The use of truncated Mru.Hsp40 proteins showed that full-length Mru.Hsp40 is required for stimulation of ATP-ase activity of Mru.Hsp70. E. coli GrpE could act as nucleotide exchange factor the in thermophilic Hsp70 ATP hydrolysis reaction. However, the role of E. coli DnaJ in the M. ruber ATP cycle needs further analysis. We selected the new substrate laccA suitable for determination of refolding activity of thermophilic chaperones.     

Biochemical properties of Hsp70 chaperone system from Meiothermus ruber

The guanidine-hydrochloride (Gdn-HCl) and thermally induced unfolding of Hsp70 from Meiothermus ruber (Mru.Hsp70) were analysed using tryptophan fluorescence and 8-anilino-1-naphthalenesulfonic acid (ANS) binding. The ANS binding to Mru.Hsp70 showed both the increase in fluorescence intensity and a shift in emission maximum. Analysis of the unfolding profile of Mru.Hsp70 indicated that Gdn-HCl induced unfolding of Mru.Hsp70 occurred through intermediate species. The tryptophan and ANS fluorescence emission spectra revealed that ATP induced conformational change increased the thermal stability of Mru.Hsp70. The data obtained are similar to those of Escherichia coli DnaK. The ATP-ase activity of chaperones is fundamental for their biological activity. It this paper we demonstrate that, in contrast to Thermus thermophilus, both Mru.Hsp40 and Mru.Hsp22 co-chaperones affect the ATP-ase activity of Mru.Hsp70. The use of truncated Mru.Hsp40 proteins showed that full-length Mru.Hsp40 is required for stimulation of ATP-ase activity of Mru.Hsp70. E. coli GrpE could act as nucleotide exchange factor the in thermophilic Hsp70 ATP hydrolysis reaction. However, the role of E. coli DnaJ in the M. ruber ATP cycle needs further analysis. We selected the new substrate laccA suitable for determination of refolding activity of thermophilic chaperones.     

Fine-tuning of the Hsc70-based Human Protein Disaggregase Machinery by the Distinctive C-terminal Extension of Apg2

Apg2, one of the three cytosolic Hsp110 chaperones in humans, supports reactivation of unordered and ordered protein aggregates by Hsc70 (HspA8). Together with DnaJB1, Apg2 serves to nucleate Hsc70 molecules into sites where productive entropic pulling forces can be developed. During aggregate reactivation, Apg2 performs as a specialized nucleotide exchange factor, but the origin of its specialization is poorly defined. Here we report on the role of the distinctive C-terminal extension present in Apg2 and other metazoan homologs. We found that the first part of this Apg2 subdomain, with propensity to adopt α-helical structure, interacts with the nucleotide binding domain of Hsc70 in a nucleotide-dependent manner, contributing significantly to the stability of the Hsc70:Apg2 complex. Moreover, the second intrinsically disordered segment of Apg2 C-terminal extension plays an important role as a downregulator of nucleotide exchange. An NMR analysis showed that the interaction with Hsc70 nucleotide binding domain modifies the chemical environment of residues located in important functional sites such as the interface between lobe I and II and the nucleotide binding site. Our data indicate that Apg2 C-terminal extension is a fine-tuner of human Hsc70 activity that optimizes the substrate remodeling ability of the chaperone system.