5S rRNA-assisted DnaK refolding

Although accumulating evidence has revealed that most proteins can fold without the assistance of molecular chaperones, little attention has been paid to other types of chaperoning macromolecules. A variety of proteins interact with diverse RNA molecules in vivo, suggesting a potential role of RNAs for folding of their interacting proteins. Here we show that the in vitro refolding of a representative molecular chaperone, DnaK, an Escherichia coli homolog of Hsp70, could be assisted by its interacting 5S rRNA. The folding enhancement occurred in RNA concentration and its size dependent manner whereas neither the RNA with the reverse sequence of 5S rRNA nor the RNase pretreated 5S rRNA stimulated the folding in vitro. Based on our results, we propose that 5S rRNA could exert the chaperoning activity on DnaK during the folding process. The results suggest an interesting possibility that the folding of RNA-interacting proteins could be assisted by their cognate RNA ligands.     

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.     

Removal of DnaK contamination during fusion protein purifications

The use of fusion proteins for recombinant protein expression in Escherichia coli has become popular because the carrier increases protein solubility, standardizes expression levels, and facilitates purification of the fusion products. However, we have observed that the peptide regions that fuse the carrier to the protein of interest bind E. coli Hsp70 molecular chaperones (DnaK) depending on their amino acid composition, resulting in an unwanted contamination during protein purification. Here we describe an approach that helps to circumvent this unwanted contamination. First, the appropriate amino acids surrounding and comprising the cloning site are chosen by using a software based on an algorithm already developed to decrease to a minimum the propensity of the fusion protein to bind DnaK. Second, DnaK contamination is significantly reduced by washing the fusion protein bound to the purification resin with MgATP plus soluble denatured E. coli proteins before elution. The approach can also be applied to eliminate other molecular chaperones.     

Single-Molecule Force Spectroscopy of Protein Folding

The use of force probes to induce unfolding and refolding of single molecules through the application of mechanical tension, known as single-molecule force spectroscopy (SMFS), has proven to be a powerful tool for studying the dynamics of protein folding. Here we provide an overview of what has been learned about protein folding using SMFS, from small, single-domain proteins to large, multi-domain proteins. We highlight the ability of SMFS to measure the energy landscapes underlying folding, to map complex pathways for native and non-native folding, to probe the mechanisms of chaperones that assist with native folding, to elucidate the effects of the ribosome on co-translational folding, and to monitor the folding of membrane proteins.     

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.     

Interaction of trigger factor with the ribosome

The trigger factor of Escherichia coli is a prolyl isomerase and a chaperone. It interacts with the ribosome and affects the folding of newly formed protein chains. Therefore, the dynamics of the interactions of trigger factor with the ribosome and with unfolded protein chains should be tailored for this function. Previously, we had found that binding of unfolded proteins to trigger factor is fast and that the lifetime of the complex between these two components is only about 100 ms. Here, we have labeled the trigger factor in its amino-terminal, ribosome-binding domain with a fluorescent dye and investigated how it interacts with the ribosome. We found that this association, as well as the dissociation of the complex, are rather slow processes. The average lifetime of the complex is about 30 seconds (at 20 degrees C). The strong differences in the dynamics of the interactions of trigger factor with the ribosome and with protein substrates might ensure that, on the one hand, trigger factor remains bound to the ribosome while a protein chain is being synthesized, and, on the other hand, allows it to scan the newly formed protein for prolyl bonds that need catalysis of isomerization.     

Glycoprotein Folding in the Endoplasmic Reticulum

Our understanding of eukaryotic protein folding in the endoplasmic reticulum has increased enormously over the last 5 years. In this review, we summarize some of the major research themes that have captivated researchers in this field during the last years of the 20th century. We follow the path of a typical protein as it emerges from the ribosome and enters the reticular environment. While many of these events are shared between different polypeptide chains, we highlight some of the numerous differences between proteins, between cell types, and between the chaperones utilized by different ER glycopro-teins. Finally, we consider the likely advances in this field as the new century unfolds and we address the prospect of a unified understanding of how protein folding, degradation, and translation are coordinated within a cell.     

Localization of BiP to translating ribosomes increases soluble accumulation of secreted eukaryotic proteins in an Escherichia coli cell-free system

The endoplasmic reticulum (ER) resident Hsp70 chaperone, BiP, docks to the Sec translocon and interacts co-translationally with polypeptides entering the ER to encourage proper folding. In order to recreate this interaction in Escherichia coli cell-free protein synthesis (CFPS) reactions, a fusion protein was formed between the ribosome-binding portion of the E. coli protein trigger factor (TF) and BiP. The biophysical affinity to ribosomes as well as the characteristic Hsp70 ATPase activity were both verified for the fusion protein. When added to E. coli-based CFPS reactions, the TF-BiP fusion chaperone increased soluble yields of several protein fragments that are normally secreted through the ER and have poor solubility in typical CFPS reactions. For comparison, a fusion between TF and the native E. coli Hsp70, DnaK, was also constructed. This fusion was also biologically active and increased soluble yields of certain protein targets in CFPS. The TF-BiP fusion described in this study can be seen as a first step in reconstituting and better understanding ER folding pathways in the prokaryotic environment of E. coli CFPS.     

Folding in vitro of bovine pancreatic trypsin inhibitor in the presence of proteins of the endoplasmic reticulum.

The rates of folding and disulfide bond formation in reduced BPTI were measured in vitro in the presence and absence of total protein from the endoplasmic reticulum. The rates were increased substantially by the endoplasmic reticulum proteins, but only to the extent expected from the known content and activity of protein-disulfide-isomerase. No effects of added ATP or Ca2+ were observed, even though protein-disulfide-isomerase binds Ca2+ tightly.     

Molecular Chaperones and Mitochondrial Protein Folding

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

Assessment of substrate-stabilizing factors for DnaK on the folding of aggregation-prone proteins

Hydrophobic interactions between molecular chaperones and their nonnative substrates have been believed to be mainly responsible for both substrate recognition and stabilization against aggregation. However, the hydrophobic contact area between DnaK and its substrate proteins is very limited and other factors of DnaK for the substrate stabilization could not be excluded. Here, we covalently fused DnaK to the N-termini of aggregation-prone proteins in vivo. In the context of a fusion protein, DnaK has the ability to efficiently solubilize its linked proteins. The point mutation of the residue of DnaK critical for the substrate recognition and the deletion of the C-terminal substrate-binding domain did not have significant effect on the solubilizing ability of DnaK. The results imply that other factors of DnaK, distinct from the hydrophobic shielding of folding intermediates, also contributes to stabilization of its noncovalently bound substrates against aggregation. Elucidation of the nature of these factors would further enhance our understanding of the substrate stabilization of DnaK for expedited protein folding.     

Molecular cloning, purification and immunological responses of recombinants GroEL and DnaK from Streptococcus pyogenes

To better understand the roles of heat shock proteins in streptococcal diseases, the groEL and dnaK genes from Streptococcus pyogenes were cloned and their products (GroEL and DnaK) and derivatives (F2GroEL, F3GroEL and C1DnaK) purified as His-tagged fusion proteins. Western blot analysis of the purified proteins with sera from individuals with streptococcal diseases demonstrated that 29 out of 36 sera tested were reactive with GroEL and eight recognized DnaK. Rabbit antiserum against myosin recognized both GroEL and DnaK. Antibodies raised against purified F2GroEL and DnaK reacted with myosin in the ELISA but not in a Western immunoblot. These data indicate that the S. pyogenes GroEL and DnaK may be important immunogens during streptococcal infections. Furthermore, we provide evidence of an immunogenic relatedness of the GroEL and DnaK proteins with myosin that could play a role in the pathogenesis of streptococcal non-suppurative sequelae.     

DnaK expression in response to heat shock of Streptococcus mutans

Abstract The oral pathogen, Streptococcus mutans , persistently colonizes human hosts and initiates oral disease despite extreme variations in environmental conditions. To begin to investigate the role of the stress protein, DnaK (Hsp70), in environmental stress responses by S. mutans , pulse—chase experiments were initially used to establish that a functional heat shock response existed in this organism. A C-terminal fragment of the S. mutans dnaK gene was cloned and engineered to be expressed with a histidine tag. Using the recombinant DnaK protein that had been purified by nickel affinity chromatography, an antibody specific for the S. mutans DnaK protein was generated to analyse DnaK expression under homeostatic and heat shock conditions. Western blot analysis indicated that the anti-recombinant DnaK antibody specifically recognized a protein (molecular mass approx. 68 kDa) which was induced in response to thermal stress. Elucidating the role of DnaK in responses by S. mutans to various environmental Stressors will provide a better understanding of how DnaK is involved in survival of extreme environments and the contribution of the DnaK protein to the virulence of S. mutans .     

DafA cycles between the DnaK chaperone system and translational machinery

DafA is encoded by the dnaK operon of Thermus thermophilus and mediates the formation of a highly stable complex between the chaperone DnaK and its co-chaperone DnaJ under normal growth conditions. DafA(Tth) contains 87 amino acid residues and is the only member of the DnaK(Tth) chaperone system for which no corresponding protein has yet been identified in other organisms and whose particular function has remained elusive. Here, we show directly that the DnaK(Tth)-DnaJ(Tth)-DafA(Tth) complex cannot represent the active chaperone species since DafA(Tth) inhibits renaturation of firefly luciferase by suppressing substrate association. Since DafA(Tth) must be released before the substrate proteins can bind we hypothesized that free DafA(Tth) might have regulatory functions connected to the heat shock response. Here, we present evidence that supports this hypothesis. We identified the 70S ribosome as binding target of free DafA(Tth). Our results show that the association of DafA(Tth) and 70S ribosomes does not require the participation of DnaK(Tth) or DnaJ(Tth). On the contrary, the assembly of DnaK(Tth)-DnaJ(Tth)-DafA(Tth) and ribosome-DafA(Tth) complexes seems to be competitive. These findings strongly suggest the involvement of DafA(Tth) in regulatory processes occurring at a translational level, which could represent a new mechanism of heat shock response as an adaptation to elevated temperature.     

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.     

Protein Folding, Misfolding, and Aggregation. Formation of Inclusion Bodies and Aggresomes

In this review the mechanisms of protein folding, misfolding, and aggregation as well as the mechanisms of cell defense against toxic protein aggregates are considered. Misfolded and aggregated proteins in cells are exposed to chaperone-mediated refolding and are degraded by proteasomes if refolding is impossible. Proteolysis-stable protein aggregates accumulate, forming inclusion bodies. In eucaryotic cells, protein aggregates form structures in the pericentrosomal area that have been termed "aggresomes". Formation of aggresomes in cells is a general cellular response to the presence of misfolded proteins when the degrading capacity of the cells is exceeded. The role of aggresomes in disturbance of the proteasomal system operation and in cellular death, particularly in the so-called "protein conformational diseases", is discussed.     

Two Bacterial Small Heat Shock Proteins,IbpA and IbpB,Form a Functional Heterodimer

Small heat shock proteins (sHsps) are a conserved class of ATP-independent chaperones which in stress conditions bind to unfolded protein substrates and prevent their irreversible aggregation. Substrates trapped in sHsps-containing aggregates are efficiently refolded into native structures by ATP-dependent Hsp70 and Hsp100 chaperones. Most γ-proteobacteria possess a single sHsp (IbpA), while in a subset of Enterobacterales, as a consequence of ibpA gene duplication event, a two-protein sHsp (IbpA and IbpB) system has evolved. IbpA and IbpB are functionally divergent. Purified IbpA, but not IbpB, stably interacts with aggregated substrates, yet both sHsps are required to be present at the substrate denaturation step for subsequent efficient Hsp70-Hsp100-dependent substrate refolding. IbpA and IbpB interact with each other, influence each other’s expression levels and degradation rates. However, the crucial information on how these two sHsps interact and what is the basic building block required for proper sHsps functioning was missing. Here, based on NMR, mass spectrometry and crosslinking studies, we show that IbpA-IbpB heterodimer is a dominating functional unit of the two sHsp system in Enterobacterales. The principle of heterodimer formation is similar to one described for homodimers of single bacterial sHsps. β-hairpins formed by strands β5 and β7 of IbpA or IbpB crystallin domains associate with the other one's β-sandwich in the heterodimer structure. Relying on crosslinking and molecular dynamics studies, we also propose the orientation of two IbpA-IbpB heterodimers in a higher order tetrameric structure.