Crystal structure of the nucleotide‐binding domain of mortalin,the mitochondrial Hsp70 chaperone

Mortalin, a member of the Hsp70‐family of molecular chaperones, functions in a variety of processes including mitochondrial protein import and quality control, Fe‐S cluster protein biogenesis, mitochondrial homeostasis, and regulation of p53. Mortalin is implicated in regulation of apoptosis, cell stress response, neurodegeneration, and cancer and is a target of the antitumor compound MKT‐077. Like other Hsp70‐family members, Mortalin consists of a nucleotide‐binding domain (NBD) and a substrate‐binding domain. We determined the crystal structure of the NBD of human Mortalin at 2.8 Å resolution. Although the Mortalin nucleotide‐binding pocket is highly conserved relative to other Hsp70 family members, we find that its nucleotide affinity is weaker than that of Hsc70. A Parkinson's disease‐associated mutation is located on the Mortalin‐NBD surface and may contribute to Mortalin aggregation. We present structure‐based models for how the Mortalin‐NBD may interact with the nucleotide exchange factor GrpEL1, with p53, and with MKT‐077. Our structure may contribute to the understanding of disease‐associated Mortalin mutations and to improved Mortalin‐targeting antitumor compounds.     

Dynamic Aha1 co‐chaperone binding to human Hsp90

Hsp90 is an essential chaperone that requires large allosteric changes to determine its ATPase activity and client binding. The co‐chaperone Aha1, which is the major ATPase stimulator in eukaryotes, is important for regulation of Hsp90's allosteric timing. Little is known, however, about the structure of the Hsp90/Aha1 complex. Here, we characterize the solution structure of unmodified human Hsp90/Aha1 complex using NMR spectroscopy. We show that the 214‐kDa complex forms by a two‐step binding mechanism and adopts multiple conformations in the absence of nucleotide. Aha1 induces structural changes near Hsp90's nucleotide‐binding site, providing a basis for its ATPase‐enhancing activity. Our data reveal important aspects of this pivotal chaperone/co‐chaperone interaction and emphasize the relevance of characterizing dynamic chaperone structures in solution.     

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.     

Maintenance of structure and function of mitochondrial Hsp70 chaperones requires the chaperone Hep1

Hsp70 chaperones mediate folding of proteins and prevent their misfolding and aggregation. We report here on a new kind of Hsp70 interacting protein in mitochondria, Hep1. Hep1 is a highly conserved protein present in virtually all eukaryotes. Deletion of HEP1 results in a severe growth defect. Cells lacking Hep1 are deficient in processes that need the function of mitochondrial Hsp70s, such as preprotein import and biogenesis of proteins containing FeS clusters. In the mitochondria of these cells, Hsp70s, Ssc1 and Ssq1 accumulate as insoluble aggregates. We show that it is the nucleotide-free form of mtHsp70 that has a high tendency to self-aggregate. This process is efficiently counteracted by Hep1. We conclude that Hep1 acts as a chaperone that is necessary and sufficient to prevent self-aggregation and to thereby maintain the function of the mitochondrial Hsp70 chaperones.     

Effect of hsp70 chaperone on the folding and misfolding of polypeptides modeling an elongating protein chain

Virtually nothing is known about the interaction of co-translationally active chaperones with nascent polypeptides and the resulting effects on peptide conformation and folding. We have explored this issue by NMR analysis of apomyoglobin N-terminal fragments of increasing length, taken as models for different stages of protein biosynthesis, in the absence and presence of the substrate binding domain of Escherichia coli Hsp70, DnaK-beta. The incomplete polypeptides misfold and self-associate under refolding conditions. In the presence of DnaK-beta, however, formation of the original self-associated species is completely or partially prevented. Chaperone interaction with incomplete protein chains promotes a globally unfolded dynamic DnaK-beta-bound state, which becomes folding-competent only upon incorporation of the residues corresponding to the C-terminal H helix. The chaperone does not bind the full-length protein at equilibrium. However, its presence strongly disfavors the kinetic accessibility of misfolding side-routes available to the full-length chain. This work supports the role of DnaK as a "holder" for incomplete N-terminal polypeptides. However, as the chain approaches its full-length status, the tendency to intramolecularly bury non-polar surface efficiently outcompetes chaperone binding. Under these conditions, DnaK serves as a "folding enhancer" by supporting folding of a population of otherwise folding-incompetent full-length protein chains.     

High-throughput screen for small molecules that modulate the ATPase activity of the molecular chaperone DnaK

DnaK is a molecular chaperone of Escherichia coli that belongs to a family of conserved 70-kDa heat shock proteins. The Hsp70 chaperones are well known for their crucial roles in regulating protein homeostasis, preventing protein aggregation, and directing subcellular traffic. Given the complexity of functions, a chemical method for controlling the activities of these chaperones might provide a useful experimental tool. However, there are only a handful of Hsp70-binding molecules known. To build this area, we developed a robust, colorimetric, high-throughput screening (HTS) method in 96-well plates that reports on the ATPase activity of DnaK. Using this approach, we screened a 204-member focused library of molecules that share a dihydropyrimidine core common to known Hsp70-binding leads and uncovered seven new inhibitors. Intriguingly, the candidates do not appear to bind the hydrophobic groove that normally interacts with peptide substrates. In sum, we have developed a reliable HTS method that will likely accelerate discovery of small molecules that modulate DnaK/Hsp70 function. Moreover, because this family of chaperones has been linked to numerous diseases, this platform might be used to generate new therapeutic leads.     

Regulation of molecular chaperones through post-translational modifications: Decrypting the chaperone code

Molecular chaperones and their associated cofactors form a group of highly specialized proteins that orchestrate the folding and unfolding of other proteins and the assembly and disassembly of protein complexes. Chaperones are found in all cell types and organisms, and their activity must be tightly regulated to maintain normal cell function. Indeed, deregulation of protein folding and protein complex assembly is the cause of various human diseases. Here, we present the results of an extensive review of the literature revealing that the post-translational modification (PTM) of chaperones has been selected during evolution as an efficient mean to regulate the activity and specificity of these key proteins. Because the addition and reciprocal removal of chemical groups can be triggered very rapidly, this mechanism provides an efficient switch to precisely regulate the activity of chaperones on specific substrates. The large number of PTMs detected in chaperones suggests that a combinatory code is at play to regulate function, activity, localization, and substrate specificity for this group of biologically important proteins. This review surveys the core information currently available as a starting point toward the more ambitious endeavor of deciphering the “chaperone code”.     

Development of a rotor-gene real-time PCR assay for the detection and quantification of Mycoplasma genitalium

We developed and validated a real-time quantitative polymerase chain reaction (qPCR) assay to determine Mycoplasma genitalium bacterial load in endocervical swabs, based on amplification of the pdhD gene which encodes dihydrolipoamide dehydrogenase, using the Rotor-Gene platform. We first determined the qPCR assay sensitivity, limit of detection, reproducibility and specificity, and then determined the ability of the qPCR assay to quantify M. genitalium in stored endocervical specimens collected from Zimbabwean women participating in clinical research undertaken between 1999 and 2007. The qPCR assay had a detection limit of 300 genome copies/mL and demonstrated low intra- and inter-assay variability. The assay was specific for M. genitalium DNA and did not amplify the DNA from other mycoplasma and ureaplasma species. We quantified M. genitalium in 119 of 1600 endocervical swabs that tested positive for M. genitalium using the commercial Sacace M. genitalium real-time PCR, as well as 156 randomly selected swabs that were negative for M. genitalium by the same assay. The M. genitalium loads ranged between < 300 and 3,240,000 copies/mL. Overall, the qPCR assay demonstrated good range of detection, reproducibility and specificity and can be used for both qualitative and quantitative analyses of M. genitalium in endocervical specimens and potentially other genital specimens.     

The role of the cysteine residue in the chaperone and anti‐apoptotic functions of human Hsp27

The small heat shock protein Hsp27 is a molecular chaperone and an anti‐apoptotic protein. Human Hsp27 has one cysteine residue at position 137. We investigated the role of this cysteine residue in the chaperone and anti‐apoptotic functions of Hsp27 by mutating the cysteine residue to an alanine (Hsp27_C137A) and comparing it to wild‐type protein (Hsp27_WT). Both proteins were multi‐subunit oligomers, but subunits of Hsp27_WT were disulfide‐linked unlike those of Hsp27_C137A, which were monomeric. Hsp27_C137A was indistinguishable from Hsp27_WT with regard to its secondary structure, surface hydrophobicity, oligomeric size and chaperone function. S‐thiolation and reductive methylation of the cysteine residue had no apparent effect on the chaperone function of Hsp27_WT. The anti‐apoptotic function of Hsp27_C137A and Hsp27_WT was studied by overexpressing them in CHO cells. No difference in the caspase‐3 or ‐9 activity was observed in staurosporine‐treated cells. The rate of apoptosis between Hsp27_C137A and Hsp27_WT overexpressing cells was similar whether the cells were treated with staurosporine or etoposide. However, the mutant protein was less protective relative to the wild‐type protein in preventing caspase‐3 and caspase‐9 activation and apoptosis induced by 1 mM H₂O₂ in CHO and HeLa cells. These data demonstrate that in human Hsp27, disulfide formation by the lone cysteine does not affect its chaperone function and anti‐apoptotic function against chemical toxicants. However, oxidation of the lone cysteine in Hsp27 might at least partially affect the anti‐apoptotic function against oxidative stress. J. Cell. Biochem. 110: 408–419, 2010. © 2010 Wiley‐Liss, Inc.     

Molecular mechanism of bacterial Hsp90 pH‐dependent ATPase activity

Hsp90 is a dimeric molecular chaperone that undergoes an essential and highly regulated open‐to‐closed‐to‐open conformational cycle upon ATP binding and hydrolysis. Although it has been established that a large energy barrier to closure is responsible for Hsp90's low ATP hydrolysis rate, the specific molecular contacts that create this energy barrier are not known. Here we discover that bacterial Hsp90 (HtpG) has a pH‐dependent ATPase activity that is unique among other Hsp90 homologs. The underlying mechanism is a conformation‐specific electrostatic interaction between a single histidine, H255, and bound ATP. H255 stabilizes ATP only while HtpG adopts a catalytically inactive open configuration, resulting in a striking anti‐correlation between nucleotide binding affinity and chaperone activity over a wide range of pH. Linkage analysis reveals that the H255‐ATP salt bridge contributes 1.5 kcal/mol to the energy barrier of closure. This energetic contribution is structurally asymmetric, whereby only one H255‐ATP salt‐bridge per dimer of HtpG controls ATPase activation. We find that a similar electrostatic mechanism regulates the ATPase of the endoplasmic reticulum Hsp90, and that pH‐dependent activity can be engineered into eukaryotic cytosolic Hsp90. These results reveal site‐specific energetic information about an evolutionarily conserved conformational landscape that controls Hsp90 ATPase activity.     

Substrate relay in an Hsp70‐cochaperone cascade safeguards tail‐anchored membrane protein targeting

Membrane proteins are aggregation‐prone in aqueous environments, and their biogenesis poses acute challenges to cellular protein homeostasis. How the chaperone network effectively protects integral membrane proteins during their post‐translational targeting is not well understood. Here, biochemical reconstitutions showed that the yeast cytosolic Hsp70 is responsible for capturing newly synthesized tail‐anchored membrane proteins (TAs) in the soluble form. Moreover, direct interaction of Hsp70 with the cochaperone Sgt2 initiates a sequential series of TA relays to the dedicated TA targeting factor Get3. In contrast to direct loading of TAs to downstream chaperones, stepwise substrate loading via Hsp70 maintains the solubility and targeting competence of TAs, ensuring their efficient delivery to the endoplasmic reticulum (ER). Inactivation of cytosolic Hsp70 severely impairs TA translocation in vivo. Our results demonstrate a new role of cytosolic Hsp70 in directly assisting the targeting of an essential class of integral membrane proteins and provide a paradigm for how “substrate funneling” through a chaperone cascade preserves the conformational quality of nascent membrane proteins during their biogenesis.     

The DNLZ/HEP zinc-binding subdomain is critical for regulation of the mitochondrial chaperone HSPA9

Human mitochondrial DNLZ/HEP regulates the catalytic activity and solubility of the mitochondrial hsp70 chaperone HSPA9. Here, we investigate the role that the DNLZ zinc-binding and C-terminal subdomains play in regulating HSPA9. We show that truncations lacking portions of the zinc-binding subdomain (ZBS) do not affect the solubility of HSPA9 or its ATPase domain, whereas those containing the ZBS and at least 10 residues following this subdomain enhance chaperone solubility. Binding measurements further show that DNLZ requires its ZBS to form a stable complex with the HSPA9 ATPase domain, and ATP hydrolysis measurements reveal that the ZBS is critical for full stimulation of HSPA9 catalytic activity. We also examined if DNLZ is active in vivo. We found that DNLZ partially complements the growth of Δzim17 Saccharomyces cerevisiae, and we discovered that a Zim17 truncation lacking a majority of the C-terminal subdomain strongly complements growth like full-length Zim17. These findings provide direct evidence that human DNLZ is a functional ortholog of Zim17. In addition, they implicate the pair of antiparallel β-strands that coordinate zinc in Zim17/DNLZ-type proteins as critical for binding and regulating hsp70 chaperones.     

Effect of evolution of the C-terminal region on chaperone activity of Hsp70

Dynamic interdomain interactions within the Hsp70 protein is the basis for the allosteric and functional properties of Hsp70s. While Hsp70s are generally conserved in terms of structure, allosteric behavior, and some overlapping functions, Hsp70s also contain variable sequence regions which are related to distinct functions. In the Hsp70 sequence, the part with the greatest sequence variation is the C-terminal α-helical lid subdomain of substrate-binding domain (SBDα) together with the intrinsically disordered region. Dynamic interactions between the SBDα and β-sandwich substrate-binding subdomain (SBDβ) contribute to the chaperone functions of Hsp70s by tuning kinetics of substrate binding. To investigate how the C-terminal region of Hsp70 has evolved from prokaryotic to eukaryotic organisms, we tested whether this region can be exchanged among different Hsp70 members to support basic chaperone functions. We found that this region from eukaryotic Hsp70 members cannot substitute for the same region in Escherichia coli DnaK to facilitate normal chaperone activity of DnaK. In contrast, this region from E. coli DnaK and Saccharomyces cerevisiae Hsp70 (Ssa1 and Ssa4) can partially support some roles of human stress inducible Hsp70 (hHsp70) and human cognate Hsp70 (hHsc70). Our results indicate that the C-terminal region from eukaryotic Hsp70 members cannot properly support SBDα–SBDβ interactions in DnaK, but this region from DnaK/Ssa1/Ssa4 can still form some SBDα–SBDβ interactions in hHsp70 or hHsc70, which suggests that the mode for SBDα–SBDβ interactions is different in prokaryotic and eukaryotic Hsp70 members. This study provides new insight in the divergency among different Hsp70 homologs and the evolution of Hsp70s.     

The <Emphasis Type="Italic">Chlamydomonas</Emphasis> genome reveals its secrets: chaperone genes and the potential roles of their gene products in the chloroplast

The first draft of the Chlamydomonas nuclear genome was searched for genes potentially encoding members of the five major chaperone families, Hsp100/Clp, Hsp90, Hsp70, Hsp60, the small heat shock proteins, and the Hsp70 and Cpn60 co-chaperones GrpE and Cpn10/20, respectively. This search yielded 34 potential (co-)chaperone genes, among them those 8 that have been reported earlier inChlamydomonas. These 34 genes encode all the (co-)chaperones that have been expected for the different compartments and organelles from genome searches in Arabidopsis, where 74 genes have been described to encode basically the same set of (co-)chaperones. Genome data from Arabidopsis and Chlamydomonas on the five major chaperone families are compared and discussed, with particular emphasis on chloroplast chaperones.     

The Four Hydrophobic Residues on the Hsp70 Inter-Domain Linker Have Two Distinct Roles

The ubiquitous molecular chaperone 70-kDa heat shock proteins (Hsp70) play key roles in maintaining protein homeostasis. Hsp70s contain two functional domains: a nucleotide binding domain and a substrate binding domain. The two domains are connected by a highly conserved inter-domain linker, and allosteric coupling between the two domains is critical for chaperone function. The auxiliary chaperone 40-kDa heat shock proteins (Hsp40) facilitate all the biological processes associated with Hsp70s by stimulating the ATPase activity of Hsp70s. Although an overall essential role of the inter-domain linker in both allosteric coupling and Hsp40 interaction has been suggested, the molecular mechanisms remain largely unknown. Previously, we reported a crystal structure of a full-length Hsp70 homolog, in which the inter-domain linker forms a well-ordered β strand. Four highly conserved hydrophobic residues reside on the inter-domain linker. In DnaK, a well-studied Hsp70, these residues are V389, L390, L391, and L392. In this study, we biochemically dissected their roles. The inward-facing side chains of V389 and L391 form extensive hydrophobic contacts with the nucleotide binding domain, suggesting their essential roles in coupling the two functional domains, a hypothesis confirmed by mutational analysis. On the other hand, L390 and L392 face outward on the surface. Mutation of either abolishes DnaK's in vivo function, yet intrinsic biochemical properties remain largely intact. In contrast, Hsp40 interaction is severely compromised. Thus, for the first time, we separated the two essential roles of the highly conserved Hsp70 inter-domain linker: coupling the two functional domains through V389 and L391 and mediating the interaction with Hsp40 through L390 and L392.     

Effect of the DnaK chaperone on the conformational quality of JCV VP1 virus‐like particles produced in Escherichia coli

Protein nanoparticles such as virus‐like particles (VLPs) can be obtained by recombinant protein production of viral capsid proteins and spontaneous self‐assembling in cell factories. Contrarily to infective viral particles, VLPs lack infective viral genome while retaining important viral properties like cellular tropism and intracellular delivery of internalized molecules. These properties make VLPs promising and fully biocompatible nanovehicles for drug delivery. VLPs of human JC virus (hJCV) VP1 capsid protein produced in Escherichia coli elicit variable hemagglutination properties when incubated at different NaCl concentrations and pH conditions, being optimal at 200 mM NaCl and at pH range between 5.8 and 7.5. In addition, the presence or absence of chaperone DnaK in E. coli cells influence the solubility of recombinant VP1 and the conformational quality of this protein in the VLPs. The hemagglutination ability of hJCV VP1 VLPs contained in E. coli cell extracts can be modulated by buffer composition in the hemagglutination assay. It has been also determined that the production of recombinant hJCV VP1 in E. coli is favored by the absence of chaperone DnaK as observed by Western Blot analysis in different E. coli genetic backgrounds, indicating a proteolysis targeting role for DnaK. However, solubility is highly compromised in a DnaK^? E. coli strain suggesting an important role of this chaperone in reduction of protein aggregates. Finally, hemagglutination efficiency of recombinant VP1 is directly related to the presence of DnaK in the producing cells. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:744–748, 2014