The nucleotide‐bound/substrate‐bound conformation of the Mycoplasma genitalium DnaK chaperone

Hsp70 chaperones keep protein homeostasis facilitating the response of organisms to changes in external and internal conditions. Hsp70s have two domains—nucleotide binding domain (NBD) and substrate binding domain (SBD)—connected by a conserved hydrophobic linker. Functioning of Hsp70s depend on tightly regulated cycles of ATP hydrolysis allosterically coupled, often together with cochaperones, to the binding/release of peptide substrates. Here we describe the crystal structure of the Mycoplasma genitalium DnaK (MgDnaK) protein, an Hsp70 homolog, in the noncompact, nucleotide‐bound/substrate‐bound conformation. The MgDnaK structure resembles the one from the thermophilic eubacteria DnaK trapped in the same state. However, in MgDnaK the NBD and SBD domains remain close to each other despite the lack of direct interaction between them and with the linker contacting the two subdomains of SBD. These observations suggest that the structures might represent an intermediate of the protein where the conserved linker binds to the SBD to favor the noncompact state of the protein by stabilizing the SBDβ‐SBDα subdomains interaction, promoting the capacity of the protein to sample different conformations, which is critical for proper functioning of the molecular chaperone allosteric mechanism. Comparison of the solved structures indicates that the NBD remains essentially invariant in presence or absence of nucleotide.     

Structural basis of J cochaperone binding and regulation of Hsp70

The many protein processing reactions of the ATP-hydrolyzing Hsp70s are regulated by J cochaperones, which contain J domains that stimulate Hsp70 ATPase activity and accessory domains that present protein substrates to Hsp70s. We report the structure of a J domain complexed with a J responsive portion of a mammalian Hsp70. The J domain activates ATPase activity by directing the linker that connects the Hsp70 nucleotide binding domain (NBD) and substrate binding domain (SBD) toward a hydrophobic patch on the NBD surface. Binding of the J domain to Hsp70 displaces the SBD from the NBD, which may allow the SBD flexibility to capture diverse substrates. Unlike prokaryotic Hsp70, the SBD and NBD of the mammalian chaperone interact in the ADP state. Thus, although both nucleotides and J cochaperones modulate Hsp70 NBD:linker and NBD:SBD interactions, the intrinsic persistence of those interactions differs in different Hsp70s and this may optimize their activities for different cellular roles.     

Nucleocytoplasmic transport under stress conditions and its role in HSP70 chaperone systems

BackgroundIn eukaryotic cells, molecular trafficking between the nucleus and cytoplasm is a highly regulated process related to cellular homeostasis and cellular signaling. However, various cellular stresses induce the perturbation of conventional nucleocytoplasmic transport pathways, resulting in the nucleocytoplasmic redistribution of many functional proteins.Scope of reviewWe describe the recent insights into the mechanism and functions of nuclear import of cytosolic chaperone HSP70 under stress conditions and the cellular distribution and functions of its co-chaperones.Major conclusionsHikeshi mediates the nuclear import of the molecular chaperone HSP70. A few of the regulators of the HSP70 chaperone system also accumulate in the nucleus under heat stress conditions. These proteins function collaboratively to protect cells from stress-induced damage and aid in the recovery of cells from stress.General significanceStudies on the regulation of nucleocytoplasmic transport under several cellular stresses should provide new insights into the fundamental principles of protein homeostasis (proteostasis) in both compartments, the nucleus and cytoplasm.     

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.     

Mechanical properties of BiP protein determined by nano‐rheology

Immunoglobulin Binding Protein (BiP) is a chaperone and molecular motor belonging to the Hsp70 family, involved in the regulation of important biological processes such as synthesis, folding and translocation of proteins in the Endoplasmic Reticulum. BiP has two highly conserved domains: the N‐terminal Nucleotide‐Binding Domain (NBD), and the C‐terminal Substrate‐Binding Domain (SBD), connected by a hydrophobic linker. ATP binds and it is hydrolyzed to ADP in the NBD, and BiP's extended polypeptide substrates bind in the SBD. Like many molecular motors, BiP function depends on both structural and catalytic properties that may contribute to its performance. One novel approach to study the mechanical properties of BiP considers exploring the changes in the viscoelastic behavior upon ligand binding, using a technique called nano‐rheology. This technique is essentially a traditional rheology experiment, in which an oscillatory force is directly applied to the protein under study, and the resulting average deformation is measured. Our results show that the folded state of the protein behaves like a viscoelastic material, getting softer when it binds nucleotides‐ ATP, ADP, and AMP‐PNP‐, but stiffer when binding HTFPAVL peptide substrate. Also, we observed that peptide binding dramatically increases the affinity for ADP, decreasing it dissociation constant (K_D) around 1000 times, demonstrating allosteric coupling between SBD and NBD domains.     

热休克蛋白对细胞凋亡的调控作用

热休克蛋白属于细胞内分子伴侣蛋白,除涉及细胞内一些蛋白质分子构象和稳定性的调节之外,热休克蛋白对细胞应激、代谢、增殖以及凋亡等生理过程均具有重要的调控作用。研究表明热休克蛋白对细胞凋亡的调控机制是复杂的,可直接作用于与凋亡相关的蛋白质,也可以通过影响细胞信号传递而间接影响凋亡的发生。由于热休克蛋白对细胞凋亡的调控机制大多依赖于其分子伴侣功能,阻断热休克蛋白的伴侣功能已经成为研究药物诱导肿瘤细胞凋亡的重要靶点。     

Expression of stress proteins of HSP70 family in response to cold in Myrmica ants from various geographic populations

Expression of HSP70 is induced by stress factors, including sublethal chilling. However, the role of HSP70 for overcoming the consequences of cold stress is not clear. If it is positive, the level of HSP70 expression might be higher in populations from cold climates. Using the immunoblotting technique we investigated dynamics of HSP70 expression in response to cold stress in two Myrmica species (M. rubra and M. ruginodis) from three localities of different latitudes (50, 60 and 67°N). The results showed that in the more thermophilic species Myrmica rubra, expression of HSP70 after cold stress was higher. Within both species, HSP70 expression did not show a direct relationship with latitude. The southernmost population of M. rubra and northernmost population of M. ruginodis displayed the fastest and the most intense response. However, two other populations of M. rubra were similar in timing and intensity of the response, while in M. ruginodis the intermediate population showed the slowest and weakest response. The data suggest that expression of HSP70 may play essential role for adaptation to cold only in the northernmost population of M. ruginodis     

Cloning of an orange-spotted grouper Epinephelus coioides heat shock protein 90AB (HSP90AB) and characterization of its expression in response to nodavirus

The heat shock proteins (HSPs) family which consists of HSP90, HSP70, and low molecular mass HSPs are involved in chaperone activity. Here, we report the cloning and characterization of HSP90AB gene from orange-spotted grouper, Epinephelus coioides. The full-length of grouper HSP90AB was 727 amino acids and possessed an ATPase domain as well as an evolutionarily conserved molecular chaperone. The HSP90AB-green fluorescent protein fusion protein was evenly distributed in the cytoplasm. Immunohistochemistry (IHC) and real-time polymerase chain reaction (PCR) analyses indicated that the expression of grouper HSP90AB was marginally increased following nodavirus infection. Grouper E. coioides that received HSP90 inhibitor geldanamycin (GA) showed an increase in HSP90AB expression and growth of nodavirus supporting nodavirus replication.     

Association analysis of HSP70A1A haplotypes with heat tolerance in Chinese Holstein cattle

Single-nucleotide polymorphisms (SNPs) in the coding and untranslated regions of heat shock 70 kDa protein 1A (HSP70A1A), an inducible molecular chaperone that is responsible for cellular protection against heat stress, have been reported as being associated with heat tolerance. A fragment of the HSP70A1A gene was amplified in Chinese Holstein cattle and eight novel mutations were found. We performed comprehensive linkage disequilibrium (LD) and haplotype analyses of the eight SNPs of the HSP70A1A gene and examined their involvement in heat resistance in 600 Chinese Holstein cattle. Our results revealed the presence of significant differences between individuals carrying haplotype 1 and those without haplotype 1 for most of the heat-tolerance traits. Haplotype 1 increased the risk of heat stress; however, association analysis of its combination with haplotype 2 showed the lowest rectal temperature and red blood cell K⁺ level, moderate respiratory rate, and the highest red blood cell NKA level, suggesting a heterozygote advantage in the penetration of the phenotype. Protein expression levels in white blood cells among haplotype combinations further confirmed the hypothesis that heterozygotes for haplotypes 1 and 2 are more sensitive to heat stress. We presume that these mutations may be useful in the future as molecular genetic markers to assist selection for heat tolerance in cattle.     

CUEDC2 interacts with heat shock protein 70 and negatively regulates its chaperone activity

Recently studies have revealed that CUEDC2, a CUE domain-containing protein, plays critical roles in many biological processes, such as cell cycle, inflammation and tumorigenesis. In this study, to further explore the function of CUEDC2, we performed affinity purification combined with mass spectrometry analysis to identify its interaction proteins, which led to the identification of heat shock protein 70 (HSP70). We confirmed the interaction between CUEDC2 and HSP70 in vivo by co-immunoprecipitation assays. Mapping experiments revealed that CUE domain was required for their binding, while the PBD and CT domains of HSP70, mediated the interaction with CUEDC2. The intracellular Luciferase refolding assay indicated that CUEDC2 could inhibit the chaperone activity of HSP70. Together, our results identify HSP70 as a novel CUEDC2 interaction protein and suggest that CUEDC2 might play important roles in regulating HSP70 mediated stress responses.     

Molecular cloning, characterization, and expression analysis of a cytosolic HSP90 gene from Haematococcus pluvialis

Heat shock protein 90 (HSP90) is a highly conserved molecular chaperone that plays key roles in the folding, maintenance of structural integrity, and regulation of a subset of cytosolic proteins. In this study, the cDNA of Haematococcus pluvialis HSP90 (designated HpHSP90) was cloned by the combination of homology cloning and rapid amplification of cDNA ends approaches. The full-length cDNA of HpHSP90 was of 2,606 bp, including an open reading frame of 2,109 bp encoding a polypeptide of 702 amino acids with predicted molecular weight of 80.14 kDa and theoretical isoelectric point of 5.07. BLAST analysis revealed that HpHSP90 shared high similarity with other known HSP90s, and the five conserved amino acid blocks defined as HSP90 protein family signatures were also identified in HpHSP90, which indicated that HpHSP90 should be a cytosolic member of the HSP90 family. Under different stress conditions, messenger RNA (mRNA) expression levels of HpHSP90 were quantified by quantitative RT-PCR. To H. pluvialis kept at different temperatures for 1 h, maximum HpHSP90 expression was observed in the range 5 to 10°C and 35 to 40°C and the expression level of HpHSP90 at 40°C was the highest (threefold compared with that at 25°C). In H. pluvialis kept at 35°C for different times, the mRNA expression level of HpHSP90 reached a maximum level after 7 h and then dropped progressively. The results indicate that HpHSP90 responded to cold and heat stresses with a temperature-dependent expression pattern as well as exposure time effect and could be used as a molecular biomarker in adverse stress environment.     

A Highlights from MBoC Selection: Role of the loop L4,5 in allosteric regulation in mtHsp70s: in vivo significance of domain communication and its implications in protein translocation

Mitochondrial Hsp70 (mtHsp70) is essential for a vast repertoire of functions, including protein import, and requires effective interdomain communication for efficient partner-protein interactions. However, the in vivo functional significance of allosteric regulation in eukaryotes is poorly defined. Using integrated biochemical and yeast genetic approaches, we provide compelling evidence that a conserved substrate-binding domain (SBD) loop, L_4,5, plays a critical role in allosteric communication governing mtHsp70 chaperone functions across species. In yeast, a temperature-sensitive L_4,5 mutation (E467A) disrupts bidirectional domain communication, leading to compromised protein import and mitochondrial function. Loop L_4,5 functions synergistically with the linker in modulating the allosteric interface and conformational transitions between SBD and the nucleotide-binding domain (NBD), thus regulating interdomain communication. Second-site intragenic suppressors of E467A isolated within the SBD suppress domain communication defects by conformationally altering the allosteric interface, thereby restoring import and growth phenotypes. Strikingly, the suppressor mutations highlight that restoration of communication from NBD to SBD alone is the minimum essential requirement for effective in vivo function when primed at higher basal ATPase activity, mimicking the J-protein–bound state. Together these findings provide the first mechanistic insights into critical regions within the SBD of mtHsp70s regulating interdomain communication, thus highlighting its importance in protein translocation and mitochondrial biogenesis.     

Crystal Structure of the Stress-Inducible Human Heat Shock Protein 70 Substrate-Binding Domain in Complex with Peptide Substrate

The HSP70 family of molecular chaperones function to maintain protein quality control and homeostasis. The major stress-induced form, HSP70 (also called HSP72 or HSPA1A) is considered an important anti-cancer drug target because it is constitutively overexpressed in a number of human cancers and promotes cancer cell survival. All HSP70 family members contain two functional domains: an N-terminal nucleotide binding domain (NBD) and a C-terminal protein substrate-binding domain (SBD); the latter is subdivided into SBDα and SBDβ subdomains. The NBD and SBD structures of the bacterial ortholog, DnaK, have been characterized, but only the isolated NBD and SBDα segments of eukaryotic HSP70 proteins have been determined. Here we report the crystal structure of the substrate-bound human HSP70-SBD to 2 angstrom resolution. The overall fold of this SBD is similar to the corresponding domain in the substrate-bound DnaK structures, confirming a similar overall architecture of the orthologous bacterial and human HSP70 proteins. However, conformational differences are observed in the peptide-HSP70-SBD complex, particularly in the loop L_{α, β} that bridges SBDα to SBDβ, and the loop L_L,1 that connects the SBD and NBD. The interaction between the SBDα and SBDβ subdomains and the mode of substrate recognition is also different between DnaK and HSP70. This suggests that differences may exist in how different HSP70 proteins recognize their respective substrates. The high-resolution structure of the substrate-bound-HSP70-SBD complex provides a molecular platform for the rational design of small molecule compounds that preferentially target this C-terminal domain, in order to modulate human HSP70 function.     

Gentamicin inhibits HSP70-assisted protein folding by interfering with substrate recognition

We previously reported that gentamicin (GM) specifically binds to heat-shock protein with subunit molecular masses of 70 kDa (HSP70). In the present study, we have investigated the effects of GM binding on HSP70-assisted protein folding in vitro. The C-terminal, and not the N-terminal of HSP70 was found to bind to GM. GM significantly suppressed refolding of firefly luciferase in the presence of HSP70 and HSP40, although the ATPase activity of HSP70 was unaffected by GM. A surface plasmon resonance analysis revealed that GM specifically interferes with the binding of HSP70 to a model peptide that mimics the exposed hydrophobic surface of the folding intermediates. These results indicated that GM inhibits the chaperone activity of HSP70 and may suppress protein folding via inhibition of HSP70 in vivo.

Structured summary

MINT-7384283: HSP40 (uniprotkb:P25685) binds (MI:0407) to HSP70 (uniprotkb:P34930) by surface plasmon resonance (MI:0107)MINT-7384430: RNaseA (uniprotkb:P61823) binds (MI:0407) to HSP70 (uniprotkb:P34930) by surface plasmon resonance (MI:0107)