Role of the GroEL chaperonin intermediate domain in coupling ATP hydrolysis to polypeptide release

Heat shock protein 60 and cardiovascular diseases: An intricate love-hate story

Cardiovascular diseases (CVDs) are the result of complex pathophysiological processes in the tissues comprising the heart and blood vessels. Inflammation is the main culprit for the development of cardiovascular dysfunction, and it may be traced to cellular stress events including apoptosis, oxidative and shear stress, and cellular and humoral immune responses, all of which impair the system's structure and function. An intracellular chaperone, heat shock protein 60 (HSP60) is an intriguing example of a protein that may both be an ally and a foe for cardiovascular homeostasis; on one hand providing protection against cellular injury, and on the other triggering damaging responses through innate and adaptive immunity. In this review we will discuss the functions of HSP60 and its effects on cells and the immune system regulation, only to later address its implications in the development and progression of CVD. Lastly, we summarize the outcome of various studies targeting HSP60 as a potential therapeutic strategy for cardiovascular and other diseases.

Toward Developing Chemical Modulators of Hsp60 as Potential Therapeutics

The 60 kDa heat shock protein (Hsp60) is classically known as a mitochondrial chaperonin protein working together with co-chaperonin 10 kDa heat shock protein (Hsp10). This chaperonin complex is essential for folding proteins newly imported into mitochondria. However, Hsp60, and/or Hsp10 have also been shown to reside in other subcellular compartments including extracellular space, cytosol, and nucleus. The proteins in these extra-mitochondrial compartments may possess a wide range of functions dependent or independent of its chaperoning activity. But the mechanistic details remain unknown. Mutations in Hsp60 gene have been shown to be associated with neurodegenerative disorders. Abnormality in expression level and/or subcellular localization have also been detected from different diseased tissues including inflammatory diseases and various cancers. Therefore, there is a strong interest in developing small molecule modulators of Hsp60. Most of the reported inhibitors were discovered through various chemoproteomics strategies. In this review, we will describe the recent progress in this area with reported inhibitors from both natural products and synthetic compounds. The former includes mizoribine, epolactaene, myrtucommulone, stephacidin B, and avrainvillamide while the latter includes o-carboranylphenoxyacetanilides and gold (III) porphyrins. The potencies of the known inhibitors range from low micromolar to millimolar concentrations. The potential applications of these inhibitors include anti-cancer, anti-inflammatory diseases, and anti-autoimmune diseases.

The versatile mutational "repertoire" of Escherichia coli GroEL, a multidomain chaperonin nanomachine

The bacterial chaperonins are highly sophisticated molecular nanomachines, controlled by the hydrolysis of ATP to dynamically trap and remove from the environment unstable protein molecules that are susceptible to denaturation and aggregation. Chaperonins also act to assist in the refolding of these unstable proteins, providing a means by which these proteins may return in active form to the complex environment of the cell. The Escherichia coli GroE chaperonin system is one of the largest protein supramolecular complexes known, whose quaternary structure is required for segregating aggregation-prone proteins. Over the course of more than two decades of research on GroE, it has become accepted that GroE, more specifically the GroEL subunit, is a "high-tolerance" molecular system, capable of accommodating numerous mutations, while retaining its molecular integrity. In some cases, a given site of mutation was revealed to be absolutely required for GroEL function, providing hints regarding the network of signals and triggers that propel this unique system. In other instances, however, a mutation has produced a more delicate response, altering only part of, or in some cases, only a single facet of, the molecular mechanism, and these mutants have often provided invaluable hints on the extent of the complexity underlying chaperonin-assisted protein folding. In this review, we highlight some examples of the latter type of GroEL mutants which compose the unique "mutational repertoire" of GroEL and touch upon the important clues that each mutant provided to the overall effort to elucidate the details of GroE action.

Opening and closing of a toroidal group II chaperonin revealed by a symmetry constrained elastic network model

Recently, the atomic structures of both the closed and open forms of Group 2 chaperonin protein Mm-cpn were revealed through crystallography and cryo-electron microscopy. This toroidal-like chaperonin is composed of two eightfold rings that face back-to-back. To gain a computational advantage, we used a symmetry constrained elastic network model (SCENM), which requires only a repeated subunit structure and its symmetric connectivity to neighboring subunits to simulate the entire system. In the case of chaperonin, only six subunits (i.e., three from each ring) were used out of the eight subunits comprising each ring. A smooth and symmetric pathway between the open and closed conformations was generated by elastic network interpolation (ENI). To support this result, we also performed a symmetry-constrained normal mode analysis (NMA), which revealed the intrinsic vibration features of the given structures. The NMA and ENI results for the representative single subunit were duplicated according to the symmetry pattern to reconstruct the entire assembly. To test the feasibility of the symmetry model, its results were also compared with those obtained from the full model. This study allowed the folding mechanism of chaperonin Mm-cpn to be elucidated by SCENM in a timely manner.

The proteomic alterations of Thermoanaerobacter tengcongensis cultured at different temperatures

Thermoanaerobacter tengcongensis, one of many thermophilic organisms, survives harsh living conditions in temperatures ranging from 50 to 80 degrees C. In this comprehensive analysis, we present a robust approach, 2-DE and MALDI-TOF MS, to compare and identify the bacterial proteins responding to the temperature stress. In total, 164 spots of 2-DE were found with the significant changes in spot volume at three culture temperatures, 55, 75, and 80 degrees C, respectively; furthermore, 87 unique proteins were characterized by MS. Our results reveal that the electrophoretic images of the bacterial proteins, extracted from two culture temperatures (55 and 75 degrees C), had similar patterns; however, the bacteria cultured at 80 degrees C had dramatically decreased their spot volumes. Additionally, the temperature-sensitive proteins are broadly divided into two groups: specific expression at certain temperatures and consistent changes of expression responsive to temperature. For instance, three proteins closely related with redox regulation, dihydrolipoamide acyltransferase, NADH:ubiquinone oxidoreductase, and ferredoxin, were only detected in the bacteria cultured at 55 degrees C. Whereas, two chaperonins, GroES and GroEL, were found to show a consistent increase during the elevated temperatures with the determinations, either by MS or Western blot. The proteomic information, thus expedites our understanding of the molecular mechanisms regarding how thermophilic bacteria adapt to the alterations in living environment.

Multiple Structural Transitions of the GroEL Subunit Are Sensitive to Intermolecular Interactions with Cochaperonin and Refolding Polypeptide

In this study we attempted to determine the specific roles of the numerous conformational changes that are observed in the bacterial chaperonin GroEL, by performing stopped-flow experiments on GroEL R231W in the presence of a refolding substrate protein. The apparent rate of one kinetic phase was decreased by approximately 25% in the presence of prebound unfolded malate dehydrogenase while another phase was suppressed completely under the same conditions, reflecting different effects of the unfolded protein on multiple structural transitions within GroEL. The addition of cochaperonin GroES counteracts the effect of the bound substrate protein in the former case, but had no effect on the latter, more extensive suppression. Using a chemically modified form of GroEL R231W which is incapable of releasing substrate proteins at low temperatures, we identified a conformational transition that is implicated in the release of substrate proteins. Parts of the actual process of substrate protein release were also observed through fluorescence resonance energy transfer experiments involving GroEL and labeled substrate protein. Analysis of the energy transfer data revealed an interesting relationship between substrate protein displacement and a specific structural transition in the GroEL apical domain.

Potential Role of Methionine Sulfoxide in the Inactivation of the Chaperone GroEL by Hypochlorous Acid (HOCl) and Peroxynitrite (ONOO–)

GroEL is an Escherichia coli molecular chaperone that functions in vivo to fold newly synthesized polypeptides as well as to bind and refold denatured proteins during stress. This protein is a suitable model for its eukaryotic homolog, heat shock protein 60 (Hsp60), due to the high number of conserved amino acid sequences and similar function. Here, we will provide evidence that GroEL is rather insensitive to oxidants produced endogenously during metabolism, such as nitric oxide (.NO) or hydrogen peroxide (H(2)O(2)), but is modified and inactivated by efficiently reactive species generated by phagocytes, such as peroxynitrite (ONOO(-)) and hypochlorous acid (HOCl). For the exposure of 17.5 microm GroEL to 100-250 microm HOCl, the major pathway of inactivation was through the oxidation of methionine to methionine sulfoxide, established through mass spectrometric detection of methionine sulfoxide and the reactivation of a significant fraction of inactivated GroEL by the enzyme methionine sulfoxide reductase B/A (MsrB/A). In addition to the oxidation of methionine, HOCl caused the conversion of cysteine to cysteic acid and this product may account for the remainder of inactivated GroEL not recoverable through MsrB/A. In contrast, HOCl produced only negligible yields of 3-chlorotyrosine. A remarkable finding was the conversion of Met(111) and Met(114) to Met sulfone, which suggests a rather low reduction potential of these 2 residues in GroEL. The high sensitivity of GroEL toward HOCl and ONOO(-) suggests that this protein may be a target for bacterial killing by phagocytes.

Assembly of chaperonin complexes

Chaperonins are a subclass of molecular chaperones that assist both the folding of newly synthesized proteins and the maintenance of proteins in a folded state during periods of stress. The best studied members of this family are the type I chaperonins, occurring in bacteria and evolutionarily derived organelles. Type II chaperonins occur in archaea and the eukaryotic cytosol. An intriguing question pertains to the mechanism by which chaperonins themselves are folded and assembled into functional oligomers. The available evidence for the assembly/disassembly of type I and II chaperonins points to a process that is highly cooperative and suggests a prominent role for nucleotides. Interestingly, the intracellular assembly of type I chaperonins appears to be a chaperone-dependent process itself and requires functional preformed chaperonin complexes.

High salt-induced conversion of Escherichia coli GroEL into a fully functional thermophilic chaperonin

The GroE chaperonin system can adapt to and function at various environmental folding conditions. To examine chaperonin-assisted protein folding at high salt concentrations, we characterized Escherichia coli GroE chaperonin activity in 1.2 m ammonium sulfate. Our data are consistent with GroEL undergoing a conformational change at this salt concentration, characterized by elevated ATPase activity and increased exposure of hydrophobic surface, as indicated by increased binding of the fluorophore bis-(5, 5')-8-anilino-1-naphthalene sulfonic acid to the chaperonin. The presence of the salt results in increased substrate stringency and dependence on the full GroE system for release and productive folding of substrate proteins. Surprisingly, GroEL is fully functional as a thermophilic chaperonin in high concentrations of ammonium sulfate and is stable at temperatures up to 75 degrees C. At these extreme conditions, GroEL can suppress aggregation and mediate refolding of non-native proteins.

The chaperonin GroEL binds to late-folding non-native conformations present in native Escherichia coli and murine dihydrofolate reductases

Dihydrofolate reductases from mouse (MuDHFR) or Escherichia coli (EcDHFR) are shown to refold via several intermediate forms, each of which can bind to the chaperonin GroEL. When stable complexes with GroEL are formed, they consist of late-folding intermediates. In addition, we find that late-folding intermediates that are present in the native enzyme bind to GroEL. For the E. coli and murine proteins, the extent of protein bound increases as the temperature is increased from 8 degreesC to 42 degreesC, at which temperature either protein is completely bound as the last (EcDHFR) or the last two (MuDHFR) folding intermediate(s). Thus for EcDHFR, the binding is transient at low temperature (<30 degreesC) and stable at high temperature (>35 degreesC). For MuDHFR, complex formation appears less temperature dependent. In general, the data demonstrate that the overall binding free energy for the interaction of GroEL with native DHFR is the sum of the free energy for the first step in DHFR unfolding, which is unfavorable, and the free energy of binding the non-native conformation, which is favorable. For EcDHFR, this results in an overall binding free energy that is unfavorable below 30 degreesC. Over the temperature range of 8 degreesC to 42 degreesC, GroEL binds MuDHFR more tightly than EcDHFR, due partially to a small free energy difference between two pre-existing non-native conformations of MuDHFR, resulting in binding to more than one folding intermediate.