Role of the chaperonin cofactor Hsp10 in protein folding and sorting in yeast mitochondria

Protein folding in mitochondria is mediated by the chaperonin Hsp60, the homologue of E. coli GroEL. Mitochondria also contain a homologue of the cochaperonin GroES, called Hsp10, which is a functional regulator of the chaperonin. To define the in vivo role of the co- chaperonin, we have used the genetic and biochemical potential of the yeast S. cerevisiae. The HSP10 gene was cloned and sequenced and temperature-sensitive lethal hsp10 mutants were generated. Our results identify Hsp10 as an essential component of the mitochondrial protein folding apparatus, participating in various aspects of Hsp60 function. Hsp10 is required for the folding and assembly of proteins imported into the matrix compartment, and is involved in the sorting of certain proteins, such as the Rieske Fe/S protein, passing through the matrix en route to the intermembrane space. The folding of the precursor of cytosolic dihydrofolate reductase (DHFR), imported into mitochondria as a fusion protein, is apparently independent of Hsp10 function consistent with observations made for the chaperonin-mediated folding of DHFR in vitro. The temperature-sensitive mutations in Hsp10 map to a domain (residues 25-40) that corresponds to a previously identified mobile loop region of bacterial GroES and result in a reduced binding affinity of hsp10 for the chaperonin at the non-permissive temperature.     

The disaggregation activity of the mitochondrial ClpB homolog Hsp78 maintains Hsp70 function during heat stress

Molecular chaperones are important components of mitochondrial protein biogenesis and are required to maintain the organellar function under normal and stress conditions. We addressed the functional role of the Hsp100/ClpB homolog Hsp78 during aggregation reactions and its functional cooperation with the main mitochondrial Hsp70, Ssc1, in mitochondria of the yeast Saccharomyces cerevisiae. By establishing an aggregation/disaggregation assay in intact mitochondria we demonstrated that Hsp78 is indispensable for the resolubilization of protein aggregates generated by heat stress under in vivo conditions. The ATP-dependent disaggregation activity of Hsp78 was capable of reversing the preprotein import defect of a destabilized mutant form of Ssc1. This role in disaggregation of Ssc1 is unique for Hsp78, since the recently identified, Hsp70-specific chaperone Zim17 had no effect on the resolubilization reaction. We observed only a minor effect of the second mitochondrial Hsp100 family member Mcx1 on protein disaggregation. A "holding" activity of the mitochondrial Hsp70 system was a prerequisite for a successful resolubilization of aggregated proteins. We conclude that the protective role of Hsp78 in thermotolerance is mainly based on maintaining the molecular chaperone Ssc1 in a soluble and functional state.     

Hsp78, a Clp homologue within mitochondria, can substitute for chaperone functions of mt-hsp70.

Hsp78 is a Clp homologue within mitochondria of Saccharomyces cerevisiae. Deletion of HSP78 does not cause any detectable changes in wild type cells, but results in a petite phenotype in the ssc1-3 mutant strain carrying a temperature-sensitive allele of mt-hsp70. When overexpressed in the ssc1-3 mutant strain, hsp78 suppresses the defect in mitochondrial protein import under permissive conditions in vitro and interacts directly with newly imported polypeptide chains. As a molecular chaperone, hsp78 prevents the aggregation of misfolded proteins in the matrix of mitochondria under conditions of impaired mt-hsp70 function. However, unlike misfolded proteins associated with mt-hsp70, hsp78-bound polypeptides are not efficiently degraded by the ATP-dependent PIM1 protease. Thus, hsp78 can partially substitute for mt-hsp70 functions in the assembly of mitochondria and may be part of a salvage pathway if mt-hsp70 is limiting.     

Function of the maize mitochondrial chaperonin hsp60: specific association between hsp60 and newly synthesized F1-ATPase alpha subunits.

Mitochondria contain a protein, hsp60, that is induced by heat shock and has been shown to function as a chaperonin in the assembly of mitochondrial enzyme complexes composed of proteins encoded by nuclear genes and imported from the cytosol. To determine whether products of mitochondrial genes are also assembled through an interaction with hsp60, we looked for association between hsp60 and proteins synthesized by isolated mitochondria. We have determined by electrophoretic, centrifugal, and immunological assays that at least two of those proteins become physically associated with hsp60. In mitochondrial matrix extracts, this association could be disrupted by the addition of Mg-ATP. One of the proteins that formed a stable association with hsp60 was the alpha subunit of the multicomponent complex F1-ATPase. We have not identified the other protein. These results indicate that hsp60 can function in the folding and assembly of mitochondrial proteins encoded by both mitochondrial and nuclear genes.     

Mitochondrial Hsp70 Ssc1: role in protein folding

Ssc1, the major Hsp70 of the mitochondrial matrix, is involved in the translocation of proteins from the cytosol into the matrix and their subsequent folding. To better understand the physiological mechanism of action of this Hsp70, we have undertaken a biochemical analysis of Ssc1 and two mutant proteins, Ssc1--2 and Ssc1--201. ssc1--2 is a temperature-sensitive mutant defective in both translocation and folding; ssc1--201 contains a second mutation in this ssc1 gene that suppresses the temperature-sensitive growth defect of ssc1--2, correcting the translocation but not the folding defect. We found that although Ssc1 was competent to facilitate the refolding of denatured luciferase in vitro, both Ssc1--2 and Ssc1--201 showed significant defects, consistent with the data obtained with isolated mitochondria. Purified Ssc1--2 had a lowered affinity for a peptide substrate compared with wild-type Ssc1 but only in the ADP-bound state. This peptide binding defect was reversed in the suppressor protein Ssc1--201. However, a defect in the ability of Hsp40 to stimulate the ATPase activity of Ssc1--2 was not corrected in Ssc1--201. Thus, the inability of these two mutant proteins to efficiently facilitate luciferase refolding correlates with their defect in stimulation of ATPase activity by Hsp40s, indicating that this interaction is critical for protein folding in mitochondria.     

Structural properties of substrate proteins determine their proteolysis by the mitochondrial AAA+ protease Pim1

The protease Pim1/LON, a member of the AAA+ family of homo-oligomeric ATP-dependent proteases, is responsible for the degradation of soluble proteins in the mitochondrial matrix. To establish the molecular parameters required for the specific recognition and proteolysis of substrate proteins by Pim1, we analyzed the in organello degradation of imported reporter proteins containing different structural properties. The amino acid composition at the amino-terminal end had no major effect on the proteolysis reaction. However, proteins with an amino-terminal extension of less than 60 amino acids in front of a stably folded reporter domain were completely resistant to proteolysis by Pim1. Substrate proteins with a longer amino-terminal extension showed incomplete proteolysis, resulting in the generation of a defined degradation fragment. We conclude that Pim1-mediated protein degradation is processive and is initiated from an unstructured amino-terminal segment. Resistance to degradation and fragment formation was abolished if the folding state of the reporter domain was destabilized, indicating that Pim1 is not able to unravel folded proteins for proteolysis. We propose that the requirement for an exposed, large, non-native protein segment, in combination with a limited unfolding capability, accounts for the selectivity of the protease Pim1 for damaged or misfolded polypeptides.     

The hsp60B gene of Drosophila melanogaster is essential for the spermatid individualization process

The 60-kDa heat shock protein family (Hsp60) is found in prokaryotes, mitochondria, and chloroplasts. The Hsp60 proteins promote proper protein folding by preventing aggregation. In Drosophila melanogaster, the hsp60 gene is essential for a variety of developmental processes, beginning at early embryogenesis. In this study we show that an additional member of the Drosophila hsp60 gene family, hsp60B, is essential in male fertility. In males homozygous for a mutation of the hsp60B gene, developmental processes appeared normal throughout most of spermatogenesis, including spermatocyte growth, meiosis, and spermatid elongation. At these stages, mitochondria also displayed a differentiation process similar to wild-types. However, we found that the mutation disrupted a late stage of spermatogenesis, the spermatid individualization process. In this process, the individualization complex is assembled at spermatid nuclear heads, traverses along spermatid tails, and generates membranes for each of the spermatids in a cyst. Our analysis further shows that the individualization complex in sterile males displayed abnormal morphology as it was traveling along the spermatid tails. The Drosophila Hsp60 proteins are believed to be exclusively localized in the mitochondria. Our observation that the hsp60B mutation displayed no apparent defect in mitochondrial differentiation during spermatogenesis suggests that the Hsp60B protein may operate in a nonmitochondrial location.     

Hsp60-independent protein folding in the matrix of yeast mitochondria.

Proteins that are imported from the cytosol into mitochondria cross the mitochondrial membranes in an unfolded conformation and then fold in the matrix. Some of these proteins require the chaperonin hsp60 for folding. To test whether hsp60 is required for the folding of all imported matrix proteins, we monitored the folding of four monomeric proteins after import into mitochondria from wild-type yeast or from a mutant strain in which hsp60 had been inactivated. The four precursors included two authentic matrix proteins (rhodanese and the mitochondrial cyclophilin Cpr3p) and two artificial precursors (matrix-targeted variants of dihydrofolate reductase and barnase). Only rhodanese formed a tight complex with hsp60 and required hsp60 for folding. The three other proteins folded efficiently without, and showed no detectable binding to, hsp60. Thus, the mitochondrial chaperonin system is not essential for the folding of all matrix proteins. These data agree well with earlier in vitro studies, which had demonstrated that only a subset of proteins require chaperones for efficient folding.     

Cyclophilin 20 is involved in mitochondrial protein folding in cooperation with molecular chaperones Hsp70 and Hsp60.

We studied the role of mitochondrial cyclophilin 20 (CyP20), a peptidyl-prolyl cis-trans isomerase, in preprotein translocation across the mitochondrial membranes and protein folding inside the organelle. The inhibitory drug cyclosporin A did not impair membrane translocation of preproteins, but it delayed the folding of an imported protein in wild-type mitochondria. Similarly, Neurospora crassa mitochondria lacking CyP20 efficiently imported preproteins into the matrix, but folding of an imported protein was significantly delayed, indicating that CyP20 is involved in protein folding in the matrix. The slow folding in the mutant mitochondria was not inhibited by cyclosporin A. Folding intermediates of precursor molecules reversibly accumulated at the molecular chaperones Hsp70 and Hsp60 in the matrix. We conclude that CyP20 is a component of the mitochondrial protein folding machinery and that it cooperates with Hsp70 and Hsp60. It is speculated that peptidyl-prolyl cis-trans isomerases in other cellular compartments may similarly promote protein folding in cooperation with chaperone proteins.     

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.     

Severe ethanol stress induces the preferential synthesis of mitochondrial disaggregase Hsp78 and formation of DUMPs in Saccharomyces cerevisiae

Severe ethanol stress (>9% v/v) induces pronounced translation repression in yeast cells. However, some proteins, which are exceptionally synthesized even under translation repression, play important roles in ethanol tolerance. These proteins are expected to provide important clues for elucidating the survival strategies of yeast cells under severe ethanol stress. In this study, we identified Hsp78 as a protein effectively synthesized under severe ethanol stress. As Hsp78 is involved in mitochondrial protein quality control, we investigated the effect of severe ethanol stress on mitochondrial proteins and found that Ilv2, Kgd1, and Aco1 aggregated with Hsp78 under severe ethanol stress, forming mitochondrial deposition sites for denatured proteins, called DUMPs (Deposits of Unfolded Mitochondrial Proteins). Aggregation of mitochondrial proteins and formation of DUMPs were accelerated in hsp78? cells compared with those in wild-type cells. During the recovery process after ethanol removal, aggregated Ilv2 and DUMP levels rapidly decreased in wild-type cells but were maintained for a long time (>180 min) in hsp78Δ cells. Furthermore, the frequency of respiration-deficient mutants caused by severe ethanol stress was higher in hsp78? cells than in wild-type cells. These results indicate that severe ethanol stress damaged mitochondrial proteins and that Hsp78 was preferentially synthesized to cope with the damage, thereby suppressing the rapid increase in aggregated protein levels under stress and achieving proper clearance of aggregated proteins during the recovery process. This study provides novel insights into the adverse effects of ethanol on mitochondria and yeast response to severe ethanol stress.     

Proteomic analysis of mitochondrial protein turnover: identification of novel substrate proteins of the matrix protease pim1

ATP-dependent oligomeric proteases are major components of cellular protein quality control systems. To investigate the role of proteolytic processes in the maintenance of mitochondrial functions, we analyzed the dynamic behavior of the mitochondrial proteome of Saccharomyces cerevisiae by two-dimensional (2D) polyacrylamide gel electrophoresis. By a characterization of the influence of temperature on protein turnover in isolated mitochondria, we were able to define four groups of proteins showing a differential susceptibility to proteolysis. The protein Pim1/LON has been shown to be the main protease in the mitochondrial matrix responsible for the removal of damaged or nonnative proteins. To assess the substrate range of Pim1 under in vivo conditions, we performed a quantitative comparison of the 2D protein spot patterns between wild-type and pim1Delta mitochondria. We were able to identify a novel subset of mitochondrial proteins that are putative endogenous substrates of Pim1. Using an in organello degradation assay, we confirmed the Pim1-specific, ATP-dependent proteolysis of the newly identified substrate proteins. We could demonstrate that the functional integrity of the Pim1 substrate proteins, in particular, the presence of intact prosthetic groups, had a major influence on the susceptibility to proteolysis.     

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.     

Structure and function of Hsp78, the mitochondrial ClpB homolog

The cellular role of Hsp100/Clp chaperones in maintaining protein stability is based on two functional aspects. Under normal growth conditions they represent components of cellular protein quality control machineries that selectively remove damaged or misfolded polypeptides in cooperation with specific proteases. After thermal stress, proteins of the ClpB subfamily have the unique ability to directly resolubilize aggregated polypeptides in concert with Hsp70-type chaperones, leading to the recovery of enzymatic activity. Hsp78, the homolog of the bacterial chaperone ClpB in mitochondria of eukaryotic organisms, participates in both protective activities. Hsp78 is involved in conferring thermotolerance to the mitochondrial compartment but also participates in protein degradation by the matrix protease Pim1. Despite the high sequence conservation between Hsp78 and ClpB, an analysis of the structural properties revealed significant differences. The identified mitochondrial Hsp78s do not contain N-terminal substrate-binding domains. In addition, formation of the oligomeric chaperone complex was more variable as anticipated from the studies with bacterial ClpB. Hsp78 predominantly formed a trimeric complex under in vivo conditions. Hence, mitochondrial Hsp78s form a distinct subgroup of the ClpB chaperone family, exhibiting specific structural and functional properties.     

Connexin45 directly binds to ZO-1 and localizes to the tight junction region in epithelial MDCK cells

The molecular chaperone protein Hsp78, a member of the Clp/Hsp100 family localized in the mitochondria of Saccharomyces cerevisiae, is required for maintenance of mitochondrial functions under heat stress. To characterize the biochemical mechanisms of Hsp78 function, Hsp78 was purified to homogeneity and its role in the reactivation of chemically and heat-denatured substrate protein was analyzed in vitro. Hsp78 alone was not able to mediate reactivation of firefly luciferase. Rather, efficient refolding was dependent on the simultaneous presence of Hsp78 and the mitochondrial Hsp70 machinery, composed of Ssc1p/Mdj1p/Mge1p. Bacterial DnaK/DnaJ/GrpE, which cooperates with the Hsp78 homolog, ClpB in Escherichia coli, could not substitute for the mitochondrial Hsp70 system. However, efficient Hsp78-dependent refolding of luciferase was observed if DnaK was replaced by Ssc1p in these experiments, suggesting a specific functional interaction of both chaperone proteins. These findings establish the cooperation of Hsp78 with the Hsp70 machinery in the refolding of heat-inactivated proteins and demonstrate a conserved mode of action of ClpB homologs.     

The Hsp60 folding machinery is crucial for manganese superoxide dismutase folding and function

Abstract

Even though the deleterious effects of increased reactive oxygen species (ROS) levels have been implicated in a variety of neurodegenerative disorders, the triggering events that lead to the increased ROS and successive damages are still ill-defined. Mitochondria are the key organelles controlling the ROS balance, being their main source and also counteracting them by the action of the ROS scavenging system. Mitochondria, moreover, control the presence of ROS-damaged proteins by action of the protein quality control (PQC) system. One of its components is the mitochondrial chaperone Hsp60 assisting the folding of a subset of mitochondrial matrix proteins. Mutations in Hsp60 cause a late onset form of the neurodegenerative disease hereditary spastic paraplegia (SPG13). In this study, we aimed to address the molecular consequences of Hsp60 shortage. We here demonstrate that a heterozygous knockout Hsp60 model that recapitulates features of the human disease and exhibits increased oxidative stress in neuronal tissues. Moreover, we indicate that the increase of ROS is, at least in part, due to impaired folding of the manganese superoxide dismutase (MnSOD), a key antioxidant enzyme. We observed that the Hsp60 and MnSOD proteins interact. Based on these results, we propose that MnSOD is a substrate of the Hsp60 folding machinery and that under conditions of diminished availability of Hsp60, MnSOD is impaired in reaching the native state. This suggests a possible link between Hsp60-dependent PQC and the ROS scavenging systems that may have the function to increase ROS production under conditions of folding stress.     

Hsp78 chaperone functions in restoration of mitochondrial network following heat stress

Under physiological conditions mitochondria of yeast Saccharomyces cerevisiae form a branched tubular network, the continuity of which is maintained by balanced membrane fusion and fission processes. Here, we show using mitochondrial matrix targeted green fluorescent protein that exposure of cells to extreme heat shock led to dramatic changes in mitochondrial morphology, as tubular network disintegrated into several fragmented vesicles. Interestingly, this fragmentation did not affect mitochondrial ability to maintain the membrane potential. Cells subjected to recovery at physiological temperature were able to restore the mitochondrial network, as long as an active matrix chaperone, Hsp78, was present. Deletion of HSP78 gene did not affect fragmentation of mitochondria upon heat stress, but significantly inhibited ability to restore mitochondrial network. Changes of mitochondrial morphology correlated with aggregation of mitochondrial proteins. On the other hand, recovery of mitochondrial network correlated with disappearance of protein aggregates and reactivation of enzymatic activity of a model thermo-sensitive protein: mitochondrial DNA polymerase. Since protein disaggregation and refolding is mediated by Hsp78 chaperone collaborating with Hsp70 chaperone system, we postulate that effect of Hsp78 on mitochondrial morphology upon recovery after heat shock is mediated by its ability to restore activity of unknown protein(s) responsible for maintenance of mitochondrial morphology.     

Identification of in vivo substrates of the yeast mitochondrial chaperonins reveals overlapping but non-identical requirement for hsp60 and hsp10.

The mechanism of chaperonin-assisted protein folding has been mostly analyzed in vitro using non-homologous substrate proteins. In order to understand the relative importance of hsp60 and hsp10 in the living cell, homologous substrate proteins need to be identified and analyzed. We have devised a novel screen to test the folding of a large variety of homologous substrates in the mitochondrial matrix in the absence or presence of functional hsp60 or hsp10. The identified substrates have an Mr of 15-90 kDa and fall into three groups: (i) proteins that require both hsp60 and hsp10 for correct folding; (ii) proteins that completely fail to fold after inactivation of hsp60 but are unaffected by the inactivation of hsp10; and (iii) newly imported hsp60 itself, which is more severely affected by inactivation of hsp10 than by inactivation of pre-existing hsp60. The majority of the identified substrates are group I proteins. For these, the lack of hsp60 function has a more pronounced effect than inactivation of hsp10. We suggest that homologous substrate proteins have differential chaperonin requirements, indicating that hsp60 and hsp10 do not always act as a single functional unit in vivo.     

Role of the novel metallopeptidase Mop112 and saccharolysin for the complete degradation of proteins residing in different subcompartments of mitochondria

Mitochondria harbor a conserved proteolytic system that mediates the complete degradation of organellar proteins. ATP-dependent proteases, like a Lon protease in the matrix space and m- and i-AAA proteases in the inner membrane, degrade malfolded proteins within mitochondria and thereby protect the cell against mitochondrial damage. Proteolytic breakdown products include peptides and free amino acids, which are constantly released from mitochondria. It remained unclear, however, whether the turnover of malfolded proteins involves only ATP-dependent proteases or also oligopeptidases within mitochondria. Here we describe the identification of Mop112, a novel metallopeptidase of the pitrilysin family M16 localized in the intermembrane space of yeast mitochondria. This peptidase exerts important functions for the maintenance of the respiratory competence of the cells that overlap with the i-AAA protease. Deletion of MOP112 did not affect the stability of misfolded proteins in mitochondria, but resulted in an increased release from the organelle of peptides, generated upon proteolysis of mitochondrial proteins. We find that the previously described metallopeptidase saccharolysin (or Prd1) exerts a similar function in the intermembrane space. The identification of peptides released from peptidase-deficient mitochondria by mass spectrometry indicates a dual function of Mop112 and saccharolysin: they degrade peptides generated upon proteolysis of proteins both in the intermembrane and matrix space and presequence peptides cleaved off by specific processing peptidases in both compartments. These results suggest that the turnover of mitochondrial proteins is mediated by the sequential action of ATP-dependent proteases and oligopeptidases, some of them localized in the intermembrane space.     

Role of the AAA protease Yme1 in folding of proteins in the intermembrane space of mitochondria

The vast majority of mitochondrial proteins are synthesized in the cytosol and transported into the organelle in a largely, if not completely, unfolded state. The proper function of mitochondria thus depends on folding of several hundreds of proteins in the various subcompartments of the organelle. Whereas folding of proteins in the mitochondrial matrix is supported by members of several chaperone families, very little is known about folding of proteins in the intermembrane space (IMS). We targeted dihydrofolate reductase (DHFR) as a model substrate to the IMS of yeast mitochondria and analyzed its folding. DHFR can fold in this compartment, and its aggregation upon heat shock can be prevented in an ATP-dependent manner. Yme1, an AAA (ATPases associated with diverse cellular activities) protease of the IMS, prevented aggregation of DHFR. Analysis of protein aggregates in mitochondria lacking Yme1 revealed the presence of a number of proteins involved in the establishment of mitochondrial ultrastructure, lipid metabolism, protein import, and respiratory growth. These findings explain the pleiotropic effects of deletion of YME1 and suggest an important role for Yme1 as a folding assistant, in addition to its proteolytic function, in the protein homeostasis of mitochondria