Importance of two ATP-binding sites for oligomerization, ATPase activity and chaperone function of mitochondrial Hsp78 protein.

The yeast mitochondrial chaperone Hsp78, a homologue of yeast cytosolic Hsp104 and bacterial ClpB, is required for maintenance of mitochondrial functions under heat stress. Here, Hsp78 was purified to homogeneity and shown to form a homo-hexameric complex, with an apparent molecular mass of approximately 440 kDa, in an ATP-dependent manner. Analysis of its ATPase activity reveals that the observed positive cooperativity effect depends both on Hsp78 and ATP concentration. Site-directed mutagenesis of the two putative Hsp78 nucleotide-binding domains suggest that the first nucleotide-binding domain is responsible for ATP hydrolysis and the second one for protein oligomerization. Studies on the chaperone activity of Hsp78 show that its cooperation with the mitochondrial Hsp70 system, consisting of Ssc1p, Mdj1p and Mge1p, is needed for the efficient reactivation of substrate proteins. These studies also suggest that the oligomerization but not the Hsp78 ATPase activity is essential for its chaperone activity.

Mitochondrial Hsp78, a member of the Clp/Hsp100 family in Saccharomyces cerevisiae, cooperates with Hsp70 in protein refolding.

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.

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.

Prion-dependent switching between respiratory competence and deficiency in the yeast nam9-1 mutant.

Nam9p is a protein of the mitochondrial ribosome. The respiration-deficient Saccharomyces cerevisiae strain MB43-nam9-1 expresses Nam9-1p containing the point mutation S82L. Respiratory deficiency correlates with a decrease in the steady level of some mitochondrially encoded proteins and the complete lack of mitochondrially encoded cytochrome oxidase subunit 2 (Cox2). De novo synthesis of Cox2 in MB43-nam9-1 is unaffected, indicating that newly synthesized Cox2 is rapidly degraded. Respiratory deficiency of MB43-nam9-1 is overcome by transient overexpression of HSP104, by deletion of HSP104, by transient exposure to guanidine hydrochloride, and by expression of the C-terminal portion of Sup35, indicating an involvement of the yeast prion [PSI(+)]. Respiratory deficiency of MB43-nam9-1 can be reinduced by transfer of cytosol from S. cerevisiae that harbors [PSI(+)]. We conclude that nam9-1 causes respiratory deficiency only in combination with the cytosolic prion [PSI(+)], presenting the first example of a synthetic effect between cytosolic [PSI(+)] and a mutant mitochondrial protein.

Cloning and characterization of the dnaK heat shock operon of the marine bacterium Vibrio harveyi.

We cloned the DNA region of the Vibrio harveyi chromosome containing the heat shock genes dnaK and dnaJ and sequenced them. These genes are arranged in the chromosome in the order dnaK-dnaJ, as in other proteobacteria of the alpha and gamma subdivisions. The dnaK gene is 1923 nucleotides in length and codes for a protein of 640 amino acid residues, with a predicted molecular mass of 69,076 Da and 81.2% similarity to the DnaK protein of Escherichia coli. The V. harveyi dnaJ gene has a coding sequence of 1158 nucleotides. The predicted DnaJ protein contains 385 amino acids, its calculated molecular mass is 41,619 Da and it has 74.7% similarity to the DnaJ protein of E. coli. Northern hybridization experiments with RNA from V. harveyi cells and a DNA probe carrying both the dnaK and dnaJ genes showed a single, heat-inducible transcript, indicating that these genes form an operon. Primer extension analysis revealed five heat-inducible transcriptional start sites upstream of the dnaK gene, two of which (T1 and T4) are preceded by sequences typical of the E. coli heat shock promoters recognized by the sigma 32 (sigma32) factor. Location of these promoters is highly similar to that of the E. coli dnaK promoters. No transcriptional start sites were detected upstream of the dnaJ gene. The V. harveyi dnaKJ operon cloned in a plasmid in E. coli cells was transcribed in a sigma32 dependent manner and the size of the transcript, the kinetics of transcription, and the transcriptional start sites were as in V. harveyi cells. This indicates a high conservation of the transcriptional heat shock regulatory elements between E. coli and V. harveyi, both belonging to the gamma subdivision of proteobacteria. We tested the ability of the cloned dnaKJ genes to complement E. coli dnaK and dnaJ mutants and found that V. harveyi DnaJ restored a thermoresistant phenotype to dnaJ mutants and enabled lambda phage to grow in the mutant cells. V. harveyi DnaK did not suppress the thermosensitivity of dnaK mutants but complemented the dnaK deletion mutant with respect to growth of lambda phage. V. harveyi DnaK, in contrast to DnaJ, failed to modulate the heat shock response in E. coli. Our results suggest that the DnaK chaperone may be more species specific than the DnaJ chaperone.

Cloning of the groE operon of the marine bacterium Vibrio harveyi using a lambda vector.

groES and groEL genes encode two co-operating proteins GroES and GroEL, belonging to a class of chaperone proteins highly conserved during evolution. The GroE chaperones are indispensable for the growth of bacteriophage lambda in Escherichia coli cells. In order to clone the groEL and groES genes of the marine bacterium Vibrio harveyi, we constructed the V. harveyi genomic library in the lambdaEMBL1 vector, and selected clones which were able to complement mutations in both groE genes of E. coli for bacteriophage lambda growth. Using Southern hybridization, in one of these clones we identified a DNA fragment homologous to the E. coli groE region. Analysis of the nucleotide sequence of this fragment showed that the cloned region contained a sequence in 71.7% homologous to the 3' end of the groEL gene of E. coli. This confirmed that the lambda clone indeed carries the groE region of V. harveyi. The positive result of our strategy of cloning with the use of the genomic library in lambda vector suggests that the same method might be useful in the isolation of the groE homologues from other bacteria. The V. harveyi cloned groE genes did not suppress thermosensitivity of the E. coli groE mutants.