Import into mitochondria of precursors containing hydrophobic passenger proteins: pretreatment of precursors with urea inhibits import

We have studied the import into isolated yeast mitochondria of three hydrophobic passenger proteins attached to the N-terminal cleavable presequence of mitochondrial ATPase subunit 9 from Neurospora crassa. One natural precursor (pN9) contained N. crassa subunit 9; two chimaeric precursors, N9L/Y8-1 and N9L/Y9-2, respectively contained yeast mitochondrial ATPase subunits 8 and 9. In the absence of urea, pN9 and N9L/Y8-1 are imported efficiently but N9L/Y9-2 is not imported. After pretreatment of precursors in 4 M urea, binding of pN9 to mitochondria is marginally affected while its import is substantially inhibited; the binding to mitochondria of chimaeric proteins, N9L/Y8-1 and N9L/Y9-2, is greatly enhanced but no import is observed. This behaviour of import precursors containing hydrophobic passenger proteins is contrasted with that of a hydrophilic chimaeric precursor pCOXIV-DHFR, whose binding and import are enhanced by pretreatment with a high concentration of urea (8 M). The import of N9L/Y8-1 is very sensitive to the presence of low concentrations of urea in the import reaction mixture, and is abolished above 0.5 M urea although precursor binding to mitochondria is increased. By contrast, neither the import nor binding of pCOXIV-DHFR is affected directly by urea up to 0.8 M. These deleterious effects of urea on import of the chimaeric precursors N9L/Y8-1 and N9L/Y9-2 are interpreted in terms of a non-productive binding of these precursors to mitochondria, brought about by exposure of their hydrophobic domains resulting from urea unfolding. The generalization that membrane translocation of mitochondrial import precursors is enhanced by their prior unfolding in urea thus does not apply in the case of these precursors containing hydrophobic passenger proteins.     

Studies on the import into mitochondria of yeast ATP synthase subunits 8 and 9 encoded by artificial nuclear genes

Direct fusions have been constructed between each of subunits 8 and 9 from mitochondrial ATPase of Saccharomyces cerevisiae, proteins normally encoded inside mitochondria, and the cleavable N-terminal transit peptide from the nuclearly encoded precursor to subunit 9 of Neurospora crassa mitochondrial ATPase. The subunit 8 construct was imported efficiently into isolated yeast mitochondria and was processed at or very near the fusion point. When expressed in vivo from its artificial nuclear gene, this cytoplasmically synthesized form of subunit 8 restored the growth defects of aap 1 mutants unable to produce subunit 8 inside the mitochondria. The subunit 9 construct was, however, unable to be imported into isolated mitochondria and could not, following nuclear expression in vivo, complement growth defects in mitochondrial oli 1 mutants. This behaviour is contrasted with the previously demonstrated import competence of another yeast subunit 9 fusion, bearing the first five residues of mature N. crassa subunit 9 interposed between its own transit peptide and the yeast subunit 9 moiety.     

The rate of import and assembly of F1-ATPase in Saccharomyces cerevisiae

Subunit specific antiserum can be employed to study the course of ATPase assembly in mitochondria isolated from bakers' yeast. Comparing rates of subunit import with rates of enzyme assembly indicated that no substantial pool of unassembled subunits exists for the three largest ATPase peptides (alpha, beta, and gamma). Blocking import of specific ATPase subunits, however, did reveal a possible accumulation of unassembled alpha and gamma subunits in isolated mitochondria. The kinetic experiments also revealed a lag in the import of beta subunit relative to the uptake of alpha and gamma precursors. Experiments conducted in yeast cells confirmed that beta subunit is assembled soon after it is imported, but did not indicate a delay in import relative to the other subunits of F1.     

Yeast mitochondrial ATPase subunit 8, normally a mitochondrial gene product, expressed in vitro and imported back into the organelle.

Subunit 8 of yeast mitochondrial F1F0-ATPase is a proteolipid made on mitochondrial ribosomes and inserted directly into the inner membrane for assembly with the other F0 membrane-sector components. We have investigated the possibility of expressing this extremely hydrophobic, mitochondrially encoded protein outside the organelle and directing its import back into mitochondria using a suitable N-terminal targeting presequence. This report describes the successful import in vitro of ATPase subunit 8 proteolipid into yeast mitochondria when fused to the targeting sequence derived from the precursor of Neurospora crassa ATPase subunit 9. The predicted cleavage site of matrix protease was correctly recognized in the fusion protein. A targeting sequence from the precursor of yeast cytochrome oxidase subunit VI was unable to direct the subunit 8 proteolipid into mitochondria. The proteolipid subunit 8 exhibited a strong tendency to embed itself in mitochondrial membranes, which interfered with its ability to be properly imported when part of a synthetic precursor.     

The mitochondrial F1ATPase alpha-subunit is necessary for efficient import of mitochondrial precursors.

The mitochondrial import and assembly of the F1ATPase subunits requires, respectively, the participation of the molecular chaperones hsp70SSA1 and hsp70SSC1 and other components operating on opposite sides of the mitochondrial membrane. In previous studies, both the homology and the assembly properties of the F1ATPase alpha-subunit (ATP1p) compared to the groEL homologue, hsp60, have led to the proposal that this subunit could exhibit chaperone-like activity. In this report the extent to which this subunit participates in protein transport has been determined by comparing import into mitochondria that lack the F1ATPase alpha-subunit (delta ATP1) versus mitochondria that lack the other major catalytic subunit, the F1ATPase beta-subunit (delta ATP2). Yeast mutants lacking the alpha-subunit but not the beta-subunit grow much more slowly than expected on fermentable carbon sources and exhibit delayed kinetics of protein import for several mitochondrial precursors such as the F1 beta subunit, hsp60MIF4 and subunits 4 and 5 of the cytochrome oxidase. In vitro and in vivo the F1 beta-subunit precursor accumulates as a translocation intermediate in absence of the F1 alpha-subunit. In the absence of both the ATPase subunits yeast grows at the same rate as a strain lacking only the beta-subunit, and import of mitochondrial precursors is restored to that of wild type. These data indicate that the F1 alpha-subunit likely functions as an "assembly partner" to influence protein import rather than functioning directly as a chaperone. These data are discussed in light of the relationship between the import and assembly of proteins in mitochondria.     

Biogenesis of mitochondria: DNA sequence analysis of mit- mutations in the mitochondrial oli1 gene coding for mitochondrial ATPase subunit 9 in Saccharomyces cerevisiae.

The nucleotide sequence of the yeast mitochondrial olil gene has been obtained in a series of mit- mutants with mutations in this gene, which codes for subunit 9 of of the mitochondrial ATPase complex. Subunit 9 is the proteolipid, 76 amino acids in length, necessary for the proton translocation function of the membrane Fo-sector. These mutants were classified on the basis of their rescue by a petite strain shown here to retain the entire wild-type olil gene. The mutation in one mit- strain removes a positively charged residue (Arg39----Met) which is likely to be located in a segment of subunit 9 that protrudes from the inner mitochondrial membrane. In a second mit- mutant, a negatively charged residue replaces a conserved glycine residue (Gly18----Asp) in a glycine-rich segment of the protein that is most likely embedded within the membrane. Other mit- mutations result in frameshifts with predicted products 7, 65 and 68 amino acid residues long. In each mit- mutant, there is the loss of one or more of the amino acid residues that are highly conserved among diverse species. The location and nature of specific changes pinpoint amino acid residues in subunit 9 essential to the activity of the mitochondrial ATPase complex.     

Protein transport into mitochondria is conserved between plant and yeast species

Protein targeting into plant mitochondria was investigated by in vitro translocation experiments. The precursor of the mitochondrial F1-ATPase beta subunit from Nicotiana plumbaginifolia was synthesized in vitro, translocated to, processed, and assembled in purified Vicia faba mitochondria. Transport (but not binding) required a membrane potential and external nucleotides and was conserved among plant species. beta subunit precursors from the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe were imported and correctly processed in plant mitochondria. This translocation used protease-sensitive components of the outer membrane. Conversely, the N. plumbaginifolia beta subunit precursor was efficiently translocated and cleaved in yeast mitochondria. However, a precursor for a chloroplast protein was not targeted to plant or yeast mitochondria. We conclude that the machinery for protein import into mitochondria is specific and conserved in plant and yeast organisms. These results are discussed in the context of a poly- or monophyletic origin of mitochondria.     

The Tim8-Tim13 complex of Neurospora crassa functions in the assembly of proteins into both mitochondrial membranes

The Tim8 and Tim13 proteins in yeast are known to exist in the mitochondrial intermembrane space and to form a hetero-oligomeric complex involved in the import of the mitochondrial inner membrane protein Tim23, the central component of the TIM23 translocase. Here, we have isolated tim8 and tim13 mutants in Neurospora crassa and have shown that mitochondria lacking the Tim8-Tim13 complex were deficient in the import of the outer membrane beta-barrel proteins Tom40 and porin. Cross-linking studies showed that the Tom40 precursor contacts the Tim8-Tim13 complex. The complex is involved at an early point in the Tom40 assembly pathway because cross-links can only be detected during the initial stages of Tom40 import. In mitochondria lacking the Tim8-Tim13 complex, the Tom40 precursor appears in a previously characterized early intermediate of Tom40 assembly more slowly than in wild type mitochondria. Thus, our data suggest a model in which one of the first steps in Tom40 assembly may be interaction with the Tim8-Tim13 complex. As in yeast, the N. crassa Tim23 precursor was imported inefficiently into mitochondria lacking the Tim8-Tim13 complex when the membrane potential was reduced. Tim23 import intermediates could also be cross-linked to the complex, suggesting a dual role for the Tim8-Tim13 intermembrane space complex in the import of proteins found in both the outer and inner mitochondrial membranes.     

Mitochondrial H+-ATPase in mutants of Saccharomyces cerevisiae with defective subunit 8 of the enzyme complex

Mutants of Saccharomyces cerevisiae carrying defined lesions in the mitochondrial aap1 gene, coding for membrane subunit 8 of the H+-ATPase, have been investigated to examine the consequence of the mutations on the function and assembly of the enzyme complex. These include three mit- mutants, which cannot grow by oxidative metabolism due to their inability to synthesize full-length subunit 8, and three partial revertants of one of the mutants. The mutations in these strains have been previously characterized by DNA sequencing. The use of a monoclonal antibody to the beta subunit of the H+-ATPase as a probe of assembly defect revealed that the presence of subunit 8 is essential for the assembly of subunit 6 to the enzyme complex. Mitochondria isolated from the mit- mutants have negligible [32Pi]ATP exchange activity and they exhibited ATPase activity which is not sensitive to inhibition by oligomycin, indicating a defective membrane F0 sector. Normal assembly of subunit 8 (and subunit 6) was observed in the revertant strains, despite 8-9 amino-acid substitutions in the membrane-spanning region of the H+-ATPase subunit 8 in two of the strains. The assembled complex, however, exhibited reduced [32Pi]ATP exchange activity and low sensitivity to oligomycin, indicating that the product of the aap1 gene is a functional subunit of the mitochondrial H+-ATPase.     

Intramitochondrial sorting of the precursor to yeast cytochrome c oxidase subunit Va

We have continued our studies on the import pathway of the precursor to yeast cytochrome c oxidase subunit Va (pVa), a mitochondrial inner membrane protein. Previous work on this precursor demonstrated that import of pVa is unusually efficient, and that inner membrane localization is directed by a membrane-spanning domain in the COOH- terminal third of the protein. Here we report the results of studies aimed at analyzing the intramitochondrial sorting of pVa, as well as the role played by ancillary factors in import and localization of the precursor. We found that pVa was efficiently imported and correctly sorted in mitochondria prepared from yeast strains defective in the function of either mitochondrial heat shock protein (hsp)60 or hsp70. Under identical conditions the import and sorting of another mitochondrial protein, the precursor to the beta subunit of the F1 ATPase, was completely defective. Consistent with previous results demonstrating that the subunit Va precursor is loosely folded, we found that pVa could be efficiently imported into mitochondria after translation in wheat germ extracts. This results suggests that normal levels of extramitochondrial hsp70 are also not required for import of the protein. The results of this study enhance our understanding of the mechanism by which pVa is routed to the mitochondrial inner membrane. They suggest that while the NH2 terminus of pVa is exposed to the matrix and processed by the matrix metalloprotease, the protein remains anchored to the inner membrane before being assembled into a functional holoenzyme complex.     

Biogenesis of mitochondria: DNA sequence analysis of mit- mutations in the mitochondrial oli2 gene coding for mitochondrial ATPase subunit 6 in Saccharomyces cerevisiae.

A series of yeast mitochondrial mit- mutants with defects in the oli2 gene, coding for subunit 6 of the mitochondrial ATPase complex, has been analyzed at the DNA sequence level. Fifteen of sixteen primary mit- mutants were shown to contain frameshift or nonsense mutations predicting truncated subunit 6 polypeptides, in various strains ranging from about 20% to 95% of the wild-type length of 259 amino acids. In only one strain could the defect in subunit 6 function be assigned to amino acid substitution in an otherwise full-length subunit 6. Many mutants carried multiple base substitutions or insertions/deletions, presumably arising from the manganese chloride mutagenesis treatment. Revertants from three of the mit- mutants were analyzed: all contained full-length subunit 6 proteins with one or more amino acid substitutions. The preponderance of truncated proteins as opposed to substituted full-length proteins in oli2 mit- mutants is suggested to reflect the ability of subunit 6 to accommodate amino acid substitutions at many locations, with little or no change in its functional properties in the membrane FO-sector of the ATPase complex.     

Assembly of F1-ATPase in isolated mitochondria

The assembly of the proton-translocating ATPase complex was studied in isolated mitochondria by incubating yeast mitochondria with radiolabeled precursors of mitochondrial proteins which had been made in a cell-free protein synthesis system. Following such an incubation, the ATPase complex (F1F0) was isolated. Newly assembled F1-ATPase was detected by autoradiography of the isolated enzyme, only peptide subunits which had been made in vitro and imported into the isolated mitochondria could be radioactive. Incorporation of radiolabeled ATPase subunits into the enzyme does not occur in the presence of an uncoupler of oxidative phosphorylation or of a divalent metal chelator, nor does it occur in submitochondrial particles rather than intact mitochondria. Incorporation of labeled ATPase subunits into the enzyme can be completed by unlabeled subunits, provided the unlabeled proteins are added before the mitochondria are incubated with radioactive precursors. These findings suggest that F1-ATPase is assembled from a pool of subunits in mitochondria.     

Tim54p connects inner membrane assembly and proteolytic pathways in the mitochondrion

Tim54p, a component of the inner membrane TIM22 complex, does not directly mediate the import of inner membrane substrates but is required for assembly/stability of the 300-kD TIM22 complex. In addition, Deltatim54 yeast exhibit a petite-negative phenotype (also observed in yeast harboring mutations in the F1Fo ATPase, the ADP/ATP carrier, mitochondrial morphology components, or the i-AAA protease, Yme1p). Interestingly, other import mutants in our strain background are not petite-negative. We report that Tim54p is not involved in maintenance of mitochondrial DNA or mitochondrial morphology. Rather, Tim54p mediates assembly of an active Yme1p complex, after Yme1p is imported via the TIM23 pathway. Defective Yme1p assembly is likely the major contributing factor for the petite-negativity in strains lacking functional Tim54p. Thus, Tim54p has two independent functions: scaffolding/stability for the TIM22 membrane complex and assembly of Yme1p into a proteolytically active complex. As such, Tim54p links protein import, assembly, and turnover pathways in the mitochondrion.     

The bipartite nuclear localization sequence of Rpn2 is required for nuclear import of proteasomal base complexes via karyopherin alphabeta and proteasome functions

26 S proteasomes fulfill final steps in the ubiquitin-dependent degradation pathway by recognizing and hydrolyzing ubiquitylated proteins. As the 26 S proteasome mainly localizes to the nucleus in yeast, we addressed the question how this 2-MDa multisubunit complex is imported into the nucleus. 26 S proteasomes consist of a 20 S proteolytically active core and 19 S regulatory particles, the latter composed of two subcomplexes, namely the base and lid complexes. We have shown that 20 S core particles are translocated into the nucleus as inactive precursor complexes via the classic karyopherin alphabeta import pathway. Here, we provide evidence that nuclear import of base and lid complexes also depends on karyopherin alphabeta. Potential classic nuclear localization sequences (NLSs) of base subunits were analyzed. Rpn2 and Rpt2, a non-ATPase subunit and an ATPase subunit of the base complex, harbor functional NLSs. The Rpt2 NLS deletion yielded wild type localization. However, the deletion of the Rpn2 NLS resulted in improper nuclear proteasome localization and impaired proteasome function. Our data support the model by which nuclear 26 S proteasomes are assembled from subcomplexes imported by karyopherin alphabeta.     

A yeast mitochondrial presequence functions as a signal for targeting to plant mitochondria in vivo.

To date, the presequence of the mitochondrial beta-subunit of ATPase from tobacco is the only signal sequence that has been shown to target a foreign protein into plant mitochondria in vivo. Here we report that the presequence of a yeast mitochondrial protein directs bacterial beta-glucuronidase (GUS) specifically into the mitochondrial compartment of transgenic tobacco plants. Fusions between the presequence of the mitochondrial tryptophanyl-tRNA-synthetase gene from yeast and the GUS gene have been introduced into tobacco plants and yeast cells. In both systems, proteins containing the complete yeast mitochondrial presequence are efficiently imported in the mitochondria. Measurements of GUS activity in different subcellular fractions indicate that there is no substantial misrouting of the chimeric proteins in plant cells. In vitro synthesized GUS fusion proteins have a higher molecular weight than those found inside yeast and tobacco mitochondria, suggesting a processing of the precursors during import. Interestingly, fusion proteins translocated across the mitochondrial membranes of tobacco have the same size as those that are imported into yeast mitochondria. We conclude that the processing enzyme in plant mitochondria may recognize a proximate or even the same cleavage site within the mitochondrial tryptophanyl-tRNA-synthetase presequence as the matrix protease from yeast.     

A purified precursor polypeptide requires a cytosolic protein fraction for import into mitochondria.

The beta-subunit of mitochondrial ATPase is coded by a nuclear gene, synthesized outside the mitochondria as a larger precursor and imported into mitochondria. The beta-subunit precursor was purified from yeast, both as a homogeneous, unlabeled polypeptide and in radiochemically pure form. Both precursor preparations were cleaved to the mature beta-subunit by partially purified processing protease from the mitochondrial matrix. However, import of the radiochemically pure precursor into isolated yeast mitochondria required a cytosolic fraction from yeast or reticulocytes. The cytosolic factor was non-dialyzable and trypsin-sensitive; its apparent mol. wt. was approximately 40 000 as judged by gel filtration. Import of some proteins into mitochondria thus requires proteins of the 'soluble' cytoplasm.     

Sequential action of mitochondrial chaperones in protein import into the matrix.

Translocation and folding of proteins imported into mitochondria are mediated by two matrix-localized chaperones, mhsp70 and hsp60. In order to investigate whether these chaperones act sequentially or in parallel, we studied their interaction with newly imported precursor proteins in isolated yeast mitochondria by coimmunoprecipitation. All precursors bound transiently to mhsp70. Release from mhsp70 required hydrolysis of ATP and did not immediately generate a tightly folded protein. For example, after imported mouse dihydrofolate reductase (a soluble monomeric enzyme) had been released from mhsp70, folding to a protease resistant conformation occurred only after a lag and was much slower than the release. Under standard import conditions, no significant association of DHFR with hsp60 could be detected. Similarly, newly imported hsp60 subunit was released from mhsp70 as an incompletely folded, unassembled intermediate which accumulated at low temperature and assembled to hsp60 14-mer at higher temperature in an ATP-dependent manner. Mas2p (the larger subunit of the MAS-encoded processing protease) first bound to mhsp70, then to hsp60, and only then assembled with its partner subunit, Mas1p. We propose that ATP-dependent release from mhsp70 is insufficient to cause folding of imported proteins and that assembly of hsp60 and Mas2p requires sequential, ATP-dependent interactions with mhsp70 and hsp60.     

The essential mitochondrial protein Erv1 cooperates with Mia40 in biogenesis of intermembrane space proteins

The proteins of the mitochondrial intermembrane space (IMS) are encoded by nuclear genes and synthesized on cytosolic ribosomes. While some IMS proteins are imported by the classical presequence pathway that involves the membrane potential deltapsi across the inner mitochondrial membrane and proteolytic processing to release the mature protein to the IMS, the import of numerous small IMS proteins is independent of a deltapsi and does not include proteolytic processing. The biogenesis of small IMS proteins requires an essential mitochondrial IMS import and assembly protein, termed Mia40. Here, we show that Erv1, a further essential IMS protein that has been reported to function as a sulfhydryl oxidase and participate in biogenesis of Fe/S proteins, is also required for the biogenesis of small IMS proteins. We generated a temperature-sensitive yeast mutant of Erv1 and observed a strong reduction of the levels of small IMS proteins upon shift of the cells to non-permissive temperature. Isolated erv1-2 mitochondria were selectively impaired in import of small IMS proteins while protein import pathways to other mitochondrial subcompartments were not affected. Small IMS precursor proteins remained associated with Mia40 in erv1-2 mitochondria and were not assembled into mature oligomeric complexes. Moreover, Erv1 associated with Mia40 in a reductant-sensitive manner. We conclude that two essential proteins, Mia40 and Erv1, cooperate in the assembly pathway of small proteins of the mitochondrial IMS.     

The role of Tim9p in the assembly of the TIM22 import complexes

Tim9p is located in the soluble 70-kDa Tim9p–Tim10p complex and the 300-kDa membrane complex in the mitochondrial TIM22 protein import system, which mediates the import of inner membrane proteins. From a collection of temperature-sensitive mutants, we have analyzed two in detail. tim9–3 contained two mutations and tim9–19 contained one mutation, all located near the 'twin CX₃C' motif that is conserved in the small Tim proteins. As a result, the import components in the tim9–3 mutant mitochondria were severely reduced and assembled into complexes of aberrant sizes. Protein import was severely reduced and Tim9p and Tim10p binding to in vitro imported ADP/ATP carrier was impaired. In the tim9–19 mutant mitochondria, the 300-kDa membrane complex was assembled, although the soluble 70-kDa Tim9p–Tim10p complex was not detectable. Protein import was decreased only two-fold. When coexpressed in Escherichia coli , tim9–19 and TIM10 proteins failed to assemble into a 70-kDa complex. Our findings suggest that residues near the 'twin CX₃C' motif are important for the assembly of Tim9p in both the Tim9p–Tim10p complex and the 300-kDa membrane complex.