The precursor of mitochondrial aspartate aminotransferase is translocated into mitochondria as apoprotein

Mitochondrial aspartate aminotransferase is synthesized on free polysomes as a higher molecular weight precursor (Sonderegger, P., Jaussi, R., Christen, P., and Gehring, H. (1982) J. Biol. Chem. 257, 3339-3345). The present study examines whether the coenzyme pyridoxal phosphate or pyridoxamine phosphate is required for the uptake of the precursor into mitochondria. Chicken embryo fibroblasts were cultured in medium prepared with and without pyridoxal. In cells grown in the presence of pyridoxal only holoform of aspartate aminotransferase and no apoenzyme was detected. Cells cultured under pyridoxal deficiency contained about 30% of apoenzyme in secondary cultures. All of this apoform was identified as mitochondrial isoenzyme. In order to differentiate whether this apoenzyme corresponded to newly synthesized protein or originated from pre-existing holoenzyme, double isotope-labeling experiments were performed. Secondary cultures of chicken embryo fibroblasts grown under pyridoxal depletion were labeled with [3H]methionine, and then pulsed with [35S]methionine. In another series of experiments, the 3H-labeled cells were pulsed with [35S]methionine in the presence of the protonophore carbonyl cyanide m-chlorophenylhydrazone in order to accumulate the precursor. Subsequently, the accumulated precursor was chased into the mitochondria by addition of the carbonyl cyanide m-chlorophenylhydrazone antagonist cysteamine. The holo- and apoenzyme from the ultrasonic extract of the double-labeled cells were separated by affinity chromatography on a phosphopyridoxyl-AH-Sepharose column, immunoprecipitated, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. Under both experimental conditions, the 3H/35S ratio of the apoenzyme was less than half of that of the holoenzyme. Therefore, the apoenzyme and not the holoenzyme is the first product of the precursor in the mitochondria. Apparently, the precursor of mitochondrial aspartate aminotransferase is transported into mitochondria as apoprotein and is processed there independently of the coenzyme.     

Import of rat liver mitochondrial malate dehydrogenase. Synthesis, transport, and processing in vitro of its precursor

Rat liver total RNA was translated in a reticulocyte lysate, and the precursor of rat liver mitochondrial malate dehydrogenase was identified by a monospecific antibody against the denatured mature enzyme. The precursor is about Mr = 1500 to 2000 larger than the monomeric form of the mature protein. The major spots of the two-dimensional peptide map of the two proteins were identical. The precursor was synthesized on free polysomes, but not membrane-bound polysomes. Upon fractionation by molecular sieve chromatography on Sephadex G-100, the size of the precursor was slightly larger than the dimeric form of the mature protein. Incubation of the precursor with isolated mitochondria from Chinese hamster ovary cells resulted in uptake and processing of the precursor to the mature size. The processed form was resistant to trypsin indicating that it was translocated into mitochondria. Processing was complete in 10 to 30 min at 30 degrees C. Rapid binding of the precursor to mitochondria was also observed at 0 or 30 degrees C. Processing but not binding was inhibited by an uncoupler.     

The synthesis of murine ferrochelatase in vitro and in vivo.

Ferrochelatase (protohaem ferro-lyase, EC 4.99.1.1), the terminal enzyme of the haem-biosynthetic pathway, is an integral membrane protein of the mitochondrial inner membrane. When murine erythroleukaemia cells are labelled in vivo with [35S]methionine, lysed, and the extract is immunoprecipitated with rabbit anti-(mouse ferrochelatase) antibody, a protein of Mr 40,000 is isolated. However, when isolated mouse RNA is translated in a cell-free reticulocyte extract, a protein of Mr 43,000 is isolated. Incubation of this Mr 43,000 protein with isolated mitochondria resulted in processing of the Mr 43,000 precursor to the Mr 40,000 mature-sized protein. Addition of carbonyl cyanide m-chlorophenylhydrazone and/or phenanthroline inhibits this processing. These data indicate that ferrochelatase, like most mitochondrial proteins, is synthesized in the cytoplasm as a larger precursor and is then translocated and processed to a mature-sized protein in an energy-required step.     

Expression of cDNAs encoding the precursor and the mature form of chicken mitochondrial aspartate aminotransferase in Escherichia coli

Both the precursor and the mature form of chicken mitochondrial aspartate aminotransferase were synthesized in Escherichia coli. The precursor was found to sediment quantitatively together with insoluble cell material. In contrast, mature mitochondrial aspartate aminotransferase could be readily extracted from the cells and was indistinguishable from the enzyme isolated from chicken heart in all respects tested: specific activity 230 units mg-1; Mr 2 X 45,000; pI greater than 9; NH2-terminal sequence SSWWSHVEMG, the initiator methionine having been removed by the bacteria. Thus, the polypeptide chain representing mature mitochondrial aspartate aminotransferase is an autonomous folding unit which attains its functional spatial structure independently of the presence of the prepiece, trans-membrane passage, and proteolytic processing.     

Presequence binding factor-dependent and -independent import of proteins into mitochondria.

A cytosolic protein factor(s) is involved in the import of precursor proteins into mitochondria. PBF (presequence binding factor) is a protein factor which binds to the precursor form (pOTC) of rat ornithine carbamoyltransferase (OTC) but not to the mature OTC, and is required for the mitochondrial import of pOTC. The precursors for aspartate aminotransferase and malate dehydrogenase as well as pOTC synthesized in a reticulocyte lysate were efficiently imported into the mitochondria. However, the precursors synthesized in the lysate depleted for PBF by treatment with pOTC-Sepharose were not imported. Readdition of the purified PBF to the depleted lysate fully restored the import. pOTC synthesized in the untreated lysate sedimented as a complex with a broad peak of around 9 S, whereas pOTC synthesized in the PBF-depleted lysate sedimented at an expected position of monomer (2.5 S). When the purified PBF was readded to the depleted lysate, pOTC sedimented as a complex of about 7 S. In contrast to most mitochondrial proteins, rat 3-oxoacyl-CoA thiolase is synthesized with no cleavable presequence and an NH2-terminal portion of the mature protein functions as a mitochondrial import signal. The thiolase synthesized in the PBF-depleted lysate could be efficiently imported into the mitochondria, and readdition of PBF had little effect on the import. The thiolase synthesized in the untreated, the PBF-depleted, or the PBF-readded lysate sedimented at an expected position of monomer (2.5 S). These observations provide support for the existence of PBF-dependent and -independent pathways of mitochondrial protein import.     

The precursor to ornithine carbamyl transferase is transported to mitochondria as a 5S complex containing an import factor

The precursor to ornithine carbamyl transferase (Mr = 40,000) was synthesized in a rabbit reticulocyte lysate system and purified by immunoaffinity chromatography. Import of purified precursor by isolated mitochondria depended upon the presence of import factor(s) in fresh reticulocyte lysate. Velocity sedimentation analyses indicated that import factor binds to precursor to form a 5S complex (approximately 90 kDa); in this form, precursor was efficiently imported by isolated mitochondria. The ability of the 5S complex to deliver precursor into mitochondria was not affected by pretreatment with high concentrations of RNase. Import factor did not bind to mitochondria in the absence of precursor; upon binding of precursor to mitochondria in the presence of import factor, subsequent transmembrane uptake of precursor did not require the continued presence of additional lysate components.     

The requirement of heat shock cognate 70 protein for mitochondrial import varies among precursor proteins and depends on precursor length.

The cytosolic heat shock cognate 70-kDa protein (hsc70) is required for efficient import of ornithine transcarbamylase precursor (pOTC) into rat liver mitochondria (K. Terada, K. Ohtsuka, N. Imamoto, Y. Yoneda, and M. Mori, Mol. Cell. Biol. 15:3708-3713, 1995). The requirement of hsc70 for mitochondrial import of various precursor proteins and truncated pOTCs was studied by using an in vitro translation import system in which hsc70 was completely depleted. hsc70-dependent import of pOTC was about 60% of the total import, while import of the aspartate aminotransferase precursor, the serine:pyruvate aminotransferase precursor, and 3-oxoacyl coenzyme A thiolase was about 50, 30, and 0%, respectively. The subunit sizes of these four precursor proteins were 40 to 47 kDa. When pOTC was serially truncated from the COOH terminal, the hsc70 requirement decreased gradually and was not evident for the shortest truncated pOTCs of 90 and 72 residues. These truncated pOTCs were imported and proteolytically processed rapidly in 0.5 to 2 min at 25 degrees C, and the processed mature portions and the presequence portion were rapidly degraded. Sucrose gradient centrifugation analysis followed by import assay showed that pOTC synthesized in rabbit reticulocyte lysate forms an import-competent complex of about 11S in an hsc70-dependent manner. S values of import-competent forms of aspartate aminotransferase precursor, serine:pyruvate aminotransferase precursor, and 3-oxoacyl coenzyme A thiolase were 9S, 9S, and 4S, respectively. Thus, the S value decreased as the hsc70 dependency decreased. Precursor proteins were coimmunoprecipitated from the reticulocyte lysate containing the newly synthesized precursor proteins with an hsc70 antibody. The amount of coimmunoprecipitated proteins was much larger in the absence of ATP than in its presence. Among the four precursor proteins, the amount of coimmunoprecipitated protein decreased as the hsc70 dependency decreased.     

Processing-independent in vitro translocation of cytochrome P-450(SCC) precursor across mitochondrial membranes

In the presence of a membrane-permeable metal chelator, bovine adrenal cortex mitochondria imported P-450(SCC) precursor without processing of the amino-terminal extension peptide. The imported precursor was bound to the matrix side surface of the inner membrane. When the inhibition due to the metal chelator was removed, the imported precursor was processed to the mature form. Unprocessed precursor was also detected in mitochondria when the import reaction was carried out at relatively low temperature. These results suggest that the translocation of P-450(SCC) precursor across mitochondrial membranes is independent of its processing to the mature form. Both membrane-bound and solubilized P-450(SCC) could be cleaved by trypsin into two fragments with molecular weights of 29 kDa and 26 kDa, respectively, suggesting a two-domain structure of the molecule. The in vitro-imported and processed P-450(SCC) was also cleaved by trypsin in the same way. This finding indicated that the in vitro-imported and processed P-450(SCC) has the same conformation as the native form.     

Primary structure requirements for correct sorting of the yeast mitochondrial protein ADH III to the yeast mitochondrial matrix space.

Alcohol dehydrogenase isoenzyme III (ADH III) in Saccharomyces cerevisiae, the product of the ADH3 gene, is located in the mitochondrial matrix. The ADH III protein was synthesized as a larger precursor in vitro when the gene was transcribed with the SP6 promoter and translated with a reticulocyte lysate. A precursor of the same size was detected when radioactively pulse-labeled proteins were immunoprecipitated with anti-ADH antibody. This precursor was rapidly processed to the mature form in vivo with a half-time of less than 3 min. The processing was blocked if the mitochondria were uncoupled with carbonyl cyanide m-chlorophenylhydrazone. Mutant enzymes in which only the amino-terminal 14 or 16 amino acids of the presequence were retained were correctly targeted and imported into the matrix. A mutant enzyme that was missing the amino-terminal 17 amino acids of the presequence produced an active enzyme, but the majority of the enzyme activity remained in the cytoplasmic compartment on cellular fractionation. Random amino acid changes were produced in the wild-type presequence by bisulfite mutagenesis of the ADH3 gene. The resulting ADH III protein was targeted to the mitochondria and imported into the matrix in all of the mutants tested, as judged by enzyme activity. Mutants containing amino acid changes in the carboxyl-proximal half of the ADH3 presequence were imported and processed to the mature form at a slower rate than the wild type, as judged by pulse-chase studies in vivo. The unprocessed precursor appeared to be unstable in vivo. It was concluded that only a small portion of the presequence contains the necessary information for correct targeting and import. Furthermore, the information for correct proteolytic processing of the presequence appears to be distinct from the targeting information and may involve secondary structure information in the presequence.     

Distinct steps in the import of ADP/ATP carrier into mitochondria

Transport of the precursor to the ADP/ATP carrier from the cytosol into the mitochondrial inner membrane was resolved into several consecutive steps. The precursor protein was trapped at distinct stages of the import pathway and subsequently chased to the mature form. In a first reaction, the precursor interacts with a protease-sensitive component on the mitochondrial surface. It then reaches intermediate sites in the outer membrane which are saturable and where it is protected against proteases. This translocation intermediate can be extracted at alkaline pH. We suggest that it is anchored to the membrane by a so far unknown proteinaceous component. The membrane potential delta psi-dependent entrance of the ADP/ATP carrier into the inner membrane takes place at contact sites between outer and inner membranes. Completion of translocation into the inner membrane can occur in the absence of delta psi. A cytosolic component which is present in reticulocyte lysate and which interacts with isolated mitochondria is required for the specific binding of the precursor to mitochondria.     

Transport of proteins across the mitochondrial outer membrane. A precursor form of the cytoplasmically made intermembrane enzyme cytochrome c peroxidase.

Cytochrome c peroxidase, a cytoplasmically made enzyme located between the inner and outer membrane of yeast mitochondria, is synthesized as larger precursor in a reticulocyte cell-free lysate as well as in pulsed yeast spheroplasts. When the pulsed spheroplasts are chased, the precursor is converted to the mature apoprotein. When the in vitro synthesized precursor is incubated with isolated yeast mitochondria in the absence of protein synthesis, it is cleaved to the mature form; the mature form co-sediments with the mitochondria and is resistant to externally added proteases. These results, in conjunction with those reported earlier (Maccecchini, M.-L., Rudin, Y., Blobel, G., and Schatz, G. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 343-347) suggest that the mechanism of protein transport into the mitochondrial intermembrane space is quite similar to that of protein transport into the matrix or the inner membrane.     

Membrane and cytosolic components affecting transport of the precursor for ornithine carbamyltransferase into mitochondria

A higher molecular weight precursor (Mr = 39,000) to the liver mitochondrial matrix enzyme, ornithine carbamyltransferase (Mr = 36,000), is imported and processed by heart mitochondria in vitro in a manner similar to liver mitochondria. In both systems, however, an additional 37-kDa ornithine carbamyltransferase polypeptide appears, but this arises from nonspecific events and, therefore, does not represent a bona fide intermediate in the overall processing sequence. Our experiments demonstrate that the outer mitochondrial membrane of mitochondria contains a protease-sensitive (5 micrograms of trypsin or chymotrypsin/ml, 15 min at 2 degrees C), salt-resistant (1.0 M KCl) protein which is required to maintain import functions. In addition, functional post-translational import requires a component of the reticulocyte lysate (i.e. cytosol) that is used for initially synthesizing precursor enzyme. The component is retained by Sephadex G-25. Import of Sephadex G-25-excluded precursor is restored by fresh reticulocyte lysate but not by a combination of other additives, including Mg2+, K+, ATP, ADP, Pi, succinate, and total translation mixture (minus lysate).     

Import of precursor proteins into mitochondria: site of polypeptide unfolding

The matrix-targeting signal of mitochondrial preornithine carbamyl transferase has been fused to either murine dihydrofolate reductase (pODHFR) or bacterial chloramphenicol acetyltransferase (pOCAT). Loosening of the tightly folded "native" structure of the two proteins following their synthesis in a rabbit reticulocyte lysate was assayed by the acquisition of protease sensitivity (pODHFR and pOCAT) or by the loss of enzyme activity (pOCAT). By these criteria, the bulk population of both precursor proteins was tightly folded following release from the ribosome, even in the presence of ATP and excess reticulocyte lysate. Neither protein unfolded as a consequence of binding to the surfaces of anionic liposomes or intact mitochondria. However, a non-native form of full-length pOCAT, exhibiting a loss of enzymatic activity and an enhanced protease sensitivity, was detected in association with a submitochondrial fraction that banded between the inner and outer mitochondrial membrane fractions on sucrose density gradients. Delivery of the precursor molecule to this position required ATP and a proteinaceous component on the surface of the organelle.     

Biosynthesis of four rat liver mitochondrial acyl-CoA dehydrogenases: in vitro synthesis, import into mitochondria, and processing of their precursors in a cell-free system and in cultured cells

The synthesis, translocation, processing, and assembly of rat liver short chain acyl-CoA, medium chain acyl-CoA, long chain acyl-CoA, and isovaleryl-CoA dehydrogenases were studied. These four acyl-CoA dehydrogenases are homotetrameric flavoproteins which are located in the mitochondrial matrix. They were synthesized in a cell-free rabbit reticulocyte lysate system, programmed by rat liver polysomal RNA, as precursor polypeptides which are 2-4 kDa larger than their corresponding mature subunits (Mr 41,000-45,000). When the radiolabeled precursors were incubated with intact rat liver mitochondria, they appeared to bind tightly to the mitochondrial outer membrane. At this stage they were completely susceptible to the action of exogenous trypsin. The precursors bound to mitochondria at 0 degrees C were translocated into the mitochondria and processed when the temperature was raised to 30 degrees C. No reaction occurred when the temperature was kept at 0 degrees C, however, suggesting that the binding of the precursors is temperature independent while the subsequent steps of the pathway are energy dependent. Indeed, the translocation reaction was inhibited by compounds such as dinitrophenol and rhodamine 6G which inhibit mitochondrial energy metabolism. The newly imported (mature) enzymes were inaccessible to the proteolytic action of added trypsin. The processing of the precursors to mature subunits was proteolytically carried out in the mitochondrial matrix, and the processed mature subunits mostly assembled to their respective tetrameric forms. Newly synthesized larger precursors of each of the four acyl-CoA dehydrogenases were recovered from intact, cultured Buffalo rat liver cells in the presence of dinitrophenol. When dinitrophenol was removed in a pulse-chase protocol, the accumulated precursors were rapidly (t1/2 3-5 min) converted to their corresponding mature subunits. On the other hand, when the chase was performed in the presence of the inhibitor, the labeled precursors disappeared with t1/2 of greater than 4 h for long chain acyl-CoA dehydrogenase and 1-2 h for the other three enzyme precursors.     

Uptake and processing of serine: pyruvate aminotransferase precursor by rat liver mitochondria in vitro and in vivo

Processing and uptake of the precursor of serine: pyruvate aminotransferase [EC 2.6.1.51] by mitochondria were studied in vitro and in vivo. Serine: pyruvate aminotransferase was synthesized mainly on free ribosomes as judged by immunoprecipitation of puromycin-labeled nascent peptides prepared from free and bound ribosomes. The precursor of rat liver serine:pyruvate aminotransferase (pSPT) synthesized in vitro was post-translationally processed to an apparently mature form by isolated rat liver mitochondria. Available evidence indicated that the processed product was localized in the matrix of mitochondria. Mature serine:pyruvate aminotransferase did not inhibit the in vitro processing, suggesting that the extra peptide was necessary for the mitochondrial uptake of the precursor. In the livers of rats fed a vitamin B6-deficient high-protein diet, the induction by glucagon of serine:pyruvate aminotransferase occurred and most of the induced enzyme existed in mitochondria as the apo-form, suggesting that pSPT was taken up by mitochondria and processed in the apo-form under the conditions employed. In the in vitro system, on the other hand, the processing of pSPT proceeded both in the absence and presence of pyridoxal 5'-phosphate. Should the precursor also bind the prosthetic molecule, therefore, it would be transported into mitochondria in both the apo- and holo-forms. When isolated rat hepatocytes were labeled with [35S]methionine, labeled pSPT appeared in the cytosolic fraction and was transported rapidly into mitochondria in association with the processing. This uptake and processing were inhibited by a fluorescent laser dye, rhodamine 123, and the precursor accumulated in the cytosol in the presence of the dye.     

Evidence for participation of the inner membrane in the import of sulfite oxidase into the intermembrane space of liver mitochondria

Sulfite oxidase, a soluble enzyme in mitochondrial intermembrane space, was synthesized as a precursor protein larger than the authentic enzyme when rat liver RNA was translated $\text{in}\text{vitro}$ using reticulocyte lysate. When the $\text{in}\text{vitro}$ translation products were incubated with isolated rat liver mitochondria, the precursor of sulfite oxidase was converted to the size of the mature enzyme. The $\text{in}\text{vitro}$ processed mature enzyme was no longer susceptible to externally added proteases and was extractable by a hypotonic treatment of the mitochondria, suggesting its location in the intermembrane space. When mitochondria were subfractionated, most of the processing activity was recovered in the mitoplast fraction. The import-processing activity of mitochondria was inhibited by CCCP, oligomycin, or atractyloside in the presence of KCN. These results suggest that the import of sulfite oxidase into mitochondrial intermembrane space requires the participation of inner membrane.     

The cytosolic factor required for import of precursors of mitochondrial proteins into mitochondria

The mechanism of import of proteins into mitochondria was studied by using the peptide of the presequence of ornithine aminotransferase (the extrapeptide), which was chemically synthesized and is composed of 34 amino acids. When the extrapeptide was incubated with isolated mitochondria in the presence of a rabbit reticulocyte lysate at 25 degrees C, it was imported into the mitochondrial matrix, and the import depended on the inner membrane potential, but not added ATP. The import of several precursors of mitochondrial proteins was competitively inhibited by the presence of excess extrapeptide in the reaction system, indicating that the extrapeptide and mitochondrial proteins were imported by the same machinery. Import of the extrapeptide was significantly stimulated by addition of a rabbit reticulocyte lysate, and a component of the lysate (the cytosolic factor) stimulating import of the extrapeptide was purified about 20,000 times by successive column chromatography on DEAE-cellulose and aminopentyl-Sepharose 4B. The binding of the extrapeptide to liposomes composed of egg lecithin and partially purified receptor of the precursor of mitochondrial protein (Ono, H., and Tuboi, S., (1985) Biochem. Int. 10, 351-357) required the cytosolic factor when the concentration of the peptide was less than 1.5 X 10(-8) M, suggesting that the physiological binding of the precursors of mitochondrial proteins to the receptor is dependent on the cytosolic factor. The extrapeptide and the cytosolic factor were shown to form a complex. From these results, the mechanism of binding of the extrapeptide to the receptor of the mitochondrial outer membrane is suggested to be as follows: the peptide (the precursor of mitochondrial protein) and the cytosolic factor form a complex, and then the complex is recognized by and bound to the receptor.     

Role for the mitochondrial inner membrane in the maturation of the precursor to ornithine carbamyl transferase

The precursor to ornithine carbamyl transferase (pOCT) is cleaved at two N-terminal sites when imported into intact mitochondria but only at the N-proximal site when incubated with a membrane-free mitochondrial lysate or matrix fraction. Disruption of the mitochondrial membrane system by sonication, freeze-thaw, or lysis with non-ionic detergents blocks the processing of pOCT to its mature form. Mitoplasts prepared from protease-inactivated, import-incompetent mitochondria recover full processing activity; disruption of the inner membrane impairs the maturation process i.e. causes the loss of the mitoplasts' ability to transform pOCT into OCT. The data reveal a dependency of a maturation event on a "specific" interaction between a precursor protein and the mitochondrial inner membrane probably to position and/or to expose the correct N-distal cleavage site of the presequence.