Peptide 68-88 of apocytochrome c plays a crucial role in its insertion into membrane and binding to mitochondria

Apocytochrome c (Apocyt. C) is the precursor of cytochrome c. It is synthesized in the cytosol and posttranslationally imported into mitochondria. In order to determine the crucial sequence in apocyt. Ctranslocation, deleted mutant and chemically synthesized peptides with different length were used. Obtained results showed that sequence 68-88 of apocyt. C plays a critical role in its insertion into membrane and binding to mitochondria.     

Peptide 68–88 of apocytochrome c plays a crucial role in its insertion into membrane and binding to mitochondria

Apocytochrome c (Apocyt. c) is the precursor of cytochrome c. It is synthesized in the cytosol and posttranslationally imported into mitochondria. In order to determine the crucial sequence in apocyt. c translocation, deleted mutant and chemically synthesized peptides with different length were used. Obtained results showed that sequence 68–88 of apocyt. c plays a critical role in its insertion into membrane and binding to mitochondria.     

Radioimmunoassay for testicular cytochrome c (ct). Evidence for the presence of apocytochrome ct pool in rat testis extract

Mammalian testis contains a tissue-specific testicular cytochrome c (cyt ct). By immunizing rabbits with rat cyt ct and phosphorylated albumin (pBSA), rabbit anti-cyt ct was produced. Then the antiserum was applied to phosphorylated bovine serum albumin and rat somatic cyt c (cs)-Sepharose affinity columns to remove cross-reacting antibodies. The resultant anti-cyt ct was highly specific for cyt ct. From immunoblot assays, no protein other than cyt ct in rat testis extract was bound by the anti-cyt ct. By using the anti-cyt ct, radioimmunoassay (RIA) was developed for the quantitation of cyt ct in rat testis extract. The observation that the RIA did not bind rat cyt cs (1-1000 pmol), and other rat tissue extracts (kidney, heart, lung) further indicated that the RIA was highly specific for rat cyt ct. Separately, the concentration of holocyt ct was determined using CM-cellulose chromatography and subsequent spectral analysis on the same testis extract. The total cyt ct concentration in the rat testis extract determined by the RIA was about 3-fold higher than those determined by the latter techniques. Since the affinity purified anti-horse cyt c cross-reacted with both horse holo- and apocyt c, anti-rat cyt ct will cross-react with rat apocyt ct. Thus the concentration of cyt ct quantitated by the polyclonal anti-cyt ct-based RIA probably included apocyt ct concentration as well. Therefore, the higher cyt ct concentration determined by the RIA was probably attributed to the presence of the apocyt ct in the testis extract. The presence of the high concentration of the apocyt ct pool in testis is probably necessary to maintain continuous spermatogenesis, during which holocyt ct is incorporated into sperm mitochondria.     

Structure and dynamics of lipid-associated states of apocytochrome c.

Apocytochrome c (apocyt c), which in aqueous solution is largely unstructured, acquires an alpha-helical conformation upon association with lipid membranes. The extent of alpha-helix induced in apocyt c is lipid-dependent and this folding process is driven by both electrostatic and hydrophobic lipid-protein interactions. The structural and dynamic properties of apocyt c in lipid membranes were investigated by attenuated total reflection Fourier transform infrared spectroscopy combined with amide H-D exchange kinetics. Apocyt c acquires a higher content of alpha-helical structure with negatively charged membranes than with zwitterionic ones. For all membranes studied here, the helices of these partially folded states of apocyt c have a preferential orientation perpendicular to the plane of the lipid membrane. The H-D exchange revealed that a small fraction of amide protons of apocyt c, possibly associated with a stable folded domain protected by the lipid, remained protected from exchange over 20 min. However, a large fraction of amide protons exchanged in less than 20 min, indicating that the helical states of apocyt c in lipid membranes are very dynamic.     

Role of cytochrome c heme lyase in mitochondrial import and accumulation of cytochrome c in Saccharomyces cerevisiae.

Heme is covalently attached to cytochrome c by the enzyme cytochrome c heme lyase. To test whether heme attachment is required for import of cytochrome c into mitochondria in vivo, antibodies to cytochrome c have been used to assay the distributions of apo- and holocytochromes c in the cytoplasm and mitochondria from various strains of the yeast Saccharomyces cerevisiae. Strains lacking heme lyase accumulate apocytochrome c in the cytoplasm. Similar cytoplasmic accumulation is observed for an altered apocytochrome c in which serine residues were substituted for the two cysteine residues that normally serve as sites of heme attachment, even in the presence of normal levels of heme lyase. However, detectable amounts of this altered apocytochrome c are also found inside mitochondria. The level of internalized altered apocytochrome c is decreased in a strain that completely lacks heme lyase and is greatly increased in a strain that overexpresses heme lyase. Antibodies recognizing heme lyase were used to demonstrate that the enzyme is found on the outer surface of the inner mitochondrial membrane and is not enriched at sites of contact between the inner and outer mitochondrial membranes. These results suggest that apocytochrome c is transported across the outer mitochondrial membrane by a freely reversible process, binds to heme lyase in the intermembrane space, and is then trapped inside mitochondria by an irreversible conversion to holocytochrome c accompanied by folding to the native conformation. Altered apocytochrome c lacking the ability to have heme covalently attached accumulates in mitochondria only to the extent that it remains bound to heme lyase.     

Forced Unfolding of Apocytochrome <Emphasis Type="Italic">b</Emphasis><Subscript>5</Subscript> by Steered Molecular Dynamics Simulation

Apocytochrome b5 (apocyt b5), a small b-type cytochrome with heme prosthetic group removal, has been subjected to steered molecular dynamics (SMD) simulations for investigating the consequences of mechanical force-induced unfolding. Both constant velocity (0.5 and 1.0 A/ps) and constant force (500, 750 and 1000 pN) stretching have been employed to model forced unfolding of apocyt b5. The results of SMD simulations elucidate that apocyt b5 is protected against external stress mainly through the interstrand hydrogen bonding between its beta1-beta2 and beta2-beta3 strands, highlighting the importance of hydrophobic core 2 in stabilization of apocyt b5. The existence of intermediate states manifested by current simulations in the forced unfolding pathway of apocyt b5 is different from the observations in pervious thermal or chemical unfolding studies in the absence of force. The present study could thus provide insights into the relationship between the two cooperative functional modules of apocyt b5 and also guide the rational molecular design of heme proteins.     

The biosynthesis of membrane and soluble plastidic c-type cytochromes of Chlamydomonas reinhardtii is dependent on multiple common gene products.

Cytochrome c6 functions in the thylakoid lumen to catalyze electron transfer from reduced cytochrome f of the cytochrome b6f complex to P700+ of photosystem I. The biogenesis of mature cyt c6 from cytosolically translated pre-apocytochrome c6 involves numerous post-translational modifications including the proteolytic removal of a transit sequence and the covalent attachment of heme to two cysteinyl thiols on the apoprotein. Here, we report on the characterization of a previously unrecognized class of non-allelic mutants of Chlamydomonas reinhardtii that are blocked at the conversion of apocyt c6 to holocyt c6. The mutants are acetate requiring since they are also deficient in cyt f, cyt b and the Rieske FeS protein. Pulse-chase studies indicate that heme attachment is not required for the two-step processing of pre-apocytochrome c6 to apocyt c6, but is required for the stability of the mature protein. This is in contrast to the biosynthesis of mitochondrial cyt c1 where heme attachment is required for the second processing step. We propose that the assembly of both holocytochrome c6 and the cytochrome b6f complex are dependent on common gene products, possibly those involved in heme delivery or metabolism. This is the first suggestion that multiple loci are involved in the biosynthesis of both plastidic c-type cytochromes.     

Different transport pathways of individual precursor proteins in mitochondria

Transport of mitochondrial precursor proteins into mitochondria of Neurospora crassa was studied in a cell-free reconstituted system. Precursors were synthesized in a reticulocyte lysate programmed with Neurospora mRNA and transported into isolated mitochondria in the absence of protein synthesis. Uptake of the following precursors was investigated: apocytochrome c, ADP/ATP carrier and subunit 9 of the oligomycin-sensitive ATPase. Addition of high concentrations of unlabelled chemically prepared apocytochrome c (1-10 microM) inhibited the appearance in the mitochondrial of labelled cytochrome c synthesized in vitro because the unlabelled protein dilutes the labelled one and because the translocation system has a limited capacity [apparent V is 1-3 pmol X min-1 X (mg mitochondrial protein)-1]. Concentrations of added apocytochrome c exceeding the concentrations of precursor proteins synthesized in vitro by a factor of about 10(4) did not inhibit the transfer of ADP/ATP carrier or ATPase subunit 9 into mitochondria. Carbonylcyanide m-chlorophenylhydrazone, an uncoupler of oxidate phosphorylation, inhibited transfer in vitro of ADP/ATP carrier and of ATPase subunit 9, but not of cytochrome c. These findings suggest that cytochrome c and the other two proteins have different import pathways into mitochondria. It can be inferred from the data presented that different 'receptors' on the mitochondria. It can be inferred from the data presented that different 'receptors' on the mitochondrial surface mediate the specific recognition of precursor proteins by mitochondria by mitochondria as a first step in the transport process.     

Biogenesis of cytochrome c in Neurospora crassa. Synthesis of apocytochrome c, transfer to mitochondria and conversion to Holocytochrome c.

1. Precipitating antibodies specific for apocytochrome c and holocytochrome c, respectively, were employed to study synthesis and intracellular transport of cytochrome c in Neurospora in vitro. 2. Apocytochrome c as well as holocytochrome c were found to be synthesized in a cell-free homogenate. A precursor product relationship between the two components is suggested by kinetic experiments. 3. Apocytochrome c synthesized in vitro was found in the post-ribosomal fraction and not in the mitochondrial fraction, whereas holocytochrome c synthesized in vitro was mainly detected in the mitochondrial fraction. A precursor product relationship between postribosomal apocytochrome c and mitochondrial holocytochrome c is indicated by the labelling data. In the microsomal fraction both apocytochrome c and holocytochrome c were found in low amounts. Their labeling kinetics do not subbest a precursor role of microsomal apocytochrome c or holocytochrome c. 4. Formation of holocytochrome c from apocytochrome c was observed when postribosomal supernatant containing apocytochrome c synthesized in vitro was incubated with isolated mitochondria, but not when incubated in the absence of mitochondria. The cytochrome c formed under these conditions was detected in the mitochondria. 5. Conversion of labelled apocytochrome c synthesized in vitro to holocytochrome c during incubation of a postribosomal supernatant with isolated mitochondria was inhibited when excess isolated apocytochrome c, but not when holocytochrome c was added. 6. The data presented are interpreted to show that apocytochrome c is synthesized on cytoplasmic ribosomes and released into the supernatant. It is suggested that apocytochrome c migrates to the inner mitochondrial membrane, where the heme group is covalently linked to the apoprotein. The hypothesis is put forward that the concomitant change in conformation leads to trapping of holocytochrome c in the membrane. The problems of permeability of the outer mitochondrial membrane to apocytochrome c and the site and nature of the reaction by which the heme group is linked to the apoprotein are discussed.     

Coupling of heme attachment to import of cytochrome c into yeast mitochondria. Studies with heme lyase-deficient mitochondria and altered apocytochromes c

Cytochrome c is synthesized in the cytoplasm as apocytochrome c, lacking heme, and then imported into mitochondria. The relationship between attachment of heme to the apoprotein and its import into mitochondria was examined using an in vitro system. Apocytochrome c transcribed and translated in vitro could be imported with high efficiency into mitochondria isolated from normal yeast strains. However, no import of apocytochrome c occurred with mitochondria isolated from cyc3- strains, which lack cytochrome c heme lyase, the enzyme catalyzing covalent attachment of heme to apocytochrome c. In addition, amino acid substitutions in apocytochrome c at either of the 2 cysteine residues that are the sites of the thioether linkages to heme, or at an immediately adjacent histidine that serves as a ligand of the heme iron, resulted in a substantial reduction in the ability of the precursor to be translocated into mitochondria. Replacement of the methionine serving as the other iron ligand, on the other hand, had no detectable effect on import of apocytochrome c in this system. Thus, covalent heme attachment is a required step for import of cytochrome c into mitochondria. Heme attachment, however, can occur in the absence of mitochondrial import since we have detected CYC3-encoded heme lyase activity in solubilized yeast extracts and in an Escherichia coli expression system. These results suggest that protein folding triggered by heme attachment to apocytochrome c is required for import into mitochondria.     

Isolation, subunit composition, and site of synthesis of human cytochrome c oxidase

Cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1), the terminal oxidase of the respiratory chain in eucaryotic cells, has been purified from human placenta mitochondria. Seven polypeptides have been identified reproducibly by high-resolution electrophoresis of the enzyme complex through sodium dodecyl sulfate (Na-DodSO4)--urea polyacrylamide gels; these correspond closely in size to the subunits of beef heart cytochrome c oxidase. When HeLa cells, grown in suspension culture, were pulse-labeled with [35S]methionine in the presence of cycloheximide to inhibit cytoplasmic protein synthesis and chased with an excess of unlabeled methionine in the absence of the drug, the mitochondrially synthesized polypeptides were resolved into at least 17 components by NaDodSO4--urea polyacrylamide gel electrophoresis. After labeled HeLa mitochondria were mixed with human placenta mitochondria and the cytochrome c oxidase was isolated, three of the labeled components were found to copurify with the three largest subunits of the complex. We conclude that human cytochrome c oxidase contains seven subunits, the three largest of which are synthesized on mitochondrial ribosomes, while the other four are synthesized in the cytoplasm.     

蛋白质跨线粒体膜运送的研究进展

线粒体拥有约1000种蛋白质,其中98％以上系由细胞核编码,在细胞质核糖体上以前体形式合成,之后再运至线粒体,经跨膜运送并分选定位于各部分。现对定位于外膜、基质和内膜的蛋白质的运送途径的研究进展作一扼要介绍。脱血红素细胞色素c是细胞色素c的前体,它不含导肽,对其转运的研究概况也作了评述。     

Kinetic studies on the transport of cytoplasmically synthesized proteins into the mitochondria in intact cells of Neurospora crassa.

The transport of cytoplasmically synthesized mitochondrial proteins was investigated in whole cells of Neurospora crassa, using dual labelling and immunological techniques. In pulse and pulse-chase labelling experiments the mitochondrial proteins accumulate label. The appearance of label in mitochondrial protein shows a lag relative to total cellular protein, ribosomal, microsomal and cytosolic proteins. The delayed appearance of label was also found in immunoprecipitated mitochondrial matrix proteins, mitochondrial ribosomal proteins, mitochondrial carboxyatractyloside-binding protein and cytochrome c. Individual mitochondrial proteins exhibit different labelling kinetics. Cycloheximide inhibition of translation does not prevent import of proteins into the mitochondria. Mitochondrial matrix proteins labelled in pulse and pulse-chase experiments can first be detected in the cytosol fraction and subsequently in the mitochondria. The cytosol matrix proteins and those in the mitochondria show a precursor-product type relationship. The results suggest that newly synthesized mitochondrial proteins exist in an extra-mitochondrial pool from which they are imported into the 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.     

An extremely acidic amino-terminal presequence of the precursor for the human mitochondrial hinge protein

Mitochondrial hinge protein is a subunit of ubiquinol-cytochrome-c reductase in the respiratory chain and 'hinges' cytochrome c with cytochrome c1. The protein is encoded in the nuclear genome, synthesized in the cytosol and then imported into the mitochondria. The cDNA of the human hinge protein has been cloned and its nucleotide sequence was determined. The deduced primary structure of the amino-terminal presequence consists of 13 amino acid residues, of which 4 amino acids are acidic and only one is basic. Since the presequences of most other precursors are rich in basic amino acids, this sequence is unique for targeting mitochondria. Expression of the gene was repressed in the presence of a phorbol ester in human promyelocyticleukemia cells (HL-60), and this repression was greater than that of the ADP/ATP translocator. These findings suggest that the hinge protein, the expression of which is well regulated, is imported into mitochondria via a specific pathway.     

Transport of cytoplasmically synthesized proteins into the mitochondria in a cell free system from Neurospora crassa.

Synthesis and transport of mitochondrial proteins were followed in a cell-free homogenate of Neurospora crassa in which mitochondrial translation was inhibited. Proteins synthesized on cytoplasmic ribosomes are transferred into the mitochondrial fraction. The relative amounts of proteins which are transferred in vitro are comparable to those transferred in whole cells. Cycloheximide and puromycin inhibit the synthesis of mitochondrial proteins but not their transfer into mitochondria. The transfer of immunoprecipitable mitochondrial proteins was demonstrated for matrix proteins, carboxyatractyloside-binding protein and cytochrome c. Import of proteins into mitochondria exhibits a degree of specificity. The transport mechanism differentiates between newly synthesized proteins and preexistent mitochondrial proteins, at least in the case of matrix proteins. In the cell-free homogenate membrane-bound ribosomes are more active in the synthesis of mitochondrial proteins than are free ribosomes. The finished translation products appear to be released from the membrane-bound ribosomes into the cytosol rather than into the membrane vesicles. The results suggest that the transport of cytoplasmically synthesized mitochondrial proteins is essentially independent of cytoplasmic translation; that cytoplasmically synthesized mitochondrial proteins exist in an extramitochondrial pool prior to import; that the site of this pool is the cytosol for at least some of the mitochondrial proteins; and that the precursors in the extramitochondrial pool differ in structure or conformation from the functional proteins in the mitochondria.     

蛋白质跨线粒体膜的运送

线粒体约含１０００种左右蛋白质,其中９８％以上系由细胞核编码,在细胞质核酸体上以前体形式合成之后再运至线粒体并选分定位于各部分,现对定位于基持和内膜的蛋白质的运送途径研究的新进展作一扼要介绍,脱血红素细胞色素ｃ是细胞色素ｃ的前体,它既不含导肽,在线粒体外膜迄今也未发现共受体,对其转运的研究概况也作了评述。     

The disulfide relay system of mitochondria is connected to the respiratory chain

All proteins of the intermembrane space of mitochondria are encoded by nuclear genes and synthesized in the cytosol. Many of these proteins lack presequences but are imported into mitochondria in an oxidation-driven process that relies on the activity of Mia40 and Erv1. Both factors form a disulfide relay system in which Mia40 functions as a receptor that transiently interacts with incoming polypeptides via disulfide bonds. Erv1 is a sulfhydryl oxidase that oxidizes and activates Mia40, but it has remained unclear how Erv1 itself is oxidized. Here, we show that Erv1 passes its electrons on to molecular oxygen via interaction with cytochrome c and cytochrome c oxidase. This connection to the respiratory chain increases the efficient oxidation of the relay system in mitochondria and prevents the formation of toxic hydrogen peroxide. Thus, analogous to the system in the bacterial periplasm, the disulfide relay in the intermembrane space is connected to the electron transport chain of the inner membrane.     

Biosynthesis of cytochrome c oxidase by isolated rat liver mitochondria.

When isolated mitochondria which have been labeled with [3H]leucine are solubilized and treated with anti-serum specific for cytochrome c oxidase, labeled polypeptides which correspond to the three largest polypeptides of this enzyme are immunoprecipitated. This indicates that the three largest polypeptides of cytochrome c oxidase which have Mr of 66,000, 39,000, and 23,000 are synthesized by isolated mitochondria whereas the three smallest ones which have Mr of 14,000, 12,500, and 10,000 are not. The smallest polypeptides are probably synthesized on cytoplasmic ribosomes as has been demonstrated in other systems by in vivo studies. These results are the first demonstration that isolated mammalian mitochondria are capable of synthesizing some of their own polypeptide components. The antiserum used in this study was prepared to highly purified cytochrome c oxidase (12.4 nmol of heme a + a3/mg of protein) from rat liver mitochondria. This antiserum gives a single precipitin line when tested by the Ouchterlony double diffusion technique. Its specificity has been demonstrated by the fact that it: 1) only precipitates heme a + a3, not hemes b, c, or c1, when added to solubilized mitochondria, 2) inhibits cytochrome c oxidase activity at least 85%, and 3) precipitates only those polypeptides found in purified cytochrome c oxidase when added to solubilized mitochondria labeled in vivo.     

A retention mechanism for distribution of mitochondria during cell division in budding yeast.

Mitochondria are indispensable for normal eukaryotic cell function. As they cannot be synthesized de novo and are self-replicating, mitochondria must be transferred from mother to daughter cells. Studies in the budding yeast Saccharomyces cerevisiae indicate that mitochondria enter the bud immediately after bud emergence, interact with the actin cytoskeleton for linear, polarized movement of mitochondria from mother to bud, but are equally distributed among mother and daughter cells [1] [2] [3]. It is not clear how the mother cell maintains its own supply of mitochondria. Here, we found that mother cells retain mitochondria by immobilization of some mitochondria in the 'retention zone', the base of the mother cell distal to the bud. Retention requires the actin cytoskeleton as mitochondria colocalized with actin cables in the retention zone, and mutations that perturb actin dynamics or actin-mitochondrial interactions produced retention defects. Our results support the model that equal distribution of mitochondria during cell division is a consequence of two actin-dependent processes: movement of some mitochondria into the daughter bud and immobilization of others in the mother cell.