Identification and characterization of the mitochondrial targeting sequence and mechanism in human citrate synthase

Citrate synthase (CS), the first and rate‐limiting enzyme of the tricarboxylic acid (TCA) cycle, plays a decisive role in regulating energy generation of mitochondrial respiration. Most mitochondrial proteins are synthesized in the cytoplasm as preproteins with an amino (N)‐terminal mitochondrial targeting sequence (MTS) that directs mitochondria‐specific sorting of the preprotein. However, the MTS and targeting mechanism of the human CS protein are not fully characterized. The human CS gene is a single nuclear gene which transcribes into two mRNA variants, isoform a (CSa) and b (CSb), by alternative splicing of exon 2. CSa encodes 466 amino acids, including a putative N‐terminal MTS, while CSb expresses 400 residues with a shorter N terminus, lacking the MTS. Our results indicated that CSa is localized in the mitochondria and the N‐terminal 27 amino acids, including a well‐conserved RXY ↓ (S/A) motif (the RHAS sequence), can efficiently target the enhanced green fluorescent protein (EGFP) into the mitochondria. Furthermore, site‐directed mutagenesis analysis of the conserved basic amino acids and serine/threonine residues revealed that the R9 residue is essential but all serine/threonine residues are dispensable in the mitochondrial targeting function. Moreover, RNA interference (RNAi)‐mediated gene silencing of the preprotein import receptors, including TOM20, TOM22, and TOM70, showed that all three preprotein import receptors are required for transporting CSa into the mitochondria. In conclusion, we have experimentally identified the mitochondrial targeting sequence of human CSa and elucidated its targeting mechanism. These results provide an important basis for the study of mitochondrial dysfunction due to aberrant CSa trafficking. J. Cell. Biochem. 107: 1002–1015, 2009. © 2009 Wiley‐Liss, Inc.     

Expression pattern of a nuclear encoded mitochondrial arginine-ornithine translocator gene from Arabidopsis

Background  

Arginine and citrulline serve as nitrogen storage forms, but are also involved in biosynthetic and catabolic pathways. Metabolism of arginine, citrulline and ornithine is distributed between mitochondria and cytosol. For the shuttle of intermediates between cytosol and mitochondria transporters present on the inner mitochondrial membrane are required. Yeast contains a mitochondrial translocator for ornithine and arginine, Ort1p/Arg11p. Ort1p/Arg11p is a member of the mitochondrial carrier family (MCF) essential for ornithine export from mitochondria. The yeast arg11 mutant, which is deficient in Ort1p/Arg11p grows poorly on media lacking arginine.     

A Highlights from MBoC Selection: More than just a ticket canceller: the mitochondrial processing peptidase tailors complex precursor proteins at internal cleavage sites

Most mitochondrial proteins are synthesized as precursors that carry N-terminal presequences. After they are imported into mitochondria, these targeting signals are cleaved off by the mitochondrial processing peptidase (MPP). Using the mitochondrial tandem protein Arg5,6 as a model substrate, we demonstrate that MPP has an additional role in preprotein maturation, beyond the removal of presequences. Arg5,6 is synthesized as a polyprotein precursor that is imported into mitochondria and subsequently separated into two distinct enzymes. This internal processing is performed by MPP, which cleaves the Arg5,6 precursor at its N-terminus and at an internal site. The peculiar organization of Arg5,6 is conserved across fungi and reflects the polycistronic arginine operon in prokaryotes. MPP cleavage sites are also present in other mitochondrial fusion proteins from fungi, plants, and animals. Hence, besides its role as a “ticket canceller” for removal of presequences, MPP exhibits a second conserved activity as an internal processing peptidase for complex mitochondrial precursor proteins.     

A basic residue at position 36p of the propeptide is not essential for the correct folding and subsequent autocatalytic activation of prochymosin.

Position 36p in the propeptides of gastric aspartic proteinases is generally occupied by lysine or arginine. This has led to the conclusion that a basic residue at this position, which interacts with the active-site aspartates, is essential for folding and activation of the zymogen. Lamb prochymosin has been shown by cDNA cloning to possess glutamic acid at 36p. To investigate the effect of this natural mutation which appears to contradict the proposed role of this residue, calf and lamb prochymosins and their two reciprocal mutants, K36pE and E36pK, respectively, were expressed in Escherichia coli, refolded in vitro, and autoactivated at pH 2 and 4.7. All four zymogens could be activated to active chymosin and, at both pH values, the two proteins with Glu36p showed higher activation rates than the two Lys36p forms. Glu36p was also demonstrated in natural prochymosin isolated from the fourth stomach of lamb, as well as being encoded in the genomes of sheep, goat and mouflon, which belong to the subfamily Caprinae. A conserved basic residue at position 36p of prochymosin is thus not obligatory for its folding or autocatalytic activation. The apparently contradictory results for porcine pepsinogen A [Richter, C., Tanaka, T., Koseki, T. & Yada, R.Y. (1999) Eur. J. Biochem. 261, 746-752] can be reconciled with those for prochymosin. Lys/Arg36p is involved in stabilizing the propeptide-enzyme interaction, along with residues nearer the N-terminus of the propeptide, the sequence of which varies between species. The relative contribution of residue 36p to stability differs between pepsinogen and prochymosin, being larger in the former.     

Evidence against the incorporation into protein of amino acids directly from the membrane transport system in rat heart

The possibility suggested recently [Hider, R.C., Fern, E.B. and London, D.R. (1969) Biochem. J. 114, 171-178; Hider, R.C., Fern, E.B. and London, D.R. (1971) Biochem. J. 121, 817-827; van Venrooij, W.J., Poort, C., Kramer, M.F. and Jansen, M.T. (1972) Eur. J. Biochem. 30, 427-433; and Adamson, L.F., Herington, A.C. and Bornstein, J. (1972) Biochim. Biophys. Acta 282, 352-365] that protein synthesis takes place using amino acids directly from the membrane transport system and not from an intracellular pool has been investigated in rat heart. The tissue was perfused first for 30 min with either [14C]glycine or [14C]leucine and then for a further 30 min with identical medium containing [3H]glycine or [3H]leucine, respectively. After an initial lag, [14C]glycine was incorporated into protein at a linear rate up to 60 min. The [3H]glycine was accumulated into tissue water and incorporated just as readily as the [14C]glycine had been. The rate of total protein synthesis agrees with literature values only if intracellular and not extracellular specific activity values are used in the calculation. Some glycine was converted to serine or threonine. Leucine influx and efflux were very rapid in contrast to the relatively slow exchange reported for incubated tissues [Hider, R.C., Fern, E.B. and London, D.R. (1969) Biochem. J. 114, 171-178; Hider, R.C., Fern, E.B. and London, D.R. (1971) Biochem. J. 121, 817-827; van Venrooij, W.J., Poort, C., Kramer, M.F. and Jansen, M.T. (1972) Eur. J. Biochem. 30, 427-433]. The results are consistent with the existence of an intracellular precursor pool for glycine. Some possible reasons for the discrepancies between this and the other studies are discussed.     

Use of the addressing sequence of yeast D-lactate dehydrogenase for insertion of CYP11A1p into the inner membrane of yeast mitochondria

Mammalian cytochrome P450scc (CYP11A1p) is a pseudointegral protein of the inner membrane of mitochondria with the active center exposed in the matrix. Upon import of the CYP11A1p precursor into yeast mitochondria, only a minor part was incorporated into the inner mitochondrial membrane and acquired catalytic activity (Kovaleva, I. E., Novikova, L. A., Nazarov, P. A., Grivennikov, S. I., and Luzikov, V. N. (2003) Eur. J. Biochem., 270, 222-229). The present work is an attempt to increase the efficiency of this process by substitution of the inherent N-terminal presequence of CYP11A1p by the addressing signal of D-lactate dehydrogenase (D-LD) of the yeast Saccharomyces cerevisiae. D-LD is known to be inserted into the inner membrane of mitochondria through its transmembrane domain located close to the N-terminus of the polypeptide chain in such a way that the protein globule is exposed in the intermembrane space. The hybrid protein D-LD(1-72)-mCYP11A1p synthesized in yeast cells was imported into yeast mitochondria, underwent processing, and was inserted into the inner membrane on the side of the intermembrane space. In the presence of adrenodoxin and adrenodoxin reductase, the hybrid protein exhibited cholesterol side-chain cleavage activity. Thus, CYP11A1p insertion into the inner membrane of mitochondria mediated by the D-LD topogenic signal resulted in the catalytically active mCYP11A1p domain in the hybrid protein.     

A chromatin-associated protein from pea seeds preferentially binds histones H3 and H4.

Pisum sativum p16 is a protein present in the chromatin of ungerminated embryonic axes. The purification of p16 and the isolation of a cDNA clone of psp54, the gene encoding its precursor have been recently reported [Castillo, J., Rodrigo, M. I., Márquez, J. A., Zú?iga, A and Franco, L. (2000) Eur. J. Biochem.267, 2156-2165]. In the present paper, we present data showing that p16 is a nuclear protein. First, after subcellular fractionation, p16 was clearly found in nuclei, although the protein is also present in other organelles. Immunocytochemical methods also confirm the above results. p16 seems to be firmly anchored to chromatin, as only extensive DNase I digestion of nuclei allows its release. Far Western and pull-down experiments demonstrate a strong in vitro interaction between p16 and histones, especially H3 and H4, suggesting that p16 is tethered to chromatin through histones. Because the psp54 gene is specifically expressed during the late development of seed, the role of p16 might be related to the changes that occur in chromatin during the processes of seed maturation and germination.     

Altered sensitivity of eukaryotic elongation factor 2 for trypsin after phosphorylation and ribosomal binding

We have used variations in the trypsin sensitivity of eukaryotic protein synthesis elongation factor 2 (eEF-2) to probe for structural alterations induced by phosphorylation, ribosomal binding, or guanosine nucleotides. We could not detect any nucleotide-related effect on the tryptic cleavage rate of Arg66. However, eEF-2 was protected from trypsin after ribosomal binding. Also, phosphorylation of eEF-2 led to a protection of Arg66. This indicates that phosphorylation leads to a structural rearrangement that could explain the reduced affinity of the phosphorylated factor for ribosomes (Carlberg, U., Nilsson, A., and Nyg?rd, O. (1990) Eur. J. Biochem. 191, 639-645). Cleavage of Arg66 led to a complete loss of the ability of the factor to be phosphorylated. Furthermore, ribosome-bound eEF-2 was found to be inaccessible for phosphorylation. Based on these findings and previously published data, we suggest that the region around the sites of phosphorylation and trypsin cleavage is vitally important for the factor function and ribosomal binding.     

Multiple relationships between rate of oxidative phosphorylation and delta microH in rat liver mitochondria

The relationship between rate of ATP synthesis and transmembrane electrochemical proton gradient has been determined in rat liver mitochondria oxidizing succinate, using the respiratory inhibitor malonate or the uncoupler FCCP to decrease delta microH progressively. As previously reported [(1982) Eur. J. Biochem. 126, 443-451] two different relationships are obtained depending on the method used. Evidence is presented that this result is not due to underestimation of the delta microH maintained by fast-respiring mitochondria, as recently suggested [(1985) FEBS Lett. 181, 323-327].     

L-lactate 2-monooxygenase from Mycobacterium smegmatis. Cloning, nucleotide sequence, and primary structure homology within an enzyme family

L-Lactate 2-monooxygenase catalyzes the oxidation of L-lactate to acetate and carbon dioxide. The catalytic mechanism has been extensively investigated but very little is known about which amino acid residues may play a role in catalysis. As a first step toward this goal, the gene for this protein from Mycobacterium smegmatis has been cloned and sequenced. Peptide sequencing data for L-lactate 2-monooxygenase was used to construct three sets of fully redundant tetradecamer oligonucleotide probes, which were hybridized to restriction-digested M. smegmatis DNA. An approximately 3-kilobase pair PstI fragment hybridized with two of the probes. This region was subsequently isolated and cloned into Escherichia coli. From this size-fractionated gene bank, a 3.1-kilobase pair genomic DNA fragment was isolated by colony hybridization to two of the oligonucleotide probes. The complete gene for L-lactate 2-monooxygenase was contained on this fragment as shown by DNA sequencing of the whole insert. The DNA sequence codes for a mature protein that is 393 amino acids in length with a subunit molecular weight of 43,072 (including the FMN). The protein sequence shows impressive homology with the primary structures of two mechanistically related proteins, yeast flavocytochrome b2 (Lederer, F., Cortial, S., Becam, A.-M., Haumont, P.-Y., and Perez, L. (1985) Eur. J. Biochem. 152, 419-428; Guiard, B. (1985) EMBO J. 4, 3265-3272) and spinach glycolate oxidase (Volkita, M., and Somerville, C. R. (1987) J. Biol. Chem. 262, 15825-15828; Cederlund, E., Lindqvist, Y., Soderlund, G., Br?ndén, C.-I., and Jornvall, H. (1988) Eur. J. Biochem. 173, 523-530). For each residue proposed from the crystal structure of glycolate oxidase to be involved in catalysis (Lindqvist, Y., and Br?ndén, C.-I. (1989) J. Biol. Chem. 264, 3624-3628), an identical residue was found in a homologous position in lactate oxidase. Furthermore, most of these residues occur in regions whose sequences are highly conserved between lactate oxidase, flavocytochrome b2, and glycolate oxidase.     

Arginine biosynthesis in Neisseria gonorrhoeae: enzymes catalyzing the formation of ornithine and citrulline.

Many of the Neisseria gonorrhoeae strains isolated from patients require arginine for growth in a defined medium. As a basis for genetic studies of these Arg- strains, we examined two biosynthetic enzymes of Arg+ (nonrequiring) gonococci. Cell-free extracts contained (i) glutamate acetyltransferase, which catalyzes the formation of L-ornithine from alpha-N-acetyl-L-ornithine, and (ii) ornithine transcaramylase, which catalyzes the reaction between L-ornithine and carbamyl phosphate, yielding L-citrulline. Arg- strains were unable to utilze alpha-N-acetyl-L-ornithine for growth lacked significant activity of glutamate acetyltransferase, and activity was gained by Arg+ clones derived by DNA-mediated transformation. Some of the Arg- patient isolates were unable to use either alpha-N-acetyl-L-ornithine or L-ornithine in place of arginine, and two separate steps of genetic transformation were required to yield Arg+ cells. Extracts of these doubly auxotrophic cells lacked glutamate acetyltransferase activity, but, unexpectedly, they displayed normal ornithine transcarbamylase activity. This finding illustrates the importance of identifying the products specified by arg loci during genetic studies of arginine auxotrophy.     

An invariant threonine is involved in self-catalyzed cleavage of the precursor protein for ornithine acetyltransferase

In Bacillus stearothermophilus ornithine acetyltransferase is a bifunctional enzyme, catalyzing the first and the fifth steps of arginine biosynthesis; it follows a ping-pong kinetic mechanism. A single chain precursor protein is cleaved between the alanine and threonine residues in a highly conserved ATML sequence leading to the formation of alpha and beta subunits that assemble into a heterotetrameric 2alpha2beta molecule. The beta subunit has been shown to form an acetylated intermediate in the course of the transacetylation reaction. The present data show that the precursor protein synthesized in vitro or in vivo undergoes a self-catalyzed cleavage involving an invariant threonine (Thr-197). Using site-directed mutagenesis T197G, T197S, and T197C derivatives have been generated. The T197G substitution abolishes both precursor protein cleavage and catalytic activity, whereas T197S and T197C substitutions reduce precursor cleavage and catalytic activity in the order Thr-197 (wild type) --> Ser-197 --> Cys-197. A mechanism is proposed in which Thr-197 plays a crucial role in the autoproteolytic cleavage of ornithine acetyltransferase.     

Inhibitory effect of glucose on the maturation of rat liver mitochondria at birth. Phospholipid and oxidative metabolism

(1) The rate of ATP synthesis coupled with succinate oxidation in rat liver mitochondria is low at birth and increases rapidly during the first postnatal hours (Nakazawa, T., Asami, K., Suzuki, H. and Yakawa, O. (1973) J. Biochem. 73, 397-406). A glucose injection given to newborn rats immediately after birth seemed to delay this maturation process. (2) Glucose administration specifically diminished the rate of 32Pi incorporation into phosphatidylcholine both in microsomes and in mitochondria while other phospholipids remained unaffected. (3) In newborn rat liver, 32Pi incorporation into phospholipids can be explained by de novo synthesis of phospholipids in microsomes followed by transfer to mitochondria with two exceptions phosphatidylserine and sphingomyelin. Indeed, after a 20-min incorporation of 32Pi into phospholipids, the specific radioactivity of phosphatidylserine and sphingomyelin was higher in mitochondria than in microsomes. (4) As far as phospholipid synthesis is concerned, no precursor-product relationship could be observed between light and heavy mitochondria.     

Reaction mechanism of the heterotetrameric (alpha2beta2) E1 component of 2-oxo acid dehydrogenase multienzyme complexes

Pyruvate decarboxylase (E1) catalyzes the first two reactions of the four involved in oxidative decarboxylation of pyruvate by the pyruvate dehydrogenase (PDH) multienzyme complex. It requires thiamin diphosphate to bring about the decarboxylation of pyruvate, which is followed by the reductive acetylation of a lipoyl group covalently bound to the N(6) amino group of a lysine residue in the second catalytic component, a dihydrolipoyl acetyltransferase (E2). Replacement of two histidine residues in the E1alpha and E1beta chains of the heterotetrameric E1 (alpha(2)beta(2)) component of the PDH complex of Bacillus stearothermophilus, considered possible proton donors at the active site, was carried out. Subsequent characterization of the mutants permitted different roles to be assigned to these two particular residues in the reaction catalyzed by E1: E1alpha His271 to stabilize the dianion formed during decarboxylation of the 2-oxo acid and E1beta His128 to provide the proton required to protonate the incoming dithiolane ring in the subsequent reductive acetylation of the lipoyl goup. On the basis of these and other results from a separate investigation into the roles of individual residues in a loop region in the E1alpha chain close to the active site of E1 [Fries, M., Chauhan, H. J., Domingo, G. J., Jung, H., and Perham, R. N. (2002) Eur. J. Biochem. 270, 861-870] together with work from other laboratories, a detailed mechanism for the E1 reaction can be formulated.     

Protonmotive force in giant mitochondria

The accompanying communication [Eur. J. Biochem. 141 (1984) 1-4] indicates that the microinjection of the pH fluorescent indicator pyranine (8-hydroxy-1,2,6- pyrenesulfonate ) into giant mitochondria or mitoplasts does not affect their ability to carry out oxidative phosphorylation. The dye can therefore be used as a quantitative indicator of internal mitochondrial pH. We found that activation of metabolism in rotenone-inhibited giant mitochondria by the addition of succinate produces an internal pH change corresponding to a pH shift of 0.3 to the alkaline range, approximately the same value found previously for conventional rat liver mitochondria.     

A P450 BM-3 mutant hydroxylates alkanes, cycloalkanes, arenes and heteroarenes

P450 monooxygenases from microorganisms, similar to those of eukaryotic mitochondria, display a rather narrow substrate specificity. For native P450 BM-3, no other substrates than fatty acids or an indolyl-fatty acid derivative have been reported (Li, Q.S., Schwaneberg, U., Fischer, P., Schmid, R.D., 2000. Directed evolution of the fatty-acid hydroxylase P450BM-3 into an indole-hydroxylating catalyst. Chem. Eur. J. 6 (9), 1531-1536). Engineering the substrate specificity of Bacillus megaterium cytochrome P-450 BM3: hydroxylation of alkyl trimethylammonium compounds. Biochem. J. 327, 537-544). We thus were quite surprised to observe, in the course of our investigations on the rational evolution of this enzyme towards mutants, capable of hydroxylating shorter-chain fatty acids, that a triple mutant P450 BM-3 (Phe87Val, Leu188-Gln, Ala74Gly, BM-3 mutant) could efficiently hydroxylate indole, leading to the formation of indigo and indirubin (Li, Q.S., Schwaneberg, U., Fischer, P., Schmid, R.D., 2000. Directed evolution of the fatty-acid hydroxylase P450BM-3 into an indole-hydroxylating catalyst. Chem. Eur. J. 6 (9), 1531-1536). Indole is not oxidized by the wild-type enzyme; it lacks the carboxylate group by which the proper fatty acid substrates are supposed to be bound at the active site of the native enzyme, via hydrogen bonds to the charged amino acid residues Arg47 and Tyr51. Our attempts to predict the putative binding mode of indole to P450 BM-3 or the triple mutant by molecular dynamics simulations did not provide any useful clue. Encouraged by the unexpected activity of the triple mutant towards indole, we investigated in a preliminary, but systematic manner several alkanes, alicyclic, aromatic, and heterocyclic compounds, all of which are unaffected by the native enzyme, for their potential as substrates. We here report that this triple mutant indeed is capable to hydroxylate a respectable range of other substrates, all of which bear little or no resemblance to the fatty acid substrates of the native enzyme.