Structural identity between the NH2-terminal domain of the rat and human ornithine carbamyltransferase "targeting" sequences

Analysis of the secondary structure of human and rat ornithine carbamyltransferase's targeting sequence revealed the presence of a highly homologous domain with the following key features: an hydrophobic patch opposite to an hydrophilic surface characterized by the disposition of basic residues at potentially strategic positions. The functional role of this domain was established using a synthetic peptide corresponding to amino acids 1-19 of the rat ornithine carbamyltransferase precursor (pOCT 1-19). When added to an in vitro import assay system, pOCT (1-19) blocked the import of pOCT specifically: it did not impede the entry and processing of the precursor to subunit 2 of the F1-ATPase (p beta). This finding suggests that at least two distinct precursor(s)-specific pathways are required for the import of mitochondrial inner membrane and matrix proteins.     

The interaction of a synthetic mitochondrial signal peptide with lipid membranes is independent of transbilayer potential.

We have used fluorescence measurements and assays of vesicle disruption (contents leakage) to monitor the interaction between lipid vesicles and a synthetic peptide corresponding to the N-terminal 27 amino acids of rat mitochondrial pre-ornithine carbamyltransferase (pOCT). This peptide and two fluorescent derivatives bind reversibly to vesicles composed of neutral and anionic phospholipids with increasing affinity as the proportion of anionic lipids in the vesicles increases. The affinity of the peptide for lipid vesicles is unaffected by the presence of a transbilayer potential (inside negative) of at least -80 mV across the vesicle membranes. Our results support the proposal that the signal sequence of pOCT may promote an initial association of the precursor protein with mitochondrial membranes prior to binding to a specific receptor. However, we find no evidence that the pOCT signal sequence can subsequently undergo transfer into or across the lipid bilayer, even in the presence of a transmembrane potential of the magnitude previously found to support the import of precursor proteins into mitochondria.     

A synthetic signal peptide blocks import of precursor proteins destined for the mitochondrial inner membrane or matrix

A peptide corresponding to amino acids 1-27 of preornithine carbamyltransferase (pOCT) has been chemically synthesized. When added to energized mitochondria in vitro, 20 microM of the peptide, designated pO(1-27), resulted in a collapse of the electrochemical potential across the mitochondrial inner membrane. This effect on transmembrane potential was not observed, however, when pO(1-27) was added to energized mitochondria under conditions that support in vitro import of precursor proteins (i.e. in the presence of reticulocyte lysate). The latter finding, therefore, made possible an examination of the ability of pO(1-27) to block import of homologous and heterologous proteins into the organelle. At 5-10 microM, pO(1-27) prevented import of pOCT in vitro; inhibition was overcome by increasing the concentration of pOCT. In contrast, pO(16-27), a peptide corresponding to amino acids 16-27 of pOCT and exhibiting a charge:mass ratio similar to pO(1-27) had no such inhibitory effect. pO(1-27) blocked import of other unrelated precursor proteins destined either for the mitochondrial matrix (pre-malate dehydrogenase and a hybrid protein containing the signal sequence of pre-carbamyl phosphate synthetase) or for the mitochondrial inner membrane (pre-thermogenin).     

A signal sequence domain essential for processing, but not import, of mitochondrial pre-ornithine carbamyl transferase

Studies using deletion mutagenesis indicate that a processing recognition site lies proximal to the normal cleavage position between gln32 and ser33 of pre-ornithine carbamyl transferase (pOCT). pOCT cDNA was manipulated to delete codons specifying amino acids 22-30 of the signal sequence. The mutant precursor, designated pOCT delta 22-30, was imported to the matrix compartment by purified mitochondria, but remained largely unprocessed; the low level of processing that was observed did not involve the normal cleavage site. Several manipulations performed downstream of the normal pOCT processing site (deletion, substitution, and hybrid protein constructions) affected neither import nor correct processing. Our data suggest that domains specifying import and processing site recognition may be functionally segregated within the signal peptide; that processing is not requisite for import of pOCT; and that a proximal region, not involving the normal signal peptide cleavage site, is required for processing site recognition.     

Sequence and structural requirements of a mitochondrial protein import signal defined by saturation cassette mutagenesis.

The Saccharomyces cerevisiae F1-ATPase beta subunit precursor contains redundant mitochondrial protein import information at its NH2 terminus (D. M. Bedwell, D. J. Klionsky, and S. D. Emr, Mol. Cell. Biol. 7:4038-4047, 1987). To define the critical sequence and structural features contained within this topogenic signal, one of the redundant regions (representing a minimal targeting sequence) was subjected to saturation cassette mutagenesis. Each of 97 different mutant oligonucleotide isolates containing single (32 isolates), double (45 isolates), or triple (20 isolates) point mutations was inserted in front of a beta-subunit gene lacking the coding sequence for its normal import signal (codons 1 through 34 were deleted). The phenotypic and biochemical consequences of these mutations were then evaluated in a yeast strain deleted for its normal beta-subunit gene (delta atp2). Consistent with the lack of an obvious consensus sequence for mitochondrial protein import signals, many mutations occurring throughout the minimal targeting sequence did not significantly affect its import competence. However, some mutations did result in severe import defects. In these mutants, beta-subunit precursor accumulated in the cytoplasm, and the yeast cells exhibited a respiration defective phenotype. Although point mutations have previously been identified that block mitochondrial protein import in vitro, a subset of the mutations reported here represents the first single missense mutations that have been demonstrated to significantly block mitochondrial protein import in vivo. The previous lack of such mutations in the beta-subunit precursor apparently relates to the presence of redundant import information in this import signal. Together, our mutants define a set of constraints that appear to be critical for normal activity of this (and possibly other) import signals. These include the following: (i) mutant signals that exhibit a hydrophobic moment greater than 5.5 for the predicted amphiphilic alpha-helical conformation of this sequence direct near normal levels of beta-subunit import (ii) at least two basic residues are necessary for efficient signal function, (iii) acidic amino acids actively interfere with import competence, and (iv) helix-destabilizing residues also interfere with signal function. These experimental observations provide support for mitochondrial protein import models in which both the structure and charge of the import signal play a critical role in directing mitochondrial protein targeting and import.     

Targeting of cytochrome b2 into the mitochondrial intermembrane space: specific recognition of the sorting signal.

Cytochrome b2 contains 2-fold targeting information: an amino-terminal signal for targeting to the mitochondrial matrix, followed by a second cleavable sorting signal that functions in directing the precursor into the mitochondrial intermembrane space. The role of the second sorting sequence was analyzed by replacing one, two or all of the three positively charged amino acid residues which are present at the amino-terminal side of the hydrophobic core by uncharged residues or an acidic residue. With a number of these mutant precursor proteins, processing to the mature form was reduced or completely abolished and at the same time targeting to the matrix space occurred. The accumulation in the matrix depended on a high level of intramitochondrial ATP. At low levels of matrix ATP, the mutant proteins were sorted into the intermembrane space like the wild-type precursors. The results: (i) suggest the existence of one or more matrix components that specifically recognize the second sorting signal and thereby trigger the translocation into the intermembrane space; (ii) indicate that the mutant signals have reduced ability to interact with the recognition component(s) and then embark on the default pathway into the matrix by interacting with mitochondrial hsp70 in conjunction with matrix ATP; (iii) strongly argue against a mechanism by which the hydrophobic segment of the sorting sequence stops translocation in the hydrophobic phase of the inner membrane.     

Mitochondrial protein import: recognition of internal import signals of BCS1 by the TOM complex

BCS1, a component of the inner membrane of mitochondria, belongs to the group of proteins with internal, noncleavable import signals. Import and intramitochondrial sorting of BCS1 are encoded in the N-terminal 126 amino acid residues. Three sequence elements were identified in this region, namely, the transmembrane domain (amino acid residues 51 to 68), a presequence type helix (residues 69 to 83), and an import auxiliary region (residues 84 to 126). The transmembrane domain is not required for stable binding to the TOM complex. The Tom receptors (Tom70, Tom22 and Tom20), as determined by peptide scan analysis, interact with the presequence-like helix, yet the highest binding was to the third sequence element. We propose that the initial recognition of BCS1 precursor at the surface of the organelle mainly depends on the auxiliary region and does not require the transmembrane domain. This essential region represents a novel type of signal with targeting and sorting functions. It is recognized by all three known mitochondrial import receptors, demonstrating their capacity to decode various targeting signals. We suggest that the BCS1 precursor crosses the TOM complex as a loop structure and that once the precursor emerges from the TOM complex, all three structural elements are essential for the intramitochondrial sorting to the inner membrane.     

Independent mutations at the amino terminus of a protein act as surrogate signals for mitochondrial import.

Intracellular delivery of the mitochondrial F1-ATPase beta-subunit precursor from the cytoplasm into the matrix of mitochondria is prevented by deletion of its mitochondrial import signal, a basic amphipathic alpha-helix at its amino terminus. Using a complementation assay, we have selected spontaneous mutations which restore the correct in vivo localization of the protein containing the import signal deletion. Analysis of these mutations revealed that different functional surrogate mitochondrial targeting signals formed within a narrow region of the extreme amino terminus of the import signal deleted beta-subunit. These modifications specifically replace different acidic residues with neutral or basic residues to generate a less acidic amphipathic helix within a region of the protein which is accessible for interaction with the membrane surface. The observations of this study confirm the requirement for amphipathicity as part of the mitochondrial import signal and suggest how mitochondrial targeting signals may have evolved within the extreme amino terminus of mitochondrial proteins.     

Identification of an outer mitochondrial membrane protein that interacts with a synthetic signal peptide

Chemical cross-linking procedures have been employed to study possible interactions between components of the mitochondrial outer membrane and NH2-terminal signal sequences located in proteins destined for import into the organelle. A synthetic peptide comprising amino acids 1-27 of pre-ornithine carbamyltransferase (pOCT) was found to interact specifically with a mitochondrial polypeptide of apparent molecular size 30 kDa. Membrane fractionation and protease accessibility analyses indicated that the polypeptide, designated p30, is located in the outer membrane. Binding of the synthetic peptide to p30 was saturable and reversible; Scatchard analysis of the binding data revealed a dissociation constant of 2 X 10(-6) M and predicts that p30 constitutes 4-10% of the outer mitochondrial membrane protein. Mild trypsin digestion of the mitochondrial surface destroyed both the ability of p30 to cross-link to the signal peptide and the ability of the organelle to import pOCT. Neither parameter was affected, however, by pretreatment of mitochondria with 1 M KCl.     

Role of the Negative Charges in the Cytosolic Domain of TOM22 in the Import of Precursor Proteins into Mitochondria

TOM22 is an essential mitochondrial outer membrane protein required for the import of precursor proteins into the organelles. The amino-terminal 84 amino acids of TOM22 extend into the cytosol and include 19 negatively and 6 positively charged residues. This region of the protein is thought to interact with positively charged presequences on mitochondrial preproteins, presumably via electrostatic interactions. We constructed a series of mutant derivatives of TOM22 in which 2 to 15 of the negatively charged residues in the cytosolic domain were changed to their corresponding amido forms. The mutant constructs were transformed into a sheltered Neurospora crassa heterokaryon bearing a tom22::hygromycin R disruption in one nucleus. All constructs restored viability to the disruption-carrying nucleus and gave rise to homokaryotic strains containing mutant tom22 alleles. Isolated mitochondria from three representative mutant strains, including the mutant carrying 15 neutralized residues (strain 861), imported precursor proteins at efficiencies comparable to those for wild-type organelles. Precursor binding studies with mitochondrial outer membrane vesicles from several of the mutant strains, including strain 861, revealed only slight differences from binding to wild-type vesicles. Deletion mutants lacking portions of the negatively charged region of TOM22 can also restore viability to the disruption-containing nucleus, but mutants lacking the entire region cannot. Taken together, these data suggest that an abundance of negative charges in the cytosolic domain of TOM22 is not essential for the binding or import of mitochondrial precursor proteins; however, other features in the domain are required.     

Analysis of the sorting signals directing NADH-cytochrome b5 reductase to two locations within yeast mitochondria.

Mitochondrial NADH-cytochrome b5 reductase (Mcr1p) is encoded by a single nuclear gene and imported into two different submitochondrial compartments: the outer membrane and the intermembrane space. We now show that the amino-terminal 47 amino acids suffice to target the Mcr1 protein to both destinations. The first 12 residues of this sequence function as a weak matrix-targeting signal; the remaining residues are mostly hydrophobic and serve as an intramitochondrial sorting signal for the outer membrane and the intermembrane space. A double point mutation within the hydrophobic region of the targeting sequence virtually abolishes the ability of the precursor to be inserted into the outer membrane but increases the efficiency of transport into the intermembrane space. Import of Mcr1p into the intermembrane space requires an electrochemical potential across the inner membrane, as well as ATP in the matrix, and is strongly impaired in mitochondria lacking Tom7p or Tim11p, two components of the translocation machineries in the outer and inner mitochondrial membranes, respectively. These results indicate that intramitochondrial sorting of the Mcr1 protein is mediated by specific interactions between the bipartite targeting sequence and components of both mitochondrial translocation systems.     

cDNA cloning and sequencing for the import precursor of subunit B in H(+)-ATP synthase from rat mitochondria

The nucleotide sequence of the import precursor of subunit b of rat liver H(+)-ATP synthase has been determined from a recombinant cDNA clone isolated by screening a rat liver cDNA library with a probe DNA. The sequence was composed of 1,124 nucleotides including a coding region for the import precursor of subunit b and noncoding regions of both the 5'- and 3'-sides. The import precursor of subunit b and its mature polypeptide deduced from the open reading frame consisted of 256 and 214 amino acid residues with a molecular weight of 28,867 and 24,628, respectively. The presequence of 42 amino acids could be the import signal peptide which serves to direct the protein into the mitochondrial matrix.     

Characterization of the targeting signal of dual-targeted pea glutathione reductase

We investigated the dual targeting signal of pea glutathione reductase (GR) that had been previously shown to be capable of targeting the passenger protein phosphinothricin acetyl transferase to mitochondria and chloroplasts in vivo. We confirmed that GR was imported into mitochondria and chloroplasts in vitro. Rupture of the outer mitochondrial membrane after the import assay indicated that GR was imported into both the intermembrane space and the matrix. Changing positive and hydrophobic residues in the targeting signal we investigated if dual targeting of GR was due to an overlapping or separate signal. Overall single mutations had a greater effect on mitochondrial import compared to chloroplasts, especially those on positive residues. Precursors containing both positive and hydrophobic residue mutations (double mutants) indicated that there might be some redundancy in targeting information for chloroplastic import as double mutants had a greater effect than predicted from the single mutants. Fusion of the targeting signal to the green fluorescent protein (GFP) followed by transient transformation indicated that this signal was only capable of targeting this passenger protein to plastids. Additionally, fusion of the complete coding sequence of GR to GFP also resulted in an exclusive chloroplastic localization. Mutations in the targeting signal that reduced import into plastids in vitro also displayed altered patterns of GFP localizations in vivo. These results indicate that some residues in the signal for dual localisation of GR play a role in both mitochondrial and chloroplastic import, and thus the signal is overlapping.     

Targeting and assembly of rat mitochondrial translocase of outer membrane 22 (TOM22) into the TOM complex

Tom22 is a preprotein receptor and organizer of the mitochondrial outer membrane translocase complex (TOM complex). Rat Tom22 (rTOM22) is a 142-residue protein, embedded in the outer membrane through the internal transmembrane domain (TMD) with 82 N-terminal residues in the cytosol and 41 C-terminal residues in the intermembrane space. We analyzed the signals that target rTOM22 to the mitochondrial outer membrane and assembly into the TOM complex in cultured mammalian cells. Deletions or mutations were systematically introduced into the molecule, and the intracellular localization of the mutant constructs in HeLa cells was examined by confocal microscopy and cell fractionation. Their assembly into the TOM complex was also examined using blue native gel electrophoresis. These experiments revealed three separate structural elements: a cytoplasmic 10-residue segment with an acidic alpha-helical structure located 30 residues upstream of the TMD (the import sequence), TMD with an appropriate hydrophobicity, and a 20-residue C-terminal segment located 22 residues downstream of the TMD (C-tail signal). The import sequence and TMD were both essential for targeting and integration into the TOM complex, whereas the C-tail signal affected the import efficiency. The import sequence combined with foreign TMD functioned as a mitochondrial targeting and anchor signal but failed to integrate the construct into the TOM complex. Thus, the mitochondrial-targeting and TOM integration signal could be discriminated. A yeast two-hybrid assay revealed that the import sequence interacted with two intramolecular elements, the TMD and C-tail signal, and that it also interacted with the import receptor Tom20.     

Molecular cloning of cDNA for the import precursor of human subunit B of H(+)-ATP synthase in mitochondria.

The nucleotide sequence of the import precursor of subunit b of human H(+)-ATP synthase has been determined from a recombinant cDNA clone isolated by screening a human kidney cDNA library with a cDNA for rat subunit b as a probe. The sequence was composed of 1,134 nucleotides including a coding region for the import precursor of subunit b and noncoding regions on the 5'- and 3'-sides. The import precursor of subunit b and its mature polypeptide deduced from the open reading frame were found to consist of 256 and 214 amino acid residues with molecular weights of 28,893 and 24,610, respectively. The presequence of 42 amino acids could be the import signal peptide for directing the protein into the mitochondrial matrix.     

Molecular cloning of cDNA for the import precursor of human coupling factor 6 of H(+)-ATP synthase in mitochondria

The nucleotide sequence of the import precursor of coupling factor 6 (factor 6) of human H(+)-ATP synthase has been determined from a recombinant cDNA clone isolated by screening a human kidney cDNA library with a cDNA for rat factor 6 as a probe. The sequence was composed of 466 nucleotides including a coding region for the import precursor of factor 6 and noncoding regions on the 5'- and 3'-sides. The import precursor of factor 6 and its mature polypeptide deduced from the open reading frame were found to consist of 108 and 76 amino acid residues with molecular weights of 12,596 and 8,969, respectively. The presequence of 32 amino acids could be the import signal peptide for directing the protein into the mitochondrial matrix.     

cDNA cloning and sequencing for the import precursor of coupling factor 6 in H(+)-ATP synthase from rat liver mitochondria

The nucleotide sequence of the import precursor of coupling factor 6 (factor 6) of rat liver H(+)-ATP synthase has been determined from a recombinant cDNA clone isolated by screening a rat liver cDNA library with a probe DNA. The sequence was composed of 458 nucleotides including a coding region for the import precursor of factor 6 and noncoding regions of both the 5'- and 3'-sides. The import precursor of factor 6 and its mature polypeptide deduced from the open reading frame consisted of 108 and 76 amino acid residues with a molecular weight of 12,494 and 8,927, respectively. The presequence of 32 amino acids could be the import signal peptide which serves to direct the protein into the mitochondrial matrix.     

Functional domains and dynamic assembly of the peroxin Pex14p, the entry site of matrix proteins

The 41-kDa membrane-anchored peroxin Pex14p functions as the peroxisome targeting signal (PTS) receptor-mediated, initial import site for matrix proteins. We here identify the functional domains of Pex14p involved in the assembly of import site subcomplexes. The minimal region of Pex14p required for restoring impaired protein import in pex14 Chinese hamster ovary cell mutant lies at residues 21-260 in the primary sequence. A highly conserved N-terminal region, encompassing residues 21-70, interacts with the PTS1 receptor Pex5p, Pex13p, and Pex19p that is essential for membrane biogenesis. N-terminal residues 21-140, including a hydrophobic segment at 110-138, function as a topogenic sequence. Site-directed mutagenesis, size fractionation, and chemical cross-linking analyses demonstrate that the coiled-coil domain at residues 156-197 regulates homodimerization of Pex14p. Moreover, AXXXA and GXXXG motifs in the transmembrane segment mediate homomeric oligomerization of Pex14p, giving rise to assembly of high molecular mass complexes and thereby assuring Pex13p-dependent localization of Pex14p to peroxisomes. Pex5p, Pex13p, and Pex19p bind to Pex14p homo-oligomers with different molecular masses, whereas cargo-unloaded Pex5p apparently disassembles Pex14p homo-oligomers. Thus, Pex14p most likely forms several distinct peroxin complexes involved in peroxisomal matrix protein import.     

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.     

The loss in hydrophobic surface area resulting from a Leu to Val mutation at the N-terminus of the aldehyde dehydrogenase presequence prevents import of the protein into mitochondria

An apparent conservative mutation, Leu to Val, at the second residue of the rat liver mitochondrial aldehyde dehydrogenase (ALDH) presequence resulted in a precursor protein that was not imported into mitochondria. Additional mutants were made to substitute various amino acids with nonpolar side chains for Leu2. The Ile, Phe, and Trp mutants were imported to an extent similar to that of the native precursor, but the Ala mutant was imported only about one-fourth as well. It was shown that the N-terminal methionine was removed from the L2V mutant in a reaction catalyzed by methionine aminopeptidase. The N-terminal methionine of native pALDH and the other mutant presequences was blocked, presumably by acetylation. Because of the difference in co-translational modification, the L2V mutant sustained a significant loss in the available hydrophobic surface of the presequence. Import competence was restored to the L2V mutant when it was translated using a system that did not remove Met1. The removal of an Arg-Gly-Pro helix linker segment (residues 11-14) from the L2V mutant, which shifted three leucine residues toward the N-terminus, also restored import competence. These results lead to the conclusion that a minimum amount of hydrophobic surface area near the N-termini of mitochondrial presequences is an essential property to determine their ability to be imported. As a result, both electrostatic and hydrophobic components must be considered when trying to understand the interactions between precursor proteins and proteins of the mitochondrial import apparatus.