Michel Thieffry

The Preprotein Translocation Channel of the Outer Membrane of Mitochondria

The preprotein translocase of the outer membrane of mitochondria (TOM complex) facilitates the recognition, insertion, and translocation of nuclear-encoded mitochondrial preproteins. We have purified the TOM complex from Neurospora crassa and analyzed its composition and functional properties. The TOM complex contains a cation-selective high-conductance channel. Upon reconstitution into liposomes, it mediates integration of proteins into and translocation across the lipid bilayer. TOM complex particles have a diameter of about 138 A, as revealed by electron microscopy and image analysis; they contain two or three centers of stain-filled openings, which we interpret as pores with an apparent diameter of about 20 A. We conclude that the structure reported here represents the protein-conducting channel of the mitochondrial outer membrane.

The Isolated Complex of the Translocase of the Outer Membrane of Mitochondria CHARACTERIZATION OF THE CATION-SELECTIVE AND VOLTAGE-GATED PREPROTEIN-CONDUCTING PORE

The complex of the translocase mitochondrial outer membrane (TOM), mediates recognition, unfolding, and translocation of preproteins. We have used a combination of biochemical and electrophysiological methods to study the properties of the preprotein-conducting pore of the purified TOM complex. The pore is cation-selective and voltage-gated. It shows three main conductance levels with characteristic slow and fast kinetics transitions to states of lower conductance following application of transmembrane voltages. These electrical properties distinguish it from the mitochondrial voltage-dependent anion channel (porin) and are identical to those of the previously described peptide-sensitive channel. Binding of antibodies to the C terminus of Tom40 on the intermembrane space side of the outer membrane modifies the channel properties and allows determination of the orientation of the channel within the lipid bilayer. Mitochondrial presequence peptides specifically interact with the pore and decrease the ion flow through the channel in a voltage-dependent manner. We propose that the presequence-induced closures of the pore are related to structural alterations of the TOM complex observed during the various stages of preprotein movement across the mitochondrial outer membrane.

Blockade of a mitochondrial cationic channel by an addressing peptide: an electrophysiological study

SummaryA voltage-dependent cationic channel of large conductance is observed in phospholipid bilayers formed at the tip of microelectrodes from proteoliposomes derived from mitochondrial membranes. This channel was blocked by a 13-residue peptide with the sequence of the amino terminal extremity of the nuclear-coded subunit IV of cytochromec oxidase. The blockade was reversible, voltage- and dose-dependent. The peptide did not affect the activity of aTorpedo chloride channel observed under the same conditions. From experiments with phospholipid monolayers, it is unlikely that the peptide inserts into bilayers under the experimental conditions used. The blockade was observed from both sides of the membrane, being characterized by more frequent transitions to the lower conductance states, and a maximum effect was observed around 0 mV. Channels, the gating mechanism of which had been eliminated by exposure to trypsin, were also blocked by the peptide. For trypsinized channels, the duration of the closure decreased and the blockade saturated at potentials below −30 mV. These observations are consistent with a translocation of the peptide through the channel. Dynorphin B, which has the same length and charge as the peptide, had some blocking activity. Introduction of negative charges in the peptide by succinylation suppressed the activity.

Comparison of mitochondrial cationic channels in wild‐type and porin‐deficient mutant yeast

Bilayers were formed at the tip of microelectrodes from a suspension of proteoliposomes derived from wild‐type and porin‐deficient mutant yeast mitochondria. In both preparations, identical cationic channels of large conductance were recorded. This result rules out any relationship between this channel and the outer membrane voltage‐dependent anion channel, the activity of which is carried by porin. The ionic selectivity and the voltage‐dependence of the yeast cationic channel suggest that it is related to that recently described in mammalian mitochondria. This hypothesis is further supported by the fact that both channels are blocked by a mitochondrial addressing peptide.

Properties of the mitochondrial peptide-sensitive cationic channel studied in planar bilayers and patches of giant liposomes.

A voltage-dependent cationic channel of large conductance is observed in phospholipid bilayers formed by the tip-dip method from proteoliposomes derived from mitochondrial membranes. It is blocked by peptide M, a 13 residue peptide having the properties of a mitochondrial signal sequence. To verify the reliability of the experimental approach, mitochondrial membranes from bovine adrenal cortex or porin-deficient mutant yeast were either fused to planar bilayers or incorporated in giant liposomes which were studied by patch clamp. Cationic channels were found with both techniques. They had the same conductance levels and voltage-dependence as those which have been described using the tip-dip method. Moreover, they were similarly blocked by peptide M. The voltage-dependence of block duration was analyzed in planar bilayer and tip-dip records. Results strengthen the idea that peptide M might cross the channel. Other mitochondrial channels were observed in planar bilayers and patch clamp of giant liposomes. Because they were never detected in tip-dip records, they are likely to be inactivated at the surface monolayer used to form the bilayer in this type of experiment.

Relationship between the Peptide-sensitive Channel and the Mitochondrial Outer Membrane Protein Translocation Machinery

The eptide-ensitive hannel (PSC), a cationic channel of the mitochondrial outer membrane, is blocked by synthetic mitochondrial presequences and by nonmitochondrial basic peptides such as dynorphin B(1-13). Both types of peptides are imported into mitochondria. However, the import of dynorphin B(1-13) had to be further characterized since its properties differed from those of the general import pathway used by mitochondrial peptides. Cross-linking experiments with iodinated dynorphin B(1-13) led to the labeling of TOM 40/ISP 42, a component of the protein import machinery of the outer membrane. Accordingly, dynorphin B(1-13) could also be used as a presequence to direct the import of a cytosolic protein into the mitochondria. Pretreatment of intact mitochondria by trypsin removed components capable of discriminating between true mitochondrial presequences and other basic peptides active on the PSC. After proteolysis, both types of peptides appeared to cross the outer membrane through the same pathway. Involvement of the PSC in the translocation complex was shown by immunoprecipitation of the PSC activity by anti-ISP 42 antibodies. Taken together, the present data reinforce the hypothesis that the PSC is the pore responsible for the translocation of protein through the outer membrane.

Characterization and Function of the Mitochondrial Outer Membrane Peptide-Sensitive Channel

The PSC (peptide-sensitive Channel), a cationic channel of large conductance, has been characterized in yeast and mammalian mitochondria by three different methods, “tip-dip,” patch clamp of giant liposomes, and planar bilayers. The yeast and mammalian PSC share the common property to be blocked by basic peptides such as pCyt OX IV (1–12)Y which contains the first 12 residues of the presequence of cytochromec oxidase subunit IV. The electrophysiological data are consistent with a translocation of the peptide through the pore. Analysis of the frequency of observation of the PSC in different fractions indicates that the channel is located in the outer mitochondrial membrane. Uptake measurements of iodinated peptides by intact mitochondria from a porin-less mutant show that the peptides are translocated through the outer membrane, presumably at the level of PSC. Among the peptides active on PSC, several, such as pCyt OX IV (1–22) and the reduced form of the mast cell degranulating peptide, induce an alteration of the voltage dependence or of the inactivation rate subsisting after washing and which is eliminated only by proteolysis of the interacting peptide. These irreversible effects may account for the variability of the properties of the PSC which would interact with cytosolic or intermembrane cations, peptides, or proteins, thus modulating the channel permeability. Finally, several lines of evidence suggest the participation of the PSC in protein translocation and some interaction with the general insertion pore of the outer membrane translocation machinery.

Solubilization and reconstitution of the mitochondrial peptide-sensitive channel

In addition to the voltage-dependent anion channel (VDAC), mitochondrial outer membranes contain a cationic channel of large conductance, which is blocked by a mitochondrial addressing peptide (peptide-sensitive channel, PSC). Bovine adrenal cortex mitochondria were solubilized in 1.5% octyl β-glucoside, and membrane vesicles were reconstituted by slow dilution with a low ionic strength buffer. The reconstituted vesicles contained a functional channel possessing the electrical characteristics of the cationic channel, including its sensitivity to the mitochondrial addressing peptide. Important features of the described protocol are the nature of the detergent, its concentration, and the addition of glycerol during the whole procedure. No solubilization could be observed in the presence of cholate.

A 28 kDa mitochondrial protein is radiolabelled by crosslinking with a 123I-labelled presequence

A 13‐residue peptide containing the first 12 amino acids of the N‐terminal part of the signal sequence of yeast cytochrome ???oxidase subunit IV is shown by chemical crosslinking to interact with a mitochondrial protein. This result is obtained with mitochondria from four different origins. Submitochondrial localization experiments suggest that the 28 kDa labelled component is present on the outer face of the inner membrane. Since such addressing peptides are imported into mitochondria through the same machinery as protein precursors, the 28 kDa protein might be a component of the translocation apparatus.

The Mitochondrial Outer Membrane Contains at Least Two Distinct Channels

The presence in the mitochondrial outer membrane of a cationic channel blocked by a 13 residue addressing peptide had been shown by the technique of “tip-dip”. This channel was studied in planar bilayers and compared to the anionic porin, the voltage-dependent anion channel, observed in the same conditions. The two activities were clearly different. The peptide sensitive channel, present in both wild type and porin-deficient mutant yeast, is not a rescue channel, but an alternate independent permeability pathway. The channel interacted more strongly with a longer extension of the addressing peptide containing 22 residues, suggesting a physiological interaction of this type of molecule with the cationic channel.