A peptide-sensitive channel of large conductance is localized on mitochondrial outer membrane.

Applying the technique of 'tip-dip' to mitochondria, we have shown the existence in this organelle of a cationic channel of large conductance, which is blocked by a 13-residue peptide possessing the sequence of the N-terminal extremity of the cytochrome c oxidase subunit IV precursor. To study the submitochondrial localization of the channel, the effect of trypsin on isolated channels and on entire mitochondria were compared. One side of isolated channels is sensitive to trypsin, which eliminates the voltage dependence. Channels isolated from trypsinized mitochondria were devoid of voltage dependence and were blocked by the peptide. This suggests a localization of the channel on the outer membrane. Consistent with this hypothesis, the channel was observed with the highest frequency in outer membrane fractions purified by different procedures, either from bovine adrenal cortex or from rat liver mitochondria. Such a localization is also consistent with digitonin solubilization experiments. The channel was solubilized before the inner membrane marker, cytochrome c oxidase. The orientation of the channel was inferred from its trypsin sensitivity and its potential dependence: a transmembrane potential (inside negative) will close the channel.     

The key role of the energized state of Saccharomyces cerevisiae mitochondria in modulations of the outer membrane channels by the intermembrane space proteins

Mitochondria of the yeast Saccharomyces cerevisiae constitute a perfect model to study the outer membrane channel modulation as besides the TOM complex channel they contain only a single isoform of the VDAC channel and it is possible to obtain viable mutants devoid of the channel. Here, we report that the fraction of the intermembrane space isolated from wild type and the VDAC channel-depleted yeast mitochondria, except of the well-known VDAC channel modulator activity, displays also the TOM complex channel modulating activity as measured in the reconstituted system and with intact mitochondria. The important factor influencing the action of both modulating activities is the energized state of mitochondria. Moreover, the presence of the VDAC channel itself seems to be crucial to properties of the intermembrane space protein (s) able to modulate the outer membrane channels because in the case of intact mitochondria quantitative differences are observed between modulating capabilities of the fractions isolated from wild type and mutant mitochondria.     

Ionic mitochondrial channels: characteristics and possible role in protein translocation

Most of the mitochondrial proteins are synthesized in the cytoplasm as precursors which are then translocated into the organelle. These precursors have a NH2-terminal extension which functions as a mitochondrial targeting signal. The import process through mitochondrial membranes is voltage-dependent; its mechanism is still unknown. Translocation has been proposed to occur through specific channels, thus, indicating the interest of the study of mitochondrial ionic channels. Two anion channels with different electrical characteristics have been described in the outer and the inner membranes. Using the technique of "Tip-Dip", we have shown the existence of a cation channel of large conductance in mitochondria. The characteristics of this channel differ from that of the other mitochondrial anion channels. A positively charged 13-residue synthetic peptide, with the sequence of the amino terminal extremity of the nuclear-coded subunit IV of yeast cytochrome C oxidase, induces a blockade of the cationic channel. From the characteristics of the blockade, it is likely that the channel could be permeable to the peptide. The specificity of this effect suggests that this channel might be involved in protein translocation.     

Comparison of the TIM and TOM channel activities of the mitochondrial protein import complexes

Water-filled channels are central to the process of translocating proteins since they provide aqueous pathways through the hydrophobic environment of membranes. The Tom and Tim complexes translocate precursors across the mitochondrial outer and inner membranes, respectively, and contain channels referred to as TOM and TIM (previously called PSC and MCC). In this study, little differences were revealed from a direct comparison of the single channel properties of the TOM and TIM channels of yeast mitochondria. As they perform similar functions in translocating proteins across membranes, it is not surprising that both channels are high conductance, voltage-dependent channels that are slightly cation selective. Reconstituted TIM and TOM channel activities are not modified by deletion of the outer membrane channel VDAC, but are similarly affected by signal sequence peptides.     

Anion channels of the inner membrane of mammalian and yeast mitochondria

The inner membrane of yeast and mammalian mitochondria has been studiedin situ with a patch clamp electrode. Anion channels were found in both cases, although their behavior and regulation are different. In mammalian mitochondria, the principal channel is of around 100 pS conductance and opens mainly under depolarized membrane potentials. As no physiological compound able to alter its peculiar voltage dependence has yet been found, it is proposed that this channel may serve as a safeguard mechanism for recharging the mitochondrial membrane potential. Two other anion channels, each with a distinct conductance (one of approx. 45 pS, the second of at least a tenfold higher value) and kinetics are harbored in the yeast inner membrane. Matrix ATP was found to interact with both, but with a different mechanism. It is proposed that the 45 pS channel may be involved in the homeostatic mechanism of mitochondrial volume.     

Control of mitochondrial protein import by pH

Protein import into mitochondria is inhibited by protons (IC(50) pH 6.5). The channels of the import machinery were examined to further investigate this pH dependence. TOM and TIM23 are the protein translocation channels of the mitochondrial outer and inner membranes, respectively, and their single channel behaviors at various pHs were determined using patch-clamp techniques. While not identical, increasing H(+) concentration decreases the open probability of both TIM23 and TOM channels. The pattern of the pH dependences of protein import and channel properties suggests TIM23 open probability can limit import of nuclear-encoded proteins into the matrix of yeast mitochondria.     

The high-conductance channels of yeast mitochondrial outer membranes: A planar bilayer study

The high-conductance channels present in the outer membranes of wild-type and porin-less yeast mitochondria have been characterized electrophysiologically after incorporation in planar bilayer membranes. The most prominent activity was ascribed to a voltage-dependent, substaterich, cationic channel which generally inactivated at potentials positive in thecis compartment, in agreement with the observations from patch-clamp experiments on porin-less mitoplasts. This channel has been identified as the so-called peptide-sensitive channel (PSC). We also observed similar channels displaying either no inactivation, or inactivation at both positive and negative potentials. These latter properties match those already described for mammalian and yeast PSC, respectively. These different behaviors are tentatively explained as arising from the presence, or lack of, peptides bound to the PSC. Very high conductances, apparently due to cooperative gating, were frequently displayed. In wild-type membranes, activity ascribable to the porin was also observed.The first two authors contributed equally to the work described in this paper.     

New insights into the mechanism of permeation through large channels

The mitochondrial channel, VDAC, regulates metabolite flux across the outer membrane. The open conformation has a higher conductance and anionic selectivity, whereas closed states prefer cations and exclude metabolites. In this study five mutations were introduced into mouse VDAC2 to neutralize the voltage sensor. Inserted into planar membranes, mutant channels lack voltage gating, have a lower conductance, demonstrate cationic selectivity, and, surprisingly, are still permeable to ATP. The estimated ATP flux through the mutant is comparable to that for wild-type VDAC2. The outer membranes of mitochondria containing the mutant are permeable to NADH and ADP/ATP. Both experiments support the counterintuitive conclusion that converting a channel from an anionic to a cationic preference does not substantially influence the flux of negatively charged metabolites. This finding supports our previous proposal that ATP translocation through VDAC is facilitated by a set of specific interactions between ATP and the channel wall.     

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.     

In yeast, Ca2+ and octylguanidine interact with porin (VDAC) preventing the mitochondrial permeability transition

In yeast, Ca(2+) and long chain alkylguanidines interact with mitochondria modulating the opening of the yeast mitochondrial unspecific channel. Mammalians possess a similar structure, the mitochondrial permeability transition pore. The composition of these pores is under debate. Among other components, the voltage-dependent anion channel has been proposed as a component of either pore. In yeast from an industrial strain, octylguanidine and calcium closed the yeast mitochondrial unspecific channel. Here, the effects of the cations Ca(2+) or octylguanidine and the voltage-dependent anion channel effector decavanadate were evaluated in yeast mitochondria from either a wild type or a voltage-dependent anion channel deletion laboratory strain. It was observed that in the absence of voltage-dependent anion channel, the yeast mitochondrial unspecific channel was desensitized to Ca(2+), octylguanidine or decavanadate but remained sensitive to phosphate. It is thus suggested that in yeast mitochondria, the voltage-dependent anion channel has a cation binding site where Ca(2+) and octylguanidine interact, conferring cation sensitivity to the yeast mitochondrial unspecific channel.     

Protein translocase of the outer mitochondrial membrane: role of import receptors in the structural organization of the TOM complex

The mitochondrial outer membrane contains a multi-subunit machinery responsible for the specific recognition and translocation of precursor proteins. This translocase of the outer membrane (TOM) consists of three receptor proteins, Tom20, Tom22 and Tom70, the channel protein Tom40, and several small Tom proteins. Single-particle electron microscopy analysis of the Neurospora TOM complex has led to different views with two or three stain-filled centers resembling channels. Based on biochemical and electron microscopy studies of the TOM complex isolated from yeast mitochondria, we have discovered the molecular reason for the different number of channel-like structures. The TOM complex from wild-type yeast contains up to three stain-filled centers, while from a mutant yeast selectively lacking Tom20, the TOM complex particles contain only two channel-like structures. From mutant mitochondria lacking Tom22, native electrophoresis separates an approximately 80 kDa subcomplex that consists of Tom40 only and is functional for accumulation of a precursor protein. We conclude that while Tom40 forms the import channels, the two receptors Tom22 and Tom20 are required for the organization of Tom40 dimers into larger TOM structures.     

In yeast, Ca and octylguanidine interact with porin (VDAC) preventing the mitochondrial permeability transition

In yeast, Ca²⁺ and long chain alkylguanidines interact with mitochondria modulating the opening of the yeast mitochondrial unspecific channel. Mammalians possess a similar structure, the mitochondrial permeability transition pore. The composition of these pores is under debate. Among other components, the voltage-dependent anion channel has been proposed as a component of either pore. In yeast from an industrial strain, octylguanidine and calcium closed the yeast mitochondrial unspecific channel. Here, the effects of the cations Ca²⁺ or octylguanidine and the voltage-dependent anion channel effector decavanadate were evaluated in yeast mitochondria from either a wild type or a voltage-dependent anion channel deletion laboratory strain. It was observed that in the absence of voltage-dependent anion channel, the yeast mitochondrial unspecific channel was desensitized to Ca²⁺, octylguanidine or decavanadate but remained sensitive to phosphate. It is thus suggested that in yeast mitochondria, the voltage-dependent anion channel has a cation binding site where Ca²⁺ and octylguanidine interact, conferring cation sensitivity to the yeast mitochondrial unspecific channel.     

Anti-apoptotic Bcl-2 Family Proteins Disassemble Ceramide Channels

Early in mitochondria-mediated apoptosis, the mitochondrial outer membrane becomes permeable to proteins that, when released into the cytosol, initiate the execution phase of apoptosis. Proteins in the Bcl-2 family regulate this permeabilization, but the molecular composition of the mitochondrial outer membrane pore is under debate. We reported previously that at physiologically relevant levels, ceramides form stable channels in mitochondrial outer membranes capable of passing the largest proteins known to exit mitochondria during apoptosis (Siskind, L. J., Kolesnick, R. N., and Colombini, M. (2006) Mitochondrion 6, 118-125). Here we show that Bcl-2 proteins are not required for ceramide to form protein-permeable channels in mitochondrial outer membranes. However, both recombinant human Bcl-x(L) and CED-9, the Caenorhabditis elegans Bcl-2 homologue, disassemble ceramide channels in the mitochondrial outer membranes of isolated mitochondria from rat liver and yeast. Importantly, Bcl-x L and CED-9 disassemble ceramide channels in the defined system of solvent-free planar phospholipid membranes. Thus, ceramide channel disassembly likely results from direct interaction with these anti-apoptotic proteins. Mutants of Bcl-x L act on ceramide channels as expected from their ability to be anti-apoptotic. Thus, ceramide channels may be one mechanism for releasing pro-apoptotic proteins from mitochondria during the induction phase of apoptosis.     

Splitting the two pore domains from TOK1 results in two cationic channels with novel functional properties.

Potassium channels are membrane-spanning proteins with several transmembrane segments and a single pore region where ion conduction takes place (Biggin, P. C., Roosild, T., and Choe, S. (2000) Curr. Opin. Struct. Biol. 4, 456-461; Doyle, D. A., Morais Cabral, J., Pfuetzner, R. A., Kuo, A., Gulbis, J. M., Cohen, S. L., Chait, B. T., and MacKinnon, R. (1998) Science 280, 69-77). TOK1, a potassium channel identified in the yeast Saccharomyces cerevisiae, was the first described member from a growing new family of potassium channels with two pore domains in tandem (2P) (Ketchum, K. A., Joiner, W. J., Sellers, A. J., Kaczmarek, L. K., and Goldstein, S. A. (1995) Nature 376, 690-695). In an attempt to understand the relative contribution of each one of the 2P from TOK1 to the functional properties of this channel, we split and expressed the pore domains separately or in combination. Expression of the two domains separately rescued a potassium transport-deficient yeast mutant, suggesting that each domain forms functional potassium-permeable channels in yeast. In Xenopus laevis oocytes expression of each pore domain resulted in the appearance of unique inwardly rectifying cationic channels with novel gating and pharmacological properties. Both pore domains were poorly selective to potassium; however, upon co-expression they partially restored TOK1 channel selectivity. The single channel conductance was different in both pore domains with 7 +/- 1 (n = 12) and 15 +/- 2 (n = 12) picosiemens for the first and second domain, respectively. In light of the known structure of the Streptomyces lividans KcsA potassium channel pore (see Doyle et al. above), these results suggest a novel non-four-fold-symmetric architecture for 2P potassium-selective channels.     

Overexpression of Bcl-2 suppresses the calcium activation of a mitochondrial megachannel

The molecular mechanism(s) by which Bcl-2 regulates apoptosis is poorly understood. Bcl-2 suppresses apoptosis by inhibiting calcium activation of the permeability transition of mitochondria. In this patch-clamp study, overexpression of Bcl-2 in mitochondria of cultured cells suppressed calcium activation of a high conductance channel that may underlie the permeability transition. All other single channel parameters were identical when multiple conductance channel activities of mitochondria from control and Bcl-2 overexpressing cells were compared. Bcl-2 forms channels in artificial membranes; however, no novel channel activities could be linked to Bcl-2 overexpression, suggesting Bcl-2 does not form channels in native inner membranes of mitochondria.     

Role of surface electrostatics in the operation of a high-conductance Ca2+-activated K+ channel

This paper demonstrates that local electric fields originating from negatively charged groups on a K+-specific ion channel modify its behavior. Single high-conductance, Ca2+-activated K+ channels were studied in neutral phospholipid bilayers. The channel protein surface charges were manipulated experimentally by carboxyl group esterification using trimethyloxonium (TMO) or by electrolyte screening. Three channel properties--ion conduction, ion blockade, and voltage-dependent gating--are affected by surface electrostatics. Negative charges increase the affinity of cationic pore blockers by establishing a local negative potential at the pore entrance; these charges modify channel gating by establishing a potential gradient across the ion channel; finally, both effects influence ion permeation through the pore.     

Opening of potassium channels modulates mitochondrial function in rat skeletal muscle

We have investigated the presence of diazoxide- and nicorandil-activated K+ channels in rat skeletal muscle. Activation of potassium transport in the rat skeletal muscle myoblast cell line L6 caused a stimulation of cellular oxygen consumption, implying a mitochondrial effect. Working with isolated rat skeletal muscle mitochondria, both potassium channel openers (KCOs) stimulate respiration, depolarize the mitochondrial inner membrane and lead to oxidation of the mitochondrial NAD-system in a strict potassium-dependent manner. This is a strong indication for KCO-mediated stimulation of potassium transport at the mitochondrial inner membrane. Moreover, the potassium-specific effects of both diazoxide and nicorandil on oxidative phosphorylation in skeletal muscle mitochondria were completely abolished by the antidiabetic sulfonylurea derivative glibenclamide, a well-known inhibitor of ATP-regulated potassium channels (K(ATP) channels). Since both diazoxide and nicorandil facilitated swelling of de-energised mitochondria in KSCN buffer at the same concentrations, our results implicate the presence of a mitochondrial ATP-regulated potassium channel (mitoK(ATP) channel) in rat skeletal muscle which can modulate mitochondrial oxidative phosphorylation.     

Multicopy suppressors of phenotypes resulting from the absence of yeast VDAC encode a VDAC-like protein.

The permeability of the outer mitochondrial membrane to most metabolites is believed to be based in an outer membrane, channel-forming protein known as VDAC (voltage-dependent anion channel). Although multiple isoforms of VDAC have been identified in multicellular organisms, the yeast Saccharomyces cerevisiae has been thought to contain a single VDAC gene, designated POR1. However, cells missing the POR1 gene (delta por1) were able to grow on yeast media containing a nonfermentable carbon source (glycerol) but not on such media at elevated temperature (37 degrees C). If VDAC normally provides the pathway for metabolites to pass through the outer membrane, some other protein(s) must be able to partially substitute for that function. To identify proteins that could functionally substitute for POR1, we have screened a yeast genomic library for genes which, when overexpressed, can correct the growth defect of delta por1 yeast grown on glycerol at 37 degrees C. This screen identified a second yeast VDAC gene, POR2, encoding a protein (YVDAC2) with 49% amino acid sequence identity to the previously identified yeast VDAC protein (YVDAC1). YVDAC2 can functionally complement defects present in delta por1 strains only when it is overexpressed. Deletion of the POR2 gene alone had no detectable phenotype, while yeasts with deletions of both the POR1 and POR2 genes were viable and able to grow on glycerol at 30 degrees C, albeit more slowly than delta por1 single mutants. Like delta por1 single mutants, they could not grow on glycerol at 37 degrees C. Subcellular fractionation studies with antibodies which distinguish YVDAC1 and YVDAC2 indicate that YVDAC2 is normally present in the outer mitochondrial membrane. However, no YVDAC2 channels were detected electrophysiologically in reconstituted systems. Therefore, mitochondrial membranes made from wild-type cells, delta por1 cells, delta por1 delta por2 cells, and delta por1 cells overexpressing YVDAC2 were incorporated into liposomes and the permeability of resulting liposomes to nonelectrolytes of different sizes was determined. The results indicate that YVDAC2 does not confer any additional permeability to these liposomes, suggesting that it may not normally form a channel. In contrast, when the VDAC gene from Drosophila melanogaster was expressed in delta por1 yeast cells, VDAC-like channels could be detected in the mitochondria by both bilayer and liposome techniques, yet the cells failed to grow on glycerol at 37 degrees C. Thus, channel-forming activity does not seem to be either necessary or sufficient to restore growth on nonfermentable carbon sources, indicating that VDAC mediates cellular functions that do not depend on the ability to form channels.     

Involvement of cationic channels in proliferation and migration of human mesenchymal stem cells

Human mesenchymal stem cells (HMSCs) have been applied in various clinic settings. Ion channels play an important role in cellular physiology. However, the potential role of cationic channels in regulating the proliferation and migration properties of hMSCs remains to be determined. In the present study, the functional expression of ion channels in hMSCs was investigated by patch clamp. MTT assay and BrdU stainings were used to assess the proliferation of hMSCs. hMSC migration was evaluated by Transwell migration assays. The results show that sodium-, L-type calcium, potassium currents have been identified in hMSCs. TEA (K⁺ channel blocker), nifedipine (Ca²⁺ channel blocker) can inhibit both proliferation and migration of hMSCs. The increase of extracellular Ca²⁺ concentration promoted both proliferation and migration of hMSCs. TTX, a Na⁺ channel blocker, promoted cell proliferation but inhibited cell migration. Our data suggest that cationic channels (sodium, L-type calcium, potassium channels) play important roles in regulating proliferation and migration of hMSCs.