Activation of a mechanosensitive BK channel by membrane stress created with amphipaths

Some BK channels are activated in response to membrane stretch. However, it remains largely unknown which membrane component transmits forces to the channel and which part of the channel senses the force. Recently, we have shown that a BK channel cloned from chick heart (named SAKCa channel) is a stretch activated channel, while deletion of a 59 amino acids splice insert (STREX) located in the cytoplasmic side, abolishes its stretch-sensitivity. This finding raised a question whether stress in the bilayer is crucial for the mechanical activation of the channel. To address this question we examined the effects of membrane perturbing amphipaths on the stretch activation of the SAKCa channel and its STREX-deletion mutant. We found that both anionic amphipath trinitrophenol (TNP) and cationic amphipath chlorpromazine (CPZ) could dose-dependently activate the channel by leftward shifting the voltage activation curve when applied alone. In contrast, TNP and CPZ compensated each other's effect when applied sequentially. These results can be understood in the framework of the bilayer couple hypothesis, suggesting that stress in the plasma membrane can activate the SAKCa channel. Interestingly, the STREX-deletion mutant channel has much less sensitivity to the amphipaths, suggesting that STREX acts as an intermediate structure that can indirectly convey stress in the membrane to the gate of the SAKCa channel via an unidentified membrane associated protein(s) that can detect or transmit stress in the membrane.     

Killer-toxin-resistantkre12 mutants ofSaccharomyces cerevisiae: genetic and biochemical evidence for a secondary K1 membrane receptor

TheSaccharomyces cerevisiae killer toxin K1 is a secreted α/β-heterodimeric protein toxin that kills sensitive yeast cells in a receptor-mediated two-stage process. The first step involves toxin binding to β-1,6-d-glucan-components of the outer yeast cell surface; this step is blocked in yeast mutants bearing nuclear mutations in any of theKRE genes whose products are involved in synthesis and/or assembly of cell wall β-d-glucans. After binding to the yeast cell wall, the killer toxin is transferred to the cytoplasmic membrane, subsequently leading to cell death by forming lethal ion channels. In an attempt to identify a secondary K1 toxin receptor at the plasma membrane level, we mutagenized sensitive yeast strains and isolated killer-resistant (kre) mutants that were resistant as spheroplasts. Classical yeast genetics and successive back-crossings to sensitive wild-type strain indicated that this toxin resistance is due to mutation(s) in a single chromosomal yeast gene (KRE12), renderingkrel2 mutants incapable of binding significant amounts of toxin to the membrane. Sincekrel2 mutants showed normal toxin binding to the cell wall, but markedly reduced membrane binding, we isolated and purified cytoplasmic membranes from akrel2 mutant and from an isogenicKre12+ strain and analyzed the membrane protein patterns by 2D-electrophoresis using a combination of isoelectric focusing and SDS-PAGE. Using this technique, three different proteins (or subunits of a single multimeric protein) were identified that were present in much lower amounts in thekre12 mutant. A model for K1 killer toxin action is presented in which the gene product ofKRE12 functions in vivo as a K1 docking protein, facilitating toxin binding to the membrane and subsequent ion channel formation.     

Mechanosensitive channel of Thermoplasma, the cell wall-less archaea

By using a functional approach of reconstituting detergent-solubilized membrane proteins into liposomes and following their function in patch-clamp experiments, we identified a novel mechanosensitive (MS) channel in the thermophilic cell wall-less archaeon Thermoplasma volcanium. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of the enriched protein fractions revealed a band of approx 15 kDa comparable to MscL, the bacterial MS channel of large conductance. 20 N-terminal residues determined by protein microsequencing, matched the sequence to an unknown open reading frame in the genome of a related species Thermoplasma acidophilum. The protein encoded by the T. acidophilum gene was cloned and expressed in Escherichia coli and reconstituted into liposomes. When examined for function, the reconstituted protein exhibited properties typical of an MS ion channel: 1) activation by negative pressure applied to the patch-clamp pipet, 2) blockage by gadolinium, and 3) activation by the anionic amphipath trinitrophenol. In analogy to the nomenclature used for bacterial MS channels, the MS channel of T. acidophilum was termed MscTA. Secondary structural analysis indicated that similar to MscL, the T. acidophilum MS protein may have two transmembrane domains, suggesting that MS channels of thermophilic Archaea belong to a family of structurally related MscL-like ion channels with two membrane-spanning regions. When the mscTA gene was expressed in the mscL ⁻ knockout strain and the MscTA protein reconstituted into liposomes, the gating of MscTA was charaterized by very brief openings of variable conductance. In contrast, when the mscTA gene was expressed in the wild-type mscL ⁺ strain of E. coli, the gating properties of the channel resembled MscL. However, the channel had reduced conductance and differed from MscL in its kinetics and in the free energy of activation, suggesting that MscTA and MscL can form functional complexes and/or modulate each other activity. Similar to MscL, MscTA exhibited an increase in activity in liposomes made of phospholipids having shorter acyl chain, suggesting a role of hydrophobic mismatch in the function of prokaryotic MS channels.     

Voltage-independent Adaptation of Mechanosensitive Channels in Escherichia coli Protoplasts

Mechanosensitive (MS) ion channels, with 560 pS conductance, opened transiently by rapid application of suction pulses to patches of E. coli protoplast membrane. The adaptation phase of the response was voltage-independent. Application of strong suction pulses, which were sufficient to cause saturation of the MS current, did not abolish the adaptation. Multiple-pulse experimental protocols revealed that once MS channels had fully adapted, they could be reactivated by a second suction pulse of similar amplitude, providing the time between pulses was long enough and suction had been released between pulses. Limited proteolysis (0.2 mg/ml pronase applied to the cytoplasmic side of the membrane patch) reduced the number of open channels without affecting the adaptation. Exposing patches to higher levels of pronase (1 mg/ml) removed responsiveness of the channel to suction and abolished adaptation consistent with disruption of the tension transmission mechanism responsible for activating the MS channel. Based on these data we discuss a mechanism for mechanosensitivity mediated by a cytoplasmic domain of the MS channel molecule or associated protein. Received: 29 January 1998/Revised: 16 April 1998     

Activation of a mechanosensitive BK channel by membrane stress created with amphipaths

Some BK channels are activated in response to membrane stretch. However, it remains largely unknown which membrane component transmits forces to the channel and which part of the channel senses the force. Recently, we have shown that a BK channel cloned from chick heart (named SAKCa channel) is a stretch activated channel, while deletion of a 59 amino acids splice insert (STREX) located in the cytoplasmic side, abolishes its stretch-sensitivity. This finding raised a question whether stress in the bilayer is crucial for the mechanical activation of the channel. To address this question we examined the effects of membrane perturbing amphipaths on the stretch activation of the SAKCa channel and its STREX-deletion mutant. We found that both anionic amphipath trinitrophenol (TNP) and cationic amphipath chlorpromazine (CPZ) could dose-dependently activate the channel by leftward shifting the voltage activation curve when applied alone. In contrast, TNP and CPZ compensated each other's effect when applied sequentially. These results can be understood in the framework of the bilayer couple hypothesis, suggesting that stress in the plasma membrane can activate the SAKCa channel. Interestingly, the STREX-deletion mutant channel has much less sensitivity to the amphipaths, suggesting that STREX acts as an intermediate structure that can indirectly convey stress in the membrane to the gate of the SAKCa channel via an unidentified membrane associated protein(s) that can detect or transmit stress in the membrane.     

Concentration dependent effect of GsMTx4 on mechanosensitive channels of small conductance in <Emphasis Type="Italic">E. coli</Emphasis> spheroplasts

The spider peptide GsMTx4, at saturating concentration of 5 μM, is an effective and specific inhibitor for stretch-activated mechanosensitive (MS) channels found in a variety of eukaryotic cells. Although the structure of the peptide has been solved, the mode of action remains to be determined. Because of its amphipathic structure, the peptide is proposed to interact with lipids at the boundaries of the MS channel proteins. In addition, GsMTx4 has antimicrobial effects, inhibiting growth of several species of bacteria in the range of 5–64 μM. Previous studies on prokaryotic MS channels, which serve as model systems to explore the principle of MS channel gating, have shown that various amphipathic compounds acting at the protein–lipid interface affect MS channel gating. We have therefore analyzed the effect of different concentrations of extracellular GsMTx4 on MS channels of small conductance, MscS and MscK, in the cytoplasmic membrane of wild-type E. coli spheroplasts using the patch-clamp technique. Our study shows that the peptide GsMTx4 exhibits a biphasic response in which peptide concentration determines inhibition or potentiation of activity in prokaryotic MS channels. At low peptide concentrations of 2 and 4 μM the gating of the prokaryotic MS channels was hampered, manifested by a decrease in pressure sensitivity. In contrast, application of peptide at concentrations of 12 and 20 μM facilitated prokaryotic MS channel opening by increasing the pressure sensitivity.     

Expression of Arabidopsis MCA1 enhanced mechanosensitive channel activity in the Xenopus laevis oocyte plasma membrane

Higher plants sense and respond to osmotic and mechanical stresses such as turgor, touch, flexure and gravity. Mechanosensitive (MS) channels, directly activated by tension in the cell membrane and cytoskeleton, are supposed to be involved in the cell volume regulation under hypotonic conditions and the sensing of these mechanical stresses based on electrophysiological and pharmacological studies. However, limited progress has been achieved in the molecular identification of plant MS channels. Here, we show that MCA1 (mid1-complementing activity 1; a putative mechanosensitive Ca²⁺-permeable channel in Arabidopsis thaliana) increased MS channel activity in the plasma membrane of Xenopus laevis oocytes. The functional and kinetic properties of MCA1 were examined by using a Xenopus laevis oocytes expression system, which showed that MCA1-dependent MS cation currents were activated by hypo-osmotic shock or by membrane stretch produced by pipette suction. Single-channel analyses suggest that MCA1 encodes a possible MS channel with a conductance of 34 pS.     

Reduced transmitter release conferred by mutations in theslowpoke-encoded Ca2+-activated K+ channel gene ofDrosophila

Potassium channels control the repolarization of nerve terminals and thus play important roles in the control of synaptic transmission. Here we describe the effects of mutations in theslowpoke gene, which is the structural gene for a calcium activated potassium channel, on transmitter release at the neuromuscular junction inDrosophila melanogaster. Surprisingly, we find that theslowpoke mutant exhibits reduced transmitter release compared to normal. Similarly, theslowpoke mutation significantly suppresses the increased transmitter release conferred either by a mutation inShaker or by application of 4-aminopyridine, which blocks theShaker-encoded potassium channel at theDrosophila nerve terminal. Furthermore, theslowpoke mutation suppresses the striking increase in transmitter release that occurs following application of 4-aminopyridine to theether a go-go mutant. This suppression is most likely the result of a reduction of Ca²⁺ influx into the nerve terminal in theslowpoke mutant. We hypothesize that the effects of theslowpoke mutation are indirect, perhaps resulting from increased Ca²⁺ channel inactivation, decreased Na⁺ or Ca²⁺ channel localization or gene expression, or by increases in the expression or activity of potassium channels distinct fromslowpoke.     

Pore forming activity of the major outer membrane protein of Rhodobacter capsulatus in lipid bilayer membranes

Porin of the outer membrane of Rhodobacter capsulatus St. Louis (ATCC 23782) was isolated and reconstituted into lipid bilayer membranes. The porin was obtained either by the sodium dodecyl sulfate treatment of cell envelopes (SDS-porin) or by saline extraction of whole cells (NaCl-porin). Nanomolar concentrations of both porin preparations resulted in a strong conductance increase of the lipid bilayer membranes by many orders of magnitude. At small protein concentrations the conductance increased in a stepwise fashion, the average single channel conductance being about 0.35 nS in 0.1 M KCl for SDS-porin and NaCl-porin as well. The single channel conductance was a linear function of the specific conductance of the aqueous phase. The results were consistent with the assumption that the porin formed large water-filled transmembrane channels in the membrane. From the average value of the single channel conductance in 0.1 M KCl an effective channel diameter of about 1.5 nm was estimated for both types of porins.Abbreviations EDTA ethylenediamine tetraacetic acid - SDS sodium dodecyl sulfate     

Ionic channels in the plasma membrane ofSchizosaccharomyces pombe: Evidence from patch-clamp measurements

Patch-clamp studies of the yeastSchizosaccharomyces pombe reveal that the plasma membrane contains a voltage-gated channel mildly selective for potassium over sodium, lithium, and chloride. The channel exhibits several conductances with a maximum of 153 pS. The channel gates in the region of physiologically relevant voltages, being closed at hyperpolarizing and open at depolarizing voltages. It is not inhibited by tetraethylammonium, quinine, or quinidine applied from the cytoplasmic side of the membrane; similarly, ATP and stretch have no effect. The frequency of its occurrence in patches implies that about 35 channels of this kind are present in the plasma membrane of a single cell.     

Membrane maintenance and electrical properties of photoreceptors of wild-type andrpa (receptor potential absent) mutant blowflies (Calliphora erythrocephala)

Summary The maintenance of photoreceptor cell membranes in the blowfly was investigated in relation to the diurnal cycle, age, and therpa (receptor potential absent) phototransduction mutation. The effect of disturbed membrane assembly on the electrical membrane properties was examined using single-electrode discontinuous current-clamp techniques. In wild-type flies the cross-sectional dimensions of the rhabdomeres were markedly reduced with age, and the quantity of synthetic organelles decreased concurrently, whereas no correlation was found between the diurnal cycle and membrane turnover. Therpa mutation is thought to block the visual transduction cascade in photoreceptor cells and to lead to degeneration of the photoreceptor cell bodies. The volume of rhabdomeres decreased markedly inrpa mutants and the quantity of synthetic organelles was reduced significantly, indicating an imbalance between photoreceptive membrane renewal and degradation. Also, the plasma membrane underwent degenerative changes. The passive electrical properties of photoreceptor cells — resting membrane voltages and input resistances — were only slightly changed from those of wild-type flies, although the photoreceptive membrane did not depolarize in response to light. This indicates no apparent disturbance in the function of the ionic channels in these membranes. Taken together, these results suggest that the photoreceptor cells need a functional phototransduction cascade with its feedback controls to maintain continuous renewal of rhabdomeres, but that the plasma membrane maintains its normal electrochemical properties despite extreme morphological degeneration of photoreceptor cell.     

Basolateral membrane K permselectivity and regulation in bullfrog cornea epithelium

Summary Ion channels permeable to barium and calcium were reconstituted from theAplysia nervous system into phospholipid bilayers formed on the tips of patch electrodes. With asymmetrical concentrations of barium or calcium on the two sides of the bilayer, the single-channel currents reversed at the calculated barium or calcium reversal potentials, indicating that the channels were cation selective. Channels with conductances of 10, 25 and 36 pS were routinely observed. Calcium and barium were equally effective as charge carriers for the 36-pS channel, whereas magnesium was at least fifteenfold less effective. The gating of all three channels was independent of the voltage across the bilayer, but was affected by the dihydropyridine calcium channel agonist Bay K 8644 (Bay K). In the presence of Bay K but not in its absence, long discrete gating events were routinely observed, suggesting that the dihydropyridine increased the probability of long open states as it does for calcium channels in other systems.Bilayers invariably contained more than a single channel (or conductance state). This was observed even when theAplysia nervous system membranes were prepared in the presence of cytoskeleton disrupting agents, or when the membrane proteins were diluted extensively with exogenous phospholipid. Furthermore, transitions between conductance levels were observed with high frequency. These findings, together with the fact that all of the conductance states share certain properties including voltage-independence and sensitivity to Bay K, suggest that the apparent multiple channel types may in fact represent subconductance states of a single ion channel.     

The fatty acid constitution and ordering state of membranes in dominant temperature-sensitive lethal mutation and wild-typeDrosophila melanogaster larvae

The ordering state and changes in fatty acid composition of microsomal (MS) and mitochondrial (MC) membranes of two dominant temperature-sensitive (DTS) lethal mutations and the wild-type Oregon-R strain larvae ofDrosophila melanogaster have been studied at 18 and 29°C and after temperature-shift experiments. The membranes of wild-type larvae have a stable ordering state, with “S” values between 0.6 (18°C) and 0.5 (29°C) in both membranes which remained unchanged in shift experiments, although the ratios of saturated/unsaturated fatty acids were changed as expected. The stronglyDTS mutation1(2)10 ^DTS forms very rigid membranes at the restrictive temperature (29°C) which cannot be normalized after shift down, while shift up or development at the permissive temperature results in normal ordering state. This mutant is less able to adjust MS and MC fatty acid composition in response to the growth temperature than the wild type. The less temperature-sensitive1(2)2 ^DTS allele occupies an intermediate state between Oregon-R and1(2)10 ^DTS in both respects. We assume and the genetical data suggest that the DTS mutant gene product is in competition with the wild-type product, resulting in a membrane structure which is not able to accommodate to the restrictive temperature.     

Functional reconstitution of ion channels from Paramecium cortex into artificial liposomes

Toward isolating channel proteins from Paramecium, we have explored the possibility of functionally reconstituting ion channels in an artificial system. Proteins from Paramecium cortex reconstituted with soybean azolectin retained several channels whose activities were readily registered under patch clamp. The most commonly encountered activities were three: (i) a 71-pS cation channel that opens at all voltages unless dior trivalent cations were added to close them, (ii) a 40 pS monovalent cation channel, and (iii) a large-conductance channel that prefers anions and exhibits many subconductance states. These channels survived mild detergent treatments without observable functional alterations. The possible origin of these channels from internal membranes, the possible role of 71-pS channel in internal Ca²⁺ release, and the prospects of their purification are discussed.This work was supported by National Institutes of Health GM 26286 and GM 22714.     

Cell swelling activates K+ and Cl− channels as well as nonselective,stretch-activated cation channels in ehrlich ascites tumor cells

Summary Cell-attached patch-clamp recordings from Ehrlich ascites tumor cells reveal nonselective cation channels which are activated by mechanical deformation of the membrane. These channels are seen when suction is applied to the patch pipette or after osmotic cell swelling. The channel activation does not occur instantaneously but within a time delay of 1/2 to 1 min. The channel is permeable to Ba²⁺ and hence presumably to Ca²⁺. It seems likely that the function of the nonselective, stretch-activated channels is correlated with their inferred Ca²⁺ permeability, as part of the volume-activated signal system. In isolated insideout patches a Ca²⁺-dependent, inwardly rectifying K⁺ channel is demonstrated. The single-channel conductance recorded with symmetrical 150 mm K⁺ solutions is for inward current estimated at 40 pS and for outward current at 15 pS. Activation of the K⁺ channel takes place after an increase in Ca²⁺ from 10^–7 to 10^–6 m which is in the physiological range. Patch-clamp studies in cellattached mode show K⁺ channels with spontaneous activity and with characteristics similar to those of the K⁺ channel seen in excised patches. The single-channel conductance for outward current at 5 mm external K⁺ is estimated at about 7 pS. A K⁺ channel with similar properties can be activated in the cellattached mode by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by cell swelling, within 1 min following hypotonic exposure. No evidence was found of channel activation by membrane stretch (suction). The time-averaged number of open K⁺ channels during regulatory volume decrease (RVD) can be estimated at 40 per cell. The number of open K⁺ channels following addition of Ca²⁺ plus ionophore A23187 was estimated at 250 per cell. Concurrent activation in cell-attached patches of stretch-activated, nonselective cation channels and K⁺ channels in the presence of 3 mm Ca²⁺ in the pipette suggests a close spatial relationship between the two channels. In excised inside-out patches (with NMDG chloride on both sides) a small 5-pS chloride channel with low spontaneous activity is observed. The channel activity was not dependent on Ca²⁺ and could not be activated by membrane stretch (suction). In cell-attached mode singlechannel currents with characteristics similar to the channels seen in isolated patches are seen. In contrast to the channels seen in isolated patches, the channels in the cell-attached mode could be activated by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by hypotonic exposure with a single-channel conductance at 7 pS (or less) and with a time delay at about 1 min. The number of open channels during RVD is estimated at 80 per cell. Two other types of Cl^– channels were regularly recorded in excised inside-out patches: a voltage-activated 400-pS channel and a 34-pS Cl^– channel which show properties similar to the Cl^– channel in the apical membrane in human airway epithelial cells. There is no evidence for a role in RVD for either of these two channels.     

Wild-type and Brachyolmia-causing Mutant TRPV4 Channels Respond Directly to Stretch Force

Whether animal ion channels functioning as mechanosensors are directly activated by stretch force or indirectly by ligands produced by the stretch is a crucial question. TRPV4, a key molecular model, can be activated by hypotonicity, but the mechanism of activation is unclear. One model has this channel being activated by a downstream product of phospholipase A₂, relegating mechanosensitivity to the enzymes or their regulators. We expressed rat TRPV4 in Xenopus oocytes and repeatedly examined >200 excised patches bathed in a simple buffer. We found that TRPV4 can be activated by tens of mm Hg pipette suctions with open probability rising with suction even in the presence of relevant enzyme inhibitors. Mechanosensitivity of TRPV4 provides the simplest explanation of its various force-related physiological roles, one of which is in the sensing of weight load during bone development. Gain-of-function mutants cause heritable skeletal dysplasias in human. We therefore examined the brachyolmia-causing R616Q gain-of-function channel and found increased whole-cell current densities compared with wild-type channels. Single-channel analysis revealed that R616Q channels maintain mechanosensitivity but have greater constitutive activity and no change in unitary conductance or rectification.     

Immunocytological evidence for abnormal symbiosome development in nodules of the pea mutant line Sprint2Fix− (sym31)

Summary Using a series of antibody probes as markers of symbiosome development, we have investigated the impaired development of symbiosomes in nodules formed by the plant mutant line Sprint2Fix⁻ (sym31). In wild-type pea (Pisum sativum L.) nodules, bacteria differentiate into large pleiomorphic, nitrogen-fixing bacteroids and are singly enclosed within a peribacteroid membrane. In thesym31 mutant, several small undifferentiated bacteroids were often enclosed within one peribacteroid membrane, or were found within a vacuole-like compartment. In wild-type nodules, the monoclonal antibody JIM18, which recognizes a plasmalemma glycolipid antigen, bound to the juvenile peribacteroid membrane, and did not recognize the mature peribacteroid membrane. However, in the mutant, the antibody bound to all peribacteroid membranes within the nodule, suggesting that differentiation of the peribacteroid membrane was arrested. Another antibody, MAC266, recognized plant glycoproteins which normally accumulate in symbiosomes at a late stage of nodule development. Binding of this antibody was much reduced within mutant nodules, labelling only a few mature cells. Similarly, MAC301, which normally recognizes a lipopolysaccharide epitope expressed on differentiated bacteroids prior to the induction of nitrogenase, failed to react with rhizobial cell extracts isolated from nodules of thesym31 mutant. On the basis of these developmental markers, the symbiosomes ofsym31 nodules appeared to be blocked at an early stage of development. The distribution of infection structures was also found to be abnormal in the mutant nodules. Models of symbiosome development are presented and discussed in relation to the morphological and developmental lesions observed in thesym31 mutant.     

The mitochondrial voltage-dependent channel,VDAC, is modified asymmetrically by succinic anhydride

Summary In the accompanying paper, succinic anhydride was shown to react with the outer mitochondrial membrane channel-forming protein, VDAC, resulting in the loss of its voltage dependence. In this paper, the anhydride was added to VDAC held in a particular conformational state by means of an applied electric field. VDAC was inserted into the membranes from thecis side and the anhydride was added either to thecis ortrans side. Channels modified in the open state behaved similarly whether anhydride was added to thecis ortrans side. Modifications of VDAC in either of the two closed states did not. Modifications resulting in the loss of voltage-dependence occurred primarily when anhydride was added to the negative side of the membrane irrespective of which closed state the VDAC was in indicating that the accessibility of the gating charges alternated between thecis andtrans sides as the channel's conformation was changed from one closed state to the other. Despite the pronounced asymmetry, in general the resulting channels behaved in the same way in response to either positive or negative fields. A model consistent with the results is presented which proposes that the same gating charges are responsible for channel closure at both positive and negative fields.     

Stretch activated ion channels in ventricular myocytes

Patch-clamp recordings from ventricular myocytes of neonatal rats identified ionic channels that open in response to membrane stretch caused by negative pressures (1 to 6 cm Hg) in the electrode. The stretch response, consisting of markedly increased channel opening frequency, was maintained, with some variability, during long (>40 seconds) stretch applications. The channels have a conductance averaging 120 pS in isotonic KCl, have a mean reversal potential 31 mV depolarized from resting membrane potential, and do not require external Ca⁺⁺ for activation. The channels appear to be relatively non-selective for cations. Since they are gated by physiological levels of tension, stretch-activated channels may represent, a cellular control system wherein beat-to-beat tension and/or osmotic balance modulate a portion of membrane conductance.Abbreviations SACs stretch-activated channels - HEPES 4-(2-hydroxyethyl)-1-piperazine-ethanesulfonic acid     

Stilbene derivatives inhibit the activity of the inner mitochondrial membrane chloride channels

Ion channels selective for chloride ions are present in all biological membranes, where they regulate the cell volume or membrane potential. Various chloride channels from mitochondrial membranes have been described in recent years. The aim of our study was to characterize the effect of stilbene derivatives on single-chloride channel activity in the inner mitochondrial membrane. The measurements were performed after the reconstitution into a planar lipid bilayer of the inner mitochondrial membranes from rat skeletal muscle (SMM), rat brain (BM) and heart (HM) mitochondria. After incorporation in a symmetric 450/450 mM KCl solution (cis/trans), the chloride channels were recorded with a mean conductance of 155 ± 5 pS (rat skeletal muscle) and 120 ± 16 pS (rat brain). The conductances of the chloride channels from the rat heart mitochondria in 250/50 mM KCl (cis/trans) gradient solutions were within the 70–130 pS range. The chloride channels were inhibited by these two stilbene derivatives: 4,4′-diisothiocyanostilbene-2,2′-disulfonic acid (DIDS) and 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid (SITS). The skeletal muscle mitochondrial chloride channel was blocked after the addition of 1 mM DIDS or SITS, whereas the brain mitochondrial channel was blocked by 300 μM DIDS or SITS. The chloride channel from the rat heart mitochondria was inhibited by 50–100 μM DIDS. The inhibitory effect of DIDS was irreversible. Our results confirm the presence of chloride channels sensitive to stilbene derivatives in the inner mitochondrial membrane from rat skeletal muscle, brain and heart cells.