Modulation of inner mitochondrial membrane channel activity

Three classes of inner mitochondrial membrane (IMM) channel activities have been defined by direct measurement of conductance levels in membranes with patch clamp techniques in 150 mM K Cl. The 107 pS activity is slightly anion selective and voltage dependent (open with matrix positive potentials). Multiple conductance channel (MCC) activity includes several levels from about 40 to over 1000 pS and can be activated by voltage or Ca²⁺. MCC may be responsible for the Ca²⁺-induced permeability transition observed with mitochondrial suspensions. A low conductance channel (LCC) is activated by alkaline pH and inhibited by Mg²⁺. LCC has a unit conductance of about 15 pS and may correspond to the inner membrane anion channel, IMAC, which was proposed from results obtained from suspension studies. All of the IMM channels defined thus far appear to be highly regulated and have a low open probability under physiological conditions. A summary of what is known about IMM channel regulation and pharmacology is presented and possible physiological roles of these channels are discussed.     

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.     

Calcium modulation of mitochondrial inner membrane channel activity.

Protocols were defined that enable patch-clamp studies of the approximately 107 pS voltage dependent channel and a class of activity we refer to as MCC (multiconductance channel) which is characterized by multiple levels and transitions as high as 1 to 1.5 nS. If free calcium was kept at 10(-7) M or lower during mitochondrial isolation, no activity was observed at low voltage (+/- 60 mV). If free calcium levels were higher, MCC activity was observed in about 96% of the patches. The observation of approximately 107 pS channel was enhanced from 2% to 68% of patches by washing isolated mitoplasts (mitochondria stripped of outer membrane) with EGTA. Increasing matrix calcium from 10(-9) to 10(-5) M decreased the probability of opening for the MCC and approximately 107 pS activities.     

Electrophysiology of the inner mitochondrial membrane

The application of electrophysiological techniques to mitochondrial membranes has allowed the observation and partial characterization of several ion channels, including an ATP-sensitive K⁺-selective one, a high-conductance megachannel, a 107 pS anionic channel and three others studied at alkaline pH's. A reliable correlation with the results of non-electrophysiological studies has been obtained so far only for the first two cases. Activities presumed to be associated with the Ca²⁺ uniporter and with the adenine nucleotide translocator, as well as the presence of various other conductances have also been reported. The review summarizes the main properties of these pores and their possible relationship to permeation pathways identified in biochemical studies.     

Bilirubin increases mitochondrial inner membrane conductance

Bilirubin accumulates within, and induces loose coupling in, rat liver mitochondria. This state, characterized by a normal protonmotive force, but increased oxygen consumption and inner membrane conductance, could impair cellular energy metabolism. Loose coupling is observed at bilirubin concentrations (12-24 microM) attained in tissues of kernicteric animals.     

Dicarboxylate transport in the inner membrane matrix fraction obtained from rat liver mitochondria

Dicarboxylate transport was studied in the inner membrane matrix fraction (mitoplasts) and compared to that in intact rat-liver mitochondria from which the former was obtained.It is concluded that, kinetics of dicarboxylate exchange measured in mitoplasts, are very similar to those observed with mitochondria. These results would indicate that the preparation technique preserves the integrity of the inner membrane and that neither the outer membrane nor the components of the peripheral space affect these results.     

Triorganotins inhibit the mitochondrial inner membrane anion channel.

The inner membrane of liver and heart mitochondria possesses an anion uniport pathway, known as the inner membrane anion channel (IMAC). IMAC is inhibited by matrix Mg2+, matrix H+, N,N'-dicyclohexycarbodiimide, mercurials and amphiphilic amines such as propranolol. Most of these agents react with a number of different mitochondrial proteins and, therefore, more selective inhibitors have been sought. In this paper, we report the discovery of a new class of inhibitors, triorganotin compounds, which block IMAC completely. One of the most potent, tributyltin (TBT) inhibits malonate uniport via IMAC 95% at 0.9 nmol/mg. The only other mitochondrial protein reported to react with triorganotins, the F1F0ATPase, is inhibited by about 0.75 nmol/mg. The potency of inhibition of IMAC increases with hydrophobicity in the sequence trimethyltin much less than triethyltin much less than tripropyltin less than triphenyltin less than tributyltin; which suggests that the binding site is accessible from the lipid bilayer. It has long been established that triorganotins are anionophores able to catalyze Cl-/OH- exchange; however, TBT is able to inhibit Cl- and NO3- transport via IMAC at doses below those required to catalyze rapid rates of Cl-/OH- exchange. Consistent with previous reports, the data indicate that about 0.8 nmol of TBT per mg of mitochondrial protein is tightly bound and not available to mediate Cl-/OH- exchange. We have also shown that the mercurials, p-chloromercuribenzene sulfonate and mersalyl, which only partially inhibit Cl- and NO3- transport can increase the IC50 for TBT 10-fold. This effect appears to result from a reaction at a previously unidentified mercurial reactive site. The inhibitory dose is also increased by raising the pH and inhibition by TBT can be reversed by S2- and dithiols but not by monothiols.     

BK通道的生物物理特性与门控及其最新研究进展

BK_(Ca)通道是细胞膜上受Ca~(2+)和膜电位双重调控的离子通道,其与细胞信号系统偶联并发挥着重要作用,该通道高度表达于高等动物的多种组织.最近的研究证实,在心肌细胞膜上存在力敏感BK通道并参与了心脏收缩与舒张的调控.本文将介绍BK通道与L-型钙通道功能上的耦合,心肌细胞质膜力敏感BK通道门控和功能的研究,以及对基底刚度的响应.这有助于更好地理解力敏感离子通道相关心脏疾病的病理和生理学基础.     

Importance of the mitochondrial outer membrane channel as a model biological channel

The channels of the mitochondrial outer membrane represent a useful model for studies into the mechanisms underlying phenomena of voltage-dependent gating and ion selectivity.     

Voltage activation of heart inner mitochondrial membrane channels

The patch clamp records obtained from mitoplast membranes prepared in the presence of a calcium chelator generally lack channel activity. However, multiconductance channel (MCC) activity can be induced by membrane potentials above ±60mV [Kinnallyet al., Biochem. Biophys. Res. Commun. 176, 1183–1188 (1991)]. Once activated, the MCC activity persists at all voltages. The present report characterizes the activation by voltage of multiconductance channels of rat heart inner mitochondrial membranes using patch-clamping. In some membrane patches, the size of single current transitions progressively increases with time upon application of voltage. The inhibitor cyclosporin has also been found to decrease channel conductance in steps. The results suggest that voltage-induced effects which are inhibited by cyclosporin Aare likely to involve either an increase in effective pore diameter or the assembly of low-conductance units. In activated patches, we have found at high membrane potentials (e.g., 130 mV) changes in conductance as high as 5 nS occurring in large steps (up to 2.7 nS). These were generally preceded by a smaller transition. Similar results were obtained less frequently at lower voltages. These results can be explained on the assumption that once assembled the channels may act in unison.     

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.     

The effect of antimycin A on mouse liver inner mitochondrial membrane channel activity.

In a patch-clamp study, we found antimycin A in low (1-2) microM concentrations decreased the open probability of the multiple conductance channel activity and the approximately 110 picosiemens channel of the inner mitochondrial membrane (for a review of mitochondrial channels see Kinnally, K. W., Antonenko, Yu. N., and Zorov, D. B. (1992) J. Bioenerg. Biomembr. 24, 99-110). Higher antimycin A concentrations (e.g. 10 microM) facilitated multiple conductance channel opening. These effects were reversible, and the binding site(s) are probably distinct from those responsible for the inhibition of the electron transport chain, since the latter are virtually irreversible. A model with two closed and two open states is presented for the approximately 110-picosiemens activity.     

Divalent cation sensitivity of BK channel activation supports the existence of three distinct binding sites

Mutational analyses have suggested that BK channels are regulated by three distinct divalent cation-dependent regulatory mechanisms arising from the cytosolic COOH terminus of the pore-forming alpha subunit. Two mechanisms account for physiological regulation of BK channels by microM Ca2+. The third may mediate physiological regulation by mM Mg2+. Mutation of five aspartate residues (5D5N) within the so-called Ca2+ bowl removes a portion of a higher affinity Ca2+ dependence, while mutation of D362A/D367A in the first RCK domain also removes some higher affinity Ca2+ dependence. Together, 5D5N and D362A/D367A remove all effects of Ca2+ up through 1 mM while E399A removes a portion of low affinity regulation by Ca2+/Mg2+. If each proposed regulatory effect involves a distinct divalent cation binding site, the divalent cation selectivity of the actual site that defines each mechanism might differ. By examination of the ability of various divalent cations to activate currents in constructs with mutationally altered regulatory mechanisms, here we show that each putative regulatory mechanism exhibits a unique sensitivity to divalent cations. Regulation mediated by the Ca2+ bowl can be activated by Ca2+ and Sr2+, while regulation defined by D362/D367 can be activated by Ca2+, Sr2+, and Cd2+. Mn2+, Co2+, and Ni2+ produce little observable effect through the high affinity regulatory mechanisms, while all six divalent cations enhance activation through the low affinity mechanism defined by residue E399. Furthermore, each type of mutation affects kinetic properties of BK channels in distinct ways. The Ca2+ bowl mainly accelerates activation of BK channels at low [Ca2+], while the D362/D367-related high affinity site influences both activation and deactivation over the range of 10-300 microM Ca2+. The major kinetic effect of the E399-related low affinity mechanism is to slow deactivation at mM Mg2+ or Ca2+. The results support the view that three distinct divalent-cation binding sites mediate regulation of BK channels.     

The mitochondrial inner membrane anion channel is inhibited by DIDS

The mitochondrial inner membrane anion channel (IMAC) is a channel, identified by flux studies in intact mitochondria, which has a broad anion selectivity and is maintained closed or inactive by matrix Mg²⁺ and H⁺. We now present evidence that this channel, like many other chloride/anion channels, is reversibly blocked/inhibited by stilbene-2,2-disulfonates. Inhibition of malonate transport approaches 100% with IC₅₀ values of 26, 44, and 88 M for DIDS, H₂-DIDS, and SITS respectively and Hill coefficients 1. In contrast, inhibition of Cl^– transport is incomplete, reaching a maximum of about 30% at pH 7.4 and 65% at pH 8.4 with an IC₅₀ which is severalfold higher than that for malonate. The IC₅₀ for malonate transport is decreased about 50% by pretreatment of the mitochondria withN-ethylmaleimide. Raising the assay pH from 7.4 to 8.4 increases the IC₅₀ by about 50%, but under conditions where only the matrix pH is made alkaline the IC₅₀ is decreased slightly. These properties and competition studies suggest that DIDS inhibits by binding to the same site as Cibacron blue 3GA. In contrast, DIDS does not appear to compete with the fluorescein derivative Erythrosin B for inhibition. These findings not only provide further evidence that IMAC may be more closely related to other Cl^– channels than previously thought, but also suggest that other Cl^– channels may be sensitive to some of the many regulators of IMAC which have been identified.     

Differential effects of beta 1 and beta 2 subunits on BK channel activity

High conductance, calcium- and voltage-activated potassium (BK) channels are widely expressed in mammals. In some tissues, the biophysical properties of BK channels are highly affected by coexpression of regulatory (beta) subunits. beta1 and beta2 subunits increase apparent channel calcium sensitivity. The beta1 subunit also decreases the voltage sensitivity of the channel and the beta2 subunit produces an N-type inactivation of BK currents. We further characterized the effects of the beta1 and beta2 subunits on the calcium and voltage sensitivity of the channel, analyzing the data in the context of an allosteric model for BK channel activation by calcium and voltage (Horrigan and Aldrich, 2002). In this study, we used a beta2 subunit without its N-type inactivation domain (beta2IR). The results indicate that the beta2IR subunit, like the beta1 subunit, has a small effect on the calcium binding affinity of the channel. Unlike the beta1 subunit, the beta2IR subunit also has no effect on the voltage sensitivity of the channel. The limiting voltage dependence for steady-state channel activation, unrelated to voltage sensor movements, is unaffected by any of the studied beta subunits. The same is observed for the limiting voltage dependence of the deactivation time constant. Thus, the beta1 subunit must affect the voltage sensitivity by altering the function of the voltage sensors of the channel. Both beta subunits reduce the intrinsic equilibrium constant for channel opening (L0). In the allosteric activation model, the reduction of the voltage dependence for the activation of the voltage sensors accounts for most of the macroscopic steady-state effects of the beta1 subunit, including the increase of the apparent calcium sensitivity of the BK channel. All allosteric coupling factors need to be increased in order to explain the observed effects when the alpha subunit is coexpressed with the beta2IR subunit.     

A BK (Slo1) channel journey from molecule to physiology

Calcium and voltage-activated potassium (BK) channels are key actors in cell physiology, both in neuronal and non-neuronal cells and tissues. Through negative feedback between intracellular Ca²⁺ and membrane voltage, BK channels provide a damping mechanism for excitatory signals. Molecular modulation of these channels by alternative splicing, auxiliary subunits and post-translational modifications showed that these channels are subjected to many mechanisms that add diversity to the BK channel α subunit gene. This complexity of interactions modulates BK channel gating, modifying the energetic barrier of voltage sensor domain activation and channel opening. Regions for voltage as well as Ca²⁺ sensitivity have been identified, and the crystal structure generated by the 2 RCK domains contained in the C-terminal of the channel has been described. The linkage of these channels to many intracellular metabolites and pathways, as well as their modulation by extracellular natural agents, has been found to be relevant in many physiological processes. This review includes the hallmarks of BK channel biophysics and its physiological impact on specific cells and tissues, highlighting its relationship with auxiliary subunit expression.     

运动对大鼠血管平滑肌大电导钾通道生物物理特性的影响

对大鼠进行不同强度的游泳训练以建立动物模型,应用膜片钳技术分析训练1～4周以及对照组的大鼠血管平滑肌细胞大电导钾通道(BK通道)的门控．实验结果显示,BK通道的开放概率在游泳训练第2、3周时明显升高,到第4周趋于稳定;游泳训练后,通道对膜电位、胞内钙离子的敏感性显著增加,通道的平均开放时间常数增大,关闭时间常数减小．实验结果还显示,由游泳训练导致的被动牵张并不改变通道的电导．BK通道在被动牵张力作用下生物物理特性的变化,可能有缓解由于游泳训练而导致血压升高的作用,进而使机体保持正常的生理状态．     

Prooxidants open both the mitochondrial permeability transition pore and a low-conductance channel in the inner mitochondrial membrane

Mitochondria can be induced by a variety of agents/conditions to undergo a permeability transition (MPT), which nonselectively increases the permeability of the inner membrane (i.m.) to small (<1500 Da) solutes. Prooxidants are generally considered to trigger the MPT, but some investigators suggest instead that prooxidants open a Ca(2+)-selective channel in the inner mitochondrial membrane and that the opening of this channel, when coupled with Ca(2+) cycling mediated by the Ca(2+) uniporter, leads ultimately to the observed increase in mitochondrial permeability [see, e.g., Schlegel et al. (1992) Biochem. J. 285, 65]. S. A. Novgorodov and T. I. Gudz [J. Bioenerg. Biomembr. (1996) 28, 139] propose that the i.m. contains a pore that, upon exposure to prooxidants, can open to two states, one of which conducts only H(+) and one of which is the classic MPT pore. Given the current interest in increased mitochondrial permeability as a factor in apoptotic cell death, it is important to determine whether i.m. permeability is regulated in one or multiple ways and, in the latter event, to characterize each regulatory mechanism in detail. This study examined the effects of the prooxidants diamide and t-butylhydroperoxide (t-BuOOH) on the permeability of isolated rat liver mitochondria. Under the experimental conditions used, t-BuOOH induced mitochondrial swelling only in the presence of exogenous Ca(2+) (>2 microM), whereas diamide was effective in its absence. In the absence of exogenous inorganic phosphate (P(i)), (1) both prooxidants caused a collapse of the membrane potential (DeltaPsi) that preceded the onset of mitochondrial swelling; (2) cyclosporin A eliminated the swelling induced by diamide and dramatically slowed that elicited by t-BuOOH, without altering prooxidant-induced depolarization; (3) collapse of DeltaPsi was associated with Ca(2+) efflux but not with efflux of glutathione; (4) neither Ca(2+) efflux nor DeltaPsi collapse was sensitive to ruthenium red; (5) collapse of DeltaPsi was accompanied by an increase in matrix pH; no stimulation of respiration was observed; (6) Sr(2+) was able to substitute for Ca(2+) in supporting t-BuOOH-induced i.m. depolarization, but not swelling; (7) in addition to being insensitive to CsA, the collapse of DeltaPsi was also resistant to trifluoperazine, spermine, and Mg(2+), all of which block the MPT; and (8) DeltaPsi was restored (and its collapse was inhibited) upon addition of dithiothreitol, ADP, ATP or EGTA. We suggest that these results indicate that prooxidants open two channels in the i.m.: the classic MPT and a low-conductance channel with clearly distinct properties. Opening of the low-conductance channel requires sulfhydryl group oxidation and the presence of a divalent cation; both Ca(2+) and Sr(2+) are effective. The channel permits the passage of cations, including Ca(2+), but not of protons. It is insensitive to inhibitors of the classic MPT.