Osmotic swelling of heart mitochondria in acetate and chloride salts. Evidence for two pathways for cation uptake

A transmitochondrial sodium gradient controls membrane potential in mammalian mitochondria

Eukaryotic cell function and survival rely on the use of a mitochondrial H+ electrochemical gradient (Δp), which is composed of an inner mitochondrial membrane (IMM) potential (ΔΨmt) and a pH gradient (ΔpH). So far, ΔΨmt has been assumed to be composed exclusively of H+. Here, using a rainbow of mitochondrial and nuclear genetic models, we have discovered that a Na+ gradient equates with the H+ gradient and controls half of ΔΨmt in coupled-respiring mammalian mitochondria. This parallelism is controlled by the activity of the long-sought Na+-specific Na+/H+ exchanger (mNHE), which we have identified as the P-module of complex I (CI). Deregulation of this mNHE function, without affecting the canonical enzymatic activity or the assembly of CI, occurs in Leber's hereditary optic neuropathy (LHON), which has profound consequences in ΔΨmt and mitochondrial Ca2+ homeostasis and explains the previously unknown molecular pathogenesis of this neurodegenerative disease.

MICU1 occludes the mitochondrial calcium uniporter in divalent-free conditions

Mitochondrial Ca2+ uptake is mediated by the mitochondrial uniporter complex (mtCU) that includes a tetramer of the pore-forming subunit, MCU, a scaffold protein, EMRE, and the EF-hand regulatory subunit, MICU1 either homodimerized or heterodimerized with MICU2/3. MICU1 has been proposed to regulate Ca2+ uptake via the mtCU by physically occluding the pore and preventing Ca2+ flux at resting cytoplasmic [Ca2+] (free calcium concentration) and to increase Ca2+ flux at high [Ca2+] due to cooperative activation of MICUs EF-hands. However, mtCU and MICU1 functioning when its EF-hands are unoccupied by Ca2+ is poorly studied due to technical limitations. To overcome this barrier, we have studied the mtCU in divalent-free conditions by assessing the Ru265-sensitive Na+ influx using fluorescence-based measurement of mitochondrial matrix [Na+] (free sodium concentration) rise and the ensuing depolarization and swelling. We show an increase in all these measures of Na+ uptake in MICU1KO cells as compared to wild-type (WT) and rescued MICU1KO HEK cells. However, mitochondria in WT cells and MICU1 stable-rescued cells still allowed some Ru265-sensitive Na+ influx that was prevented by MICU1 in excess upon acute overexpression. Thus, MICU1 restricts the cation flux across the mtCU in the absence of Ca2+, but even in cells with high endogenous MICU1 expression such as HEK, some mtCU seem to lack MICU1-dependent gating. We also show rearrangement of the mtCU and altered number of functional channels in MICU1KO and different rescues, and loss of MICU1 during mitoplast preparation, that together might have obscured the pore-blocking function of MICU1 in divalent-free conditions in previous studies.

Mitochondrial osmoregulation in evolution, cation transport and metabolism

This review provides a retrospective on the role of osmotic regulation in the process of eukaryogenesis. Specifically, it focuses on the adjustments which must have been made by the original colonizing α-proteobacteria that led to the evolution of modern mitochondria. We focus on the cations that are fundamentally involved in volume determination and cellular metabolism and define the transporter landscape in relation to these ions in mitochondria as we know today. We provide analysis on how the cations interplay and together maintain osmotic balance that allows for effective ATP synthesis in the organelle.

The deactive form of respiratory complex I from mammalian mitochondria is a Na+/H+ antiporter

In mitochondria, complex I (NADH:ubiquinone oxidoreductase) uses the redox potential energy from NADH oxidation by ubiquinone to transport protons across the inner membrane, contributing to the proton-motive force. However, in some prokaryotes, complex I may transport sodium ions instead, and three subunits in the membrane domain of complex I are closely related to subunits from the Mrp family of Na(+)/H(+) antiporters. Here, we define the relationship between complex I from Bos taurus heart mitochondria, a close model for the human enzyme, and sodium ion transport across the mitochondrial inner membrane. In accord with current consensus, we exclude the possibility of redox-coupled Na(+) transport by B. taurus complex I. Instead, we show that the "deactive" form of complex I, which is formed spontaneously when enzyme turnover is precluded by lack of substrates, is a Na(+)/H(+) antiporter. The antiporter activity is abolished upon reactivation by the addition of substrates and by the complex I inhibitor rotenone. It is specific for Na(+) over K(+), and it is not exhibited by complex I from the yeast Yarrowia lipolytica, which thus has a less extensive deactive transition. We propose that the functional connection between the redox and transporter modules of complex I is broken in the deactive state, allowing the transport module to assert its independent properties. The deactive state of complex I is formed during hypoxia, when respiratory chain turnover is slowed, and may contribute to determining the outcome of ischemia-reperfusion injury.

Energetic performance is improved by specific activation of K+ fluxes through K(Ca) channels in heart mitochondria

Mitochondrial volume regulation depends on K+ movement across the inner membrane and a mitochondrial Ca2+-dependent K+ channel (mitoK(Ca)) reportedly contributes to mitochondrial K+ uniporter activity. Here we utilize a novel K(Ca) channel activator, NS11021, to examine the role of mitoK(Ca) in regulating mitochondrial function by measuring K+ flux, membrane potential (DeltaPsi(m)), light scattering, and respiration in guinea pig heart mitochondria. K+ uptake and the influence of anions were assessed in mitochondria loaded with the K+ sensor PBFI by adding either the chloride (KCl), acetate (KAc), or phosphate (KH2PO4) salts of K+ to energized mitochondria in a sucrose-based medium. K+ fluxes saturated at approximately 10 mM for each salt, attaining maximal rates of 172+/-17, 54+/-2.4, and 33+/-3.8 nmol K+/min/mg in KCl, KAc, or KH2PO4, respectively. NS11021 (50 nM) increased the maximal K+ uptake rate by 2.5-fold in the presence of KH2PO4 or KAc and increased mitochondrial volume, with little effect on DeltaPsi(m). In KCl, NS11021 increased K+ uptake by only 30% and did not increase volume. The effects of NS11021 on K+ uptake were inhibited by the K(Ca) toxins charybdotoxin (200 nM) or paxilline (1 microM). Fifty nanomolar of NS11021 increased the mitochondrial respiratory control ratio (RCR) in KH2PO4, but not in KCl; however, above 1 microM, NS11021 decreased RCR and depolarized DeltaPsi(m). A control compound lacking K(Ca) activator properties did not increase K+ uptake or volume but had similar nonspecific (toxin-insensitive) effects at high concentrations. The results indicate that activating K+ flux through mitoK(Ca) mediates a beneficial effect on energetics that depends on mitochondrial swelling with maintained DeltaPsi(m).

SWELLING MITOCONDRIAL EM AMOSTRAS TECIDUAIS DE GATOS SUBMETIDOS À OCLUSÃO DA ARTÉRIA CEREBRAL MÉDIA

A isquemia cerebral tem sido largamente estudada com intuito de se obter medidas terapêuticas eficazes que minimizem seus efeitos, visto que uma grande quantidade de pacientes, clínicos ou cirúrgicos, apresentam conseqüências freqüentemente irreversíveis da mesma. A escolha de um modelo experimental satisfatório a fim de nortear pesquisas com agentes neuroprotetores tem sido a base desses estudos. No presente trabalho foi escolhido o gato como modelo experimental de isquemia e a avaliação foi realizada através do swelling mitocondrial. Os trinta e dois animais utilizados neste experimento, foram divididos em quatro grupos distintos, cada qual com dez animais sendo submetido a um tempo de isquemia, que aumentou progressivamente (15, 30 e 60 minutos), exceto no último grupo com dois animais e que não foi submetido a nenhum procedimento isquemiante. Foram observadas alterações evidentes nas curvas de swelling mitocondrial energizado nos animais submetidos a 60 minutos de isquemia, quando se comparou amostras do lado isquêmico em relação ao controle, isto ficou ainda mais claro quando se adicionou o antibiótico Alameticina durante os ensaios laboratoriais do swelling mitocondrial. Foi possível chegar às seguintes conclusões: o swelling funciona como indicador de diferenciação mitocondrial entre diversos tecidos; a mitocôndria do cérebro, quando exposta ao efeito da Alameticina, apresenta uma sensibilidade diferenciada em relação às dos outros tecidos; a mitocôndria do cérebro submetido a isquemia durante 60 minutos se torna mais sensível à Alameticina; e finalmente, as mitocôndrias do cérebro apresentam uma instalação extremamente rápida da reversão do swelling.

Mitochondrial transport of cations: channels, exchangers, and permeability transition

This review provides a selective history of how studies of mitochondrial cation transport (K+, Na+, Ca2+) developed in relation to the major themes of research in bioenergetics. It then covers in some detail specific transport pathways for these cations, and it introduces and discusses open problems about their nature and physiological function, particularly in relation to volume regulation and Ca2+ homeostasis. The review should provide the basic elements needed to understand both earlier mitochondrial literature and current problems associated with mitochondrial transport of cations and hopefully will foster new interest in the molecular definition of mitochondrial cation channels and exchangers as well as their roles in cell physiology.

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.

Close correlations between mitochondrial swelling and ATP-content in the ischemic canine myocardium. A combined morphometric and biochemical study

This study investigates how far mitochondrial swelling in the ischemic heart is influenced by factors pertaining to anaerobic energy turnover. Canine hearts were arrested by aortic cross clamping or cardioplegically with St. Thomas or HTK solution and incubated at 25 degrees C in the solution used for cardiac arrest. Samples of the left ventricle were taken at the end of cardiac arrest and during ischemia for structural evaluation and biochemical analysis. The extracellular pH in the interventricular septum was measured. Mitochondrial swelling was determined with the surface to volume ratio, a parameter independent of the reference space. Values obtained for different swelling were related to defined metabolite concentrations and pHe values to establish possible correlations between structural and biochemical parameters in the ischemic heart. At the onset of ischemia and during the breakdown of creatine phosphate (CP) to 3 mumol/g wet weight mitochondrial volume depends on the method of cardiac arrest and does not increase significantly in any of the three groups. The degree of mitochondrial swelling after depletion of CP correlates with the decline in ATP independent of the form of cardiac arrest. Characteristic values of the surface to volume ratio ascertained at different times of ischemia for all groups correspond to determined ATP concentrations. Acid pHe values seem to intensify mitochondrial swelling. With increased lactate concentrations mitochondria swell, but first initially the degree of swelling differs significantly in the forms of cardiac arrest investigated. Thus, the surface to volume ratio is a powerful and valid ultrastructural parameter, which makes correlations between mitochondrial structure and metabolism possible and furthermore indicates a strong correlation between mitochondrial swelling and ATP-concentration in the ischemic heart.

Subcellular electrolyte alterations during progressive hypoxia and following reoxygenation in isolated neonatal rat ventricular myocytes

This study characterizes the sequential alterations of, and relations between, multiple electrolytes in cytoplasm, mitochondria, and whole cells during hypoxia and on reoxygenation in isolated neonatal rat ventricular myocytes. Subcellular electrolyte content and distribution were measured by electron probe x-ray microanalysis, membrane phospholipid degradation by tritiated arachidonic acid release, and cell morphology by electron microscopy. At 1-2 hours of hypoxia, the myocyte population showed a loss of cytoplasmic potassium, magnesium, and chlorine without alteration of cytoplasmic sodium or calcium. Mitochondria showed increased potassium with unchanged magnesium content. There was no morphological evidence of cell injury or tritiated arachidonic acid release. At 3-5 hours of hypoxia, the myocyte population showed a further loss of cytoplasmic potassium and magnesium and an increase in cytoplasmic sodium, chlorine, and calcium. At a single-cell level, the increase in cytoplasmic sodium preceded the increase in cytoplasmic calcium. Mitochondria showed increased sodium and chlorine and decreased magnesium before increased calcium content; potassium loss was manifest only at 5 hours of hypoxia. At 3-5 hours of hypoxia, there was also tritiated arachidonic acid release and morphological evidence of cell injury. Reoxygenation for 1 hour after 5 hours of hypoxia partially reversed the mean alterations of all electrolytes, except calcium, in the cytoplasm of the myocyte population, whereas analysis was required at a single-cell level to show a partial reversal in calcium levels in cytoplasm of reoxygenated cells. Reoxygenation for 1 hour after 5 hours of hypoxia partially reversed the mean alterations of all electrolytes, including calcium, in the mitochondria of the myocyte population. Recovery of potassium in the cytoplasm correlated with reduction of mitochondrial calcium content on reoxygenation and best predicted recovery of cellular homeostasis of sodium, chlorine, magnesium, and calcium. This study demonstrates that in this experimental model of hypoxia 1) initial losses of cytoplasmic potassium and magnesium occur in the absence of cell injury; 2) increases of sodium, chlorine, and calcium occur in association with cell injury, with sodium increasing before calcium; 3) membrane phospholipid degradation and electrolyte derangement, including increased calcium, may contribute to reversible and irreversible phases of cell injury; 4) analysis of calcium at a subcompartmental level and at a single-cell level is required to correlate reduction of calcium on reoxygenation with recovery of cell homeostasis; 5) reduction of calcium content in mitochondria may predict recovery of cell homeostasis; and 6) recovery of potassium on reoxygenation best predicts recovery of cell membrane function and cell homeostasis.

Contributions of sodium and chloride to ultrastructural damage after dendrotomy

To determine the contributions of sodium and chloride to ultrastructural changes after mechanical injury, we amputated primary dendrites of cultured mouse spinal neurons in low calcium medium in which sodium chloride had been replaced with either choline chloride or sodium isethionate or sodium propionate. Uninjured cultured neurons were also exposed to the sodium ionophore, monensin. A third set of neurons was injured in medium in which all sodium and calcium chloride had been replaced with sucrose. Neurons injured in low-calcium, low-sodium medium exhibited few ultrastructural changes, except very near the lesion, where there was some dilation of mitochondria and cisternae of the smooth endoplasmic reticulum (SER). Mitochondria in other regions of the neurons developed an electron opaque matrix, and those nearer to the lesion converted to the condensed configuration, characterized by expanded intracristal spaces as well as a dense matrix. If sodium but not chloride was present in the medium, there was some dilation of the Golgi cisternae after injury, as well as some increased electron opacity of the mitochondria. Monensin treated neurons also exhibited dilation of the Golgi cisternae. Neurons injured in sucrose-substituted medium showed none of the changes associated with injury in normal culture medium. These results indicate that sodium influx through the lesion is involved in the dilation of the SER, which is seen even in low-calcium medium, and that a permeant anion, such as chloride, is also involved. This dilation of the SER may result from uptake of calcium released from mitochondria in response to elevated cytosolic sodium. Dilation of the Golgi cisternae appears to be a response only to elevated intracellular sodium. Condensation of the mitochondria after injury is thought to be due to increased demands for ATP synthesis and may involve a "futile cycling" of calcium across the mitochondrial membrane, involving sodium-mediated calcium release in response to elevated intracellular calcium.

A mitochondrial protein fraction catalyzing transport of the K+ analog T1+

A protein fraction has been obtained from detergent-solubilized mitochondrial membranes by its affinity for quinine, an inhibitor of K+ transport. A peptide derived from the predominant 53 kDa protein in this fraction is found to be identical in sequence to a portion of aldehyde dehydrogenase. Antigenically unrelated bands at 97, 77, 57, and 31 kDa are also seen on polyacrylamide gels. Observations utilizing a fluorescent probe entrapped in the lumen of membrane vesicles indicate that the reconstituted protein fraction imparts permeability to the K+ analog Tl+. These and other findings suggest that the affinity purified fraction includes a cation transport catalyst.

A gated pathway for electrophoretic Na+ fluxes in rat liver mitochondria. Regulation by surface Mg2+

Addition of EDTA to mitochondria incubated aerobically in a phosphate-supplemented medium containing Na+ ions results in activation of cation uptake which is accompanied by membrane depolarization and stimulation of respiration. The same results are obtained in media containing Li+ but not K+, indicating that this pathway for cation transport is selective. The activation of Na+ transport is not accompanied by changes of matrix Mg2+, indicating that cation transport is controlled by surface-bound rather than intramitochondrial Mg2+. Na+ transport in respiring mitochondria is competitively inhibited by Mg2+ with a Ki in the nanomolar range. A Na+ current can also be induced by a K+ diffusion potential in the absence of respiration. The K(+)-diffusion-driven Na+ current has the same magnitude in the absence or presence of inorganic phosphate, suggesting that Na+ transport is mediated by Na+ uniport rather than by electrogenic nNa+/H+ antiport with n greater than 1. Analysis of the flow/force relationship indicates that the putative Na+ uniporter has a conductance of about 0.2 nmol Na+ x mg protein-1 x min-1 x mV-1, and that it is active only when the membrane potential exceeds about 150 mV.

Inhibition of oxidative phosphorylation by organotin thiocarbamates

A series of triphenyl-, tricyclohexyl- and tribenzyltin compounds have been synthesized and examined as inhibitors of mitochondrial oxidative phosphorylation. All compounds tested inhibit oxidative phosphorylation linked to succinate oxidation by potato tuber mitochondria. All of the organotin compounds inhibit ADP-stimulated O2 uptake linked to succinate oxidation with concentrations for 50% inhibition in the range 2-50 microM. This inhibition is not due to inhibition of electron transport from succinate to O2 per se: none of the organotin compounds at 50 microM substantially inhibit the rate of succinate oxidation in the presence of 2,4-dinitrophenol. Representative organotin compounds at 0.5-50 microM do not act as uncouplers of succinate oxidation. It is concluded that the organotin compounds act as energy transfer inhibitors to inhibit oxidative phosphorylation in potato tuber mitochondria. A similar mode of action of representative organotin compounds was found with rat liver mitochondria. These organotin compounds inhibit a hydrophobic Ca2+-dependent plant protein kinase in the absence but not in the presence of thiols.

Characterization of the mitochondrial Na+-H+ exchange. The effect of amiloride analogues

The kinetic properties and inhibitor sensitivity of the Na+-H+ exchange activity present in the inner membrane of rat heart and liver mitochondria were studied. (1) Na+-induced H+ efflux from mitochondria followed Michaelis-Menten kinetics. In heart mitochondria, the Km for Na+ was 24 +/- 4 mM and the Vmax was 4.5 +/- 1.4 nmol H+/mg protein per s (n = 6). Basically similar values were obtained in liver mitochondria (Km = 31 +/- 2 mM, Vmax = 5.3 +/- 0.2 nmol H+/mg protein per s, n = 4). (2) Li+ proved to be a substrate (Km = 5.9 mM, Vmax = 2.3 nmol H+/mg protein per s) and a potent competitive inhibitor with respect to Na+ (Ki approximately 0.7 mM). (3) External H+ inhibited the mitochondrial Na+-H+ exchange competitively. (4) Two benzamil derivatives of amiloride, 5-(N-4-chlorobenzyl)-N-(2',4'-dimethyl)benzamil and 3',5'-bis(trifluoromethyl)benzamil were effective inhibitors of the mitochondrial Na+-H+ exchange (50% inhibition was attained by approx. 60 microM in the presence of 15 mM Na+). (5) Three 5-amino analogues of amiloride, which are very strong Na+-H+ exchange blockers on the plasma membrane, exerted only weak inhibitory activity on the mitochondrial Na+-H+ exchange. (6) The results indicate that the mitochondrial and the plasma membrane antiporters represent distinct molecular entities.

Sodium/proton antiporters in the mitochondrial inner membrane

The two mitochondrial Na+/H+ antiporters differ in several important respects, and the most physiologically significant of these may be their differences in regulation. The Mg2+-dependent Na+/H+ antiporter controls mitochondrial volume in a dangerous, high-K+ environment. To play this vital role, this porter must always lie poised far from K+/H+ equilibrium; i.e., it must be under dynamic regulation, as proposed in the Mg2+ carrier-brake hypothesis (7). Being regulated, it is not necessary for this antiporter to be cation-selective, since all electroneutral cation movements will be followed by redistributions of anions and water. On the other hand, there is no indication at present that the Mg2+-independent Na+/H+ antiporter is regulated. This transporter is therefore required to exhibit high discrimination against K+ in order to prevent the collapse of matrix volume dueto uncontrolled loss of K+ salts and water (4). Do the properties of the mitochondrial Na+/H+ antiporters help us in any way to understand the plasmalemmal Na+/H+ antiporters? I believe they do, if we allow that there are a limited number of ways in which nature constructs such porters. The difference in cation selectivities very likely reflects a fundamental structural difference between the two mitochondrial antiporters, and this difference appears to be mirrored in two types of plasmalemmal Na+/H+ antiporters. Thus, the Mg2+-independent Na+/H+ antiporter resembles the renal tubular Na+/H+ antiporter in its discrimination against K+ and its competitive inhibition by Li+. On the other hand, the Mg2+-dependent Na+/H+ antiporter resembles a cardiac sarcolemmal Na+/H+ antiporter which transports all alkali cations, including Na+ and K+, and which is inhibited by DCCD and amphiphilic amines (S. Kakar, A. Askari and K. Garlid, in preparation). The existence of the latter class of antiporter in plasmalemma may seem unlikely at first glance, since it would tend to catalyze Na+/K+ exchange and dissipate the effects of the Na+,K+-ATPase. Nevertheless, a sound design principle would be followed if the cell, like mitochondria, were to regulate volume by governing a passive back-flow process rather than an active transport process. In conclusion, it seems premature to conclude that plasma membranes contain only one type of Na+/H+ antiporter. Nor does it seem likely that there is an unlimited variety of such transporters. I propose as a working hypothesis that antiporters from both mitochondria and plasmalemma may be separated into two classes: Na+-selective and non-Na+-selective.(ABSTRACT TRUNCATED AT 400 WORDS)

Evidence for the existence of an inner membrane anion channel in mitochondria

Mitochondria normally exhibit very low electrophoretic permeabilities to physiologically important anions such as chloride, bicarbonate, phosphate, succinate, citrate, etc. Nevertheless, considerable evidence has accumulated which suggests that heart and liver mitochondria contain a specific anion-conducting channel. In this review, a postulated inner membrane anion channel is discussed in the context of other known pathways for anion transport in mitochondria. This anion channel exhibits the following properties. It is anion-selective and inhibited physiologically by protons and magnesium ions. It is inhibited reversibly by quinine and irreversibly by dicyclohexylcarbodiimide. We propose that the inner membrane anion channel is formed by inner membrane proteins and that this pathway is normally latent due to regulation by matrix Mg2+. The physiological role of the anion channel is unknown; however, this pathway is well designed to enable mitochondria to restore their normal volume following pathological swelling. In addition, the inner membrane anion channel provides a potential futile cycle for regulated non-shivering thermogenesis and may be important in controlled energy dissipation.

Effects of quinine on K+ transport in heart mitochondria

Quinine inhibits the respiration-dependent extrusion of K+ from Mg2+-depleted heart mitochondria and the passive osmotic swelling of these mitochondria in K+ and Na+ acetate at alkaline pH. These observations concur with those of Nakashima and Garlid (J. Biol. Chem. 257, 9252, 1982) using rat liver mitochondria. Quinine also inhibits the respiration-dependent contraction of heart mitochondria swollen passively in Na+ or K+ nitrate and the increment of elevated respiration associated with the extrusion of ions from these mitochondria. Quinine, at concentrations up to 0.5 mM, inhibits the respiration-dependent 42K+/K+ exchange seen in the presence of mersalyl, but higher levels of the drug produce increased membrane permeability and net K+ loss from the matrix. These results are all consistent with an inhibition of the putative mitochondrial K+/H+ antiport by quinine. However, quinine has other effects on the mitochondrial membrane, and possible alternatives to this interpretation are discussed.

Some effects of dibutylchloromethyltin chloride and other reagents on mitochondrial K+ flux

Respiration-dependent K+ fluxes across the limiting membranes of isolated rat liver mitochondria, measured by means of 42K, are stimulated by the oxidative phosphorylation inhibitor dibutylchloromethyltin chloride (DBCT). A lack of effect of Cl- concentration indicates that the stimulation of K+ flux by DBCT is not attributable to Cl-/OH- exchange activity. The mercurial mersalyl was previously shown to stimulate respiration-dependent K+ influx. The combined presence of mersalyl plus DBCT results in a greater stimulation of K4 influx than is caused by either DBCT or mersalyl alone. The oxidative phosphorylation inhibitor oligomycin, which alone has no effect on respiration-dependent K+ influx, enhances the stimulatory effect of mersalyl on K+ influx. The data are consistent with, although not proof of, a direct interaction of the K+ transport mechanism with the mitochondrial energy transduction apparatus.

Regulation of the monovalent cation permeability of brain mitochondria

The Na+ and K+ conductances of rat brain mitochondria were estimated from rates of metabolically dependent swelling and uncoupling of respiration. These were maximal in the presence of EDTA plus Pi. Pi could not be replaced with acetate. Na+ conductance was greater than that of K+ and was therefore examined in greater detail. According to the influences of N-ethylmaleimide, internal Pi (exogenous and perhaps endogenous) promoted Na+ permeability. Treatment with the ionophore A23187 obviated the Pi requirement although EDTA was still necessary. The stimulation by EDTA with Pi or A23187 and inhibition by exogenous Mg2+ suggested endogenous polyvalent cations could also regulate Na+ conductance. The influence of these substances upon endogenous Mg2+ (and Ca2+) levels is consistent with such a role of membrane-bound Mg2+. Low levels of ruthenium red (150 pmol/mg) inhibit Na+ permeation, indicating that the number of 'sites' or 'channels' involved may be small. The Ca2+ uniport is not directly involved in Na+ flow according to its greater sensitivity to inhibition by ruthenium red.

Mechanism of mitochondrial transport of thallous ions

Rat liver mitochondria were found to swell under nonenergized conditions when suspended in media containing 30-40 mM TINO3. Respiration on succinate caused a rapid contraction of mitochondria swollen under nonenergized conditions. In the presence of thallous acetate, there was a rapid initial swelling under nonenergized conditions until a plateau was reached; respiration on succinate then caused a further swelling. Trace amounts of 204Tl (less than 100 microM) equilibrated fairly rapidly across the mitochondrial membrane. The influx of Tl+ was able to promote the decay not only of a valinomycin-induced K+-diffusion potential but also of respiration-generated fields in the inner membrane in accordance with the electrophoretic nature of Tl+ movement. Efflux of Tl+ showed a half-time of about 10 sec at 20 degrees C and was not affected appreciably by the energy state. Efflux was retarded by Mg2+ and by lowering the temperature. The data indicate that Tl+ when present at high concentrations, 30mM or more, distributes across the mitochondrial inner membrane both in response to electrical fields and to delta pH. In energized mitochondria the uptake of Tl+ would occur electrophoretically, while Tl+/H+ exchange would constitute a leak. In the presence of NO3-, the movements of Tl+ are determined by that of NO3-, indicating short-range coupling of electrical forces. At low concentrations of Tl+, 5 mM or less, there was no indication of a Tl+/H+ exchange, which appears to be induced by high concentrations of Tl+.

Induction of Na+/K+ exchange in swollen heart mitochondria

Heart mitochondria swollen passively in nitrate salts contract in a respiration-dependent reaction which can be attributed to an endogenous cation/H+ exchange component (or components). The rate of contraction increases with increased extent of passive swelling in both Na+ and K+ salts. Since nearly constant internal cation concentrations are maintained during osmotic swelling, this result suggests that both Na+/H+ and K+/H+ exchange is enhanced by increased matrix volume. Endogenous Mg2+ is also lost with increased matrix volume, and this observation, in conjunction with other evidence available in the literature, suggests that monovalent cation/H+ exchanges may be regulated by divalent cations. Passive exchange of Na+/K+, 42K+/K+, and 24Na+/Na+ can be readily demonstrated in mitochondria swollen in nitrate. All these exchanges are low or not detectable in unswollen control mitochondria, and it appears that they are manifestations of the activated cation/H+ component (or components) functioning in the absence of delta pH.