Adenine nucleotide translocase as a site of regulation by ADP of the rat liver mitochondria permeability to H+ and K+ lons

In the presence of oligomycin ADP inhibits the osmotic swelling of the nonenergized rat liver mitochondria in the NH₄NO₃ medium. With the energized mitochondria ADP enhances contraction of the mitochondria swollen in the NH₄NO₃ medium. Carboxyatractyloside and atractyloside abolish or prevent the effects of ADP. The direct measurements of the proton conductance of rat liver mitochondria shows that the inhibitory action of ADP + oligomycin on the H⁺ permeability does not depend on the energization of mitochondria. In these experiments the local anesthetic nupercaine and ADP additively inhibit the inner membrane conductance for protons, but carboxyatractyloside abolishes only the effect of ADP. In the presence of oligomycin ADP also inhibits the osmotic swelling of the nonenergized liver mitochondria in the KNO₃ medium, and the energy-dependent swelling of rat liver mitochondria in the medium with K⁺ ions and P_i. The inhibition by ADP of the membrane passive permeability for K⁺ is also sensitive to carboxyatractyloside. It is concluded that rat liver mitochondria possess an ADP-regulated channel for H⁺ and K⁺. The properties of this pathway for protons and potassium ions favor the idea that ADP regulates the mitochondrial permeability via adenine nucleotide translocase. It is assumed that the adenine nucleotides carrier should operate according to the “gated pore” mechanism.     

Tl+ induces both cationic and transition pore permeability in the inner membrane of rat heart mitochondria

Effects of Tl⁺ were studied in experiments with isolated rat heart mitochondria (RHM) injected into 400 mOsm medium containing TlNO₃ and a nitrate salt (KNO₃ or NH₄NO₃) or TlNO₃ and sucrose. Tl⁺ increased permeability of the inner membrane of the RHM to K⁺ and H⁺. This manifested as an increase of the non-energized RHM swelling, in the order of sucrose < K⁺ < NH₄ ⁺, respectively. After succinate administration, the swollen RHM contracted. The Tl⁺-induced opening of the mitochondrial permeability pore (MPTP) in Ca²⁺-loaded rat heart mitochondria increased both the swelling and the inner membrane potential dissipation, as well as decreased basal state and 2,4-dinitrophenol-stimulated respiration. These effects of Tl⁺ were suppressed by the MPTP inhibitors (cyclosporine A, ADP, bongkrekic acid, and n-ethylmaleimide), activated in the presence of the MPTP inducer (carboxyatractyloside) or mitoK_ATP inhibitor (5-hydroxydecanoate), but were not altered in the presence of mitoK_ATP agonists (diazoxide or pinacidil). We suggest that the greater sensitivity of heart and striated muscles, versus liver, to thallium salts in vivo can result in more vigorous Tl⁺ effects on muscle cell mitochondria.     

THE PERMEABILITY OF PINCHED-OFF NERVE ENDINGS TO SODIUM, POTASSIUM AND CHLORIDE AND THE EFFECTS OF GRAMICIDIN

Abstract—

• 1 The passive permeability of synaptosomes to ions was measured by a light-scattering technique. Synaptosomes were freely permeable to acetate, HCO₃^_, SCN^?and NH₄⁺ and were impermeable to choline and SO₄^2-.
• 2 Gramicidin D selectively increased the permeability of synaptosomes to Na⁺ and K⁺ ions.
• 3 The relative permeabilities of Na⁺, K⁺ and Cl^?, measured in the presence of a number of more permeant counter-ions, was in the ratio 1:19:12. These values are discussed in terms of the source of the resting potential.

     

Effect of Mg2+ depletion of mitochondria on their permeability to K+: the mechanism by which ionophore A23187 increases K+ permeability.

Ionophore A23187 produces rapid swelling of rat liver mitochondria suspended in isotonio KNO₃ if an uncoupler and EDTA are also present. It also produces swelling of mitochondria in isotonic Mg(NO₃)₂ in the presence of an uncoupler. Washing with serum albumin removes the ionophore from mitochondria, as indicated by lack of swelling in magnesium nitrate (+ uncoupler). However, such treatment does not abolish rapid swelling in KNO₃ (+ uncoupler). This finding is interpreted in the sense that depletion of mitochondrial magnesium mobilizes K⁺/H⁺ antiport in the inner mitochondrial membrane.     

Effects of Tl<Superscript>+</Superscript> on ion permeability,membrane potential and respiration of isolated rat liver mitochondria

It is known that permeability of the inner mitochondrial membrane is low to most univalent cations (K⁺, Na⁺, H⁺) but high to Tl⁺. Swelling, state 4, state 3, and 2,4-dinitrophenol (DNP)-stimulated respiration as well as the membrane potential (ΔΨ_mito) of rat liver mitochondria were studied in media containing 0–75 mM TlNO₃ either with 250 mM sucrose or with 125 mM nitrate salts of other monovalent cations (KNO₃, or NaNO₃, or NH₄NO₃). Tl⁺ increased permeability of the inner mitochondrial membrane to K⁺, Na⁺, and H⁺, that was manifested as stimulation of the swelling of nonenergized and energized mitochondria as well as via an increase of state 4 and dissipation of ΔΨ_mito. These effects of Tl⁺ increased in the order of sucrose <K⁺ <Na⁺ ≤ NH₄⁺. They were stimulated by inorganic phosphate and decreased by ADP, Mg²⁺, and cyclosporine A. Contraction of energized mitochondria, swollen in the nitrate media, was markedly inhibited by quinine. It suggests participation of the mitochondrial K⁺/H⁺ exchanger in extruding of Tl⁺-induced excess of univalent cations from the mitochondrial matrix. It is discussed that Tl⁺ (like Cd²⁺ and other heavy metals) increases the ion permeability of the inner membrane of mitochondria regardless of their energization and stimulates the mitochondrial permeability transition pore in low conductance state. The observed decrease of state 3 and DNP-stimulated respiration in the nitrate media resulted from the mitochondrial swelling rather than from an inhibition of respiratory enzymes as is the case with the bivalent heavy metals.     

Metabolism of N6,O2'-[3H]dibutyryl cyclic adenosine 3',5'-monophosphate and macromolecular interactions of the products perfused rat liver.

Mitochondria from liver, kidney, brain, and skeletal muscle metabolized acetaldehyde. Acetaldehyde oxidation by liver and kidney mitochondria was maximal at low levels of acetaldehyde and was sensitive to rotenone, suggesting the involvement of a NAD⁺-dependent aldehyde dehydrogenase with a high affinity for acetaldehyde. Acetaldehyde oxidation was stimulated 50% by ADP, suggesting that, in state 4, reoxidation of NADH is rate limiting for acetaldehyde oxidation. In state 4, acetaldehyde oxidation was decreased by NAD⁺-dependent substrates, as well as by succinate and ascorbate. The inhibition by the latter two substrates was prevented by ADP, dinitrophenol, valinomycin, and gramicidin, but not by oligomycin. Since these compounds are linked to energy transduction and utilization, the data suggest that the inhibition is mediated via energy-dependent reversed electron transport. In state 3, all of these substrates caused considerably less inhibition of acetaldehyde oxidation, suggesting that the activity of aldehyde dehydrogenase, and not of NADH reoxidation, is probably rate limiting for acetaldehyde oxidation. The ionophores valinomycin and gramicidin stimulated acetaldehyde oxidation to a greater extent than ADP. These ionophores also stimulated acetaldehyde oxidation in the presence of ADP. Stimulation by valinomycin occurred in the presence of monovalent cations transported by this ionophore, e.g., K⁺, Rb⁺, Cs⁺. Stimulation by gramicidin also occurred in the presence of these cations, but did not occur with Na⁺ or Li⁺. Na⁺ prevents the stimulation of acetaldehyde oxidation, which occurs in the presence of gramicidin and K⁺. The stimulation by valinomycin and gramicidin was energy dependent and required the presence of a permeant anion. In the absence of an ionophore, potassium phosphate had no effect on acetaldehyde oxidation. These data suggest that the oxidation of acetaldehyde by rat liver and kidney mitochondria is influenced by the oxidation-reduction state of the mitochondria and by the cationic environment. With brain and muscle mitochondria, the rate of acetaldehyde oxidation increased two- to threefold as the concentration of acetaldehyde was raised from 0.167 to 0.50 mm. Acetaldehyde oxidation in these mitochondria was also sensitive; to rotenone, indicating dependence on NAD⁺. ADP, valinomycin, gramicidin, and succinate, compounds which either increased or decreased the rate of acetaldehyde oxidation by liver and kidney mitochondria, had no effect on acetaldehyde oxidation by muscle or brain mitochondria. In state 4, mitochondria from Becker-transplantable hepatocellular carcinoma HC-252 oxidized acetaldehyde at the same rate as liver mitochondria. However, in the presence of ADP, dinitrophenol, valinomycin and gramicidin, the rate of acetaldehyde oxidation by the tumor mitochondria was two to three times greater than that of liver mitochondria, suggesting the presence of a more active; acetaldehyde-oxidizing system in tumor than in liver mitochondria.     

Characteristics of thyroxine swelling in skeletal muscle mitochondria: Relationship to valinomycin swelling and swelling in the absence of Mg2+

Summary Divalent cation-depleted skeletal muscle mitochondria undergo energy-dependent swelling in the presence of thyroxine analogues+Mg²⁺, as well as in the presence of valinomycin or the absence of Mg²⁺. ATP-supported swelling shows a K⁺-specificity in the presence of thyroxine analogues or valinomycin, in contrast to a Na⁺-specificity in the absence of Mg²⁺. Substrate-supported swelling shows a K⁺-specificity in the presence of valinomycin but fails to show an alkali metal cation specificity under the other two swelling conditions. All three kinds of swelling show a permeant anion dependency. Although Mg²⁺ inhibits the swelling which occurs in its absence and also inhibits uncoupling of respiration, even in the presence of valinomycin, nevertheless Mg²⁺ does not inhibit the energy-dependent swelling which occurs in the presence of valinomycin or thyroxine analogues. The findings show that thyroxine does not promote swelling simply because it chelates Mg²⁺. Rather, they show that thyroxine promotes a selective change in accessibility of monovalent cations. They suggest that thyroxine in the presence of Mg²⁺ acts at the first coupling site as an electron ccepptor. An observed inhibition of oxygen uptake would appear to be explained on the basis of thyroxine in higher concentration acting as an electron sink. The findings suggest that, as with the lipid-soluble K⁺ carrier, valinomycin, in the presence of Mg²⁺, a change in the status of electrical gradients in the membrane can account for the osmotic swelling observed in the presence of thyroxine analogues.Contribution No. 346 from the Animal Research Institute, Canada Department of Agriculture, Ottawa, Canada.     

KINETIC STUDY OF GLUTAMATE TRANSPORT IN RAT BRAIN MITOCHONDRIA

Abstract— The experiments reported here confirm that glutamate can penetrate the inner membrane of isolated rat brain non-synaptosomal mitochondria, either on a glutamate-hydroxyl antiporter or on a glutamate-aspartate antiporter. An inhibition of respiratory activity of mitochondria with glutamate as substrate was obtained in the presence of avenaciolide or N-ethylmaleimide. Swelling of the mitochondria in iso-osmotic NH4⁺-l -glutamate was inhibited in the presence of avenaciolide and N-ethylmaleimide, but mersalyl, kainic acid, glisoxepide and amino-oxyacetic acid had no effect on the glutamate-hydroxyl exchange. Glutamate induced the reduction of intramitochondrial NAD(P), as estimated by double-beam spectrophotometry, and this reduction was inhibited on the one hand by N-ethylmaleimide, avenaciolide or fuscine, on the other hand by aminooxyacetic acid. A direct estimation of the penetration of l -[¹⁴C]glutamate into brain mitochondria was performed by using the centrifugation-stop procedure. This penetration followed saturation kinetics, with a mean apparent K_m of 1.56 M^M at pH 7.4 and at 20°C, the value of Knax was 4.34 nmol per min per mg protein in the same conditions. IV-Ethylmaleimide slowed down the initial rate of glutamate penetration, and this inhibition appeared to be non-competitive with a K_i of 0.7 Mm -at pH 7.4 and at 20°C. The entry of glutamate was pH-dependent and it increased 2-fold in the pH range of 7.4 to 6.4. A temperature-dependence of glutamate transport was also shown between 2 and 25°C; the Arrhenius plot was a straight line, with a calculated E_A of 12.8 kCal per mol of glutamate and a Q₁₀ of 2.16. The activity of γ-glutamyl transpeptidase was practically absent in these rat brain mitochondria. Oxidation of extramitochondrial NADH by the‘malate-aspartate shuttle’reconstituted in vitro was followed in rat brain non-synaptosomal mitochondria. In the absence of extramitochondrial malate or glutamate the ‘shuttle’ did not function, and in the absence of extramitochondrial aspartate the rate of NADH oxidation was low. Glutamine or γ-aminobutyrate did not replace glutamate efficiently. A high inhibition of the‘malate-aspartate shuttle’occurred in the presence of avenaciolide or mersalyl, and a moderate one in the presence of n-ethylmaleimide, glisoxepide or n-butylmalonate. Glutaminase activity in intact brain mitochondria was inhibited in the presence of extramitochondrial glutamate.     

Glutamine Transport in Rat Brain Synaptic and Non-Synaptic Mitochondria

Glutamine transport into rat brain mitochondria (synaptic and non-synaptic) was monitored by the uptake of [³H]glutamine as well as by mitochondrial swelling. The uptake is inversely correlated to medium osmolarity, temperature-dependent, saturable and inhibited by mersalyl, and glutamine is upconcentrated in the mitochondria. These results indicate that glutamine is transported into an osmotically active space by a protein catalyzed mechanism. The uptake is slightly higher in synaptic mitochondria than in non-synaptic ones. It is inhibited both by rotenone and the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone, the latter at pH 6.5, showing that the transport is activated by an electrochemical proton gradient. The K⁺/H⁺ ionophore nigericin also inhibits the uptake at pH 6.5 in the presence of external K⁺, which indicates that glutamine, at least in part, is taken up by a proton symport transporter. In addition, glutamine uptake as measured by the swelling technique revealed an additional glutamine transport activity with at least 10 times higher K_m value. This uptake is inhibited by valinomycin in the presence of K⁺ and is thus also activated by the membrane potential. Otherwise, the two methods show similar results. These data indicate that glutamine transport in brain mitochondria cannot be described by merely a simple electroneutral uniport mechanism, but are consistent with the uptake of both the anionic and the zwitterionic glutamine.     

POTASSIUM ALLEVIATES THE INHIBITORY ACTION OF AMMONIUM UPON THE PHOTOSYNTHETIC RECOVERY OF NOSTOC FLAGELLIFORME (CYANOPHYCEAE) DURING REHYDRATION1

Effects of ammonium on the photosynthetic recovery of Nostoc flagelliforme Berk. et M. A. Curtis were assayed when being rehydrated in low‐K⁺ or high‐K⁺ medium. Its photosynthetic recovery was K⁺ limited after 3 years of dry storage. The potassium absorption of N. flagelliforme reached the maximum after 3 h rehydration in low‐K⁺ medium but at 5 min in high‐K⁺ medium. The K⁺ content of N. flagelliforme rehydrated in high‐K⁺ medium was much higher than that in low‐K⁺ medium. The maximal PSII quantum yield (F_v/F_m) value of N. flagelliforme decreased significantly when samples were rehydrated in low‐K⁺ medium treated with 5 mM NH₄Cl. However, the treatment of 20 mM NH₄Cl had little effect on its F_v/F_m value in high‐K⁺ medium. The relative F_v/F_m 24 h EC₅₀ (concentration at which 50% inhibition occurred) value of NH₄⁺ in high‐K⁺ medium (64.35 mM) was much higher than that in low‐K⁺ medium (22.17 mM). This finding indicated that high K⁺ could alleviate the inhibitory action of NH₄⁺ upon the photosynthetic recovery of N. flagelliforme during rehydration. In the presence of 10 mM tetraethylammonium chloride (TEACl), the relative F_v/F_m 24 h EC₅₀ value of NH₄⁺ was increased to 46.34 and 70.78 mM, respectively, in low‐K⁺ and high‐K⁺ media. This observation suggested that NH₄⁺ entered into N. flagelliforme cells via the K⁺ channel. Furthermore, NH₄⁺ could decrease K⁺ absorption in high‐K⁺ medium.     

Unmasking the mitochondrial K/H exchanger: swelling-induced K+-loss.

Matrix swelling induces a rapid, transient, energy-independent potassium efflux in rat liver mitochondria. Swelling-induced K⁺-loss is electroneutral; therefore it does not reflect electrophoretic diffusion secondary to increased membrane permeability. Matrix swelling unmasks an endogenous $\text{K}\text{H}$ transport mechanism in the mitochondrial membrane, providing a valuable experimental approach to the study of K⁺ transport in mitochondria.     

Regulation of Pea Mitochondrial Pyruvate Dehydrogenase Complex : Does Photorespiratory Ammonium Influence Mitochondrial Carbon Metabolism?

Inactivation of the pyruvate dehydrogenase complex catalyzed by pyruvate dehydrogenase kinase was studied using intact mitochondria purified from green leaf tissue of pea (Pisum sativum L.) and dialyzed mitochondrial extracts. Thiamine pyrophosphate was inhibitory in dialyzed extracts but not in intact mitochondria, except in the presence of high concentrations of Na⁺. NH₄⁺, at concentrations as low as 20 micromolar, markedly stimulated inactivation in dialyzed extracts. K⁺ in the range 1 to 10 millimolar also enhanced inactivation. In contrast, Na⁺ was without affect at lower concentrations but was inhibitory at 10 to 100 millimolar levels. The effect of NH₄⁺ is discussed in relation to a possible regulatory interaction between photorespiratory NH₄⁺ production and the entry of carbon into the tricarboxylic acid cycle by way of the pyruvate dehydrogenase complex.     

Effect of potential-dependent potassium uptake on production of reactive oxygen species in rat brain mitochondria

The effect of potential-dependent potassium uptake on reactive oxygen species (ROS) generation in mitochondria of rat brain was studied. It was found that the effect of K⁺ uptake on ROS production in the brain mitochondria under steady-state conditions (state 4) was determined by potassium-dependent changes in the membrane potential of the mitochondria (ΔΨ_m). At K⁺ concentrations within the range of 0–120 mM, an increase in the initial rate of K⁺-uptake into the matrix resulted in a decrease in the steady-state rate of ROS generation due to the K⁺-induced depolarization of the mitochondrial membrane. The selective blockage of the ATP-dependent potassium channel (K _ATP ⁺ -channel) by glibenclamide and 5-hydroxydecanoate resulted in an increase in ROS production due to the membrane repolarization caused by partial inhibition of the potential-dependent K⁺ uptake. The ATP-dependent transport of K⁺ was shown to be ～40% of the potential-dependent K⁺ uptake in the brain mitochondria. Based on the findings of the experiments, the potential-dependent transport of K⁺ was concluded to be a physiologically important regulator of ROS generation in the brain mitochondria and that the functional activity of the native K _ATP ⁺ -channel in these organelles under physiological conditions can be an effective tool for preventing ROS overproduction in brain neurons.     

Stimulation of potassium cycling in mitochondria by long-chain fatty acids

Nonesterified long-chain fatty acids (myristic, palmitic, oleic and arachidonic), added at low amounts (around 20 nmol/mg protein) to rat liver mitochondria, energized by respiratory substrates and suspended in isotonic solutions of KCl, NaCl, RbCl or CsCl, adjusted to pH 8.0, induce a large-scale swelling followed by a spontaneous contraction. Such swelling does not occur in alkaline solutions of choline chloride or potassium gluconate or sucrose. These changes in the matrix volume reflect a net uptake, followed by net extrusion, of KCl (or another alkali metal chloride) and are characterized by the following features: (1) Lowering of medium pH from 8.0 to 7.2 results in a disappearance of the swelling-contraction reaction. (2) The contraction phase disappears when the respiration is blocked by antimycin A. (3) Quinine, an inhibitor of the K⁺/H⁺ antiporter, does not affect swelling but suppresses the contraction phase. (4) The swelling phase is accompanied by a decrease of the transmembrane potential and an increase of respiration, whereas the contraction is followed by an increase of the membrane potential and a decrease of oxygen uptake. (5) Nigericin, a catalyst of the K⁺/H⁺ exchange, prevents or partly reverses the swelling and partly restores the depressed membrane potential. These results indicate that long-chain fatty acids activate in liver mitochondria suspended in alkaline saline media the uniporter of monovalent alkali metal cations, the K⁺/H⁺ antiporter and the inner membrane anion channel. These effects are presumably related to depletion of mitochondrial Mg²⁺, as reported previously [Arch. Biochem. Biophys. 403 (2002) 16], and are responsible for the energy-dissipating K⁺ cycling. The uniporter and the K⁺/H⁺ antiporter are in different ways activated by membrane stretching and/or unfolding, resulting in swelling followed by contraction.     

Mitochondria from rat uterine smooth muscle possess ATP-sensitive potassium channel

The objective of this study was to detect ATP-sensitive K⁺ uptake in rat uterine smooth muscle mitochondria and to determine possible effects of its activation on mitochondrial physiology. By means of fluorescent technique with usage of K⁺-sensitive fluorescent probe PBFI (potassium-binding benzofuran isophthalate) we showed that accumulation of K ions in isolated mitochondria from rat myometrium is sensitive to effectors of K_ATP-channel (ATP-sensitive K⁺-channel) – ATP, diazoxide, glibenclamide and 5HD (5-hydroxydecanoate). Our data demonstrates that K⁺ uptake in isolated myometrium mitochondria results in a slight decrease in membrane potential, enhancement of generation of ROS (reactive oxygen species) and mitochondrial swelling. Particularly, the addition of ATP into incubation medium led to a decrease in mitochondrial swelling and ROS production, and an increase in membrane potential. These effects were eliminated by diazoxide. If blockers of K_ATP-channel were added along with diazoxide, the effects of diazoxide were removed. So, we postulate the existence of K_ATP-channels in rat uterus mitochondria and assume that their functioning may regulate physiological conditions of mitochondria, such as matrix volume, ROS generation and polarization of mitochondrial membrane.     

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-dependent⁴²K⁺/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.     

EFFECT OF TEMPERATURE AND IONOPHORES ON THE PERMEABILITY OF SYNAPTOSOMES

Synaptosomes swell rapidly in isosmotic solutions of glycerol or urea, but the swelling in solutions of larger non-electrolytes, such as erythritol, glucose or sucrose is slower. The permeability of synaptosomes to non-electrolytes is temperature dependent, and the low activation energies for the permeation of urea (13 kcal/mol) and erythritol (9.5 kcal/mol) indicate that the penetration of non-electrolytes into the synaptosomes does not imply complete dehydration of the molecules. The relative permeability of synaptosomes to cations, as measured by the rate of swelling in isosmotic solutions of acetate salts is in the order: NH⁺₄ > Na⁺ > Li⁺ > K⁺ > Ca²⁺. The ionophores, X-537A and nigericin, or valinomycin + FCCP, which promote exchange of cations for H⁺, cause swelling of synaptosomes in solutions of potassium salts of acetate or propionate, but not in KCI, whereas H⁺ release is higher in KCI medium. This suggests that the organic unions cross the membrane after combining with H⁺ to form the respective weak acids. The relative permeability to anions is in the order: acetate ? propionate > Cl^? > SO^2-₄? maleate ? succinate. The energies of activation for the permeability of synaptosomes to potassium acetate in the presence of X-537A or gramicidin D are 13 kcal/mol and 7.5 kcal/mol, respectively, which reflects different mechanisms of action for the two ionophores in the membranes.     

K+ transport in mitoplasts

K⁺ transport into mitoplasts, prepared by digitonin disruption and removal of the outer membranes from rat liver mitochondria, has been studied. Unidirectional K⁺ influx has been measured by means of ⁴²K, in the presence of the respiratory substrate succinate. K⁺ influx is inhibited by CN^?, antimycin A and dicyclohexylcarbodiimide, but is insensitive to oligomycin. A linear dependence of the reciprocal of the K⁺-influx rate on the reciprocal of the external K⁺ concentration is observed. Under the conditions studied, the apparent K_m for K⁺ of the transport mechanism is approx. 6 mM, while the V_max of K⁺ influx is approx. 5 μ mol K⁺/g protein per min. The rate of K⁺ influx increases with increasing external pH over the range from 6.8 to 8.0. The observed kinetics, pH dependence and inhibitor sensitivity are essentially similar to previously reported characteristics of K⁺ transport into intact rat liver mitochondria. It is concluded that the outer mitochondrial membrane does not have a role in controlling K⁺ flux into rat liver mitochondria.     

Mechanisms of passive potassium influx in corn mitochondria

Corn mitochondria in 100 millimolar KCl show accelerated passive swelling upon addition of uncoupler. This unusual response has been compared with swelling produced by valinomycin, tripropyltin, and nigericin. It is concluded that the driving force for swelling lies with the chloride gradient and a high P_Cl:P_K ratio, the chloride influx creating a negative membrane potential. The action of uncoupler is to facilitate K⁺ influx via the endogenous H⁺/K⁺ antiporter. The antiporter is active over the pH range 6 to 8, is not sensitive to Mg²⁺ concentration, and is not inactivated by aging. It is not clear why corn mitochondria show this exceptional activity of the H⁺/K⁺ antiporter in K⁺ influx. It is speculated that during isolation the antiporter may be exposed or activated, and that it contributes to cyclic K⁺ transport and high State 4 respiration rates.