Effect of antibodies against mitochondrial K+-transporting protein on K+ transport in rat liver mitochondria

The K+ transport in rat liver mitochondria was studied by the immunochemical method. Antibodies to mitochondrial K+-transporting protein with molecular weight 60 kDa were obtained and used as possible inhibitor or K+ transport. Antibodies depressed the DNP-induced K+ efflux and energy-dependent swelling by 50% without causing changes in respiration and oxidative phosphorylation.     

Reconstitution and partial purification of the glibenclamide-sensitive, ATP-dependent K+ channel from rat liver and beef heart mitochondria.

The transport properties of mitochondria are such that net potassium flux across the inner membrane determines mitochondrial volume. It has been known that K+ uptake is mediated by diffusive leak driven by the high electrical membrane potential maintained by redox-driven, electrogenic proton ejection and that regulated K+ efflux is mediated by an 82-kDa inner membrane K+/H+ antiporter. There is also long-standing suggestive evidence for the existence of an inner membrane protein designed to catalyze electrophoretic K+ uptake into mitochondria. We report reconstitution of a highly purified inner membrane protein fraction from rat liver and beef heart mitochondria that catalyzes electrophoretic K+ flux in liposomes and channel activity in planar lipid bilayers. The unit conductance of the channel at saturating [K+] is about 30 pS. Reconstituted K+ flux is inhibited with high affinity by ATP and ADP in the presence of divalent cations and by glibenclamide in the absence of divalent cations. The mitochondrial ATP-dependent K+ channel is selective for K+, with a Km of 32 mM, and does not transport Na+. K+ transport depends on voltage in a manner consistent with a channel activity that is not voltage-regulated. Thus, the mitochondrial ATP-dependent K+ channel exhibits properties that are remarkably similar to those of the ATP-dependent K+ channels of plasma membranes.     

The proton stoichiometry of electron transport in Ehrlich ascites tumor mitochondria.

Initial rate measurements of the stoichiometric relationships between H+ ejection, K+ and Ca2+ uptake, and electron transport were carried out on mitochondria from Ehrlich ascites tumor cells grown in mice. With succinate as substrate and N-ethylmaleimide to prevent interfering H+ reuptake via the phosphate carrier, close to 8 H+ were ejected per oxygen atom reduced (H+/O ejection ratio = 8.0); with the NAD-linked substrates pyruvate or pyruvate + malate, the H+/O ejection ratio was close to 12. The average H+/site ratio (H+ ejected/2e-/energy-conserving site) was thus close to 4. The simultaneous uptake of charge-compensating cations, either K+ (in the presence of valinomycin) or Ca2+, was also measured, yielding average K+/site uptake ratios of very close to 4 and Ca2+/site ratios close to 2. It was also demonstrated that each calcium ion enters the respiring tumor mitochondria carrying two positive electric charges. These stoichiometric data observed in mitochondria from Ehrlich ascites tumor cells thus are in complete agreement with similar data on normal rat liver and rat heart mitochondria and suggest that the H+/site ratio of mitochondrial electron transport may be 4 generally. It was also observed that the rate of deltaH+ back-decay in anaerobic tumor mitochondria following oxygen pulses is some 6- to 8-fold greater than in rat liver mitochondria tested at equal amounts of mitochondrial protein.     

Calcium uptake in rat liver mitochondria accompanied by activation of ATP-dependent potassium channel

The influence of potassium ions on calcium uptake in rat liver mitochondria is studied. It is shown that an increase in K+ and Ca2+ concentrations in the incubation medium leads to a decrease in calcium uptake in mitochondria together with a simultaneous increase in potassium uptake due to the potential-dependent transport of K+ in the mitochondrial matrix. Both effects are more pronounced in the presence of an ATP-dependent K+-channel (K+(ATP)-channel) opener, diazoxide (Dz). Activation of the K+(ATP)-channel by Dz alters the functional state of mitochondria and leads to an increase in the respiration rate in state 2 and a decrease in the oxygen uptake and the rate of ATP synthesis in state 3. The effect of Dz on oxygen consumption in state 3 is mimicked by valinomycin, but it is opposite to that of the classical protonophore uncoupler CCCP. It is concluded that the potential-dependent uptake of potassium is closely coupled to calcium transport and is an important parameter of energy coupling responsible for complex changes in oxygen consumption and Ca2+-transport properties of mitochondria.     

Effect of methyl mercury on phosphorylation, transport, and oxidation in mammalian mitochondria.

the toxic effects of CH3HgCL on mitochondria of mammalian organs including human and rat liver were examined. [203Hg]CH3HGCl was bound mainly to mitochondrial proteins. The binding was not effected by the energy state of mitochondria. The state 3 respiration, oxidative phosphorylation and 32Pi-ATP exchange reaction were inhibited by 10 to 50 nmol of CH3HgCl per mg of mitochondrial protein, while NADH-and succinate-dehydrogenase and ATPase were more resistant to it The difference spectrum of the treated mitochondria indicated that the point of inhibition was located after flavin and before cytochrome b. Mitochondrial swelling was induced by CH3HgCl, in accordance with previous morphological observations in vivo. The swelling, stimulation of ATPase and energy-dependent H+ extrusion cauded by CH3HgCl were equally dependent on K+. Under these conditions, uptake of K+ by mitochondria was increased and the membrane potential was dissipated. Unlike the case with other organomercuric compounds, transport of phosphate was not inhibited by CH3HgCl. When tested on liposomes, CH3HgCl itself was not lipid-soluble, as some organomercuric compounds are, and was not an uncoupler or a K+-carrier. It was concluded that protein bound CH3HgS-induced K+ uptake into mitochondria and the resulting loss of membrane potential was the major cause of uncoupling, though at higher concentrations, the electron transport system was also inhibited.     

A Highly Active ATP-Insensitive K+ Import Pathway in Plant Mitochondria

We describe here a regulated and highly active K+ uptake pathway in potato (Solanum tuberosum), tomato (Lycopersicon esculentum), and maize (Zea mays) mitochondria. K+ transport was not inhibited by ATP, NADH, or thiol reagents, which regulate ATP-sensitive K+ channels previously described in plant and mammalian mitochondria. However, K+ uptake was completely prevented by quinine, a broad spectrum K+ channel inhibitor. Increased K+ uptake in plants leads to mitochondrial swelling, respiratory stimulation, heat release, and the prevention of reactive oxygen species formation. This newly described ATP-insensitive K+ import pathway is potentially involved in metabolism regulation and prevention of oxidative stress.     

Regulation of ion transport in mitochondria by respiratory chain enzymes and ATPase

The effects of the respiratory chain inhibitors as well as those of the inhibitors and substrates of ATP-synthetase in Ca2+ and K+ transport induced in the mitochondria upon the medium acidification in the presence of phosphate or arsenate, were investigated. Evidence has been obtained suggesting that under the experimental conditions used the transmembrane fluxes of K+ and Ca2+ are paralleled with H+ leakage through the proton channel of ATPase. It was found also that the system inducing cation fluxes at low pH values included peroxidation and hydrolysis of phospholipids. A scheme of regulation of ion transport in the mitochondria involving oxidative phosphorylation and oxidation and hydrolysis of lipids is proposed.     

Valinomycin-induced chloride permeability in isolated rat liver mitochondria

1. Ionophore-induced osmotic swelling was used to study Cl- transport in isolated rat liver mitochondria. 2. Energy-dependent, neutral ionophore-induced swelling in Cl- salts at pH 7.2 required K+ and was preceded by a brief lag phase that was absent in chlorotributyltin-induced swelling. 3. Treatments that stimulated or inhibited mitochondrial K+/H+ exchange had qualitatively similar effects on both valinomycin-induced swelling and the associated lag phase. 4. The results suggest that valinomycin-induced Cl- permeability results from an interaction between the K+/H+ antiporter and neutral ionophore K+ complexes.     

Purification of a reconstitutively active K+/H+ antiporter from rat liver mitochondria

We describe purification of three different states of the 82-kDa K+/H+ antiporter from rat liver mitochondria. The denatured 82-kDa protein, identified by its selective labeling with [14C]dicyclohexylcarbodiimide (DCCD), was purified by preparative two-dimensional gel electrophoresis. This purified product was used to raise and immunopurify monospecific polyclonal antibodies. Western blot analysis showed that the [14C] DCCD-labeled 82-kDa protein is not a DCCD-crosslinked product. The native, [14C]DCCD-labeled, 82-kDa protein was purified by (NH4)2SO4 fractionation and column chromatography, using 14C labeling and gel electrophoresis to track the protein. The native, non-DCCD-labeled 82-kDa protein was purified by similar procedures, using immunopurified antibodies to track the protein. DCCD binding had no effect on chromatographic behavior of the antiporter protein. This protocol resulted in purification of the 82-kDa protein to apparent homogeneity. The purified, native 82-kDa protein was reconstituted into proteoliposomes and assayed for K+ transport with the new fluorescent probe, PBFI. K+ transport was electroneutral and was inhibited by DCCD, Mg2+, and timolol. The turnover number for K+ transport was about 1000 s-1, very similar to the value previously estimated in intact mitochondria.     

Effect of bivalent metal ions on the fluctuations of ion currents in rat liver mitochondria

Ions of bivalent metals are shown to arrange in the Sr2+ greater than Ca2+ greater than Ba2+ greater than Mn2+ series as to their ability to induce ion flow vibration in the rat liver mitochondria. Application of Sr2+ results in the most stable prolonged vibrations of ion flows in mitochondria. Ca2+, Ba2+ and Mn2+ induce slightly pronounced and intensively damped vibrations. The studied Mg2+, Co2+, Ni2+, Pb2+ Fe2+ cations have effect on valinomycin-induced K+ transport in mitochondria and do not induce vibrations. It is established that the ability of bivalent cations to induce vibrations is associated with the possibility of their transfer through the mitochondrion membrane and accumulation in the matrix. Inhibitors of the electrogenic Ca2+ transport in mitochondria produce the similar effect on vibrations induced by Sr2+, Ca2+, Ba2+ and Mn2+.     

Characterisation of an ATP-dependent Ca2+ transport system in a plasma membrane enriched fraction from rat parotid

A membrane fraction enriched in plasma membrane marker enzymes K+-dependent p-nitrophenyl phosphatase, 5'-nucleotidase and alkaline phosphatase was prepared from rat parotid glands using Percoll self-forming gradient. This fraction contained an ATP-dependent CA2+ transport system which was distinct from those located on the endoplasmic reticulum and mitochondria of parotid glands. The Km for ATP was 0.57 +/- 0.07 mM (n = 3). Nucleotides other than ATP such as ADP, AMP, GTP, CTP, UTP or ITP were unable to support significant Ca2+ uptake. ATP-dependent Ca2+ uptake displayed sigmoidal kinetics with respect to free Ca2+ concentration with a Hill coefficient of 2.02. The K0.5 for Ca2+ was 44 +/- 3.1 nM (n = 3) and the average Vmax was 13.5 +/- 1.1 nmol/min per mg of protein. The pH optimum was 7.2. Trifluorperazine inhibited Ca2+ transport with half maximal inhibition observed at 30.8 microM. Complete inhibition was observed at 70 microM trifluorperazine. Exogenous calmodulin however had no effect on the rate of transport. Na+ and K+ ions activated Ca2+ transport at 20 to 30 mM ion concentrations. Higher concentrations of Na+ or K+ were inhibitory.     

The effect of ferric iron complex on isolated rat liver mitochondria. II. Ion movements

It has been found that addition of iron(III)-gluconate complex to rat liver mitochondria disturbed the mitochondrial Ca2+ transport. Indirect evidence when the changes in the membrane potential during the transport of Ca2+ were followed, as well as direct evidence, when the fluxes of Ca2+ were monitored by a Ca2+-selective electrode, indicated that this iron complex induced an efflux of Ca2+ from liver mitochondria. The mechanisms by which iron induced Ca2+ release appeared to be linked to the induction of lipoperoxidation of mitochondrial membrane. The mitochondrial membrane, however, did not become irreversibly damaged under these conditions, as indicated by its complete repolarization. It was also shown that the induction by iron of lipoperoxidation brought about an efflux of K+ from mitochondria.     

Reconstitution of the beef heart and rat liver mitochondrial K+/H+ (Na+/H+) antiporter. Quantitation of K+ transport with the novel fluorescent probe, PBFI

New indicators for fluorescent measurement of Na+ and K+ ions should prove particularly useful for studies of reconstituted carriers of these ions. We show that PBFI, a K(+)-specific probe, provides a convenient and sensitive assay for the study of K+ uptake mediated by the reconstituted mitochondrial K+/H+ (Na+/H+) antiporter. Fluorescent measurements have enabled us for the first time to establish reconstitution of the K+/H+ (Na+/H+) antiporter from beef heart as well as from rat liver mitochondria. This technique has also enabled us to establish that dicyclohexylcarbodiimide is capable of complete inhibition of K+/H+ antiport in the reconstituted system, in accord with findings in intact mitochondria. PBFI fluorescence, which measures net K+ uptake, was essential for this corroboration, since dicyclohexylcarbodiimide is not capable of complete inhibition of 42K+/K+ or 86Rb+/Rb+ exchange, presumably because it acts selectively on proton transport within the carrier.     

Electrophoresis of chloride ions and changes in the membrane potential of energized mitochondria]

In energized rat liver mitochondria the simultaneous H+, K+ and C1- transport was studied by corresponding ion selective electrodes. It was shown that the C1- transport induced by valinomycin, by valinomycin plus carbonyclyanide m-chlorophenylhydrazone was governed by the membrane potential. It is suggested that observed in energized mitochondria the C1- electrophoresis may servt as an indicator of membrane potential changes.     

Evidence for more than one Ca2+ transport mechanism in mitochondria.

The active transport and internal binding of the Ca2+ analogue Mn2+ by rat liver mitochondria were monitored with electron paramagnetic resonance. The binding of transported Mn2+ depended strongly on internal pH over the range 7.7-8.9. Gradients of free Mn2+ were compared with K+ gradients measured on valinomycin-treated samples. In the steady state, the electrochemical Mn2+ activity was larger outside than inside the mitochondria. The observed gradients of free Mn2+ and of H+ could not be explained by a single "passive" uniport or antiport mechanism of divalent cation transport. This conclusion was further substantiated by observed changes in steady-state Ca2+ and Mn2+ distributions induced by La3+ and ruthenium red. Ruthenium red reduced total Ca2+ or Mn2+ uptake, and both inhibitors caused release of divalent cation from preloaded mitochondria. A model is proposed in which divalent cations are transported by at least two mechanisms: (1) a passive uniport and (2) and active pump, cation antiport or anion symport. The former is more sensitive to La3+ and ruthenium red. Under energized steady-state conditions, the net flux of Ca2+ or Mn2+ is inward over (1) and outward over (2). The need for more than one transport system inregulating cytoplasmic Ca2+ is discussed.     

Inhibition of succinate oxidation and K+ transport in mitochondria during hibernation

Respiration of liver mitochondria of ground squirrels changes with physiological state. The inhibition of respiration at the level of dehydrogenases occurs during hibernation which is spontaneously removed during arousal. The main mechanism causing a decrease in respiration during hibernation seems to be the inhibition of succinate oxidation, induced by oxaloacetic acid. This is evidenced by the removal of the inhibition by glutamic and isocitric acids. A close correlation between the changes of K+ transport in mitochondria and of the physiological state of hibernator is observed. During hibernation the K+ transport rate decreases 3 times and during arousal it increases 1.5-fold in comparison with the active animals. The K+ content in mitochondria of hibernating and active ground squirrels is the same, whereas during arousal it increases 2-fold.     

Regulation of thyroid hormones of the interaction of mitochondria with low-molecular weight cytoplasmic mediators, induced by phosphate- dependent transport of K+ and H+ ions through the mitochondrial inner membrane

In vivo thyroid hormones control the binding to mitochondria of low molecular weight water-soluble cytoplasmic mediators that are capable to induce oxidative phosphorylation uncoupling, by increasing the sensitivity of mitochondria to the effects of these mediators. In hyperthyroid rat liver mitochondria cytoplasmic mediators stimulate the phosphate-dependent transport of K+ and H+ in a greater degree than in liver mitochondria of control rats. The increase in the oxidative phosphorylation uncoupling by cytoplasmic mediators is one of mechanisms of thermogenesis stimulation by thyroid hormones.     

Isolation of low molecular weight cytoplasmic regulators from the rat liver inducing the electrophoretic transport of K+ ions and phosphate across the inner mitochondrial membrane

A water-soluble thermostable factor from rat liver cytoplasm whose activity decreases during starvation, causes the uncoupling of oxidative phosphorylation and stimulates pyruvate oxidation in rat liver mitochondria. The activity of this factor is insensitive to pronase treatment. Gel filtration and ion-exchange chromatography resulted in three low molecular weight water-soluble fractions which bear a negative charge at alkaline values of pH and induce electrophoretic transport of K+ and phosphate across the inner mitochondrial membrane. The effect of this factor on K+ transport is manifested at pH less than or equal to 7.0, that on phosphate transport-at pH 6.5-7.6.     

The reconstituted isolated uncoupling protein is a membrane potential driven H+ translocator.

The isolated uncoupling protein (UCP) from brown fat adipose tissue mitochondria has been reconstituted into artificial phospholipid vesicles. Because of the high lability of H+ transport, several new steps have been introduced in the reconstitution; the detergent octyl-POE, the addition of phospholipids to mitochondria prior to solubilization and purification, the vesicle formation by rapid removal of detergent with polystyrene beads and of external salts by a mixed ion exchange. In the K+-loaded proteoliposomes, H+ influx can be induced by a diffusion potential on addition of valinomycin. H+ influx is inhibited to more than 90% by GTP addition, in the assay for UCP activity. By reversing delta psi with external K+, H+ efflux is measured, however, at a four times lower rate. In vesicles loaded with internal GTP, H+ influx is fully inhibited but can be activated by Dowex-OH treatment to an even higher rate than that found in the GTP-free vesicles. Binding studies with GTP show that most of the active UCP are oriented with the binding site outside as in mitochondria, and that in GTP-loaded vesicles GTP is also bound at the outside. The rate of H+ transport is linearly dependent on the membrane potential. Despite the ordered orientation, there is no 'valve' mechanism, since there is H+ efflux with a reversed potential. pH dependency is only small between pH 6.5 and 7.5, indicating that the H+-translocating site differs from the highly pH-dependent nucleotide-binding site. The turnover number of reconstituted UCP is commensurate with mitochondrial function and indicates a carrier instead of a channel-type H+ transport.(ABSTRACT TRUNCATED AT 250 WORDS)     

The K+ conductance of the inner mitochondrial membrane. A study of the inducible uniport for monovalent cations

Addition of A23187 plus EDTA to rat liver mitochondria induces a common uniport pathway for monovalent cations. In this study, we have carried out a detailed characterization of the flow/force relationship for K+ transport along this pathway under steady state conditions. In the presence of EDTA, the K+ conductance is a linear function of external K+ in the range 0-20 mM K+, with a slope of 0.15 nmol of K+ x mg of protein-1 x min-1 x mV-1. The K+ conductance is inhibited by Mg2+ in the range 10(-9)-10(-6) M, while K+ flux is stimulated by the sulfhydryl group reagent mersalyl. Uniport activity can be detected in native mitochondria. These findings are compatible with the notion that electrophoretic K+ flux across the inner membrane takes place via a regulated K+ uniport with the potential of transporting K+ at rates in excess of 600 nmol x mg of protein-1 x min-1.