Ion transport by heart mitochondria: XXVII. The relation of mercurial-dependent adenosine triphosphatase activity to ion movements

The properties of a mercurial-dependent adenosine triphosphatase activity have been examined in isolated beef heart mitochondria. The reaction differs from that induced by uncouplers in that it is associated with extensive ion uptake and osmotic swelling, is highly specific for K⁺ over Na⁺, and is enhanced by respiration. Evidence is presented which suggests that the following events can account for the observations: (1) The mercurial blocks the phosphate transporter so that phosphate hydrolyzed from ATP is trapped in the matrix. (2) This interior negative potential causes cations to move inward and swelling results. (3) Permeability to K⁺ but not to Na⁺ is enhanced greatly by the reaction of the mercurial with the membrane. The inward movement of K⁺ closely resembles that produced by valinomycin, in that it is accompanied by proton ejection into the medium and it rapidly establishes a condition in which ion gradients cannot be maintained. This marked increase in permeability may be related to the pH gradient and is manifest as additional passive swelling in the absence of sucrose and passive contraction when sucrose is present. A comparison of the kinetics of swelling and of ATP hydrolysis shows that the elevated rates of ATPase are correlated with this condition of high permeability. When a corresponding condition of high permeability to Na⁺ is established by treatment with gramicidin or EDTA, the mercurial-dependent ATPase is nearly as rapid in Na⁺ as in the K⁺ medium. It appears, therefore, that the K⁺ specificity resides at the level of membrane permeability and is not a feature of the ATPase reaction per se. (4) Respiration appears to affect the ATPase reaction by virtue of its ability to extrude ions from the matrix in the presence of the mercurial. p-Chloromercuriphenyl sulfonate causes a switch from respiration-dependent ion accumulation to respiration-dependent ion extrusion to occur. A model to explain these reactions is presented.     

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.     

Effect of hypoxen on bioenergetic processes in mitochondria and activity of ATP-sensitive potassium channel

The effect of Hypoxen (HX) on bioenergetic processes in the mitochondria of heart and liver of rats connected with respiration, generation of hydrogen peroxide and activity of ATP-sensitive K-channel (mitoKATP) has been studied. It is shown that HX in the range of 0.05–10 μg/mL stimulates respiration, increases the coupling in the respiratory chain, and increases the formation of H₂O₂ and energy-dependent swelling associated with potassium transport in mitochondria. HX removes the inhibitory effect of ATP on the energy-dependent swelling of mitochondria and partially reduces the accumulation of H₂O₂ in the presence of ATP. The role of antihypoxic and antioxidant action of HX associated with the activation of mitoK_ATP is discussed.     

Energy-dependent contraction of swollen heart mitochondria--activation by butacaine.

Butacaine and certain other local anesthetics markedly stimulate the rate, extent, and efficiency of respiration-dependent contraction of heart mitochondria in nitrate salts at alkaline pH. The local anesthetics also induce respiratory control associated with contraction (i.e., the elevated rate of respiration during contraction declines to a State 4-like controlled rate when contraction is complete) so that the reaction at alkaline pH closely resembles the rapid and highly efficient process seen at neutral pH. Respiration-dependent contraction appears to be an osmotic response to cation extrusion on an endogenous cation/H⁺ exchanger (G. P. Brierley, M. Jurkowitz, E. Chavez, and D. W. Jung, 1977, J. Biol. Chem.252, 7932–7939). At alkaline pH, net ion extrusion is slow and inefficient due to the elevated permeability of the membrane to monovalent cations through a putative uniport pathway. Butacaine and other local anesthetics seem to decrease influx-efflux cycling of cations at alkaline pH by restricting cation influx through this uniport. Passive swelling at pH 8.3 in nitrate salts indicates that the uniport reaction is sensitive to Ca²⁺ and has a cation-selectivity of Na⁺ > K⁺ > Li⁺. Butacaine does not inhibit passive swelling under these conditions but produces effects identical to those of classical uncouplers and consistent with increased H⁺ conductance and accelerated influx of cations by cation/H⁺ exchange in nonrespiring mitochondria. However, since contraction in respiring mitochondria is inhibited by uncouplers but stimulated by butacaine, it is apparent that butacaine is not an effective proton conductor in energized mitochondria.     

The uptake and extrusion of monovalent cations by isolated heart mitochondria

Summary The factors involved in the movement of monovalent cations across the inner membrane of the isolated heart mitochondrion are reviewed. The evidence suggests that the energy-dependent uptake of K⁺ and Na⁺ which results in swelling of the matrix is an electrophoretic response to a negative internal potential. There are no clear cut indications that this electrophoretic cation movement is carrier-mediated and possible modes of entry which do not require a carrier are examined. The evidence also suggests that the monovalent cation for proton exchanger (Na⁺ > K⁺) present in the membrane may participate in the energy-dependent extrusion of accumulated ions. The two processes, electrophoretic cation uptake (swelling) and exchange-dependent cation extrusion (contraction) may represent a means of controlling the volume of the mitochondrion within the functioning cell. A number of indications point to the possibility that the volume control process may be mediated by the divalent cations Ca⁺² and Mg⁺². Studies with mercurial reagents also implicate certain membrane thiol groups in the postulated volume control process.An invited article.     

OSMOTICALLY LYSED RAT LIVER MITOCONDRIA : Biochemical and Ultrastructural Properties in Relation to Massive Ion Accumulation

Osmotically lysed rat liver mitochondria have been utilized for a study of the biochemical and ultrastructural properties in relation to divalent ion accumulation. Osmotic lysis of mitochondria by suspension and washing in cold, distilled water results in the extraction of about 50% of the mitochondrial protein, the loss of the outer mitochondrial membrane, an increase in respiration, and a marked decrease in the ability to catalyze oxidative phosphorylation. Nevertheless, except for a decrease in the ability to accumulate Sr²⁺ by an ATP-supported process, these lysed mitochondria retain full capacity to accumulate massive amounts of divalent cations by respiration-dependent and ATP-supported mechanisms. The decreased ability of osmotically lysed mitochondria to accumulate Sr²⁺ by an ATP-energized process does not appear to be due to a loss or inactivation of a specific Sr²⁺-activated ATPase. The energy-dependent accumulation processes in lysed mitochondria show an increased sensitivity to inhibition by monovalent cations. Extraction of cytochrome c from osmotically lysed mitochondria results in a complete loss of phosphorylation and the respiration-dependent accumulation of Ca²⁺; a lesser, but significant, decrease in the ATP-supported accumulation of Ca²⁺ also was observed. The addition of cytochrome c fully restores the respiration-dependent accumulation of Ca²⁺ to the level present in unextracted, osmotically lysed mitochondria. The ATP-supported process is not affected by the addition of cytochrome c to extracted mitochondria, indicating that cytochrome c is not involved in ion transport energized by ATP. The osmotically lysed mitochondria are devoid of outer membranes and contain relatively little matrix substance. The accumulation of Ca²⁺ and P_i by lysed mitochondria under massive loading conditions is accompanied by the formation of electron-opaque deposits within the lysed mitochondria associated with the inner membranes. This finding suggests that the inner membrane plays a role in the deposition of divalent ions within intact rat liver mitochondria. The relevance of these observations to those of other investigators is discussed.     

Mechanisms of gentamicin-induced dysfunction of renal cortical mitochondria: II. Effects on mitochondrial monovalent cation transport

Mitochondrial swelling techniques were used to evaluate the effects of the aminoglycoside antibiotic gentamicin on renal cortical mitochondrial monovalent cation permeability. Gentamicin behaved like EDTA to enhance energy-dependent Na⁺- and K⁺-acetate uptake with a relatively greater effect on Na⁺-acetate uptake. Mg²⁺ prevented and reversed the effects of both EDTA and gentamicin. Neither agent affected energy-independent uptake of Na⁺ and K⁺-acetate. Gentamicin did not enhance energy-independent uptake of K⁺- and Na⁺-nitrate. Gentamicin enhanced energy-dependent swelling in a chloride- and phosphate-containing medium as a function of the medium Na⁺ and K⁺ concentration. This effect occurred simultaneously with gentamicin-induced stimulation of State 4 respiration and was blocked by Mg²⁺. Gentamicin did not affect phosphate transport. The results are taken to indicate a specific action of gentamicin to enhance mitochondrial monovalent cation permeability at an Mg²⁺-sensitive site and it is proposed that this accounts for the effects of gentamicin on mitochondrial respiration.     

Respiration-dependent uptake and extrusion of Mg2+ by isolated heart mitochondria

It has been known for some time that isolated heart mitochondria can both take up and extrude Mg2+ by respiration-dependent, uncoupler-sensitive processes. A re-examination of these reactions reveals that the respiration-dependent uptake of Mg2+ can be quite rapid and efficient and is apparently preceded by a passive binding to the inner membrane. The rate of Mg2+ uptake can exceed 30 ng ion/min/mg protein at an efficiency of about 1 ng ion Mg2+ accumulated per ng atom O2 consumed. Passive binding and respiration-dependent accumulation of Mg2+ are strongly inhibited by K+ and other monovalent cations and the uptake reaction is further decreased by the presence of ATP or ADP. Under conditions approaching those faced by mitochondria in situ (state 3 respiration in a KCl medium) the rate of Mg2+ uptake, as estimated from 28Mg2+ distribution, is no more than 0.25 ng ion/min/mg. When heart mitochondria are suspended in a Mg2+-free medium, a slow, respiration-dependent Mg2+ efflux is seen. This reaction is quite insensitive to external K+ and otherwise shows an inhibitor profile markedly different from that of the Mg2+ accumulation reaction. Neither the uptake nor the loss of Mg2+ is inhibited by ruthenium red or diltiazem. These reactions therefore appear unrelated to those involved in the uptake and release of Ca2+. It is concluded that heart mitochondria have separate pathways available for Mg2+ uptake and release.     

Effect of hypoxenum on bioenergetic processes in mitochondria and the activity of ATP-sensitive potassium channel

The effect of hypoxenum on bioenergetic processes in heart and liver mitochondria of rats, connected with respiration, the generation of hydrogen peroxide, and the activity of ATP-sensitive K-channel ((mitoK)ATP) has been studied. It was shown that hypoxenum in the concentration range of 0.05-10 microg/ml stimulates respiration, increases the coupling in the respiratory chain, and enhances the formation of H2O2 and energy-dependent swelling associated with potassium transport in mitochondria. Hypoxenum removes the inhibitory effect of ATP on the energy-dependent swelling of mitochondria and partially reduces the accumulation of H2O2 in the presence of ATP. The role of antihypoxic and antioxidant action of hypoxenum associated with the activation of (mitoK)ATP is discussed.     

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

Swelling of nonenergized heart mitochondria suspended in acetate salts appears to depend on the activity of an endogenous cation/H⁺ exchanger. Passive swelling in acetate shows a characteristic cation selectivity sequence of Na⁺ >Li⁺ >K⁺, Rb⁺, Cs⁺, or tetramethylammonium, a sharp optimum at pH 7.2–7.3, activation by Ca²⁺, and loss of activity on aging which can be related to loss of endogenous K⁺. The reaction is nearly insensitive to either addition of exogenous Mg²⁺ or removal of membrane Mg²⁺ with EDTA. Each of these characteristics of passive swelling in acetate salts is duplicated in chloride media when tripropyltin is added to induce Cl^?/OH^? exchange. In contrast to nonenergized mitochondria, swelling of respiring mitochondria has been postulated to depend on electrophoretic uptake of cations in response to an interior negative membrane potential. Respiration-dependent swelling in acetate shows an indistinct cation selectivity sequence with Li⁺ and Na⁺ supporting higher rates of swelling at higher efficiency than K⁺, Rb⁺, and Cs⁺. The high rates of respiration-dependent swelling in Li⁺ and Na⁺ are inhibited by low levels of exogenous Mg²⁺ (K_i of 5–10 μm), but a significant swelling with almost no cation selectivity persists in the presences of 2 mm Mg²⁺. Removal of membrane Mg²⁺ by addition of EDTA strongly activates the rate of respiration-dependent swelling and converts a sigmoid dependency of swelling rate on Li⁺ concentration to a hyperbolic one with a Km of about 14 mm Li⁺. The cation selectivity and Mg²⁺ dependence of the reaction induced in chloride salts by tripropyltin are identical to these properties in acetate. Energy-dependent swelling in acetate shows optimum activity at pH 6.5 which appears related to the availability of free acetic acid, since the corresponding reaction induced in chloride shows a broad optimum at about pH 7.5. These studies support the concept that monovalent cations enter nonenergized mitochondria by electroneutral exchange with protons but penetrate respiring mitochondria by electrophoretic movement through one or more uniport pathways. They further suggest that both a Mg²⁺-sensitive uniport with high activity for Na⁺ and Li⁺ and a Mg²⁺-insensitive pathway with little cation discrimination are available in the membrane.     

Energy-dependent accumulation of iron by isolated rat liver mitochondria. IV. Relationship to the energy state of the mitochondria

1. The energy-dependent accumulation of iron by isolated rat liver mitochondria, respiring on endogenous substrates, is strongly dependent on the efficiency of energy coupling in the respiratory chain as measured by respiratory control with ADP and the endogenous energy dissipation. The accumulation reached a saturation level at respiratory control with ADP values (with succinate as the substrate) of approx. 4.0.2. In the presence of exogenous substrate, the energy-dependent accumulation of iron was markedly reduced, primarily due to binding of iron as carboxylate complexes having less favourable dissociation constants than the iron(III)-sucrose complex(es).3. The effect of added ATP was at least 2-fold, i.e. that of providing energy and that of chelating iron. When the mitochondria respired on endogenous substrate, the energy-dependent accumulation of iron increased at low concentrations of ATP, whereas higher concentrations (> 50 μM) gradually inhibited the uptake.4. Energization of the mitochondria by the generation of an artificial K⁺ gradient across the inner membrane with valinomycin in a K⁺-free medium increased the energy-dependent accumulation of iron.     

Viriditoxin induces swelling and atpase by activation of calcium transport in liver mitochondria.

Viriditoxin activates ATP hydrolysis (ATPase) and swelling in rat liver mitochondria. The monocarboxylic ionophore of divalent cations, A23187, inhibits both activities at low concentrations of viriditoxin, but does not inhibit the ATPase induced by viriditoxin at concentrations above 2.5 × 10^?5M. However, the monocarboxylic ionophore of monovalent cations, monensin, has no effect on the viriditoxin induced ATPase, but inhibits the valinomycin induced activity. Viriditoxin may facilitate the active transport of membrane bound calcium into the matrix of mitochondria     

Amino acid and divalent ion permeability of the pores formed by the Bacillus thuringiensis toxins Cry1Aa and Cry1Ac in insect midgut brush border membrane vesicles

The pores formed by Bacillus thuringiensis insecticidal toxins have been shown to allow the diffusion of a variety of monovalent cations and anions and neutral solutes. To further characterize their ion selectivity, membrane permeability induced by Cry1Aa and Cry1Ac to amino acids (Asp, Glu, Ser, Leu, His, Lys and Arg) and to divalent cations (Mg²⁺, Ca²⁺ and Ba²⁺) and anions (SO₄²⁻ and phosphate) was analyzed at pH 7.5 and 10.5 with midgut brush border membrane vesicles isolated from Manduca sexta and an osmotic swelling assay. Shifting pH from 7.5 to 10.5 increases the proportion of the more negatively charged species of amino acids and phosphate ions. All amino acids diffused well across the toxin-induced pores, but, except for aspartate and glutamate, amino acid permeability was lower at the higher pH. In the presence of either toxin, membrane permeability was higher for the chloride salts of divalent cations than for the potassium salts of divalent anions. These results clearly indicate that the pores are cation-selective.     

Ionophoric actions of avenaciolide on mitochondrial cations

Avenaciolide produces an initial stimulation of mitochondrial respiration followed at high doses of the drug by a decline in respiration to less than the unstimulated rate; under these conditions the mitochondria are insensitive to ADP and to uncoupler. At lower avenaciolide concentrations followed by ADP there is a sustained acceleration of respiration which is sensitive to EDTA and oligomycin, pointing to the existence of a Mg-requiring ATPase.Spectrophotometric tests with bromthymol blue and fluorimetry show a similarity between the responses to avenaciolide and divalent cations.Mitochondrial contents of substrate anions and cations are altered by avenaciolide; the extent of the changes depend on the level of the drug used and also on the composition of the medium. If K⁺ is present with an energy source, the uptake of K⁺ at the start of an incubation is enhanced by avenaciolide when supplied at less than 25–30 nmole/mg protein, and the K⁺ gain is accompanied by an uptake of substrate anion; at higher concentrations of avenaciolide the direction of flow is reversed with loss of K⁺, divalent cations, and substrate anions. In potassium-free media, or in the absence of energy only losses of ions are found.Addition of avenaciolide to mitochondria onto which [¹⁴C]octyl malonate had previously been adsorbed results in a discharge of the labeled compound.     

Citrate transport in corn mitochondria

Citrate uptake by corn mitochondria (Zea mays L. B73 × Mol9) was investigated by osmotic swelling and [¹⁴C]citrate accumulation. Uptake driven by passive influx, ammonium gradients, and respiration was followed. There was no requirement for phosphate and/or malate to secure citrate uptake, although under some conditions these additives were promotive. Inhibition of the phosphate and dicarboxylate carriers did not eliminate citrate uptake. Citrate_in/malate_out exchange occurs, but at a rate too slow to account for observed citrate uptake, and depletion of endogenous malate only reduced citrate uptake by 38%. It was concluded that citrate can be rapidly accumulated by a mechanism other than by exchange for dicarboxylates. The effect of uncoupler on respiration-driven [¹⁴C]citrate accumulation, and studies of passive swelling using ionophores and uncouplers indicated that the major avenue of citrate uptake is by H⁺/citrate co-transport with a pH optimum near 4.5. The in vivo role of this mechanism is not yet understood.     

Citrate and succinate uptake by potato mitochondria

The uptake of [¹⁴C]citrate and [¹⁴C]succinate was studied in potato mitochondria (Solanum tuberosum var. Russet Burbank) using cellulose pore filtration and was found to occur by the same mechanisms as described for mammalian mitochondria. Potato mitochondria, in the absence of respiration, have a very low capacity for uptake by exchange with endogenous anions, taking up only 2.4 nanomoles citrate and 2.0 nanomoles succinate per milligram protein. Maximum citrate uptake of over 17 nanomoles per milligram protein occurs in the presence of inorganic phosphate, a dicarboxylic acid, and an external energy source (NADH), conditions where net anion accumulation proceeds, mediated by the interlinking of the inorganic phosphate, dicarboxylate, and tricarboxylate carriers. Maximum succinate uptake in the absence of respiratory inhibitors requires only added inorganic phosphate.     

Activation of endogenous respiration and anion transport in corn mitochondria by acidification of the medium

Acidification of the suspending medium of corn mitochondria (Zea mays L., WF9 × Mo17) from pH 7.5 to pH 6.8 to 6.4 initiates osmotic swelling with the transportable anions citrate, sulfate, and phosphate. Swelling becomes pronounced with a combination of citrate plus sulfate or phosphate. Acidification proves to activate endogenous respiration, which is essentially zero at pH 7.5. The endogenous respiration transports citrate (in the presence of sulfate or phosphate) which then contributes to respiration and the accelerated osmotic swelling. Mersalyl will inhibit the swelling and antimycin inhibits the endogenous respiration. Magnesium appears to reduce the permeability of the membranes under the acid conditions.     

The metabolic effects and uptake of ethidium bromide by rat liver mitochondria.

The uptake of ethidium bromide by rat liver mitochondria and its effect on mitochondria, submitochondrial particles, and F₁ were studied. Ethidium bromide inhibited the State 4-State 3 transition with glutamate or succinate as substrates. With glutamate, ethidium bromide did not affect State 4 respiration, but with succinate it induced maximal release of respiration. These effects appear to depend on the uptake and concentration of the dye within the mitochondrion. In submitochondrial particles, the aerobic oxidation of NADH is much more sensitive to ethidium bromide than that of succinate. Ethidium bromide partially inhibited the ATPase activity of submitochondrial particles and of a soluble F₁ preparation. Ethidium bromide behaves as a lipophilic cation which is concentrated through an energy-dependent process within the mitochondria, producing its effects at different levels of mitochondrial function. The ability of mitochondria to concentrate ethidium bromide may be involved in the selectivity of the dye as a mitochondrial mutagen.     

Mechanism of active shrinkage in mitochondria II. Coupling between strong electrolyte fluxes

1. Addition of succinate to valinomycin-treated mitochondria incubated in KCl causes a large electrolyte penetration. The process depends on a steady supply of energy and involves a continuous net extrusion of protons. Rates of respiration and of electrolyte penetration proceed in a parallel manner.2. A passive penetration of K⁺ salt of permeant anions occurs in respiratory-inhibited mitochondria after addition of valinomycin. Addition of succinate at the end of the passive swelling starts an active extrusion of anions and cations with restoration of the initial volume. The shrinkage is accompanied by a slow reuptake of protons. The initiation of the active shrinkage correlates with the degree of stretching of the inner membrane. The extrusion of electrolytes is inhibited by nigericin, while it is only slightly sensitive to variations of the valinomycin concentration larger than two orders of magnitude.3. Passive swelling and active shrinkage occurs also when K⁺ is replaced by a large variety of organic cations. The rate of organic cation penetration is enhanced by tetraphenylboron, while the rate of electrolyte extrusion is insensitive to variation of the tetraphenylboron concentration.4. Active shrinkage, either with K⁺ or organic cation salts, is inhibited by weak acids. The phosphate inhibition is removed by SH inhibitors. The active shrinkage is also inhibited by mersalyl to an extent of about 60%.5. Three models of active shrinkage are discussed: (a) mechanoprotein, (b) electrogenic proton pump, and (c) proton-driven cation anion pump.