Oxaloacetate and malate transport by plant mitochondria

The permeability of mitochondria from pea (Pisum sativum L. var Kleine Rheinländerin) leaves, etiolated pea shoots, and potato (Solanum tuberosum) tuber for malate, oxaloacetate, and other dicarboxylates was investigated by measurement of mitochondrial swelling in isoosmolar solutions of the above mentioned metabolites. For the sake of comparison, parallel experiments were also performed with rat liver mitochondria. Unlike the mammalian mitochondria, the plant mitochondria showed only little swelling in ammonium malate plus phosphate media but a dramatic increase of swelling on the addition of valinomycin. Similar results were obtained with oxaloacetate, maleate, fumarate, succinate, and malonate. n-Butylmalonate and phenylsuccinate, impermeant inhibitors of malate transport in mammalian mitochondria, had no marked inhibitory effect on valinomycin-dependent malate and oxaloacetate uptake of the plant mitochondria. The swelling of plant mitochondria in malate plus valinomycin was strongly inhibited by oxaloacetate, at a concentration ratio of oxaloacetate/malate of 10⁻³. From these findings it is concluded: (a) In a malate-oxaloacetate shuttle transferring redox equivalents from the mitochondrial matrix to the cytosol, malate and oxaloacetate are each transported by electrogenic uniport, probably linked to each other for the sake of charge compensation. (b) The transport of malate between the mitochondrial matrix and the cytosol is controlled by the oxaloacetate level in such a way that a redox gradient can be maintained between the NADH/NAD systems in the matrix and the cytosol. (c) The malate-oxaloacetate shuttle functions mainly in the export of malate from the mitochondria, whereas the import of malate as a respiratory substrate may proceed by the classical malate-phosphate antiport.     

Spermidine Uptake by Mitochondria of Helianthus tuberosus

In the present work evidence is provided that spermidine, a polyamine largely present in plant tissues, may be transported, at physiological concentrations, into the matrix space of mitochondria isolated from tubers of Helianthus tuberosus L. cv OB1 (Jerusalem artichoke). It is concluded that the movement of spermidine strictly depends on membrane potential, since it is drastically blocked by valinomycin and only slightly sensitive to nigericin. Mg²⁺ and K⁺ inhibit the transport of spermidine in line with the general concept that these cations compete for the same binding sites on the mitochondrial membrane. In contrast to previous data on mammalian mitochondria, spermidine uptake by plant mitochondria does not depend on the presence of inorganic phosphate. This latter result, along with evidence that Ca²⁺ does not affect accumulation of spermidine, indicates that the control of the polyamine uptake mechanism in plant mitochondria is distinct from that of mammalian systems.     

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.     

Specific inhibition by macrocyclic polyethers of mitochondrial electron transport at site I

The macrocyclic polyethers dibenzo-18-crown-6 (XXVIII) and dicyclohexyl-18-crown-6 (XXXI) inhibit the valinomycin-mediated K⁺ accumulation energized by glutamate, -ketoglutarate, malate plus pyruvate or isocitrate but not that promoted by succinate, ascorbate plus TMPD or ATP. The polyethers inhibit the oxidation of the former group of substrates without preventing either the oxidation of succinate or ascorbate plus TMPD or the hydrolysis of ATP.The substrate oxidation inhibited by the macrocyclic polyethers is relieved in intact mitochondria by increasing the concentration of K⁺ in the medium. It is also completely reverted by supplementing the medium with valinomycin, Cs⁺ and phosphate, or else by the addition of vitamin K₃.In submitochondrial sonic particles the macrocyclic polyethers inhibit the oxidation of NADH as well as the ATP-driven reversal of electron flow at the site I of the electron transport chain. They also block the oxidation of NADH in non-phosphorylating Keilin-Hartree particles as well as in Hatefi's NADH-coenzyme Q reductase. The polyethers do not inhibit electron transport in mitochondria from the yeast which lack the first coupling site.The inhibition of electron transport by the polyethers do not require of the addition of alkali metal cations such as K⁺ in intact mitochondria or other membrane preparations.It is established that the macrocyclic polyethers XXVIII and XXXI, already characterized as mobile carrier molecules for K⁺ in model lipid membranes, inhibit electron transport at site I of the electron transport chain from mitochondrial membranes.It is suggested that the ability of the polyethers to coordinate alkali metal cations in aqueous versus lipid environments, but not K⁺ transportper se, is related to their rotenone-like induced inhibition of electron flow in mitochondrial membranes.Supported in part by a Grant from the Research Corporation.     

THE PENETRATION OF THE MEMBRANE OF BRAIN MITOCHONDRIA BY ANIONS

The permeability of the membrane of rat brain non-synaptosomal mitochondria, towards inorganic and substrate anions, was assessed by measuring the rate of swelling that occurred when mitochondria were suspended in an iso-osmotic solution of a permeant anion, in the presence of a permeant cation such as NH⁺₄ or K⁺ in the presence or absence of valinomycin. In NH⁺₄-phosphate swelling was higher than it was in KCI or K⁺-phosphate, which showed the prevalence of the mechanism of phosphate transport previously demonstrated in liver mitochondria. The entry of succinate and L-malate seemed to require the presence in the inner mitochondrial membrane of specific carriers. as previously postulated for liver mitochondria, but the rate of swelling of brain mitochondria was lower than that of liver organelles. In K⁺-succinate, in the presence of antimycin, added ATP induced swelling and this was attributable to the simultaneous permeation both of the anion and the cation. Fumarate did not penetrate into brain mitochondria. Practically no swelling was recorded in NH⁺₄ or K⁺-citrate, which indicated that this anion penetrated poorly into the isolated brain mitochondria even in the presence of malate. Swelling occurred in NH⁺₄-L-glutamate in the presence of rotenone, and the entry of this anion seemed to follow a gradient of concentration although the presence of a specific translocator in the inner mitochondrial membrane might be concerned. The entry of glutamate was independent of that of phosphate and N-ethylmaleimide appeared to be a specific inhibitor of this entry. Swelling in K⁺-L-glutamate, in the presence of rotenone, was enhanced by the addition of valinomycin or ATP but in the latter case when osmotic equilibrium was reached swelling was not reversed by oligomycin. In conclusion, the lesser extent of swelling of isolated brain mitochondria compared with liver mitochondria could be attributed to the heterogeneity of the populations of these organelles, each population possessing its own characteristics of membrane permeability. Observations of electron micrographs of brain mitochondria incubated in iso-osmotic substrate anions confirmed the heterogeneous rate of swelling of these particles.     

Mechanism of uncoupling by uncouples of oxidative phosphorylation

Classical uncouplers duplicate exactly the uncoupling actions of the valinomycin-nigericin ionophoric combination in presence of K⁺ — a combination that mediates cyclical transport of K⁺ driven by electron transfer or pyrophosphorolysis of ATP in mitochondria. Evidence has been presented that uncouplers have the properties essential for mediating coupled cyclical transport of cations and that uncoupling of oxidative phosphorylation can be rationalized in terms of one coupled process being displaced and replaced by another. The critical demonstrations were first that uncoupling is a cation-dependent process and that only those cations that can undergo complexation with uncouplers are effective in restoring mitochondrial uncoupler action in a cation-deficient medium. The second demonstration was that uncouplers are ionophores, not only of the nigericin type but also of the valinomycin type (electrogenic). This combination in one molecule of electrogenic as well as non-electrogenic ionophoric activity for cations endows uncouplers with the capability for duplicating the uncoupling action of the valinomycin-nigericin combination and for mediating coupled cyclical transport of cations.     

Effects of antibiotic ionophore, A23187, on oxidative phosphorylation and calcium transport of liver mitochondria

A23187, a new antibiotic with ionophore properties, uncoupled oxidative phosphorylation in mitochondria which oxidized either malate plus glutamate or succinate. Ca²⁺, but not Mg²⁺, enhanced the uncoupling effect. Fluorescence of ANS¹ was increased by A23187 suggesting the mitochondrial membranes were de-energized. This de-energization was presumably by activation of the energy-dependent uptake of Ca²⁺. The steady-state measurements of murexide-divalent cation complexes showed that A23187 caused mitochondria to release the accumulated Ca²⁺ to the medium. This reduced the transmembrane Ca²⁺ gradient even though normal active Ca²⁺ uptake could take place. A23187 inhibited activity of ATPase induced by 2,4-dinitrophenol, valinomycin, and Ca²⁺. The addition of Mg²⁺ could prevent this inhibition presumably by maintaining the endogenous Mg²⁺ concentration. The above metabolic events could be explained by the fact that molecules of A23187 function in the mitochondrial inner membrane as mobile carriers for divalent cations.     

Increased Potassium Conductance of Brain Mitochondria Induces Resistance to Permeability Transition by Enhancing Matrix Volume

Modulation of K⁺ conductance of the inner mitochondrial membrane has been proposed to mediate preconditioning in ischemia-reperfusion injury. The mechanism is not entirely understood, but it has been linked to a decreased activation of mitochondrial permeability transition (mPT). In the present study K⁺ channel activity was mimicked by picomolar concentrations of valinomycin. Isolated brain mitochondria were exposed to continuous infusions of calcium. Monitoring of extramitochondrial Ca²⁺ and mitochondrial respiration provided a quantitative assay for mPT sensitivity by determining calcium retention capacity (CRC). Valinomycin and cyclophilin D inhibition separately and additively increased CRC. Comparable degrees of respiratory uncoupling induced by increased K⁺ or H⁺ conductance had opposite effects on mPT sensitivity. Protonophores dose-dependently decreased CRC, demonstrating that so-called mild uncoupling was not beneficial per se. The putative mitoK_ATP channel opener diazoxide did not mimic the effect of valinomycin. An alkaline matrix pH was required for mitochondria to retain calcium, but increased K⁺ conductance did not result in augmented ΔpH. The beneficial effect of valinomycin on CRC was not mediated by H₂O₂-induced protein kinase Cϵ activation. Rather, increased K⁺ conductance reduced H₂O₂ generation during calcium infusion. Lowering the osmolarity of the buffer induced an increase in mitochondrial volume and improved CRC similar to valinomycin without inducing uncoupling or otherwise affecting respiration. We propose that increased potassium conductance in brain mitochondria may cause a direct physiological effect on matrix volume inducing resistance to pathological calcium challenges.     

Salinomycin-induced apoptosis of human prostate cancer cells due to accumulated reactive oxygen species and mitochondrial membrane depolarization

The anticancer activity of salinomycin has evoked excitement due to its recent identification as a selective inhibitor of breast cancer stem cells (CSCs) and its ability to reduce tumor growth and metastasis in vivo. In prostate cancer, similar to other cancer types, CSCs and/or progenitor cancer cells are believed to drive tumor recurrence and tumor growth. Thus salinomycin can potentially interfere with the end-stage progression of hormone-indifferent and chemotherapy-resistant prostate cancer. Androgen-responsive (LNCaP) and androgen-refractive (PC-3, DU-145) human prostate cancer cells showed dose- and time-dependent reduced viability upon salinomycin treatment; non-malignant RWPE-1 prostate cells were relatively less sensitive to drug-induced lethality. Salinomycin triggered apoptosis of PC-3 cells by elevating the intracellular ROS level, which was accompanied by decreased mitochondrial membrane potential, translocation of Bax protein to mitochondria, cytochrome c release to the cytoplasm, activation of the caspase-3 and cleavage of PARP-1, a caspase-3 substrate. Expression of the survival protein Bcl-2 declined. Pretreatment of PC-3 cells with the antioxidant N-acetylcysteine prevented escalation of oxidative stress, dissipation of the membrane polarity of mitochondria and changes in downstream molecular events. These results are the first to link elevated oxidative stress and mitochondrial membrane depolarization to salinomycin-mediated apoptosis of prostate cancer cells.     

Voltage-Dependent Conductance Induced in Thin Lipid Membranes by Monazomycin

When present in micromolar amounts on one side of phospholipid bilayer membranes, monazomycin (a positively charged, polyene-like antibiotic) induces dramatic voltage-dependent conductance effects. Voltage clamp records are very similar in shape to those obtained from the potassium conductance system of the squid axon. The steady-state conductance is proportional to the 5th power of the monazomycin concentration and increases exponentially with positive voltage (monazomycin side positive); there is an e-fold change in conductance per 4–6 mv. The major current-carrying ions are univalent cations. For a lipid having no net charge, steady-state conductance increases linearly with KCl (or NaCl) concentration and is unaffected by Ca⁺⁺ or Mg⁺⁺. The current-voltage characteristic which is normally monotonic in symmetrical salt solutions is converted by a salt gradient to one with a negative slope-conductance region, although the conductance-voltage characteristic is unaffected. A membrane treated with both monazomycin and the polyene antibiotic nystatin (which alone creates anion-selective channels) displays bistability in the presence of a salt gradient. Thus monazomycin and nystatin channels can exist in parallel. We believe that many monazomycin monomers (within the membrane) cooperate to form a multimolecular conductance channel; the voltage control of conductance arises from the electric field driving monazomycin molecules at the membrane surface into the membrane and thus affecting the number of channels that are formed.     

Effect of an anti-tumor platinum complex,Pt(II)diaminotoluene,on mitochondrial membrane properties

The effects of platinum complexes, selected for their potent anti-tumor activities, have been studied on rat liver mitochondria. Among the mitochondrial properties which have been studied, the most marked effects of platinum complexes were obtained on functions linked to the inner membrane.cis-Pt(II)(3,4-diaminotoluene) dichloride is shown to stimulate state 4 respiration. It inhibits the phosphate transport into mitochondria, decreases the accumulation of Ca²⁺, and induces a more rapid release of the accumulated Ca²⁺. A release of Mg²⁺ from mitochondria incubated in the absence of added divalent cations, and an efflux of divalent cations from mitochondrial membranes are also observed.All these results indicate a profound modification of the permeability of mitochondrial membrane.     

Perturbation of intracellular K<Superscript>+</Superscript> homeostasis with valinomycin promotes cell death by mitochondrial swelling and autophagic processes

Perturbation of cellular K⁺ homeostasis is a common motif in apoptosis but it is unknown whether a decrease in intracellular K⁺ alone is sufficient to replicate apoptotic hallmarks. We investigated, which mode of cell death is induced by decreasing the intracellular K⁺ concentration using valinomycin, a highly K⁺-selective ionophore. Valinomycin treatment induced mitochondrial swelling and minor nuclear changes in cell lines (BV-2, C6, HEK 293), and in primary mouse microglia and astrocytes. In the microglial cell line BV-2, we identified and quantified three phenotypes in valinomycin-exposed cells. The first and most prevalent phenotype (62 ± 2%) was characterized by swollen mitochondria and no chromatin condensation, and the second (25 ± 3%) by swollen mitochondria and slight chromatin condensation. Only the third phenotype (11 ± 4%) fulfilled criteria of apoptosis by having normal-sized mitochondria and strongly condensed chromatin. Valinomycin-induced swelling of mitochondria was not altered by the adenine nucleotide translocase inhibitor bongkrekic acid (BA), the pan caspase inhibitor Z-VAD-FMK, changing extracellular K⁺ or Cl⁻ concentrations, or the membrane-permeable Ca²⁺ chelator BAPTA-AM. Only co-exposure of cells to valinomycin and the Ca²⁺ ionophore ionomycin in high K⁺ Cl⁻-free extracellular solution suppressed mitochondrial swelling. Ionomycin alone caused shrinkage of mitochondria. Additionally, valinomycin promoted autophagic processes, which were further enhanced by preincubation with BA or with Z-VAD-FMK. Valinomycin-dependent chromatin condensation was inhibited by BA, Z-VAD-FMK, BAPTA-AM, and ionomycin. Our findings demonstrate that mitochondrial swelling and autophagy are common features of valinomycin-exposed cells. Accordingly, valinomycin promotes an autophagic cell death mode, but not apoptosis.     

Modulation of mitochondrial K permeability and reactive oxygen species production by the p13 protein of human T-cell leukemia virus type 1

Human T-cell leukemia virus type-1 (HTLV-1) expresses an 87-amino acid protein named p13 that is targeted to the inner mitochondrial membrane. Previous studies showed that a synthetic peptide spanning an alpha helical domain of p13 alters mitochondrial membrane permeability to cations, resulting in swelling. The present study examined the effects of full-length p13 on isolated, energized mitochondria. Results demonstrated that p13 triggers an inward K⁺ current that leads to mitochondrial swelling and confers a crescent-like morphology distinct from that caused by opening of the permeability transition pore. p13 also induces depolarization, with a matching increase in respiratory chain activity, and augments production of reactive oxygen species (ROS). These effects require an intact alpha helical domain and strictly depend on the presence of K⁺ in the assay medium. The effects of p13 on ROS are mimicked by the K⁺ ionophore valinomycin, while the protonophore FCCP decreases ROS, indicating that depolarization induced by K⁺ vs. H⁺ currents has different effects on mitochondrial ROS production, possibly because of their opposite effects on matrix pH (alkalinization and acidification, respectively). The downstream consequences of p13-induced mitochondrial K⁺ permeability are likely to have an important influence on the redox state and turnover of HTLV-1-infected cells.     

The effect of the energy state of mitochondria on the kinetics of unidirectional cation fluxes

Unidirectional fluxes of triphenylmethylphosphonium and of Cs⁺ as its valinomycin complex were studied using trace concentrations of the cations. The rate constants of influx and efflux were estimated mainly at 0 °C from the uptake kinetics in respiring mitochondria and the in/out ratios in the steady state. The efflux rate constants in the energized state were also measured after dilution of the mitochondrial suspension in the steady state, and in deenergized mitochondria from the efflux rates of cations after inhibition of respiration. It was found that the energy state of mitochondria had little effect on the rate constants of efflux, while the rate of influx was strongly stimulated by respiration. The former finding is not readily explained by the classical chemiosmotic theory, since a transmembrane potential, negative on the inside, formed on energization would be expected to strongly inhibit the efflux of cations. The data may be explained by a pump-and-leak model in which localized electrical fields in hydrophobic domains of the membrane are coupled to the pumping of hydrophobic cations against an electrochemical gradient, while leaks would effect efflux.     

Valinomycin induced energy-dependent mitochondrial swelling,cytochrome <Emphasis Type="Italic">c</Emphasis> release,cytosolic NADH/cytochrome <Emphasis Type="Italic">c</Emphasis> oxidation and apoptosis

In valinomycin induced stimulation of mitochondrial energy dependent reversible swelling, supported by succinate oxidation, cytochrome c (cyto-c) and sulfite oxidase (Sox) [both present in the mitochondrial intermembrane space (MIS)] are released outside. This effect can be observed at a valinomycin concentration as low as 1 nM. The rate of cytosolic NADH/cyto-c electron transport pathway is also greatly stimulated. The test on the permeability of mitochondrial outer membrane to exogenous cyto-c rules out the possibility that the increased rate of exogenous NADH oxidation could be ascribed either to extensively damaged or broken mitochondria. Accumulation of potassium inside the mitochondria, mediated by the highly specific ionophore valinomycin, promotes an increase in the volume of matrix (evidenced by swelling) and the interaction points between the two mitochondrial membranes are expected to increase. The data reported and those previously published are consistent with the view that “respiratory contact sites” are involved in the transfer of reducing equivalents from cytosol to inside the mitochondria both in the absence and the presence of valinomycin. Magnesium ions prevent at least in part the valinomycin effects. Rather than to the dissipation of membrane potential, the pro-apoptotic property of valinomycin can be ascribed to both the release of cyto-c from mitochondria to cytosol and the increased rate of cytosolic NADH coupled with an increased availability of energy in the form of glycolytic ATP, useful for the correct execution of apoptotic program.     

THE ACCUMULATION AND THE RELEASE OF DIVALENT CATIONS ACROSS MITOCHONDRIAL MEMBRANES

Accumulated divalent cations and phosphate (P₁) in isolated bean mitochondria are released by conditions which inhibit respiration, including anaerobiosis and KCN, or by conditions which divert conserved energy from divalent cation uptake. These include ATP synthesis, K^T transport in the presence of valinomycin, and the presence of the uncouplers, 2,4-dinitrophenol and oleic acid. The results indicate that plant mitochondria are not permanent deposit sites for divalent cation and P₁ salts but, rather, function as temporary sequestering sites for these ions. It is suggested that mitochondria may play a role in the control of the movement as well as a regulation of the concentrations of these ions within the cell.     

Proton transport is necessary for divalent metal cations release from deenergized mitochondria

The release of divalent cations (Ca2+ and Sr2+) from rat liver mitochondria after membrane depolarization with protonophore (carbonyl cyanide m-chlorophenyl hydrazone, CCCP), sodium azide and K(+)-ionophore (valinomycin) was studied. It is stated that membrane depolarization itself is not sufficient for cations release from mitochondrial matrix (provided that mitochondrial permeability transition pore is blocked by cyclosporin A). Complete delivering of divalent cations is observed only after protonophore (CCCP) addition to suspension of deenergized mitochondria. The data show that membrane permeabilisation to hydrogen ions (H+) is necessary for complete cation release from the mitochondrial matrix. The enhancement in K(+)-conductivity of mitochondrial membrane (by valinomycin), on the contrary, is not able to provide complete delivering of cations from mitochondria. It is shown that quantity of divalent metal cation released from mitochondria (depolarized and permeabilized for K+ as well) is proportional to the concentration of protonophore (but not K(+)-ionophore) introduced in the incubation medium. The data obtained lead to the conclusion that H(+)-permeabilization of the mitochondrial membrane is necessary for the complete release of Ca2+ and Sr2+ from mitochondria after membrane depolarization. The possible mechanism of divalent metal cations release from deenergized mitochondria is discussed.     

Inhibition of mitochondrial swelling by 19-nor-ethynyltestosterone acetate and other steroids

The swelling of rat liver mitochondria observed after addition of Ca²⁺, phosphate or valinomycin under suitable experimental conditions is inhibited by 19-nor-ethynyl-testosterone acetate (NEA) in the concentration range from 3 to 60 μm. The inhibition is proportional to NEA concentration and occurs when swelling is supported by oxidation of NAD-linked substrates (malate-glutamate), or endogenous substrate. Little or no inhibition occurs when swelling is supported by succinate oxidation. These observations suggest a site-specific effect near the NADH-flavoprotein portion of the respiratory chain. NEA also inhibits slightly the ATP-dependent contraction of Ca²⁺ swollen mitochondria, indicating a secondary effect on the energy-transfer mechanism. In contrast to these effects, NEA does not significantly affect: (a) H⁺ ejection after Ca²⁺ uptake supported by succinate oxidation; (b) valinomycin-induced swelling supported by ATP addition; (c) Na-acetate-induced swelling, in which the permeability of membranes to Na⁺ is rate limiting; and (d) loss of endogenous mitochondrial pyridine nucleotide. Other steroids such as androsterone, 17β-estradiol, and testosterone derivatives affect mitochondrial swelling like NEA, though to a lesser extent. Effects (a) and (d) are at variance with a previously postulated increase of mitochondrial permeability by steroids, accompanied by swelling. The studies which led to this postulate were carried out at steroid concentrations above 200 μm, where nonspecific effects on membrane permeability may well occur.     

Failure of atractyloside to inhibit synaptosomal mitochondrial energy transduction

Studies on synaptosome mitochondrial respiration are complicated by “free” mitochondria. Veratridine stimulation of synaptosomal respiration was due to increased Na⁺ cycling at the synaptosome membrane associated with increased oxidative phosphorylation of intraterminal ADP and was inhibited by oligomycin, ouabain or Na⁺ free medium. Atractylate or carboxyatractyloside failed to block veratridine-stimulated respiration but inhibited exogenous-ADP-stimulated respiration. Protein synthesis in the synaptosome fraction was inhibited by oligomycin, valinomycin or 2,4-dinitrophenol but was unaffected by excess atractylate. No change in synaptosomal adenine nucleotide content was found in the presence of atractylate, although a significant decrease in the [ATP]/[ADP] was found with oligomycin, veratridine or valinomycin. These findings show that atractylate does not modify intraterminal mitochondrial energy transduction and indirectly suggest an impermeability of the synaptosome membrane to atractylate.     

Effect of KCl Medium on Malate Oxidation in Mitochondria of Sugar Beet Taproot

Isolated mitochondria were obtained from growing and stored sugar beet (Beta vulgaris L.) taproots. These preparations were used to monitor the mitochondrial matrix volume and malate oxidation after the replacement of sucrose with KCl in the reaction medium. The transfer of mitochondria from sucrose-containing isolation medium to the isoosmotic KCl solution initiated spontaneous or energy-dependent (in the presence of respiratory substrate) swelling whose kinetic parameters (the initial rate and amplitude) were virtually independent of the plant age. At the same time, effects of KCl-induced swelling on oxidative and phosphorylating activities of mitochondria were age-dependent. In mitochondria from growing taproots, K⁺ ions stimulated nonphosphorylating malate oxidation, thereby decreasing the respiratory control ratio and the ADP/O coefficient. The incubation of mitochondria from stored taproots in KCl solution induced a short-term activation and subsequent progressive inhibition of malate oxidation but did not inhibit the oxidation of exogenous NADH. The inhibition of malate oxidation was not released by adding ADP or uncouplers and was enhanced in the presence of valinomycin. The swelling of mitochondria in KCl solutions did not impair the integrity of mitochondrial membranes and did not preclude stimulation of malate oxidation by exogenous NAD. It is supposed that the KCl-induced inhibition of respiration is related to a large increase in the matrix volume and a drastic decrease in the concentration of a coenzyme NAD. Previous studies with isolated mitochondria from stored taproots showed that the mitochondrial NAD level was a rate-limiting factor of malate oxidation assayed in the sucrose-containing media. A possible role of K⁺-transporting mechanisms in regulation of mitochondrial matrix volume and metabolic activity of plant mitochondria is discussed.