NADH-dependent respiration in osmotically inactive swollen mitochondria: does transport replace phosphorylation in mediating respiratory control in swollen mitochondria?

Rotenone-sensitive, uncoupler-insensitive, NADH-dependent respiration was demonstrated in osmotically inactive fragments of the mitochondrial inner-membrane obtained following high amplitude (spontaneous) swelling. This NADH-dependent respiration as well as mitochondrial ATPase activity was stimulated by ligands which are known to be transported by specific transporters/mechanisms. The ligands capable of this anomalous respiratory control included several intermediates of the citric acid cycle, besides non-metabolizable ligands including lactate, cations such as K+ and Ca2+. The interaction between NADH-dependent respiration and these ligands, as manifested by stimulation of respiration, was strongly ionic strength-dependent. The thermodynamic relationship between respiratory control and stimulation of transport ATPase by the relevant transportable ligands could also be demonstrated in the conventional (rat liver) microsomes. These experimental results offer a novel experimental base for search into an intra-membranous mechanism of energy transduction.     

The impairing effects of chaetochromin D on mitochondrial respiration and structure

Chaetochromin D, a toxic secondary metabolite ofChaetomlum graclle, was examined for impairing effects on mitochondrial respiration and structure (swelling-induction) using isolated rat liver mitochondria to gain Insight into the molecular mechanism for Its cytotoxicity. Chaetochromin D exerted similar mode of effects to those of chaetochromin A, cephalochromin, and ustilaginoldin A on mitochondrial reactions, causing uncoupling of oxidative phosphorylation, depression of state 3 respiration, and induction of drastic swelling In mitochondria. Chaetochromin D induced the same style of swelling as that induced by chaetochromin A, being characterized by a very high rate and small amplitude of swelling. The swelling terminated In the middle and the amplitude was about half of the full swelling. Once the quick swelling ceased in the middle, subsequent swelling could not be elicited by the second addition of chaetochromin D at any of the concentrations tested.     

Membrane instability in respiring mitochondria: role of phosphate.

Metabolically-induced (spontaneous) high amplitude swelling of mitochondria has been shown to be due to a serial disruption of the mitochondrial membranes [D. Sambasivarao & V. Sitaramam (1985), Biochim Biophys Acta, 806, 195-209]. Phosphate- and arsenate-induced swelling was investigated in mitochondria to evaluate the role of phosphate transport in the instability created in the mitochondrial membranes. Phosphate-induced swelling in respiring mitochondria was similar to spontaneous swelling. Both represent essentially colloidal swelling due to the variable porosity induced in the inner membrane to polyols by respiration. Swelling of non-respiring mitochondria at high ammonium phosphate concentrations was, on the other hand, primarily due to high permeability to phosphate. This membrane instability created by phosphate transport in the surrounding lipid involves neither the endogenous nor the exogenous Ca2+.     

Respiration induces variable porosity to polyols in the mitochondrial inner membrane

The osmotic basis of low and high amplitude swelling in mitochondria was investigated in detail using sucrose and mannitol as external osmolytes. Osmotic behaviour of mitochondria in various respiratory states was consistent with significant changes in the porosity of the inner membrane corresponding to the rate of respiration. The stoichiometry of oxidative phosphorylation was confirmed to be dependent on the physical state (i.e., osmotic stretch) of the inner membrane regardless of the external polyol used. High amplitude swelling in polyol media was shown to arise from a sequential disruption of the outer and inner mitochondrial membranes, due to a dynamic instability induced by a combination of respiration, unscreened (fixed) surface charge density and the consequent variable porosity of the inner membrane. These novel experimental findings based on the physical theory of osmosis emphasize the need to define the fine structural changes of the inner membrane associated with oxidative phosphorylation to arrive at a comprehensive mechanism.     

Mitochondrial inner membrane particles seen in sections ofin situ large amplitude swollen mitochondria in rhizodermal cells of cress (Lepidium sativum L.)

Addition of 5–40 mM sodium acetate to root explants of cress (Lepidium sativum L.) growing in a nutrient medium causes large amplitude swelling of mitochondria in rhizodermal cells. On the average, 10 mM sodium acetate causes a fourfold increase in mitochondrial volume, with 40 mM sodium acetate producing an up to tenfold increase in mitochondrial volume. During swelling, however, the mitochondrial membranes remain predominantly intact, and only the outer membrane occasionally appears to be broken. Two types of swelling can be observed: an overall swelling of mitochondrial matrices and a less frequent local swelling which leads to clearly different matrical regions. These regions may sometimes be separated by a septum formed from the inner mitochondrial membrane. After large amplitude swelling in 10 or 40 mM sodium acetate, the visibility of lollipop-like particles on the matrix side of inner mitochondrial membranes is strongly enhanced. These particles are suggested to be identical with mitochondrial inner membrane particles as visualized by negative staining. The distribution of these particles is described. Possible mechanisms which may cause enhanced visibility are discussed.     

The morphology and configurational states of isolated heavy beef heart mitochondria by the freeze fracture technique

Configurational changes of glutaraldehyde fixed heavy beef heart mitochondria are confirmed using the freeze fracture technique. Large amplitude swelling occurred after unfixed mitochondria were suspended in 30% glycerol. Fine structure of the outer and inner mitochondrial membranes is described using unfixed heavy beef heart mitochondria by the freeze fracture technique. The matrix side of the inner membrane appears to be covered with 90 Å particles while the opposite side (cytochromec side) is also particulate covered by a high density of lower profile particles with a smooth underlying mosaic layer beneath. The outer surface of the outer membrane is smooth with particles embedded within the membrane. Possible structure of the membrane is discussed.     

L-Carnitine suppresses oleic acid-induced membrane permeability transition of mitochondria

Membrane permeability transition (MPT) of mitochondria has an important role in apoptosis of various cells. The classic type of MPT is characterized by increased Ca(2+) transport, membrane depolarization, swelling, and sensitivity to cyclosporin A. In this study, we investigated whether L-carnitine suppresses oleic acid-induced MPT using isolated mitochondria from rat liver. Oleic acid-induced MPT in isolated mitochondria, inhibited endogenous respiration, caused membrane depolarization, and increased large amplitude swelling, and cytochrome c (Cyt. c) release from mitochondria. L-Carnitine was indispensable to beta-oxidation of oleic acid in the mitochondria, and this reaction required ATP and coenzyme A (CoA). In the presence of ATP and CoA, L-carnitine stimulated oleic acid oxidation and suppressed the oleic acid-induced depolarization, swelling, and Cyt. c release. L-Carnitine also contributed to maintaining mitochondrial function, which was decreased by the generation of free fatty acids with the passage of time after isolation. These results suggest that L-carnitine acts to maintain mitochondrial function and suppresses oleic acid-mediated MPT through acceleration of beta-oxidation.     

Evidence of a phosphate-transporter system in the inner membrane of isolated mitochondria

1. The organic mercurial sodium mersalyl, formaldehyde, dicyclohexylcarbodiimide and tributyltin each blocked respiratory-chain-linked ATP synthesis in rat liver mitochondria. 2. Mersalyl and formaldehyde also blocked a number of other processes dependent on the entry of inorganic phosphate into mitochondria, including mitochondrial respiration and swelling stimulated by cations and phosphate, the substrate-level phosphorylation reaction of the citric acid cycle, and swelling in ammonium phosphate. 3. Dicyclohexylcarbodi-imide and tributyltin did not inhibit the entry of phosphate into mitochondria. 4. Mersalyl and formaldehyde had a relatively slight effect on succinate oxidation and swelling stimulated by cations when phosphate was replaced by acetate, on succinate oxidation stimulated by uncoupling agents, and on swelling in solutions of ammonium salts other than phosphate or arsenate. 5. Formaldehyde blocked the oxidation of NAD-linked substrates in mitochondria treated with 2,4-dinitrophenol and the ATP-dependent reduction of NAD by succinate catalysed by ox heart submitochondrial particles. Both these effects appear to be due to an inhibition by formaldehyde of the NAD-flavin region of the respiratory chain. 6. Concentrations of dicyclohexylcarbodiimide or tributyltin sufficient to abolish ADP-stimulated respiration blocked the dinitrophenol-stimulated adenosine triphosphatase activity, whereas mersalyl and formaldehyde caused only partial inhibition of ATP hydrolysis. 7. When mitochondria were incubated with dinitrophenol and ATP, less than 10% of the total inorganic phosphate liberated was recovered in the mitochondria and no swelling occurred. In the presence of mersalyl or formaldehyde at least 80% of the total inorganic phosphate liberated was retained in the mitochondria and extensive swelling was observed. This swelling was inhibited by oligomycin but not by antimycin or rotenone. 8. The addition of mersalyl to mitochondria swollen by treatment with valinomycin, K(+) and phosphate blocked the contraction induced by dinitrophenol and caused an increase in the phosphate content of the mitochondria, but had no effect on the contraction of mitochondria when phosphate was replaced by acetate. 9. It is concluded that mitochondria contain a phosphate-transporter system, which catalyses the movement of phosphate in either direction across the mitochondrial membrane, and that this system is inactivated by organic mercurials and by formaldehyde. Evidence is presented that the phosphate-transporter system is situated in the inner membrane of rat liver mitochondria and is also present in other types of mammalian mitochondria.     

Synthetic and natural polyanions induce cytochrome c release from mitochondria in vitro and in situ

A synthetic polyanion composed of styrene, maleic anhydride, and methacrylic acid (molar ratio 56:37:7) significantly inhibited the respiration of isolated rat liver mitochondria in a time-dependent fashion that correlated with 1) collapse of the mitochondrial membrane potential and 2) high amplitude mitochondrial swelling. The process is apparently Ca(2+) dependent. Since it is blocked by cyclosporin A, the process is ascribed to induction of the mitochondrial permeability transition. In mitoplasts, i.e., mitochondria lacking their outer membranes, the polyanion rapidly blocked respiration. After incubation of rat liver mitochondria with the polyanion, cytochrome c was released into the incubation medium. In solution, the polyanion modified by conjugation with fluorescein formed a complex with cytochrome c. Addition of the polyanion to cytochrome c-loaded phosphatidylcholine/cardiolipin liposomes induced the release of the protein from liposomal membrane evidently due to coordinated interplay of Coulomb and hydrophobic interactions of the polymer with cytochrome c. We conclude that binding of the polyanion to cytochrome c renders it inactive in the respiratory chain due to exclusion from its native binding sites. Apparently, the polyanion interacts with cytochrome c in mitochondria and releases it to the medium through breakage of the outer membrane as a result of severe swelling. Similar properties were demonstrated for the natural polyanion, tobacco mosaic virus RNA. An electron microscopy study confirmed that both polyanions caused mitochondrial swelling. Exposure of cerebellar astroglial cells in culture to the synthetic polyanion resulted in cell death, which was associated with nuclear fragmentation.     

Oxidative properties of swollen rat liver mitochondria.

Rat liver mitochondria undergo extensive swelling when they are incubated in hypotonic sucrose medium containing 5 mm P_i. After 30 min of swelling at 25 °C, a three- to fourfold increase in volume has occurred, accompanied by gross disorganization of the matrix as observed by electron microscopy. Succinate-supported respiration was unchanged, but the respiration of NAD-linked substrates was reduced and there was a complete and irreversible loss of phosphorylation in both cases. β-Hydroxybutyrate-supported respiration was regained completely on addition of NAD to the swollen mitochondria. α-Ketoglutarate- and malate + pyruvate-supported respiration was only partially restored by the addition of NAD. This inhibition of respiration in swollen mitochondria may be due to a disorganization of a putative complex of Krebs cycle enzymes on the inner surface of the inner membrane.     

Toxicity of emestrin,a new macrocyclic dithiodioxopiperazine mycotoxin,to mitochondrial function

The effect of emestrin, a new macrocyclic epidithiodioxopiperazine mycotoxin from severalEmericella species, on mitochondrial reactions was studied using isolated rat liver mitochondria to gain insight into the molecular mechanism for itsin vivo toxicity to rat and mouse. Emestrin was found to inhibit ATP synthesis in mitochondria causing an uncoupling of oxidative phosphorylation and a depression of respiration in isolated mitochondria. In addition to these effects on mitochondrial respiration, emestrin elicited a dratsic structural alteration (swelling) of mitochondria as observed in thein vivo system. The mitochondrial swelling was significantly enhanced by the subsequent addition of calcium ion. Emestrin B, in which dithio group is replaced by trithio group, exerted an uncoupling effect on oxidative phosphorylation without accompanying such depressive effect on state 3 respiration as observed for emestrin.     

Intramitochondrial phospholipase activity and the effects of Ca2+ plus N-ethylmaleimide on mitochondrial function.

Liver mitochondria treated with N-ethylmaleimide can accumulate Ca2+ but cannot retain it. Ca2+ loss following uptake occurs in parallel with a proton uptake and collapse of the membrane potential. Respiration is not activated during Ca2+ release and cannot be stimulated by uncoupler. After Ca2+ release and accompanying phenomena are nearly complete, the mitochondria undergo a large amplitude swelling. Nupercaine inhibits the premature release of Ca2+, proton uptake, decline in membrane potential, inhibition of uncoupler-stimulated respiration, and large amplitude swelling. Ruthenium red also prevents these effects. Neither Sr2+ or Mn2+ will substitute for Ca2+ to induce these effects in N-ethylmaleimide-treated mitochondria. The effects of N-ethylmaleimide plus Ca2+ on mitochondria are not accompanied by a significant alteration in the content or composition of phospholipids but are accompanied by small increases in the mitochondrial content of free fatty acids. Free fatty acids accumulate more rapidly in response to limited Ca2+ loading in the absence of N-ethylmaleimide than they do in its presence. In the absence of N-ethylmaleimide, polyunsaturated fatty acids and saturated plus monounsaturated fatty acids accumulate at nearly equal rates. In the presence of N-ethylmaleimide, polyunsaturated fatty acids accumulate more rapidly than saturated plus monounsaturated fatty acids. Any condition or agent tested which inhibited swelling and the other effects produced by Ca2+ plus N-ethylmaleimide also prevented the more rapid accumulation of polyunsaturated, compared to saturated plus monounsaturated, fatty acids. In the light of a positional analysis of phospholipid acyl moieties, these data suggest that 1-acyllysophospholipids accumulate in swelling mitochondria but not in response to noraml Ca2+ loading or when swelling is blocked by other agents. The free fatty acid accumulation, per se, is not responsible for swelling, but levels of exogenous palmitic acid as low as 1 nmol/mg of protein dramatically alter the dependence of swelling velocity on Ca2+ concentration, producing a shift from a sigmoidal- to a hyperbolic-like relationship. This same alteration is brought about by aging the mitochondrial preparation at 0 degrees C. Either pyruvate or DL-carnitine prevents the effect of exogenous palmitate and restores the Aa2+ swelling dependence of aged N-ethylmaleimide-treated mitochondria to that of fresh N-ethylmaleimide-treated mitochondria. Intramitochondrial acylcoenzyme A or acylcarnitine, or both, therefore, to be the modulator of Ca2+ sensitivity rather than free fatty acid. The findings are discussed in terms of the role of intramitochondrial phospholipase and other phospholipid metabolizing enzymes in the mechanisms of N-ethylmaleimide plus Ca2+ effects on mitochondria.     

Coenzyme Q releases the inhibitory effect of free fatty acids on mitochondrial glycerophosphate dehydrogenase

Data presented in this paper show that the size of the endogenous coenzyme Q (CoQ) pool is not a limiting factor in the activation of mitochondrial glycerophosphate-dependent respiration by exogenous CoQ(3), since successive additions of succinate and NADH to brown adipose tissue mitochondria further increase the rate of oxygen uptake. Because the inhibition of glycerophosphate-dependent respiration by oleate was eliminated by added CoQ(3), our data indicate that the activating effect of CoQ(3) is related to the release of the inhibitory effect of endogenous free fatty acids (FFA). Both the inhibitory effect of FFA and the activating effect of CoQ(3) could be demonstrated only for glycerophosphate-dependent respiration, while succinate- or NADH-dependent respiration was not affected. The presented data suggest differences between mitochondrial glycerophosphate dehydrogenase and succinate or NADH dehydrogenases in the transfer of reducing equivalents to the CoQ pool.     

Effects of Gramicidin on Corn Mitochondria

The effects of gramicidin D, S, and J on corn mitochondria respiration and swelling were studied. Only gramicidin D was found to have any pronounced effect on mitochondrial swelling. In buffered KCl gramicidin D produced a rapid, respiration-independent swelling which was not reversed with respiratory inhibitors or substrate exhaustion. The respiration rate of exogenous reduced nicotinamide adenine dinucleotide was stimulated by all three gramicidins, but the effects on malate-pyruvate and succinate respiration depended on the type of gramicidin and the reaction media. The respiration effects of gramicidin D may be due to action at specific sites for each substrate.     

The effects of colloids on the appearance and substrate permeability of rat liver mitochondria

The electron microscopic appearance of rat liver mitochondria fixed in glutaraldehyde is altered if certain colloids (serum albumin, dextran or Ficoll) are present in the medium at about 3%. To compare behaviour in control and albumin-supplemented media, the rate of stimulated respiration was measured with various substrates. It was found that the rate of respiration was reduced with succinate or pyruvate and was almost abolished with oxoglutarate, while malate oxidation (in presence of glutamate) was unaffected. The rate of oxoglutarate oxidation could be restored by causing mitochondrial swelling. It is suggested that the effects are due to the presence of endogenous colloids in the particles whose effects on water activity have to be balanced by external colloid. In the absence of external colloid, swelling of the internal colloid-containing compartments may give rise to an enhanced permeability of the membrane so that reactions occurin vitro which do not take place rapidly if at allin vivo.     

4-Bromo-2-octenoic acid specifically inactivates 3-ketoacyl-CoA thiolase and thereby fatty acid oxidation in rat liver mitochondria

In an attempt to develop a compound which would specifically inhibit 3-ketoacyl-CoA thiolase (EC 2.3.1.16) in whole mitochondria, 4-bromo-2-octenoic acid was synthesized and studied. After rat liver mitochondria were preincubated with 4-bromo-2-octenoic acid for 3 min, respiration supported by either palmitoylcarnitine or pyruvate was completely abolished, whereas no inhibition was observed with rat heart mitochondria. Addition of carnitine stimulated respiration supported by pyruvate without relieving inhibition of palmitoylcarnitine-dependent respiration. Hence, this compound seems to be a specific inhibitor of beta-oxidation. When the enzymes of beta-oxidation were assayed in a soluble extract prepared from mitochondria preincubated with 4-bromo-2-octenoic acid, only 3-ketoacyl-CoA thiolase was found to be inactivated. 4-Bromo-2-octenoic acid is metabolized by mitochondrial beta-oxidation enzymes to 3-keto-4-bromooctanoyl-CoA which effectively and irreversibly inhibits 3-ketoacyl-CoA thiolase but not acetoacetyl-CoA thiolase (EC 2.3.1.9). Even though 3-keto-4-bromooctanoyl-CoA inhibits the latter enzyme reversibly, 4-bromo-2-octenoic acid does not inhibit ketogenesis in rat liver mitochondria with acetylcarnitine as a substrate. It is concluded that 4-bromo-2-octenoic acid specifically inhibits mitochondrial fatty acid oxidation by inactivating 3-ketoacyl-CoA thiolase in rat liver mitochondria.     

Uncoupling Action of Antibiotic Sporaviridins with Rat-liver Mitochondria

The effects of the glycoside antibiotic sporaviridins (SVDs) on oxidative phosphorylation of rat-liver mitochondria were examined. SVDs released state 4 respiration, dissipated transmembrane electrical potential, and accelerated ATPase activity. These facts demonstrated that SVDs are potent uncouplers of oxidative phosphorylation. During the uncoupling caused by SVDs, large amplitude swelling and oxidation of intramitochondrial NAD(P)H occurred, suggesting that SVDs greatly enhanced nonspecific permeability of the inner mitochondrial membrane. It is suggested that the uncoupling action of SVDs might be caused by dissipation of proton electrochemical potential due to an increase in the permeability of inner mitochondrial membrane.     

Investigating the receptor-independent neuroprotective mechanisms of nicotine in mitochondria

Although nicotine has been associated with a decreased risk of developing Parkinson disease, the underlying mechanisms are still unclear. By using isolated brain mitochondria, we found that nicotine inhibited N-methyl-4-phenylpyridine (MPP(+)) and calcium-induced mitochondria high amplitude swelling and cytochrome c release from intact mitochondria. Intra-mitochondria redox state was also maintained by nicotine, which could be attributed to an attenuation of mitochondria permeability transition. Further investigation revealed that nicotine did not prevent MPP(+)- or calcium-induced mitochondria membrane potential loss, but instead decreased the electron leak at the site of respiratory chain complex I. In the presence of mecamylamine hydrochloride, a nonselective nicotinic acetylcholine receptor inhibitor, nicotine significantly postponed mitochondria swelling and cytochrome c release induced by a mixture of neurotoxins (MPP(+) and 6-hydroxydopamine) in SH-SY5Y cells, suggesting that there is a receptor-independent nicotine-mediated neuroprotective effect of nicotine. These results show that interaction of nicotine with mitochondria respiratory chain together with its antioxidant effects should be considered in the neuroprotective effects of nicotine.     

Uncoupling action of antibiotic sporaviridins with rat-liver mitochondria.

The effects of the glycoside antibiotic sporaviridins (SVDs) on oxidative phosphorylation of rat-liver mitochondria were examined. SVDs released state 4 respiration, dissipated transmembrane electrical potential, and accelerated ATPase activity. These facts demonstrated that SVDs are potent uncouplers of oxidative phosphorylation. During the uncoupling caused by SVDs, large amplitude swelling and oxidation of intramitochondrial NAD(P)H occurred, suggesting that SVDs greatly enhanced nonspecific permeability of the inner mitochondrial membrane. It is suggested that the uncoupling action of SVDs might be caused by dissipation of proton electrochemical potential due to an increase in the permeability of inner mitochondrial membrane.     

The impairment of mitochondrial function by Triton X-100. A study of mitochondrial respiration and energy-dependent swelling

Coupled and uncoupled respiration, and energy-dependent phosphate swelling have been studied in rat liver mitochondria in the presence of various concentration of Triton X-100. Detergent concentrations up to 10(-5) M do not affect any of the processes under study. At 10(-5) M, Triton X-100 produces a slight decrease of coupled respiration and a considerable inhibition of mersalyl-induced shrinking in swollen mitochondria. Increasing the surfactant concentration to 10(-4), coupled as well as uncoupled O2 consumption is decreased, succinate-dependent phosphate swelling is inhibited and an energy-dependent phosphate swelling in the absence of valinomycin is observed. At 2 X 10(-4) M. Triton X-100, ATP- dependent phosphate swelling is abolished, and passive swelling may be induced by various ions. Higher detergent concentrations do not allow observation of any of these events. On the basis of these results, a model of membrane-detergent interaction is proposed.