Swelling in Bean Shoot Mitochondria Induced by a Series of Potassium Salts of Organic Anions

A series of potassium salts of organic anions were examined for their effect on the volume change of bean shoot mitochondria as measured by spectrophotometric light scatterings. A passive osmotic swelling (substrate independent) as well as an active osmotic swelling (substrate dependent) was shown with a series of organic anions. Both oxidizable substrates and non-oxidizable substrates induce swelling. The monocarboxylic acids including acetate, β-OH-butyrate, propionate, and pyruvate induce active swelling which is partially inhibited by the presence of an ATP generating system or the uncoupler 2,4-dinitrophenol (DNP). Dicarboxylic acids produce less extensive rates and amounts of active swelling. Moreover, the swelling induced by dicarboxylic acids is inhibited less completely by an ATP generating system or by DNP. Metabolizable substrates including citrate, pyruvate, glutarate, and α-oxo-glutarate induced swelling despite their poor rates or lack of oxidation. It was concluded that with these anions, penetration across the inner membrane as measured by osmotic swelling of isolated mitochondria is not the rate limiting step in their metabolism.     

On the “swelling” of mitochondria under palmitic acid,calcium, and hypotension treatment

The high-amplitude swelling of mitochondria is critically considered. In contrast to numerous statements by some authors about a marked swelling of isolated liver mitochondria under the influence of palmitic acid, calcium ions, or hypotension, we have shown that mitochondria are generally not subject to highamplitude swelling. According to optical-microscopy data even during long-lasting incubation (in distilled water) where full hypotension takes place, the size of liver mitochondria (approximately 1 µm) can be enlarged by no more than by 40%. Under short-lasting hypotension or the addition of palmitic acid the mitochondrial diameter becomes greater by only 20% or remains virtually unchanged. The light scattering of the mitochondrial suspension measured using a photometer according to the decrease in optical density declines by 2.5 times. A decrease in the light scattering in hypotension or via the addition of palmitic acid or calcium (in an isotonic medium) occurs because of damage (even destruction) to the outer membrane, rather than due to the swelling of mitochondria, as was previously believed. The inner membrane is not significantly expanded. The destruction of the outer membrane reduces the probability of light scattering by each mitochondrion at the boundary layer of the water/membrane interface. Release of substances from the matrix resulting in a decrease of its refractive index may additionally contribute to the decrease in light scattering. Palmitic acid and calcium (at concentrations of 10 to 100 µM) cause permeabilization and disruption of the outer membrane gradually, over several minutes. Full hypotension activates this process very rapidly, viz., within a fraction of a second. Under low ionic-strength conditions, the addition of calcium leads to neutralization of negative charges on the membrane surface, which induces aggregation of mitochondria, thus enhancing light scattering and creating the illusion of mitochondrial swelling.     

Anion transporters in plant mitochondria

The swelling of potato (Solanum tuberosum L.) mitochondria in isosmotic ammonium salts of phosphate, chloride, malate, succinate, and citrate was investigated by measuring light scattering. Potato mitochondria swell spontaneously in ammonium phosphate, and this swelling can be inhibited in N-ethylmaleimide. They swell in ammonium malate or succinate only after the addition of inorganic phosphate and in ammonium citrate only after the addition of both phosphate and a dicarboxylic acid. Pentylmalonate inhibits swelling in ammonium citrate solutions by competing for dicarboxylate entry. The results indicate that potato mitochondria possess a phosphate-hydroxyl carrier, a dicarboxylate carrier, and a tricarboxylate carrier.     

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.     

Transport and oxidation of choline by liver mitochondria

1. Rapid choline oxidation and the onset of P(i)-induced swelling by liver mitochondria, incubated in a sucrose medium at or above pH7.0, required the addition of both P(i) and an uncoupling agent. Below pH7.0, P(i) alone was required for rapid choline oxidation and swelling. 2. Choline oxidation was inhibited by each of several reagents that also inhibited P(i)-induced swelling under similar conditions of incubation, including EGTA, mersalyl, Mg(2+), the Ca(2+)-ionophore A23187, rotenone and nupercaine. None of these reagents had any significant effect on the rate of choline oxidation by sonicated mitochondria. There was therefore a close correlation between the conditions required for rapid choline oxidation and for P(i)-induced swelling to occur, suggesting that in the absence of mitochondrial swelling the rate of choline oxidation is regulated by the rate of choline transport across the mitochondrial membrane. 3. Respiratory-chain inhibitors, uncoupling agents (at pH6.5) and ionophore A23187 caused a loss of endogenous Ca(2+) from mitochondria, whereas nupercaine and Mg(2+) had no significant effect on the Ca(2+) content. Inhibition of choline oxidation and mitochondrial swelling by ionophore A23187 was reversed by adding Ca(2+), but not by Mg(2+). It is concluded that added P(i) promotes the Ca(2+)-dependent activation of mitochondrial membrane phospholipase activity in respiring mitochondria, causing an increase in the permeability of the mitochondrial inner membrane to choline and therefore enabling rapid choline oxidation to occur. Nupercaine and Mg(2+) appear to block choline oxidation and swelling by inhibiting phospholipase activity. 4. Choline was oxidized slowly by tightly coupled mitochondria largely depleted of their endogenous adenine nucleotides, suggesting that these compounds are not directly concerned in the regulation of choline oxidation. 5. The results are discussed in relation to the possible mechanism of choline transport across the mitochondrial membrane in vivo and the influence of this process on the pathways of choline metabolism in the liver.     

The relationship between the size of mitochondria and the intensity of light that they scatter in different energetic states

The intensity of light scattered at 90° to the incident beam and the effective hydrodynamic radii of mitochondria incubated under a variety of conditions have been measured. Addition of high concentrations of uncouplers to respiring mitochondria resulted in a decrease in scatter which was not due to swelling. Addition of valinomycin to mitochondria depleted of substrate in K⁺-free medium produced an increase in scatter that was not due to shrinking. It is concluded that changes in the intensity of scattered light are not reliable indices of changes of volume of mitochondria, and that changes in conformation with changes in metabolic state dominate changes in light scatter. A molecular mechanism for the effect of metabolic state upon the scattered intensity is suggested.     

Retention of Ca2+ by rat liver and rat heart mitochondria: Effect of phosphate,Mg2+, and NAD(P) redox state

Parallel measurements of Ca²⁺ uptake, oxygen consumption, endogenous Mg²⁺ efflux, and swelling in rotenone-poisoned rat liver and rat heart mitochondria showed that heart mitochondria is much more resistant to uncoupling by Ca²⁺ in the presence of phosphate than rat liver mitochondria. The extent of Mg²⁺ efflux and swelling induced by Ca²⁺ accumulation are much less pronounced in heart mitochondria. Uncoupling and swelling in liver mitochondria seem to result from the loss of membrane-bound Mg²⁺ as a consequence of Ca²⁺ recycling across the membrane as induced by phosphate. Exogenous Mg²⁺ protects liver mitochondria against the deleterious effects of Ca²⁺ by inhibiting a ruthenium red-insensitive Ca²⁺ efflux induced by phosphate. Phosphate does not induce recycling of Ca²⁺ in heart mitochondria. On the other hand, heart mitochondria respiring on NAD-linked substrates or with succinate in the absence of rotenone behave like liver mitochondria with respect to the alterations caused by Ca²⁺ recycling. In heart mitochondria the recycling of Ca²⁺ is related to the redox state of pyridine nucleotides, which suggests that the ruthenium red-insensitive efflux of Ca²⁺ is subject to metabolic control. In addition it has been observed that Sr²⁺does not undergo cyclic movements across the membrane. The data indicate that the efflux pathway is more specific for Ca²⁺ than the ruthenium red-sensitive influx transporter.     

Heterogeneity of the calcium-induced permeability transition in isolated non-synaptic brain mitochondria

Calcium overload of neural cell mitochondria plays a key role in excitotoxic and ischemic brain injury. This study tested the hypothesis that brain mitochondria consist of subpopulations with differential sensitivity to calcium-induced inner membrane permeability transition, and that this sensitivity is greatly reduced by physiological levels of adenine nucleotides. Isolated non-synaptosomal rat brain mitochondria were incubated in a potassium-based medium in the absence or presence of ATP or ADP. Measurements were made of medium and intramitochondrial free calcium, light scattering, mitochondrial ultrastructure, and the elemental composition of electron-opaque deposits within mitochondria treated with calcium. In the absence of adenine nucleotides, calcium induced a partial decrease in light scattering, accompanied by three distinct ultrastructural morphologies, including large-amplitude swelling, matrix vacuolization and a normal appearance. In the presence of ATP or ADP the mitochondrial calcium uptake capacity was greatly enhanced and calcium induced an increase rather than a decrease in mitochondrial light scattering. Approximately 10% of the mitochondria appeared damaged and the rest contained electron-dense precipitates that contained calcium, as determined by electron-energy loss spectroscopy. These results indicate that brain mitochondria are heterogeneous in their response to calcium. In the absence of adenine nucleotides, approximately 20% of the mitochondrial population exhibit morphological alterations consistent with activation of the permeability transition, but less than 10% exhibit evidence of osmotic swelling and membrane disruption in the presence of ATP or ADP.     

Studies of Ca2+ -dependent smooth muscle mitochondria swelling using flow cytometry and spermine effects on this process

In the experiments, which were carried out using flow cytometry on isolated uterus mitochondria of nonpregnant rats, conditions for studying Ca2+-induced increase in nonspecific permeability of mitochondial membrane were tested. Fluorescent probe nonyl acridin orange was used to determine the purity of isolated mitochondria. Mitochondrial swelling induced by addition of Ca2+ or alamethicin was detected as a decrease in light side scattering (SS). It was shown that mitochondrial swelling in the presence of 100 microM Ca plus 1 microM A23187 was 86 +/- 4% compared with maximal response after alamethicin treatment. The calcium-induced swelling of mitochondria was inhibited by the addition of 5 microM cyclosporin plus 40 microM ADP. Mitochondrial swelling was inhibited by spermine at a dose of 0.1 micromol/mg or induced at a dose of 10 micromol/mg. It was supposed that the experimental approach proposed in this paper can be useful for mitochondrial pore modulating effectors screening.     

Regulation of cyclosporin A sensitive mitochondrial permeability transition by the redox state of pyridine nucleotides

The mechanisms involved in the induction of cyclosporine A sensitive mitochondrial swelling by oxidative stress were investigated in isolated guinea pig liver mitochondria. The aim of our study was to investigate, if swelling is inevitably associated with the oxidation of pyridine nucleotides, and if the oxidized pyridine nucleotides have to be hydrolysed for the induction of mitochondrial swelling. Quantitative measurement of oxidized pyridine nucleotides was performed with HPLC. Mitochondrial swelling was recorded by monitoring the decrease in light scattering of the mitochondrial suspension. Reduction and oxidation of pyridine nucleotides were followed by monitoring the changes of the autofluorescence signal of reduced pyridine nucleotides. Qualitative measurement of mitochondrial membrane potential was performed with the fluorescence indicator rhodamine 123. Neither t-butyl hydroperoxide nor the dissipation of the mitochondrial inner membrane potential with FCCP (carbonyl cyanide-p-trifluoromethoxyphenyl hydrazone) induced the opening of the membrane permeability transition pore, unless an extensive oxidation of mitochondrial pyridine nucleotides took place. Mitochondrial swelling induced by our experimental conditions was always sensitive to cyclosporine A and accompanied by a cyclosporine A sensitive release of inner mitochondrial pyridine nucleotides without pyridine nucleotide hydrolysis. Not the cycling of calcium across the mitochondrial inner membrane but the accumulation of calcium inside the mitochondria was a prerequisite for mitochondrial swelling. The mitochondrial membrane permeability transition is neither caused nor accompanied by the hydrolysis of mitochondrial pyridine nucleotides.     

SIZE AND SHAPE TRANSFORMATIONS CORRELATED WITH OXIDATIVE PHOSPHORYLATION IN MITOCHONDRIA : I. Swelling-Shrinkage Mechanisms in Intact Mitochondria

Two types of swelling-shrinkage change manifested by isolated mammalian heart mitochondria have been studied. One type, designated as phase I or "low amplitude" swelling-shrinkage, is estimated to lead to changes in mitochondrial volume of 20 to 40 per cent, to changes in light scattering of about 30 per cent, and to changes in viscosity. These physical changes in mitochondria are brought about rapidly and reversibly by normal reactants of the respiratory chain. Their speed, specificity, and reversibility indicate that they are closely geared to the normal function of the respiratory chain and are a true reflection of a mechanochemical coupling process characteristic of the physiology of mitochondria. A second type of swelling-shrinkage mechanism, designated as phase II or "high amplitude," leads to changes in light scattering, viscosity, and mitochondrial volume which, frequently but not always, are of higher magnitude than the phase I type. Phase II swelling-shrinkage seems to be only partly under the control of the respiratory chain. Prior to the completion of phase II swelling, a stepwise loss of mitochondrial function can be identified, such as changes in the rate of substrate utilization and loss of respiratory control. Reversal of this type of swelling cannot be effected if the swelling change reaches a steady state. This type of swelling may provide cells with a mechanism for destroying mitochondrial substance.     

Complex contribution of cyclophilin D to Ca2+-induced permeability transition in brain mitochondria, with relation to the bioenergetic state

Cyclophilin D (cypD)-deficient mice exhibit resistance to focal cerebral ischemia and to necrotic but not apoptotic stimuli. To address this disparity, we investigated isolated brain and in situ neuronal and astrocytic mitochondria from cypD-deficient and wild-type mice. Isolated mitochondria were challenged by high Ca(2+), and the effects of substrates and respiratory chain inhibitors were evaluated on permeability transition pore opening by light scatter. In situ neuronal and astrocytic mitochondria were visualized by mito-DsRed2 targeting and challenged by calcimycin, and the effects of glucose, NaCN, and an uncoupler were evaluated by measuring mitochondrial volume. In isolated mitochondria, Ca(2+) caused a large cypD-dependent change in light scatter in the absence of substrates that was insensitive to Ruthenium red or Ru360. Uniporter inhibitors only partially affected the entry of free Ca(2+) in the matrix. Inhibition of complex III/IV negated the effect of substrates, but inhibition of complex I was protective. Mitochondria within neurons and astrocytes exhibited cypD-independent swelling that was dramatically hastened when NaCN and 2-deoxyglucose were present in a glucose-free medium during calcimycin treatment. In the presence of an uncoupler, cypD-deficient astrocytic mitochondria performed better than wild-type mitochondria, whereas the opposite was observed in neurons. Neuronal mitochondria were examined further during glutamate-induced delayed Ca(2+) deregulation. CypD-knock-out mitochondria exhibited an absence or a delay in the onset of mitochondrial swelling after glutamate application. Apparently, some conditions involving deenergization render cypD an important modulator of PTP in the brain. These findings could explain why absence of cypD protects against necrotic (deenergized mitochondria), but not apoptotic (energized mitochondria) stimuli.     

Light scattering from intact cells reports oxidative-stress-induced mitochondrial swelling

Angularly resolved light scattering measurements were performed on suspensions of EMT6 cells and on mitochondria isolated from rabbit liver. Mie theory analysis of the scattering from intact cells indicated that mitochondrial-sized organelles dominated scattering in the range 5-90 degrees . This interpretation was supported by the analysis of scattering from isolated mitochondria. Intact cells were subjected to oxidative stress by photodynamic insult. After 3 h of incubation in the heme precursor aminolevulinic acid hexylester, EMT6 cells accumulated abundant protoporphyrin IX, an endogenous photosensitizer formed in mitochondria. Irradiation of aminolevulinic acid/protoporphyrin IX-sensitized cells with 10 J cm(-2) of 514 nm light led to pronounced changes in angularly resolved light scattering consistent with mitochondrial swelling. Electron microscopy of similarly treated EMT6 cell monolayers showed significant changes in mitochondrial morphology, which included distension of the outer unit membrane and bloating of the internal mitochondrial compartment. Informed by these electron microscopy results, we implemented a coated sphere model to interpret the scattering from intact cells subjected to oxidative stress. The coated sphere interpretation was compatible with the scattering measurements from these cells, whereas simpler Mie theory models based on homogenous swelling were dramatically unsuccessful. Thus, in this system, angularly resolved light scattering reports oxidative-stress-induced changes in mitochondrial morphology.     

Molecular mechanism of uncoupling in brown adipose tissue mitochondria. The non-identity of proton and chloride conducting pathways

Specific permeability properties of the inner membrane of brown adipose tissue mitochondria were analysed with the aid of simultaneous pH measurements outside mitochondria and of mitochondria swelling. It was shown that valinomycin-induced potassium diffusion potential drives a parallel passive uptake of chlorides and extrusion of proton. Electrogenic H+ -extrusion was independent on anion transport, no competition was found between the two processes and the former process exerted a lower sensitivity to the inhibitory effect of GDP. The existence of two distinct, independent pathways for translocation of protons and halide anions across the membrane is suggested.     

LIGHT-INDUCED VOLUME CHANGES IN SPINACH CHLOROPLASTS

A light-dependent mechanism that results in a slow, high-amplitude swelling of spinach chloroplasts in vitro has been discovered. The swelling is readily observed by optical and gravimetric methods, and by the use of an electronic particle counter; all show a 100 per cent increase of chloroplast volume in the light with an approximately 10-minute half-time. The existence of an osmotic mechanism for chloroplast swelling in the dark is confirmed. The volume of illuminated chloroplasts versus NaCl concentration represents the addition of osmotic and light effects. The action of light is enhanced by electron flow cofactors, such as phenazine methosulfate (PMS). However, neither conditions for ATP hydrolysis or synthesis nor NH₄Cl influence the time course and extent of swelling. Hence, high-amplitude chloroplast swelling is light- (or electron flow), but not energy-dependent. A remarkable inhibitory effect of inorganic phosphate on chloroplast swelling is observed in the light, but not in the dark. Another action of light on chloroplasts is known to result in a shrinkage of chloroplasts which is rapid, reversible, energy-dependent, and requires phosphate. Thus phosphate determines the action of light on chloroplast volume. Since shrinkage is reversible, but swelling is not, it may be that they reflect physiological and deteriorative processes, respectively. Chloroplasts and mitochondria appear to control their volume by similar mechanisms.     

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.     

Cisplatin nephrotoxicity involves mitochondrial injury with impaired tubular mitochondrial enzyme activity

Cisplatin is a widely used antineoplastic agent. However, its major limitation is dose-dependent nephrotoxicity whose precise mechanism is poorly understood. Recent studies have suggested that mitochondrial dysfunction in tubular epithelium contributes to cisplatin-induced nephrotoxicity. Here the authors extend those findings by describing the role of an important electron transport chain enzyme, cytochrome c oxidase (COX). Immunohistochemistry for COX 1 protein demonstrated that, in response to cisplatin, expression was mostly maintained in focally damaged tubular epithelium. In contrast, COX enzyme activity in proximal tubules (by light microscopy) was decreased. Ultrastructural analysis of the cortex and outer stripe of the outer medulla showed decreased mitochondrial mass, disruption of cristae, and extensive mitochondrial swelling in proximal tubular epithelium. Functional electron microscopy showed that COX enzyme activity was decreased in the remaining mitochondria in the proximal tubules but maintained in distal tubules. In summary, cisplatin-induced nephrotoxicity is associated with structural and functional damage to the mitochondria. More broadly, using functional electron microscopy to measure mitochondrial enzyme activity may generate mechanistic insights across a spectrum of renal disorders.     

The effect of osmotic pressure on oligomycin-sensitive ATPase activity and the liberation of Mg2+ from liver mitochondria of rats of various ages]

The influence of osmotic pressure of the incubating medium (25-500 mM sucrose) on oligomycin--sensitive, 2,4-dinitrophenyl-stimulated ATP-ase-activity, Mg2+ release and swelling of the liver mitochondria in 1-, 3-, 12-, 24-months Wistar rats is, investigated to determine age changes of structurally functional state of mitochondria. An increase in the sucrose concentration in the medium from 150 to 500 mM causes almost equal and practically absolute inhibition of ATP-ase-activity in different-age groups of rats, regardless of the presence or absence of Mg2+ ions in the medium A fall of the sucrose concentration to 150-25 mM induces a decrease in mitochondria ATP-ase-activity in Mg2+ free medium in 12- and 24-months rats (to 30 and 22%, respectively). No changes are observed in 1- and 3-months animals. Differences in rates of exogenous NADH oxidation by mitochondria of 1- and 12-months rats as a reflection of inner membrane damage degree are not observed under these conditions. Relative changes in ATP-ase-activity in a Mg2+ free medium with sucrose concentration of 25 mM (compared with 150 mM) correlate (r = 0.82) with those of optical density of mitochondria, measured at light wave length of 520 nm. It is obvious that the liver mitochondria of young and old rats sufficiently differ in spontaneous swelling rate in the media with different osmotic pressure: mitochondria of 1-month rats swell much faster than those of old rats. Considerable age differences of osmotic dependence of Mg2+ output from mitochondria are observed. They depend also on peculiarities of spontaneous organelle swelling dynamics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mitochondrial oxidative stress induced by Ca2+ and monoamines: different behaviour of liver and brain mitochondria in undergoing permeability transition

Mitochondrial permeability transition (MPT) is correlated with the opening of a nonspecific pore, the so-called transition pore, that triggers bidirectional traffic of inorganic solutes and metabolites across the mitochondrial membrane. This phenomenon is caused by supraphysiological Ca(2+) concentrations and by other compounds leading to oxidative stress, while cyclosporin A, ADP, bongkrekic acid, antioxidant agents and naturally occurring polyamines strongly inhibit it. The effects of polyamines, including the diamine agmatine, have been widely studied in several types of mitochondria. The effects of monoamines on MPT have to date, been less well-studied, even if they are involved in a variety of neurological and neuroendocrine processes. This study shows that in rat liver mitochondria (RLM), monoamines such as tyramine, serotonin and dopamine amplify the swelling induced by calcium, and increase the oxidation of thiol groups and the production of hydrogen peroxide, effects that are counteracted by the above-mentioned inhibitors. In rat brain mitochondria (RBM), the monoamines do not amplify calcium-induced swelling, even if they demonstrate increases in the extent of oxidation of thiol groups and hydrogen peroxide production. In these mitochondria, the antioxidants are not at all or scarcely effective in suppressing mitochondrial swelling. In conclusion, we hypothesize that different mechanisms induce the MPT in the two different types of mitochondria evaluated. Calcium and monoamines induce oxidative stress in RLM, which in turn appears to induce and amplify MPT. This process is not apparent in RBM, where MPT seems resistant to oxidative stress.     

Mitochondrial precursor signal peptide induces a unique permeability transition and release of cytochrome c from liver and brain mitochondria

This study tested the hypothesis that mitochondrial precursor targeting peptides can elicit the release of cytochrome c from both liver and brain mitochondria by a mechanism distinct from that mediated by the classical, Ca2+-activated permeability transition pore. Human cytochrome oxidase subunit IV signal peptide (hCOXIV1-22) at concentrations from 15 to 100 microM induced swelling, a decrease in membrane potential, and cytochrome c release in both types of mitochondria. Although cyclosporin A and bongkrekic acid were without effect, dibucaine, propanolol, dextran, and the uncoupler FCCP were each able to inhibit signal peptide-induced swelling and cytochrome c release. Adenylate kinase was coreleased with cytochrome c, arguing against a signal peptide-induced cytochrome c-specific pathway of efflux across the outer membrane. Taken together, the data indicate that a human mitochondrial signal peptide can evoke the release of cytochrome c from both liver and brain mitochondria by a unique permeability transition that differs in several characteristics from the classical mitochondrial permeability transition.