Effects of phthalate esters on the respiration of rat liver mitochondria.

The effects of phthalate esters on the oxidation of succinate, glutamate, beta-hydroxybutyrate and NADH by rat liver mitochondria were examined and it was found that di-n-butyl phthalate (DBP) strongly inhibited the succinate oxidation by intact and sonicated rat mitochondria, but did not inhibit the State 4 respiration with NAD-linked substrates such as glutamate and beta-hydroxybutyrate. However, oxygen uptake accelerated by the presence of ADP and substrate (State 3) was inhibited and the rate of oxygen uptake decreased to that without ADP (State 4). It was concluded that phthalate esters were electron and energy transport inhibitors but not uncouplers. Phthalate esters also inhibited NADH oxidation by sonicated mitochondria. The degree of inhibition depended on the carbon number of alkyl groups of phthalate esters, and DBP was the most potent inhibitor of respiration. The activity of purified beef liver glutamate dehydrogenase [EC 1.4.1.3] was slightly inhibited by phthalate esters.     

The redox state of the nicotinamide–adenine dinucleotides in rat liver homogenates

1. The redox state of the NAD couple of rat liver mitochondria, as measured by the [beta-hydroxybutyrate]/[acetoacetate] ratio, rapidly changed in the direction of oxidation during the preparation of homogenates in a saline medium. The value of the [beta-hydroxybutyrate]/[acetoacetate] ratio fell from 2.3 to 0.15 in 10min. EDTA diminished the fall and succinate prevented it. 2. The redox state of the rat liver cytoplasm, as measured by the [lactate]/[pyruvate] ratio, changed slightly in the direction of reduction during the preparation of homogenate. This was prevented by succinate. 3. In unsupplemented homogenates the differences in the redox states of mitochondria and cytoplasm decreased. Succinate and EDTA together maintained the differences within the physiological range. A measure of the ability of the mitochondria to maintain different redox states in mitochondria and cytoplasm is the value of the expression [lactate][acetoacetate]/[pyruvate][beta-hydroxybutyrate]. If there are no differences in the redox states of the NAD in the two cell compartments the value of the expression is 444 at 37 degrees . The value in the intact rat liver is between 4.7 and 21. 4. alpha-Oxoglutarate or glutamate were still more effective than succinate in maintaining high [beta-hydroxybutyrate]/[acetoacetate] ratios in the homogenates because these substrates supply a reducing agent of NAD(+) and, through succinate, an inhibitor of the oxidation of NADH. 5. When supplemented with alpha-oxoglutarate and EDTA, homogenates readily adjust the redox state of the beta-hydroxybutyrate dehydrogenase system after it has been upset by the addition of either acetoacetate or beta-hydroxybutyrate. 6. Amytal and rotenone raised the value of the [beta-hydroxybutyrate]/[acetoacetate] ratio. This is taken to indicate that the reduction of acetoacetate in the homogenates was not an energy-linked process. 7. 2,4-Dinitrophenol shifted the [beta-hydroxybutyrate]/[acetoacetate] ratio in the presence of succinate in favour of oxidation because it inhibited the oxidation of succinate and accelerated the oxidation of NADH. 8. Rotenone increased the rate of ketone-body formation of liver homogenates, though it decreased the rate of oxygen uptake.     

Calcium ion-induced uptakes and transformations of substrates in liver mitochondria

Substrate-depleted rat liver mitochondria will reaccumulate malate, succinate, oxoglutarate, beta-hydroxybutyrate and glutamate if provided with an energy source and Ca(2+) (or Ca(2+) and Mn(2+)). The energy requirement for ion uptake by fresh mitochondria causes a transient oxidation of their NADH and presumably this leads to an increased oxaloacetate concentration. A consequence is the promotion of formation of citrate, which tends to remain in the particles, provided the pH is above 7. Analyses made of systems blocked with fluorocitrate show that citrate accumulates when Ca(2+) is added with the following substrates; (a) pyruvate in the presence of ATP or malate, (b) palmitoyl-l(-)-carnitine in presence of malate and (c) oxoglutarate. Lowering the pH, even to 6.8, causes the citrate to emerge. This could be the basis of a cellular control mechanism. The generation of citrate in response to Ca(2+) can explain the stoichiometry of one proton ejected per Ca(2+) ion taken up. The new carboxyl group formed from acetyl-CoA when it condenses with oxaloacetate provides an internal anionic charge and a proton to emerge when Ca(2+) enters.     

The dependence on dicarboxylic acids and energy of citrate accumulation in depleted rat liver mitochondria

The accumulation of some organic anions in the space inaccessible to sucrose of rat liver mitochondria was measured. In untreated mitochondria anions were apparently concentrated from 1mm applied concentration by between five- and 22-fold, depending on their charge. After depletion of endogenous reserves either with uncoupling agent or with oligomycin uptakes were decreased. The accumulation of citrate was restored by combinations of a dicarboxylic acid (malate, succinate, maleate or meso-tartrate) and energy. The energy could either be provided by oxidation of a suitable dicarboxylic acid or from ascorbate in the presence of tetramethylphenylenediamine, or from ATP. The restoration of citrate uptake is not necessarily accompanied by a gain of K(+), but a cation- and energy-linked citrate uptake can be induced with valinomycin. When citrate is added to mitochondria in the presence of malate the latter is competitively displaced. The anion accumulation could arise from an internal energy-linked positive potential.     

Upper and lower limits of the charge translocation stoichiometry of mitochondrial electron transport

The upper and lower limits of the mechanistic stoichiometry (n) of electric charge translocation coupled to mitochondrial electron transport have been determined for the oxidation of succinate and beta-hydroxybutyrate using a recently described method (Beavis, A. D., and Lehninger, A. L. (1986) Eur. J. Biochem. 158, 307-314). This method requires no assumptions regarding the magnitude of proton leakage or pump slippage, but it takes advantage of the ability to predict the direction of change as the coupled fluxes are modulated by specific means. In this study, the rates of K+ uptake (JK) and O2 consumption (JO) were determined from simultaneous electrode measurements in the presence of various concentrations of valinomycin or inhibitors of electron flow. When valinomycin is varied, the rate of proton leakage or pump slippage should decrease as JO increases, with the result that the slope dJK/dJO will be greater than n. On the other hand, when an inhibitor of electron flow is varied, the rate of proton leakage or pump slippage should increase as JO increases, with the result that the slope dJK/dJO should be less than n. The data obtained using this approach indicate that n lies between 6.7 and 7.3 for succinate oxidation and between 10.2 and 11.7 for beta-hydroxybutyrate (or NADH) oxidation. It is concluded that the mechanistic stoichiometry of charge separation coupled to electron flow is 7 q+/O in the span from succinate to oxygen and 11 q+/O in the span from NADH to oxygen. These conclusions are fully consistent with the limits of the mechanistic ATP/O ratios previously determined for these spans (Beavis, A. D., and Lehninger, A. L. (1986) Eur. J. Biochem. 158, 315-322).     

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.     

Oxidative phosphorylation in mitochondria from different fiber types of chicken muscles

Isolated mitochondria from different types of muscle fibers from chickens 3 to 5 weeks were studied to evaluate the comparative oxidation of various substrates. Pectoralis (alphaW fibers), lateral adductor (betaR fibers), and medial adductor (alphaR fibers) were the muscles used. Oxygen consumption rates, RCR, and ADP/O ratios were measured to study mitochondrial function. Mitochondria from pectoralis muscle utilized pyruvate, succinate, L-glutamate, alpha-glycerophosphate, and beta-hydroxybutyrate. Mitochondria from the other two muscle types utilized all of those substrates except alpha-glycerophosphate. In each muscle type utilization of NADH was minimum and was not coupled with phosphorylation of ADP. Thus, in alphaW muscles oxidation of alpha-glycerophosphate may play an important role in transport of cytoplasmic NADH to the mitochondrial respiratory chain. In alphaR and betaR muscles "shuttle" systems other than alpha-glycerophosphate oxidation, e.g., beta-hydroxybutyrate, may perform that important role.     

A novel, simple and rapid method for the isolation of mitochondria which exhibit respiratory control, from rat small intestinal mucosa

A method is described for the isolation of functional mitochondria from rat intestinal mucosa. Its novel feature is the removal of mucus from the initial homogenate by treatment with DEAE-cellulose. The preparations exhibited acceptable ADP:O ratios, high State-3 respiration rates, and respiratory control ratios in excess of 3 when succinate, beta-hydroxybutyrate, glutamate/malate and glutamine were test substrates.     

Properties of substantially chlorophyll-free pea leaf mitochondria prepared by sucrose density gradient separation

Mitochondria isolated from pea leaves (Pisum sativum L. var Massey Gem) and purified on a linear sucrose density gradient were substantially free of contamination by Chl and peroxisomes. They showed high respiratory rates and good respiratory control and ADP/O ratios. Malate, glutamate, succinate, glycine, pyruvate, α-ketoglutarate, NADH, and NADPH were oxidized but little or no oxidation of citrate, isocitrate, or proline was detected. The oxidation of NADPH by the purified mitochondria did not occur via a transhydrogenase or phosphatase converting it to NADH. NADPH oxidation had an absolute requirement for added Ca²⁺, whereas NADH oxidation proceeded in its absence. In addition, oxidation of the two substrates showed different sensitivities to chelators and sulfhydryl reagents, and faster rates of O₂ uptake were observed with both substrates than with either alone. This indicates that the NADPH dehydrogenase is distinct from the exogenous NADH dehydrogenase.     

Oxidation of Various Substrates by Mitochondria as Related to the Concentration of Osmotics in the Medium

Wheat (Triticum aestivumL.) root mitochondria were used to investigate the effect of solute concentration in the medium on the rates of succinate, malate, -ketoglutarate, and glutamate oxidation; the corresponding values of the apparent Michaelis constant (K _M); and the changes in the organelle volumes. The oxidation rates and the K _M values for all substrates were lower in the 0.5 M sucrose solution than in the 0.3 M solution. Under high osmotic concentration, mitochondria did not shrink. On the contrary, in the absence of the substrate, mitochondria swelled more in the 0.5 M sucrose solution than in the 0.3 M solution. This effect was absent when the substrate was added. The authors conclude that the decrease in the oxidation rate imposed by sucrose was not related to the hindered influx of substrates caused by matrix contraction. Rather, the osmotic effect of sucrose is related to the changes in the structure of mitochondrial enzyme complexes.     

Isolation and properties of flight muscle mitochondria of the bumblebee Bombus terrestris (L.)

This report describes the isolation procedure and properties of tightly coupled flight muscle mitochondria of the bumblebee Bombus terrestris (L.). The highest respiratory control index was observed upon oxidation of pyruvate, whereas the highest respiration rates were registered upon oxidation of a combination of the following substrates: pyruvate + malate, pyruvate + proline, or pyruvate + glutamate. The respiration rates upon oxidation of malate, glutamate, glutamate + malate, or succinate were very low. At variance with flight muscle mitochondria of a number of other insects reported earlier, B. terrestris mitochondria did not show high rates of respiration supported by oxidation of proline. The maximal respiration rates were observed upon oxidation of α-glycerophosphate. Bumblebee mitochondria are capable of maintaining high membrane potential in the absence of added respiratory substrates, which was completely dissipated by the addition of rotenone, suggesting high amount of intramitochondrial NAD-linked oxidative substrates. Pyruvate and α-glycerophosphate appear to be the optimal oxidative substrates for maintaining the high rates of oxidative metabolism of the bumblebee mitochondria.     

Effect of sydnone SYD-1, a mesoionic compound, on energy-linked functions of rat liver mitochondria

An important antitumour effect of SYD-1 (3-[4-chloro-3-nitrophenyl]-1,2,3-oxadiazolium-5-olate) has been shown. We now report the effects of this mesoionic compound on mitochondrial metabolism. SYD-1 (1.5 micromol mg(-1) protein) dose-dependently inhibited the respiratory rate by 65% and 40% in state 3 using sodium glutamate and succinate, respectively, as substrates. Phosphorylation efficiency was depressed by SYD-1, as evidenced by stimulation of the state 4 respiratory rate, which was more accentuated with glutamate ( approximately 180%) than with succinate ( approximately 40%), with 1.5 micromol mg(-1) protein of SYD-1. As a consequence of the effects on states 3 and 4, the RCC and ADP/O ratios were lowered by SYD-1 using both substrates, although this effect was stronger with glutamate. The formation of membrane electrical potential was inhibited by approximately 50% (1.5 micromol SYD-1mg(-1) protein). SYD-1 interfered with the permeability of the inner mitochondrial membrane, as demonstrated by assays of mitochondrial swelling in the presence of sodium acetate and valinomycin +K(+). SYD-1 (1.5 micromol mg(-1) protein) inhibited glutamate completely and succinate energized-mitochondrial swelling by 80% in preparations containing sodium acetate. The swelling of de-energized mitochondria induced by K(+) and valinomycin was inhibited by 20% at all concentrations of SYD-1. An analysis of the segments of the respiratory chain suggested that the SYD-1 inhibition site goes beyond the complex I and includes complexes III and IV. Glutamate dehydrogenase was inhibited by 20% with SYD-1 (1.5 micromol mg(-1) protein). The hydrolytic activity of complex F(1)F(o) ATPase in intact mitochondria was greatly increased ( approximately 450%) in the presence of SYD-1. Our results show that SYD-1 depresses the efficiency of electron transport and oxidative phosphorylation, suggesting that these effects may be involved in its antitumoural effect.     

NADH-linked substrate dependence of peroxide-induced respiratory inhibition and calcium efflux in isolated renal mitochondria

Peroxide-induced state 3 respiratory inhibition and Ca2+ efflux in isolated renal mitochondria exhibited a NADH-linked substrate dependence. ADP-stimulated respiratory rates in the presence of various concentrations of tert-butyl hydroperoxide (tBOOH, 0-1000 nmol/mg protein) were determined using glutamate, beta-hydroxybutyrate, or pyruvate as substrates. Pyruvate-driven respiration was most sensitive to inhibition (Ki approximately equal to 75 nmol of tBOOH/mg protein) followed by beta-hydroxybutyrate and glutamate (Ki approximately equal to 150 nmol of tBOOH/mg protein for each). Calcium (5-10 nmol/mg protein) potentiated tBOOH-induced respiratory inhibition using all three substrates. Mitochondrial Ca2+ efflux, induced by tBOOH, was most pronounced with pyruvate as substrate. Glutamate prevented Ca2+ efflux while the efflux rate with beta-hydroxybutyrate was intermediate between glutamate and pyruvate. The substrate-dependent pattern of tBOOH-induced NAD(P)H (NADH plus NADPH) and cytochrome b oxidation was similar to that seen for respiratory inhibition and Ca2+ efflux suggesting that NAD(P)H may be a common factor in both responses. Low tBOOH concentrations inhibited pyruvate dehydrogenase flux while higher concentrations enhanced pyruvate dehydrogenase flux and activation. The results are discussed in relation to currently proposed theories of reactive oxygen-induced respiratory inhibition, Ca2+ efflux, and reperfusion injury.     

Stimulation of menaquinone-dependent electron transfer in the respiratory chain of Bacillus subtilis by membrane energization

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Calcium transport in bovine sperm mitochondria: effect of substrates and phosphate.

Calcium uptake into filipin-treated bovine spermatozoa is completely inhibited by the uncoupler CCCP or by ruthenium red. Both Pi and mitochondrial substrates are required to obtain the maximal rate of calcium uptake into the sperm mitochondria. Bicarbonate and other anions such as lactate, acetate or beta-hydroxybutyrate do not support a high rate of calcium uptake. There are significant differences among various mitochondrial substrates in supporting calcium uptake. The best substrates are durohydroquinone, alpha-glycerophosphate and lactate. Pyruvate is a relatively poor substrate, and its rate can be greatly enhanced by malate or succinate but not by oxalacetate or lactate. This stimulation is blocked by the dicarboxylate translocase inhibitor, butylmalonate and can be mimiced by the non-metabolized substrate D-malate. The Ka for pyruvate was found to be 17 microM and 67 microM in the presence and absence of L-malate, respectively. The Ka for L-malate is 0.12 mM. It is suggested that in addition to the known pyruvate/lactate translocase there is a second translocase for pyruvate which is malate/succinate-dependent and does not transport lactate. In the presence of succinate, glutamate stimulates calcium uptake 3-fold, and this effect is not inhibited by rotenone. In the presence of glutamate plus malate or oxalacetate there is only an additive effect. It is suggested that glutamate stimulates succinate transport and/or oxidation in bovine sperm mitochondria. The alpha-hydroxybutyrate is almost as good as lactate in supporting calcium uptake. Since the alpha-keto product is not further metabolized in the citric acid cycle, it is suggested that lactate can supply the mitochondrial needs for NADH from its oxidation to pyruvate by the sperm lactate dehydrogenase x. Thus, when there is sufficient lactate in the sperm mitochondria, pyruvate need not be further metabolized in the citric acid cycle in order to supply more NADH.     

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.     

Calcium uptake by bovine epididymal spermatozoa is regulated by the redox state of the mitochondrial pyridine nucleotides

Immature caput epididymal sperm accumulate calcium from exogenous sources at a rate 2- to 4-fold greater than mature caudal sperm. Calcium accumulation by these cells, however, is maximal in the presence of lactate as external substrate. This stimulation of calcium uptake by optimum levels of lactate (0.8-1.0 mM) is about 5-fold in caput and 2-fold in caudal sperm compared to values observed with glucose as substrate. Calcium accumulation by intact sperm is almost entirely mitochondrial as evidenced by the inhibition of uptake by rotenone, antimycin, and ruthenium red. The differences in the ability of the various substrates in sustaining calcium uptake appeared to be related to their ability to generate NADH (nicotinamide adenine dinucleotide). Previous reports have documented that mitochondrial calcium accumulation in several somatic cells is regulated by the oxidation state of mitochondrial NADH. A similar situation obtains for bovine epididymal sperm since calcium uptake sustained by site III oxidation of ascorbate in the presence of tetramethyl phenylenediamine and rotenone was also stimulated by NADH-producing substrates, including lactate, and inhibited by substrates generating NAD+ (nicotinamide adenine dinucleotide, oxidized form). Further, calcium uptake by digitonin-permeabilized sperm in the presence of succinate was stimulated when NADH oxidation was inhibited by rotenone. The compounds alpha-keto butyric, valeric, and caproic acids, which generate NAD+, inhibited the maximal calcium uptake observed in the presence of succinate and rotenone, and the hydroxy acids lactate and beta-hydroxybutyrate reversed this inhibition. These results document the regulation of sperm calcium accumulation by the physiological substrate lactate, emphasize the importance of mitochondria in the accumulation of calcium by bovine epididymal sperm, and suggest that the mitochondrial location of the isozyme LDH-X in mammalian sperm may be involved in the regulation of calcium accumulation.     

Generation of H2O2 in Brain Mitochondria

Generation of H2O2 by rat brain mitochondria using succinate and glycerol-1-phosphate as substrates has been demonstrated. Earlier workers were unable to detect this activity in sucrose-Tris buffer. We found that this was due to a lag in the expression of activity in sucrose medium. Using phosphate buffer (50 mM), good rates are now obtained. Generation of H2O2 by rat brain mitochondria required the presence of antimycin A and was dependent on the substrates succinate and glycerol-1-phosphate. Low rates were obtained with NAD+-linked substrates and none with choline, glutamate, and NADH. The Km and Vmax values for H2O2 generation were considerably lower than the corresponding values for the respective dehydrogenase activity, measured by dye reduction. Oxygen-radical scavengers inhibited H2O2 generation, suggesting oxygen radical involvement. Depletion of ubiquinone from mitochondria resulted in loss of H2O2 generation. Reconstitution of such depleted particles with ubiquinone restored the capacity to generate H2O2 in a concentration-dependent manner. Levels of H2O2 production were found to be maximal in cerebellum. Brain mitochondria from rabbit, hamster, mouse, and guinea pig also have the capacity to generate H2O2 on oxidation of glycerol-1-phosphate.     

Correlation of the effects of citric acid cycle metabolites on succinate oxidation by rat liver mitochondria and submitochondrial particles.

1. Succinate dehydrogenase is inhibited by citrate and beta-hydroxy-butyrate in a complex manner, both in mitochondria and submitochondrial particles. Kinetics of inhibition in the particles points to a competitive component in the mechanism involved. 2. Pyruvate, alpha-ketoglutarate, malate, and glutamate stimulate oxidation of succinate by mitochondria. 3. Stimulation by alpha-ketoglutarate and glutamate is not influenced by the presence of rotenone. 4. Stimulation by pyruvate is higher in the absence of rotenone and increases significantly in the presence of K+ and valinomycin. Pyruvate supplies in mitochondria reducing equivalents for malate dehydrogenase operating in the reverse direction-reduction of oxaloacetate to malate. 5. Stimulation by malate is higher in the presence of rotenone.     

The transport of L-cysteinesulfinate in rat liver mitochondria.

1. The mechanism of L-cysteinesulfinate permeation into rat liver mitochondria has been investigated. 2. Mitochondria do not swell in ammonium or potassium salts of L-cysteinesulfinate in all the conditions tested, including the presence of valinomycin and/or carbonylcyanide p-trifluoromethoxyphenylhydrazone. 3. The activation of malate oxidation by L-cysteinesulfinate is abolished by aminooxyacetate, an inhibitor of the intramitochondrial aspartate aminotransferase, it is not inhibited by high concentrations of carbonylcyanide p-trifluoromethoxyphenylhydrazone (in contrast to the oxidation of malate plus glutamate) and it is decreased on lowering the pH of the medium. 4. All the aspartate formed during the oxidation of malate plus L-cysteinesulfinate is exported into the extramitochondrial space. 5. Homocysteinesulfinate, cysteate and homocysteate, which are all good substrates of the mitochondrial aspartate aminotransferase, are unable to activate the oxidation of malate. Homocysteinesulfinate and homocysteate have no inhibitory effect on the L-cysteinesulfinate-induced respiration, whereas cysteate inhibits it competitively with respect to L-cysteinesulfinate. 6. In contrast to D-aspartate, D-cysteinesulfinate and D-glutamate, L-aspartate inhibits the oxidation of malate plus L-cysteinesulfinate in a competitive way with respect to L-cysteinesulfinate. Vice versa, L-cysteinesulfinate inhibits the influx of L-aspartate. 7. Externally added L-cysteinesulfinate elicits efflux of intramitochondrial L-aspartate or L-glutamate. The cysteinesulfinate analogues homocysteinesulfinate, cysteate and homocysteate and the D-stereoisomers of cysteinesulfinate, aspartate and glutamate do not cause a significant release of internal glutamate or aspartate, indicating a high degree of specificity of the exchange reactions. External L-cysteinesulfinate does not cause efflux of intramitochondrial Pi, malate, malonate, citrate, oxoglutarate, pyruvate or ADP. The L-cysteinesulfinate-aspartate and L-cysteinesulfinate-glutamate exchanges are inhibited by glisoxepide and by known substrates of the glutamate-aspartate carrier. 8. The exchange between external L-cysteinesulfinate and intramitochondrial glutamate is accompanied by translocation of protons across the mitochondrial membrane in the same direction as glutamate. The L-cysteinesulfinate-aspartate exchange, on the other hand, is not accompanied by H+ translocation. 9. The ratios delta H+/delta glutamate, delta L-cysteinesulfinate/delta glutamate and delta L-cysteinesulfinate/delta aspartate are close to unity. 10. It is concluded that L-cysteinesulfinate is transported by the glutamate-aspartate carrier of rat liver mitochondria. The present data suggest that the dissociated form of L-cysteinesulfinate exchanges with H+-compensated glutamate or with negatively charged aspartate.