ULTRASTRUCTURAL TRANSFORMATION IN MITOCHONDRIA ISOLATED FROM KIDNEYS OF NORMAL AND LEAD-INTOXICATED RATS

Mitochondria isolated from kidneys of lead-intoxicated rats have been shown to have decreased oxidative and phosphorylative abilities. The purpose of this study was to determine whether these abnormal mitochondria would undergo ultrastructural transformation during controlled respiration in the absence of phosphate acceptor (State IV), as previously demonstrated for normal liver mitochondria. It was first shown that normal rat kidney mitochondria transforms from a condensed ultrastructural conformation to an orthodox conformation after 5 min of State IV respiration with pyruvate-malate substrate. Reversal to a condensed conformation follows stimulation of respiration with adenosine diphosphate (ADP). A large portion of kidney mitochondria from lead-poisoned rats do not change from condensed to orthodox conformation during State IV respiration. Other mitochondria do transform to the orthodox form but they rapidly degenerate. State IV respiration decreases as these few orthodox mitochondria disintegrate. The conclusion is that those mitochondria that do not undergo change in ultrastructure have impairment of electron transport, and that those that do become orthodox have increased membrane lability and undergo degeneration.     

ULTRASTRUCTURAL BASES FOR METABOLICALLY LINKED MECHANICAL ACTIVITY IN MITOCHONDRIA : II. Electron Transport-Linked Ultrastructural Transformations in Mitochondria

Isolated mitochondria are capable of undergoing dramatic reversible ultrastructural transformations between a condensed and an orthodox conformation. These two conformations are the extremes in ultrastructural organization between which structually and functionally intact mitochondria transform during reversible respiratory cycles. It has been found that electron transport is required for the condensed-to-orthodox ultrastructural transformation which occurs in mitochondria under State IV conditions, i.e., under conditions in which exogenous substrate is present and ADP is deficient. Inhibition of State IV electron transport at the cyanide-, antimycin A-, or Amytal-sensitive sites in the respiratory chain results in inhibition of this transformation. Resumption of electron transport in initially inhibited mitochondrial systems, initiated by channeling electrons through pathways which bypass the inhibited sites, results in resumption of the ultrastructural transformation. The condensed-to-orthodox transformation is DNP insensitive and, therefore, does not require participation of the coupling enzymes of the energy-transfer pathway. It is concluded that this ultrastructural transformation is manifest by the conversion of the chemical energy of electron transport directly into mechanical work. The reversed ultrastructural transformation, i.e., orthodox-to-condensed, which occurs during ADP-activated State III electron transport, is inhibited by DNP and parallels suppression of acceptor control and oxidative phosphorylation. Mechanochemical ultrastructural transformation as a basis for energy transfer in mitochondria is considered with respect to the results presented.     

Effect of various inhibitors on oxidative activity and ultrastructure of rat liver mitochondria]

Parallel studies concerning the influence of some inhibitors on electron transfer, and ultrastructural aspects of rat liver mitochondria led to the conclusion that metabolic activity and mitochondrial ultrastructure are closely linked ; when mitochondria oxidize succinate, their configuration change from the "condensed" to the "orthodox" state ; this change does not occur if the oxidation is inhibited.     

ION-INDUCED ULTRASTRUCTURAL TRANSFORMATIONS IN ISOLATED MITOCHONDRIA : The Energized Uptake of Calcium

The energized uptake of low levels of Ca²⁺ in the presence and absence of phosphate by isolated rat liver mitochondria, and the perturbation effected by this activity on ultrastructural and metabolic parameters of mitochondria have been investigated. In the presence of phosphate, low levels of Ca²⁺ are taken up by mitochondria and result in various degrees of ultrastructural expansion of the inner mitochondrial compartment. This indicates that low levels of Ca²⁺ in the presence of phosphate, are accumulated in an osmotically active form into the water phase of the inner compartment. The first clearly observable quantitative increase in the volume of the inner compartment occurs after the accumulation of 100 nmoles Ca²⁺/mg protein. An accumulation of 150–200 nmoles Ca²⁺/mg protein, which is equivalent to the osmolar concentration of endogenous K⁺, is required to effect a doubling of the volume of the inner compartment. This degree of osmotic perturbation occurs as mitochondria transform from a condensed to an orthodox conformation. The osmotically induced orthodox conformation differs from the mechanochemically induced orthodox conformation previously described, in that its development is concomitant with a marked decrease in acceptor control and oxidative phosphorylation efficiency and it fails to transform to a condensed conformation in response to addition of ADP. In the absence of added phosphate, a maximum of 190 nmoles Ca²⁺/mg protein was found to be taken up by mitochondria (state 6). Ca²⁺ is apparently bound under state 6 conditions since the uptake does not effect an ultrastructural expansion of the inner compartment. Phosphate added after state 6 Ca²⁺ binding, however, results in an immediate ultrastructural expansion of the inner compartment. The addition of phosphate to mitochondria in the absence of exogenous Ca^2- fails to effect an osmotic ultrastructural transformation. Under state 6 conditions, the binding of between 40 and 190 nmoles Ca²⁺/mg protein results in the formation of dense matrix inclusions which appear to be composed of tightly packed, concentrically oriented membranes. Under conditions in which the bound Ca²⁺ is subsequently released, there is a concomitant loss in the density of these matrix inclusions, leaving behind morphologically distinct membrane whorls in the mitochondrial matrix.     

Mitochondrial ultrastructural transformations in P. lividus eggs stimulated by ammonia

In mitochondria of P. lividus eggs the transition from the condensed to the orthodox form is accomplished in about 45 min after fertilization. Similar ultrastructural transformations are induced by exposure to ammonia that is known to cause a partial egg activation.     

Mitochondrial regulation in sea urchins. I. Mitochondrial ultrastructure transformations and changes in the ADP:ATP ratio at fertilization.

Mitochondrial ultrastructural transformations have been examined in intact eggs and embryos from three sea urchins, Arbacia punctulata, Strongylocentrotus purpuratus, and Lytechinus pictus. Following fertilization, naturally occurring ultrastructural transformations (designated as condensed to orthodox) were observed to occur in mitochondria of all three families. The ratios of the soluble ADP and ATP pools were examined in eggs of S. purpuratus before and after fertilization in order to test whether the ultrastructural transformations reflect a decrease in relative size of the ADP pool following fertilization. Our data indicate that there is a decrease in the ADP:ATP ratio at fertilization. These findings and their implications are discussed with respect to presently accepted theories on mitochondrial regulation.     

THE MORPHOLOGY OF THE SWELLING PROCESS IN RAT LIVER MITOCHONDRIA

Through the use of combined spectrophotometric and electron microscope techniques, large amplitude swelling of rat liver mitochondria has been described as an ordered sequence of ultrastructural transitions. Prior to the actual swelling, mitochondria undergo two major conformational changes: condensed to twisted form and twisted to orthodox form. This sequence is independent of (a) the nature of swelling agents and (b) the time of onset of swelling. Agents that delay the onset of swelling act to increase the duration of the twisted conformation. Agents that prevent extensive swelling hold mitochondria in intermediate conformations. Gross swelling, immediately preceded by a decrease in electron opacity of the matrix, involves the rupture of the outer membrane and expansion of the inner compartment of the mitochondrion.     

Relationship between the conformation of isolated rat liver mitochondria and their susceptibility to rabbit reticulocyte lipoxygenase]

Lipoxygenase from rabbit reticulocytes cause disruption of mitochondrial membranes and peroxidation of their lipids as judged by electronmicroscopy, release of matrix enzymes and formation of malonyldialdehyde. Without substrate mitochondria become orthodox and strong lysis by lipoxygenase appears. The lysis is prevented by ATP or ADP plus succinate; in this case mitochondria remain condensed or partly condensed. The protection by substrate was even observed in the presence of 2,4-DNP, although the mitochondria were transformed to the condensed state. Lysis was more pronounced in hypotonic than in hypertonic sucrose, condensed mitochondria are also attacked. No relation seems to exist between lipoxygenase attack and the conformational state of mitochondria. Lysis of mitochondria is dependent on the susceptibility of the fatty acid moiety of phospholipids, which may be influenced by both metabolic and structural events via alteration of protein-lipid interactions.     

A study of rapid mitochondrial structural changes in vitro by spray- freeze-etching

The spray-freeze-etching technique has been used to study energy-linked mitochondrial structural changes in rat liver mitochondria incubated in vitro. The technique involves spraying the suspension of mitochondria into liquid propane at -190 degrees C, and does not require the use of cryoprotectants or chemical fixatives. The results confirmed that freshly isolated mitochondria have a condensed matrix and that this expands at the expense of the outer compartment to give the orthodox configuration when the mitochondria are incubated in a K+ medium in the presence of substrate and phosphate. Addition of adenosine diphosphate (ADP) caused a rapid shrinkage of the matrix compartment, and the time-course and extent of this shrinkage has been measured quantitatively by coupling a rapid sampling device to the spray-freezing apparatus. These data show that for orthodox mitochondria the onset of phosphorylation is accompanied by a reduction of 30% in the matrix volume in 20's, and there is no evidence that the decrease in matrical volume affects the phosphorylation efficiency. These results suggest that natural ionophores in the mitochondrial inner membrane make it permeable enough to permit a rapid readjustment of matrix volume after the addition of ADP, and that the associated ion movement does not cause uncoupling of oxidative phosphorylation.     

An analysis of the contribution of the preparatory technique to the appearance of condensed and orthodox conformations of liver mitochondria

The structure and volume of isolated mitochondria embedded for electron microscopy during different respiratory states were analyzed in thin sections. Three different embedding methods were compared; osmium tetroxide fixation/acetone dehydration, glutaraldehyde fixation/acetone dehydration, and glutaraldehyde fixation-osmium tetroxide postfixation/acetone dehydration. Analysis of fresh mitochondria, isolated in a sucrose medium, revealed the presence of a homogeneous population with respect to structure when any of the three methods were applied. After fixation with osmium alone, or in combination with glutaraldehyde, nearly 100% of the mitochondria were in a "condensed" conformation. Mitochondria fixed with glutaraldehyde alone resulted in a population of mitochondria that had large spaces separating the two membranes of the cristae which corresponds to the condensed conformation as observed after osmium fixation. Transfer of the mitochondria to the incubation medium led to the appearance of two classes of mitochondria with respect to size. One class had a volume close to that observed when suspended in sucrose, and another class was present that was 30-45% larger. In osmium fixed or in double-fixed preparations, these small and large classes corresponded to "condensed" and "orthodox" forms of mitochondria respectively. When glutaraldehyde was used alone as the fixative, the two size classes were also present. However, the mitochondria were homogeneous with respect to structure. In these mitochondria, the width of the space that separated the cristae membranes had become reduced when compared to mitochondria suspended in sucrose. The two size classes were also present in samples of mitochondria prepared during both states 3 and 4. State 4 conditions did not lead to any significant increase of the number of condensed mitochondria. In state 3 preparations, 65-70% of the population were condensed. The condensed and orthodox forms could be related to normal and swollen forms of mitochondria. Conditions that led to a swelling also led to an increase in the number of orthodox mitochondria in osmium-fixed material. The different appearance of the mitochondria is explained by the different conditions for fixation of the mitochondria that exist when nonswollen and swollen mitochondria are fixed. This difference is particularly crucial in the case of osmium tetroxide due to the unique way this fixative, among generally used fixatives, denatures proteins.     

OXIDATIVE PHOSPHORYLATION AND ULTRASTRUCTURAL TRANSFORMATION IN MITOCHONDRIA IN THE INTACT ASCITES TUMOR CELL

We have examined the ultrastructure of mitochondria as it relates to energy metabolism in the intact cell. Oxidative phosphorylation was induced in ultrastructurally intact Ehrlich ascites tumor cells by rapidly generating intracellular adenosine diphosphate from endogenous adenosine triphosphate by the addition of 2-deoxyglucose. The occurrence of oxidative phosphorylation was ascertained indirectly by continuous and synchronous monitoring of respiratory rate, fluorescence of pyridine nucleotide, and 90° light-scattering. Oxidative phosphorylation was confirmed by direct enzymatic analysis of intracellular adenine nucleotides and by determination of intracellular inorganic orthophosphate. Microsamples of cells rapidly fixed for electron microscopy revealed that, in addition to oxidative phosphorylation, an orthodox → condensed ultrastructural transformation occurred in the mitochondria of all cells in less than 6 sec after the generation of adenosine diphosphate by 2-deoxyglucose. A 90° light-scattering increase, which also occurs at this time, showed a t ½ of only 25 sec which agreed temporally with a slower orthodox → maximally condensed mitochondrial transformation. Neither oxidative phosphorylation nor ultrastructural transformation could be initiated in mitochondria in intact cells by the intracellular generation of adenosine diphosphate in the presence of uncouplers of oxidative phosphorylation. Partial and complete inhibition of oxidative phosphorylation by oligomycin resulted in a positive relationship to partial and complete inhibition of 2-deoxyglucose-induced ultrastructural transformation in the mitochondria in these cells. The data presented reveal that an orthodox → condensed ultrastructural transformation is linked to induced oxidative phosphorylation in mitochondria in the intact ascites tumor cell.     

Studies on ultrastructure and purification of isolated plant mitochondria

Sweetpotato mitochondria, that showed respiratory control, were studied with respect to ultrastructure. If fixed in media containing sucrose at 0.4 M, the cristae were dilated and the matrix was highly condensed. A more orthodox ultrastructural form was observed when the mitochondria were fixed in a medium containing sucrose at 0.25 M, i.e., the matrix was more expanded, the cristae were less dilated, and peripherally, the inner membrane element lay adjacent to the outer membrane element. These results are discussed in terms of a sucrose-accessible space (space between outer and inner membrane elements including intracristal space), and a space relatively inaccessible to sucrose (matrix). Ultrastructural shifts were not observed with change in metabolic steady state of the mitochondria. High resolution electron micrographs showed that the ultrastructure of sweetpotato mitochondria is very similar to that of animal mitochondria.

Purity and homogeneity of mitochondrial fractions were followed both by phase-contrast and electron microscopy. Preparations from sweetpotato, using older methods, were relatively homogeneous with respect to particle type and size, whereas avocado preparations contained a high proportion of chloroplasts and cellular debris. A method of purification involving sucrose-density-gradient centrifugation was developed. Purified mitochondria exhibited respiratory control and appeared similar to unpurified mitochondria under the electron microscope.

     

Thyroxine-induced changes in rat liver mitochondrial ubiquinone

Ubiquinone was extracted from liver mitochondria isolated from euthyroid and hyperthyroid rats. The redox state of ubiquinone was determined during States III and IV respiration with succinate or glutamate-malate substrates. Ubiquinone was more reduced during State III or IV in the hyperthyroid mitochondria with either substrate. Furthermore, the concentration of ubiquinone increased in the hyperthyroid rats.     

Studies on the transition of the cristal membrane from the orthodox to the aggregated configuration. II: Determinants of the orthodox-aggregated transition in adrenal cortex mitochondria

Bovine adrenal cortex mitochondria when isolated in a medium 0·25 M in sucrose contaminated (with calcium) have tubular cristae which are periodically expanded to spherical vesicles and contracted to flattened connecting sections. This scalloped tubular form of the cristae corresponds to the nonenergized orthodox configuration—a configuration in which the matrix space is maximally expanded. When adrenal cortex mitochondria are isolated in media in which the free calcium content is relatively low, e.g., a medium 0·25 M in sucrose and 0·1 mM in EDTA, the cristae assume the aggregated configuration—a nonenergized configuration in which the matrix space is maximally contracted. The composition of the isolation medium determined the configuration. Procedures have been described for isolating bovine adrenal cortex mitochondria (a) predominantly in the orthodox configuration, (b) predominantly in the aggregated configuration, or (c) in a mixed (11) population of configurations. The concentration of Ca²⁺ bound to the mitochondrion was found to be a determinant of the nonenergized configuration. When the level of bound Ca⁺⁺ was 20–25 moles/mg protein, the cristae of the mitochondria were entirely in the orthodox configuration. Addition of Ca²⁺ could induce the transition of cristae from the aggregated to the orthodox configuration whereas addition of Mg²⁺ could induce the transition of cristae from the orthodox to the aggregated configuration. The configurational transition could be followed by any of several methods—a change in 90° light scattering, a change in O.D._{520 m}, a change in pH, or examination by electron microscopy. The orthodox to aggregated transition is energy-independent since it proceeds even in presence of inhibitors both of electron transfer and of ATP hydrolysis. The binding of Ca²⁺ is independent of the binding of Mg²⁺; this independent binding is consistent with the opposite effects induced by Ca²⁺ and Mg²⁺, respectively. Whereas Ca²⁺ induces a proton release, a decrease in 90° light scattering and a decrease in O.D._{520 m} (when the cristae are initially in the aggregated configuration), Mg²⁺ induces equal and opposite changes (when the cristae are initially in the orthodox configuration).     

Steroidogenesis in the zona glomerulosa of the adrenal cortex I. Isolation and some properties of mitochondria from the zona glomerulosa of the bovine adrenal cortex

Isolation procedures for mitochondria from the zona glomerulosa of the bovine adrenal cortex are described and the properties of the mitochondria thus prepared are compared with those isolated from the zona fasciculoreticularis. The cristal membranes of mitochondria in the zona glomerulosa in situ are tubular or tubulovesicular, whereas those of mitochondria in the zona fasciculoreticularis in situ are vesicular. When mitochondria are isolated from the former zone, they invariably showed the condensed configuration regardless of isolation media, whereas those isolated from the latter zone in an ST medium showed the orthodox configuration. When Ca²⁺ was added to mitochondria isolated either from the zona glomerulosa or the zona fasciculoreticularis in an STE medium in the condensed configuration, a transition from the condensed to the orthodox configuration took place; the cristal membranes of mitochondria from the zona glomerulosa became tubular or tubulovesicular and those of mitochondria from the zona fasciculoreticularis became vesicular. Contaminations of mitrochondria of the zona glomerulosa with other cellular organelles were examined using various marker enzymes. There was no difference in cytochrome content between mitochondria of the two zones specified above. The coupling efficiency of mitochondria of the zona glomerulosa was found to be remarkably effected by temperature during the isolation procedures. Effects of various substrates, isolation media, and bovine serum albumin on the coupling efficiency of mitochondria of the glomerulosa are also described.     

Quantitative and ultrastructural analysis of the chondriome in ovogenesis and embryogenesis of the sea urchin Paracentrotus lividus.

The dynamics of chondriome in the ovogenesis of the sea urchin Paracentrotus lividus was studied. Growing oocytes 20-30, 50-60 and 90-100 microm in diameter ("small", "medium-sized" and "large", respectively) and mature eggs were used for the ultrastructural and stereological analysis of mitochondria. Linear parameters of mitochondria (length and thickness) were measured on 3-D reconstructions of serial ultrathin sections using the software developed in the laboratory. The following transformations of chondriome structure were shown to occur during ovogenesis: (1) the number of mitochondria (MT) increases with the growth of cytoplasmic compartment; (2) the modal length of MT increases from 0.5 microm in small oocytes to 1 microm in large ones and decreases again to 0.5 microm in the egg; this process is accompanied by changes in the relative number of spherical MT which decreases in medium-sized oocytes and subsequently rises again in the egg; (3) in medium-sized oocytes, dumbbell-shaped MT appear first, the number of these MT reaching the maximum to the stage of large oocytes. In mature eggs, the dumb-bell-shaped MT are absent; (4) in small and medium-sized oocytes, the orthodox conformation of MT is observed, in contrast to MT with a condensed matrix in large oocytes and eggs; (5) in mature eggs, mitochondrial clusters containing 10 to 20 MT of various size are formed. Based on the data obtained, we suggested that during ovogenesis of the sea urchin, specific differentiation of the chondriome is induced which leads to the increase in the quantity of MT via multiple division acts, while restricting the MT growth and variability of their shape.     

Studies on the transition of the cristal membrane from the orthodox to the aggregated configuration. III. Loss of coupling ability of adrenal cortex mitochondria in the orthodox configuration

When the cristae of adrenal cortex mitochondria are stabilized in the orthodox configuration by the binding of 20–25 mmoles/mg protein of either Ca²⁺ or free fatty acids (oleic acid), both the capacity for carrying out coupled reactions and the capacity for undergoing energized configurational transitions are lost. The coupled reactions studied included ATP synthesis, divalent cation translocation, monovalent cation trnaslocation, and reversed electron transfer. The coupled processes and energized configurational changes are fully operative when the cristae of adrenal cortex mitochondria are in the aggregated configuration. However, two processes that have been shown to depend on conformational changes (the anaerobic-aerobic proton ejection and energized accumulation of inorganic phosphate) still proceed when mitochondria are in the orthodox configuration. When the mitochondria are initially in the orthodox configuration, addition of divalent cations (Mg²⁺ or Mn²⁺) or albumin induces a transition of the cristae to the aggregated configuration and leads to restoration of all the coupled processes. the orthodox to aggregated transition is reversible and the modulation of this reversibility appears to be one of the key points of control in the mitochondrion and possibly of cellular functions.On leave of absence from the Department of Pathology, Nagoya University School of Medicine, Nagoya, Japan.     

Mitochondrial dynamics in heart cells: Very low amplitude high frequency fluctuations in adult cardiomyocytes and flow motion in non beating Hl-1 cells

The arrangement and movement of mitochondria were quantitatively studied in adult rat cardiomyocytes and in cultured continuously dividing non beating (NB) HL-1 cells with differentiated cardiac phenotype. Mitochondria were stained with MitoTracker® Green and studied by fluorescent confocal microscopy. High speed scanning (one image every 400 ms) revealed very rapid fluctuation of positions of fluorescence centers of mitochondria in adult cardiomyocytes. These fluctuations followed the pattern of random walk movement within the limits of the internal space of mitochondria, probably due to transitions between condensed and orthodox configurational states of matrix and inner membrane. Mitochondrial fusion or fission was seen only in NB HL-1 cells but not in adult cardiomyocytes. In NB HL-1 cells, mitochondria were arranged as a dense tubular network, in permanent fusion, fission and high velocity displacements of ~90 nm/s. The differences observed in mitochondrial dynamics are related to specific structural organization and mitochondria-cytoskeleton interactions in these cells.     

ENERGY-LINKED ULTRASTRUCTURAL TRANSFORMATIONS IN ISOLATED LIVER MITOCHONDRIA AND MITOPLASTS : Preservation of Configurations by Freeze-Cleaving Compared to Chemical Fixation

An investigation was carried out in which microsamples of isolated rat liver mitochondria and freshly prepared mitoplasts in defined energy states were freeze-cleaved. Parallel microsamples were fixed with osmium tetroxide and with glutaraldehyde followed by osmium tetroxide as previously used in this laboratory for the preservation of energy-linked mitochondrial configurations. The details of the orthodox configuration of energized mitochondria and the condensed configuration of de-energized mitochondria, as revealed previously by chemical fixation, are confirmed in this report for nonfixed, freeze-cleaved mitochondria. The precise agreement in preservation of configuration obtained by the physical fixation of rapid freezing and by chemical fixation establishes unequivocally that mitochondria undergo energy-linked ultrastructural transformation between the condensed and the orthodox configurations which are thus natural structural states related to the metabolic activity of the mitochondrion. Configurations observed by freeze-cleaving and by chemical fixation reveal that mitoplasts also undergo a specific and dramatic ultrastructural transformation with the induction of oxidative phosphorylation. The transformation appears to be isovolumetric and therefore is thought to be mediated through energized conformational activity in the surface electron-transport membrane of the mitoplast. Passively swollen, spherical, osmotically active mitoplasts could not be fixed rapidly enough by chemical fixatives as normally used without altering the spherical form. In this special case preservation of configurational form required rapid freezing or chemical fixatives of low osmolar concentration.     

Involvement of oxygen free radicals in the respiratory uncoupling induced by free calcium and ADP-magnesium in isolated cardiac mitochondria: Comparing reoxygenation in cultured cardiomyocytes

Recently, we have observed that the simultaneous application of free calcium (fCa) and ADP-magnesium (Mg) reduced the ADP:O ratio in isolated cardiac mitochondria. The uncoupling was prevented by cyclosporin A, an inhibitor of the permeability transition pore. The purpose of this study was to know if the generation of oxygen free radicals (OFR) is involved in this phenomenon and if it occurs during reoxygenation (Reox) of cultured cardiomyocytes. Cardiac mitochondria were harvested from male Wistar rats. Respiration was assessed in two media with different fCa concentrations (0 or 0.6 M) with palmitoylcarnitine and ADP-Mg as respiration substrates. The production of Krebs cycle intermediates (KCI) was determined. Without fCa in the medium, the mitochondria displayed a large production of citrate + isocitrate + -ketoglutarate. fCa drastically reduced these KCI and promoted the accumulation of succinate. To know if OFR are involved in the respiratory uncoupling, the effect of 4OH-TEMPO (250 M), a hydrosoluble scavenger of OFR, was tested. 4OH-TEMPO completely abolished the fCa- and ADP-Mg-induced uncoupling. Conversely, vitamin E contributed to further decreasing the ADP:O ratio. Since no hydrosoluble electron acceptor was added in our experiment, the oxygen free radical-induced oxidized vitamin E was confined near the mitochondrial membranes, which should reduce the ADP:O ratio by opening the permeability transition pore. The generation of OFR could result from the matrix accumulation of succinate. Taken together, these results indicate that mitochondrial Ca uptake induces a slight increase in membrane permeability. Thereafter, Mg enters the matrix and, in combination with Ca, stimulates the isocitrate and/or -ketoglutarate dehydrogenases. Matrix succinate favors oxygen free radical generation that further increases membrane permeability and allows respiratory uncoupling through proton leakage. To determine whether the phenomenon takes place during Reox, cultured cardiomyocytes were subjected to hypoxia and Reox. ¹⁴C-palmitate was added during Reox to determine the KCI profile. Succinate had not increased during Reox. In conclusion, calcium- and ADP-Mg-induced respiratory uncoupling is due to oxygen free radical generation through excess matrix accumulation of succinate. The phenomenon does not occur during reoxygenation because of a total restoration of mitochondrial magnesium and/or ADP concentration.