Control of mitochondrial Mg++-efflux]

Inorganic phosphate stimulates the release of Mg++ from liver mitochondria, depending on concentration; a concentration as low as 0.1 mM phosphate is already effective. The process is dependent on the electron transfer of the respiratory chain, and its rate is highest under conditions of endogenous respiration and with ascorbate and TMPD as substrates, respectively. The phosphate stimulated release of Mg++ is followed, with a pronounced delay, by a Ca++ efflux and a swelling of mitochondria. Addition of EGTA strongly reduced the rate of Mg++ liberation in the presence and absence of inorganic phosphate. Exogenous Ca++ is able to abolish the EGTA effect. ADP and ATP inhibit the phosphate stimulated release of Mg++. Phosphoenol pyruvate and free fatty acids enhance the rate of Mg++ and Ca++ efflux from the mitochondria. The results permit the conclusion that inorganic phosphate, Ca++ and various metabolites of the cell metabolism influence the Mg++ distribution between the extra- and intramitochondrial space, thus controlling the permeability of the mitochondrial inner membrane for monovalent cations.     

Effects of amyl ester of unsubstituted rhodamine on respiration and Ca2+ transport in rat liver mitochondria.

In rat liver mitochondria the amylrhodamine is responsible for uncoupling (respiratory stimulation in state 4) by two distinct processes. Immediately after amylrhodamine addition (2-12 microM) stimulation of respiration takes place. Respiration rate for this phase is constant in time, it is independent of the potassium or inorganic phosphate content in the medium, not inhibited by oligomycin, ruthenium red, cyclosporine A, N-ethyl-maleimide and EGTA. The second phase of the respiratory stimulation is not linear in time. Respiration rate within this phase increases with rising of potassium and phosphate content in the medium. This effect is abolished by oligomycin, ruthenium red, cyclosporine A, N-ethylmaleimide and EGTA. The beginning of respiratory increment coincides with the second phase of Ca2+ release from mitochondria.     

The use of calcium uptake by small amounts of mitochondria from pancreatic islets to study mitochondrial respiration: the effects of diazoxide and sodium

The net uptake of 45Ca into mitochondria from pancreatic islets is stimulated by substrates that transfer reducing equivalents to various sites of the respiratory chain, such as succinate or glycerol 3-phosphate (site II), malate plus pyruvate (site I) or ascorbate plus TMPD (site III). Diazoxide, a known inhibitor of insulin release in vivo and in vitro, strongly inhibited net 45Ca uptake supported by glycerol phosphate and succinate and weakly inhibited 45Ca uptake supported by the other substrates. These results suggest that diazoxide, although not completely specific, is predominately an inhibitor at site II of the respiratory chain. This result is consistent with previous work that showed diazoxide inhibits the enzyme activity of the mitochondrial glycerol phosphate dehydrogenase in islets. Sodium ion inhibited the net accumulation of 45Ca by islet mitochondria suggesting a similarity between islet mitochondria and those of heart and some other endocrine tissues.     

Further studies on the effect of phosphoenolpyruvate on respiration-dependent calcium transport by rat heart mitochondria.

Phosphoenolpyruvate was found to depress extra oxygen consumption associated with Ca2+ -induced respiratory jump by rat heart mitochondria. Addition of phosphoenolpyruvate to mitochondria which have accumulated Ca2+ in the presence of glutamate and inorganic phosphate causes the release of Ca2+ from mitochondria. The phosphoenolpyruvate-stimulated Ca2+ efflux can be observed with mitochondria loaded with low initial Ca2+ concentration (0.12 mM) in the incubation medium. Measurements of mitochondrial H+ translocation produced by addition of Ca2+ to respiring mitochondria show that phosphoenolpyruvate depresses H+ ejection and enhances H+ uptake by mitochondria. The Ca2+ -releasing effect of phosphoenolpyruvate was found to be significantly stronger than that produced by rotenone when added to mitochondria loaded with Ca2+ in the presence of glutamate and inorganic phosphate. Dithiothreitol cannot overcome the effect of phosphoenolpyruvate on mitochondrial Ca2+ transport.     

Uptake of spermine by rat liver mitochondria and its influence on the transport of phosphate

Spermine, a polyamine present in the mammalian cells at rather high concentration, has, among other actions, a remarkable stabilizing effect on mitochondria, functions which have generally been attributed to the capability of this and other polyamines to bind to membrane anionic sites. In the present paper evidence is provided that at physiological concentrations spermine may also be transported into rat liver mitochondrial matrix space, provided that mitochondria are energized and inorganic phosphate is simultaneously transported. The close dependence of spermine transport is also demonstrated by the concurrent efflux of spermine and inorganic phosphate when mitochondria preloaded with the two ionic species are deenergized either with uncouplers or respiratory chain inhibitors. Furthermore, Mersalyl, the known inhibitor of phosphate transport, prevents both spermine uptake and release. Mg2+ inhibits the transport of spermine conceivably by competing for the some binding sites on the mitochondrial membrane. The physiological significance of these results is discussed.     

Ion transport induced by polycations and its relationship to loose coupling of corn mitochondria

Treatment of corn mitochondria (Zea mays L., WF9 (Tms) × M14) with polycations (protamine, pancreatic ribonuclease, or polylysine) releases acceptorless respiration if phosphate is present. Concurrently, there is extensive active swelling which is reversed when respiration is uncoupled or stopped. Mersalyl, the phosphate transport inhibitor, blocks both the release of respiration and the active swelling. Diversion of energy into phosphate transport lowers respiratory control and ADP: O ratios. This response is termed “loose coupling” in distinction to “uncoupling” in which energy is made unavailable for either transport or ATP formation. Corn mitochondria as used here are endogenously loose coupled to some extent, and show state 4 respiration linked to active transport.     

BIOCHEMICAL EFFECTS OF VICTORIN ON OAT TISSUES AND MITOCHONDRIA

Victorin, the pathotoxin produced by the plant pathogenic fungus Helminthosporium victoriae, causes changes in respiration and permeability which are typical of diseased plant tissues. To provide information on the site and mode of action of this toxin, the effects of victorin on mitochondria were studied and the nature and quantities of materials released from victorin-treated tissues were determined. Victorin added to isolated mitochondria had no effect on release of electrolytes or on oxidative-phosphorylative capacity. Hence the high respiratory rate found in victorin-treated tissues does not appear to be the result of a direct effect of the toxin on the respiratory centers. With mitochondria extracted from tissue pretreated with victorin, electrolyte release was unaffected but oxygen uptake was slightly higher and phosphate esterification considerably lower than controls. Thus the toxin produces indirect effects on mitochondrial activity, but the relation of these effects to tissue respiration remains undetermined. Victorin-treated tissue lost much larger quantities of certain organic and inorganic materials than control tissue with the most striking difference in the amount of potassium released.     

Functional relationship between the ADP/ATP-carrier and the F1-ATPase in mitochondria.

1. The distribution of labeled and unlabeled adenine-nucleotides inside and outside mitochondria was followed after addition of [14C]ADP to rat liver mitochondria. Two types of mitochondria were used: 1, respiring mitochondria which were carrying out oxidative phosphorylation and which had been replenished in ATP by incubation in a medium supplemented with succinate and phosphate; 2, non-respiring mitochondria which had been partially depleted of ATP by incubation in a medium supplemented with rotenone and phosphate. During the first minute following addition of [14C]ADP to the respiring mitochondria, the pre-existing intramitochondrial (internal) [12C]ATP was released into the medium and replaced by newly synthesized [14C]ATP. No [14C]ADP accumulated in the mitochondria. It is suggested that extramitochondrial (external) ADP entering respiring mitochondria in exchange for internal ATP is phosphorylated to ATP before its complete release in the matrix space. In non-respiring mitochondria, the entry of [14C]ADP into the mitochondria was accompanied by the appearance in the external space of [12C]ADP and [12C]ATP, with a marked predominance of [12C]ADP. Thus in non-respiring mitochondria, the residual internal ATP is dephosphorylated to ADP in the inner membrane before being released outside the mitochondria. 2. When mitochondria were incubated with glutamate, ADP and [32P]phosphate, the [32P]ATP which accumulated in the matrix space became rapidly labeled in both the P gamma and P beta groups of the ATP, due to the presence of a transphosphorylation system in the mitochondrial matrix. The [32P]ATP which accumulated outside the mitochondria was also labeled in the P beta group, although less rapidly than the internal ATP. Our data show that a large fraction (75-80%) of the ATP produced by phosphorylation of added ADP within the inner mitochondrial membrane is released into the matrix space before being transported out from the mitochondria; only a small part (20-25%) is released directly outside the mitochondria without penetrating the matrix space. 3. In respiring and phosphorylating mitochondria, the value of the Km of the ADP-carrier for external ADP was 2-4 times lower than its value in non-respiring and non-phosphorylating mitochondria. 4. The above experimental data are discussed with reference to the topological and functional relationships between the ADP-carrier and the oxidative phosphorylation complex in the inner mitochondrial membrane. They strongly suggest that the ADP-carrier comes to the close neighbourhood of the ATP synthetase on the matrix side of the inner membrane.     

High content of mitochondrial glycerol-3-phosphate dehydrogenase in pancreatic islets and its inhibition by diazoxide

Homogenates of isolated pancreatic islets contain 40-70 times as much flavin-linked glycerol-3-phosphate dehydrogenase (EC 1.1.99.5) as homogenates of whole pancreas, liver, heart, or skeletal muscle when the activity is assayed with either iodonitrotetrazolium or with dichloroindophenol as an electron acceptor. Intact mitochondria from islets release 3HOH from [2-3H]glycerol phosphate 7 times faster than do skeletal muscle mitochondria. The activity of the cytosolic, NAD-linked, glycerol phosphate dehydrogenase (EC 1.1.1.8) in pancreatic islets is comparable to that of the mitochondrial dehydrogenase so a glycerol phosphate shuttle is possible in pancreatic islets. Diazoxide, an inhibitor of insulin release in vivo and in vitro, inhibits the islet mitochondrial glycerol phosphate dehydrogenase in all three of the assays mentioned above at concentrations that inhibit insulin release and CO2 formation from glucose by isolated pancreatic islets. Diazoxide does not inhibit the dehydrogenase in mitochondria from skeletal muscle, liver, and heart. A slight inhibition in mitochondria from whole pancreas can be accounted for as inhibition of the islet dehydrogenase because no inhibition is observed in mitochondria from pancreas of rats treated with alloxan, an agent that causes diabetes by destroying pancreatic beta cells. The results of this study are compatible with the hypothesis that the mitochondrial glycerol phosphate dehydrogenase has a key role in stimulus-secretion coupling in the pancreatic beta cell during glucose-induced insulin release.     

Exogenous phospholipids specifically affect transmembrane potential of brain mitochondria and cytochrome C release

Release of cytochrome c, a decrease of membrane potential (Deltapsi(m)), and a reduction of cardiolipin (CL) of rat brain mitochondria occurred upon incubation in the absence of respiratory substrates. Since CL is critical for mitochondrial functioning, CL enrichment of mitochondria was achieved by fusion with CL liposomes. Fusion was triggered by potassium phosphate at concentrations producing mitochondrial permeability transition pore opening but not cytochrome c release, which was observed only at >10 mm. Cyclosporin A inhibited phosphate-induced CL fusion, whereas Pronase pretreatment of mitochondria abolished it, suggesting that mitochondrial permeability transition pore and protein(s) are involved in the fusion process. Phosphate-dependent fusion was enhanced in respiratory state 3 and influenced by phospholipid classes in the order CL > phosphatidylglycerol (PG) > phosphatidylserine. The probe 10-nonylacridine orange indicated that fused CL had migrated to the inner mitochondrial membrane. In state 3, CL enrichment of mitochondria resulted in a pH decrease in the intermembrane space. Cytofluorimetric analysis of mitochondria stained with 3,3'-diexyloxacarbocyanine iodide and 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzymidazolylcarbocyanine iodide showed Deltapsi(m) increase upon fusion with CL or PG. In contrast, phosphatidylserine fusion required Deltapsi(m) consumption, suggesting that Deltapsi(m) is the driving force in mitochondrial phospholipid importation. Moreover, enrichment with CL and PG brought the low energy mitochondrial population to high Deltapsi(m) values and prevented phosphate-dependent cytochrome c release.     

The role of inorganic phosphate in the release of Ca2+ from rat-liver mitochondria

The effect of inorganic phosphate on Ca2+ retention has been investigated using phosphate-depleted liver mitchondria. Phosphate induces the release of Ca2+ through an efflux route insensitive to ruthenium red. This effect is not due to functional or structural damage, since mitochondria maintain their membrane potential during phosphate-induced Ca2+ efflux. Direct enzymatic measurement of mitochondria pyridine nucleotides has established that changes in their redox state (i.e. increased oxidation) do not play a role in the phosphate-effect. The phosphate-induced Ca2+ efflux requires transport of phosphate out of mitochondria. However, the fluxes of Ca2+ and phosphate do not coincide: the release of phosphate preceeds that of Ca2+.     

Calcium modulates the ATP and ADP hydrolysis in human placental mitochondria

This study evaluated the effect of Ca2+ on the extramitochondrial hydrolysis of ATP and ADP by the extramitochondrial ATPase in isolated mitochondria and submitochondrial particles (SMPs) from human term placenta. The effect of different oxidizable substrates on the hydrolysis of ATP and ADP in the presence of sucrose or K+ was evaluated. Ca2+ increased phosphate release from ATP and ADP, but this stimulation showed different behavior depending on the oxidizable substrate present in the incubation media. Ca2+ stimulated the hydrolysis of ATP and ADP in the presence of sucrose. However, Ca2+ did not stimulate the hydrolysis of ADP in the medium containing K+. Ca2+ showed inhibition depending on the respiratory substrate. This study suggests that the energetic state of mitochondria controls the extramitochondrial ATPase activity, which is modulated by Ca2+ and respiratory substrates.     

Calcium ion accumulation and volume changes of isolated liver mitochondria. Reversal of calcium ion-induced swelling

1. The excessive accumulation of Ca²⁺ by mitochondria suspended in an iso-osmotic buffered potassium chloride medium containing oxidizable substrate and phosphate led to extensive swelling and release of accumulated Ca²⁺ from the mitochondria. When the Ca²⁺ was removed from the medium by chelation with ethylene glycol bis(aminoethyl)tetra-acetate, the swelling was reversed in a respiration-dependent contraction. The contracted mitochondria were shown to have regained some degree of respiratory control. 2. The respiration-dependent contraction could be supported by electron transport through a restricted portion of the respiratory chain, and by substrates donating electrons at different levels in the respiratory chain. 3. Respiratory inhibitors appropriate to the substrate present completely inhibited the contraction. Uncoupling agents, and the inhibitors oligomycin and atractyloside, were without effect. 4. When the reversal of swelling had been prevented by respiratory inhibitors, the addition of ATP induced a contraction of the mitochondria. In the absence of added chelating agent the contraction was very slow. The ATP-induced contraction was completely inhibited by oligomycin and atractyloside, was incomplete in the presence of uncoupling agents and was unaffected by respiratory inhibitors. 5. The relationship between the energy requirements of respiration-dependent contraction and the requirements of ion transport and other contractile systems are discussed.     

On the state of calcium ions in isolated rat liver mitochondria. II. Effects of phosphate and pH on Ca2+-induced Ca2+ release

At high K+ concentration, the effect of phosphate on Ca2+ uptake and release was studied in isolated rat liver mitochondria. Phosphate stimulated uptake at moderately high Ca2+ concentration, and inhibited release at high pH. At low pH, phosphate accelerated Ca2+ release. Ca2+ was released after a lag phase. The time of onset and the velocity of Ca2+ release depended on Ca2+ concentration. Ca2+ release was associated with mitochondrial swelling and destruction of the permeability barrier for sucrose and for chloride. Mg2+ inhibited Ca2+ release and the accompanying events. Ruthenium red and EGTA protected mitochondria from the destructive Ca2+ release and induced an immediate, slow release of Ca2+ and phosphate. Destructive Ca2+ release depended on the time of preincubation of respiration-inhibited mitochondria in the presence of Ca2+, prior to respiration-initiated Ca2+ uptake. The presence of phosphate and mitochondrial energization antagonized the destructive effect of calcium ions. Ca2+ release by acetoacetate also depended on pH. At pH 6.8, phosphate-stimulated Ca2+ release by acetoacetate, while it inhibited the acetoacetate effect at pH 7.6. The results suggest that an essential cause for the destruction of mitochondrial integrity is an increase in the intramitochondrial concentration of free calcium ions under the influence of phosphate.     

Further studies on the effect of phosphoenolpyruvate on respiration-dependent calcium transport by rat heart mitochondria

Phosphoenolpyruvate was found to depress extra oxygen consumption associated with Ca²⁺-induced respiratory jump by rat heart mitochondria. Addition of phosphoenolpyruvate to mitochondria which have accumulated Ca²⁺ in the presence of glutamate and inorganic phosphate causes the release of Ca²⁺ from mitochondria. The phosphoenolpyruvate-stimulated Ca²⁺ efflux can be observed with mitochondria loaded with low initial Ca²⁺ concentration (0.12 mM) in the incubation medium. Measurements of mitochondrial H⁺ translocation produced by addition of Ca²⁺ to respiring mitochondria show that phosphoenolpyruvate depresses H⁺ ejection and enhances H⁺ uptake by mitochondria. The Ca²⁺-releasing effect of phosphoenolpyruvate was found to be significantly stronger than that produced by rotenone when added to mitochondria loaded with Ca²⁺ in the presence of glutamate and inorganic phosphate. Dithiothreitol cannot overcome the effect of phosphoenolpyruvate on mitochondrial Ca²⁺ transport.     

Release of AMP and adenosine from rat heart mitochondria

Release of AMP and adenosine from rat heart mitochondria was studied. The rate of appearance of extramitochondrial adenosine was independent of the extramitochondrial phosphate concentration between 5 and 20 mM. In the absence of exogenous, respiratory substrates or in the presence of glutamate/malate plus rotenone, the rate of appearance of adenosine was relatively low when phosphate was not added. The appearance of extramitochondrial AMP + adenosine was found to be directly proportional to the extra-mitochondrial phosphate concentration. Zn2+ (10 mM) decreased the rate of adenosine appearance by 90% and increased the rate of AMP appearance 6-fold. The mitochondrial preparations dephosphorylated exogenous AMP; this activity was inhibited by 10 mM Zn2+. We conclude that the adenosine appearing in the extramitochondrial space was not due to a direct release from the matrix, but instead was due to adenine nucleotide release with subsequent conversion to adenosine in the extramitochondrial space.     

Mitochondrial permeability transition in the crustacean Artemia franciscana: absence of a calcium-regulated pore in the face of profound calcium storage

When mammalian mitochondria are exposed to high calcium and phosphate, a massive swelling, uncoupling of respiration, and release of cytochrome c occur. These changes are mediated by opening of the mitochondrial permeability transition pore (MPTP). Activation of the MPTP in vivo in response to hypoxic and oxidative stress leads to necrotic and apoptotic cell death. Considering that embryos of the brine shrimp Artemia franciscana tolerate anoxia for years, we investigated the MPTP in this crustacean to reveal whether pore opening occurs. Minimum molecular constituents of the regulated MPTP in mammals are believed to be the voltage-dependent anion channel, the adenine nucleotide translocators, and cyclophilin D. Western blot analysis revealed that mitochondria from A. franciscana possess all three required components. When measured with a calcium-sensitive fluorescent probe, rat liver mitochondria are shown to release matrix calcium after addition of >/=100 microM extramitochondrial calcium (MPTP opening), whereas brine shrimp mitochondria continue to take up extramitochondrial calcium and do not release internal stores even up to 1.0 mM exogenously added calcium (no MPTP opening). Furthermore, no swelling of A. franciscana mitochondria in response to added calcium was observed, and no release of cytochrome c could be detected. HgCl(2)-dependent swelling and cytochrome c release were readily confirmed, which is consistent with the presence of an "unregulated pore." Although the absence of a regulated MPTP in A. franciscana mitochondria could contribute to the extreme hypoxia tolerance in this species, we speculate that absence of the regulated MPTP may be a general feature of invertebrates.     

Tissue-, substrate-, and site-specific characteristics of mitochondrial reactive oxygen species generation

Reactive oxygen species are a by-product of mitochondrial oxidative phosphorylation, derived from a small quantity of superoxide radicals generated during electron transport. We conducted a comprehensive and quantitative study of oxygen consumption, inner membrane potentials, and H₂O₂ release in mitochondria isolated from rat brain, heart, kidney, liver, and skeletal muscle, using various respiratory substrates (α-ketoglutarate, glutamate, succinate, glycerol phosphate, and palmitoyl carnitine). The locations and properties of reactive oxygen species formation were determined using oxidative phosphorylation and the respiratory chain modulators oligomycin, rotenone, myxothiazol, and antimycin A and the uncoupler CCCP. We found that in mitochondria isolated from most tissues incubated under physiologically relevant conditions, reactive oxygen release accounts for 0.1–0.2% of O₂ consumed. Our findings support an important participation of flavoenzymes and complex III and a substantial role for reverse electron transport to complex I as reactive oxygen species sources. Our results also indicate that succinate is an important substrate for isolated mitochondrial reactive oxygen production in brain, heart, kidney, and skeletal muscle, whereas fatty acids generate significant quantities of oxidants in kidney and liver. Finally, we found that increasing respiratory rates is an effective way to prevent mitochondrial oxidant release under many, but not all, conditions. Altogether, our data uncover and quantify many tissue-, substrate-, and site-specific characteristics of mitochondrial ROS release.     

Phototactic responses of Chlamydomonas reinhardtii in electric fields

Crude mitochondria isolated from Jerusalem artichoke ( Helianthus tuberosus L.) tubers were purified on a 23% (v/v) continuous Percoll gradient. Microbodies and damaged mitochondria banded on top of the gradient, whereas the purified mitochondria handed close to the bottom. The purified mitochondria showed improved membrane integrities, specific enzyme activities and respiratory properties (higher rate, respiratory control, ADP/O ratio) than the crude mitochondria. Purified mitochondria could he stored for 24 h on ice in a phosphate buffer with only small loss of activity.     

The isolation of coupled mitochondria from Physarum polycephalum and their response to Ca2+

A method for the isolation of coupled mitochondria from the acellular slime mould Physarum polycephalum is described. The mitochondria oxidize respiratory substrates at rates comparable to those of mitochondria from other micro-organisms and show similar responses to respiratory inhibitors. ADP/O values approach similar values to those obtained with mitochondria from higher organisms: 3 with NAD-linked substrates, 2 with succinate, and 1 with ascorbate-TMPD.Mitochondria actively take up low concentrations of Ca²⁺ with stimulation of their respiration. With succinate or pyruvate-malate as substrates respiratory responses are depressed by Ca²⁺ concentrations in excess of 200 μM in the presence or absence of phosphate.Exogenous NADH is unique in supporting the uptake of large amounts of Ca²⁺ in the presence of phosphate and in showing an unusual ‘uncoupled’ response in the absence of phosphate.A sigmoidal relationship occurs between initial velocity of Ca²⁺ uptake and Ca²⁺ concentration with a maximum velocity of approx. 15 nmol/s per mg protein and half maximum velocity occurring at approx. 50 μM Ca²⁺.