Uptake of safranine by cardiac mitochondria. Competition with calcium ions and dependence on anions.

Some characteristics of the energized uptake of safranine by rat heart mitochondria were studied. When monitored by changes in differential absorbance (between 524 and 554 nm) of a whole suspension in safranine-containing medium, the changes seen are not linearly related to the quantity of the safranine moving. It happens coincidentally that the changes observed are nearly linearly related to the logarithm of the ratio between the accumulated safranine and its residual concentration in the medium; this explains why the changes of absorbance have been found by other authors to be linearly related to the logarithms of the ratio of internal/external concentrations of such other cations as are permeable. The uptake process appears to compete for energy with Ca2+ uptake and vice versa. Energized safranine uptake has an anion requirement, which is seen when movement of endogenous Pi has been inhibited; the small residual safranine uptake obtained when energy is provided in the presence of mersalyl may be attributable to internal Pi. However, a limited anion-independent energized uptake of safranine, in exchange for internal K+, may be elicited in the presence of nigericin. Adding ATP to the energized system in the presence of an inhibitor of Pi movement elicits an additional uptake of safranine that is oligomycin-sensitive and that probably arises on account of generation of internal Pi by hydrolysis of the entering ATP.     

Species-related difference in calcium accumulation by cardiac mitochondria.

1. Mitochondria isolated from the ventricles of Cavia porcellus, Mesocricetus auratus, Rattus rattus and Mus musculus accumulate calcium in an energy-linked process. 2. Measurements of the initial velocity of accumulation by dual-wavelength spectrophotometry show species-dependent variation, with Cavia demonstrating the fastest rate and Rattus the slowest rate of accumulation. 3. Total amount of calcium accumulated per unit protein varied in a manner similar to rate of accumulation, with Cavia accumulating the greatest amount of calcium and Rattus the least.     

Dihydrolipoic acid activates oligomycin-sensitive thiol groups and increases ATP synthesis in mitochondria.

Investigations with dihydrolipoic acid in rat heart mitochondria and mitoplasts reveal an activation of ATP-synthase up to 45%, whereas ATPase activities decrease by 36%. In parallel with an increase in ATP synthesis oligomycin-sensitive mitochondrial -SH groups are activated at 2-4 nmol dihydrolipoic acid/mg protein. ATPase activation by the uncouplers carbonylcyanide-p-trifluoromethoxyphenylhydrazone and oleate is diminished by dihydrolipoic acid, and ATP synthesis depressed by oleate is partially restored. No such efficiency of dihydrolipoic acid is seen with palmitate-induced ATPase activation or decrease of ATP synthesis. This indicates different interference of oleate and palmitate with mitochondria. In addition to its known coenzymatic properties dihydrolipoic acid may act as a substitute for coenzyme A, thereby diminishing the uncoupling efficiency of oleate. Furthermore, dihydrolipoic acid is a very potent antioxidant, shifting the -SH-S-S- equilibrium in mitochondria to the reduced state and improving the energetic state of cells.     

Nitric oxide and thiol groups.

S-Nitroso(sy)lation reactions have recently been appreciated to regulate protein function and mediate 'nitrosative' stress. S-Nitrosothiols (SNOs) have been identified in a variety of tissues, and represent a novel class of signaling molecules which may act independently of homolytic cleavage to NO - and, indeed, in a stereoselective fashion - or be metabolized to other bioactive nitrogen oxides. It is now appreciated that sulfur-NO interactions have critical physiological relevance to mammalian neurotransmission, ion channel function, intracellular signaling and antimicrobial defense. These reactions are promising targets for the development of new medical therapies.     

Oxidation of NADH by plant mitochondria: Kinetics and effects of calcium ions

The kinetics of NADH oxidation by the outer membrane electron transport system of intact beetroot (Beta vulgaris L.) mitochondria were investigated. Very different values for V_max and the K_m for NADH were obtained when either antimycin A-insensitive NADH-cytochrome c activity (V_max= 31 ± 2.5 nmol cytochrome c (mg protein)^?1 min^?1; K_m= 3.1 ± 0.8 μM) or antimycin A-insensitive NADH-ferricyanide activity (V_max= 1.7 ± 0.7 μmol ferricyanide (mg protein)^?1 min^?1; K_m= 83 ± 20 μM) were measured. As ferricyanide is believed to accept electrons closer to the NADH binding site than cytochrome c, it was concluded that 83 ± 20 μM NADH represented a more accurate estimate of the binding affinity of the outer membrane dehydrogenase for NADH. The low K_m determined with NADH-cytochrome c activity may be due to a limitation in electron flow through the components of the outer membrane electron transport chain. The K_m for NADH of the externally-facing inner membrane NADH dehydrogenase of pea leaf (Pisum sativum L. cv. Massey Gem) mitochondria was 26.7 ± 4.3 μM when oxygen was the electron acceptor. At an NADH concentration at which the inner membrane dehydrogenase should predominate, the Ca²⁺ chelator, ethyleneglycol-(β-aminoethylether)-N,N,-tetraacetic acid (EGTA), inhibited the oxidation of NADH through to oxygen and to the ubiquinone-10 analogues, duroquinone and ubiquinone-1, but had no effect on the antimycin A-insensitive ferricyanide reduction. It is concluded that the site of action of Ca²⁺ involves the interaction of the enzyme with ubiquinone and not with NADH.     

Modification by calcium ions of adenine nucleotide translocation in rat liver mitochondria

1. Added Ca(2+) stimulates the translocation of ATP by isolated rat liver mitochondria. 2. The apparent K(m) for added Ca(2+) in stimulating the translocation of 200mum-ATP is approx. 160mum (75mum ;free' Ca(2+)). 3. The greatest stimulation of ATP translocation by Ca(2+) occurs at the lower concentrations of ATP. 4. Sr(2+) (and to a lesser extent Ba(2+)) can replace Ca(2+) whereas Mg(2+) and Mn(2+) have only little ability to stimulate ATP translocation. 5. Translocation of dATP is also stimulated by Ca(2+) whereas that of ADP is stimulated to only a relatively small degree. 6. Studies with metabolic inhibitors and uncouplers provide evidence that stimulation by Ca(2+) and by uncouplers is additive and that the mechanism of Ca(2+) stimulation does not seem to involve the high-energy intermediate of oxidative phosphorylation. 7. In the presence of Ca(2+), ATP is able to effectively compete with ADP for translocation. 8. Added K(+) further enhances the ability of Ca(2+) to stimulate ATP translocation. 9. These findings are discussed in relation to the potential involvement of Ca(2+) in modifying enzymic reactions involved in the regulation of cell metabolism.     

Interaction between glucocorticoids and glucagon in the hormonal modification of calcium retention by isolated rat liver mitochondria.

1. The administration of dexamethasone to intact fed rats by intraperitoneal injection for 3h was associated with a 6-fold increase in the time for which mitochondria subsequently isolated from the liver retain a given load of exogenous Ca2+. This effect was blocked by the co-administration of cycloheximide with dexamethasone, and partially blocked by the co-administration of puromycin. Daily administration of dexamethasone for periods of 4--7 days resulted in liver mitochondria that exhibited a decreased ability to retain exogenous Ca2+. 2. When glucagon was administered to fed adrenalectomized rats, the increase in mitochondrial Ca2+-retention time that results from the action of this hormone was reduced by 50% when compared with its effect on intact animals. The administration of dexamethasone to adrenalectomized rats partially restored the full effect of glucagon. 3. Dexamethasone did not enhance the effect of glucagon on mitochondrial Ca2+-retention time when administered to intact fed rats. 4. It is concluded that these data support the hypothesis that the hormone-induced modification of liver mitochondria, which results in an increase in the time for which exogenous Ca2+ is retained, involves a step in which new protein is synthesized.     

Protective role of transient pore openings in calcium handling by cardiac mitochondria

Long-lasting mitochondrial permeability transition pore (mPTP) openings damage mitochondria, but transient mPTP openings protect against chronic cardiac stress. To probe the mechanism, we subjected isolated cardiac mitochondria to gradual Ca(2+) loading, which, in the absence of BSA, induced long-lasting mPTP opening, causing matrix depolarization. However, with BSA present to mimic cytoplasmic fatty acid-binding proteins, the mitochondrial population remained polarized and functional, even after matrix Ca(2+) release caused an extramitochondrial free [Ca(2+)] increase to >10 μM, unless mPTP openings were inhibited. These findings could be explained by asynchronous transient mPTP openings allowing individual mitochondria to depolarize long enough to flush accumulated matrix Ca(2+) and then to repolarize rapidly after pore closure. Because subsequent matrix Ca(2+) reuptake via the Ca(2+) uniporter is estimated to be >100-fold slower than matrix Ca(2+) release via mPTP, only a tiny fraction of mitochondria (<1%) are depolarized at any given time. Our results show that transient mPTP openings allow cardiac mitochondria to defend themselves collectively against elevated cytoplasmic Ca(2+) levels as long as respiratory chain activity is able to balance proton influx with proton pumping. We found that transient mPTP openings also stimulated reactive oxygen species production, which may engage reactive oxygen species-dependent cardioprotective signaling.     

Effects of atractyloside and palmitoyl coenzyme A on calcium transport in cardiac mitochondria.

Palmitoyl CoA (PCoA) and the adenine translocase inhibitor atractyloside (ATR) appear to produce a similar effect in discharging accumulated calcium from cardiac mitochondria. Although mitochondrial respiration is stimulated upon addition of either PCoA or ATR to preparations preloaded with calcium, the effect is not the same as that produced by classical uncouplers. PCoA and ATR also do not interfere with respiration-supported calcium uptake by mitochondria. The presence of exogenous ATP can prevent the calcium discharging effects of PCoA or ATR. Carnitine will prevent the PCoA calcium discharging effect, but has no effect on ATR-induced discharge. It is suggested the PCoA may act at a site on or near the adenine translocase, perhaps through allosteric interaction, to produce an efflux of calcium from mitochondria. The results also suggest that the internal adenine nucleotide pool plays a significant role in mitochondrial calcium retention.     

Production of oxygen free radicals by cardiac mitochondria: effect of hypoxia-reoxygenation

The effect of the duration of hypoxia on superoxide radical production in isolated rat heart mitochondria was studied by the spin trapping technique. 4,5-Dioxybenzene was used as a spin trap. Samples were placed into the cavity of an EPR spectrometer in thin-wall gas-permeable capillary tubes, which allowed keeping the suspension of mitochondria in aerobic or hypoxic conditions. Previously we have demonstrated that the rate of superoxide generation by mitochondria isolated from postischemic hearts depends radically on the duration of myocardial ischemia. By contrast, in mitochondria isolated from intact hearts, the effect did not depend on the duration of hypoxia. The rate of superoxide production by isolated mitochondria in the presence of antimycin A (a complex III Q-cycle inhibitor) and complex I or complex II substrates was 0.9 +/- 0.1 nmole O2*- /min/mg protein at 25 degrees C. Under reoxygenation conditions, after 10 min of hypoxia, the rate of superoxide production was considerably higher than before hypoxia. At the same time, after prolonged hypoxia, its value was practically the same as after 10-min hypoxia. The results enable the conclusion that isolated mitochondria are less sensitive to hypoxic conditions than mitochondria in ischemic heart.     

Role of mitochondria in calcium regulation of spontaneously contracting cardiac muscle cells.

Mitochondrial involvement in the regulation of cytosolic calcium concentration ([Ca2+]i) in cardiac myocytes has been largely discounted by many authors. However, recent evidence, including the results of this study, has forced a reappraisal of this role. [Ca2+]i and Ca2+ in the mitochondria ([Ca2+]m) were measured in this study with specific fluorescent probes, fluo-3 and di-hydro-rhod-2, respectively; mitochondrial membrane potential (DeltaPsim) was monitored with JC-1. Addition of uncouplers or inhibitors of the mitochondrial respiratory chain was found to cause a twofold decrease in the rate of removal of Ca2+ from the cytosol after a spontaneously generated Ca2+ wave. These agents also caused a progressive elevation of [Ca2+]i, an increase in the number of hotspots of Ca2+ release (Ca2+ sparks), and depression of mitochondrial potential. The Ca2+-indicative fluorophore dihydro-rhod-2 has a net positive charge that contributes to selective accumulation by mitochondria, as supported by its co-localization with other mitochondrial-specific probes (MitoTracker Green). Treatment of dihydro-rhod-2-loaded cells with NaCN resulted in rapid formation of "black holes" in the otherwise uniformly banded pattern. These are likely to represent individual or small groups of mitochondria that have depressed mitochondrial potential, or have lost accumulated rhod-2 and/or Ca2+; all of these eventualities are possible upon onset of the mitochondrial permeability transition. Release of Ca2+ from the sarcoplasmic reticulum and the resultant spontaneous contractility of cardiac muscle are proposed to be triggered by the induction of the mitochondrial permeability transition and the subsequent loss of [Ca2+]m.