Inhibition by dithioerythritol of alloxan induced efflux of Ca2+ and accompanying alterations in isolated liver mitochondria

Isolated mouse liver mitochondria respiring on succinate released Ca2+ when incubated with alloxan, accompanied by decreased membrane potential, stimulated state 4 respiration and swelling. All these effects of alloxan were inhibited by equimolar or higher concentrations of dithioerythritol (DTE), and in presence of added ATP a carboxyatractyloside-sensitive reuptake of Ca2+ was observed. The process of release and uptake of Ca2+ could be repeated by additional administrations of higher concentrations of alloxan and DTE plus ATP, respectively. The data suggest that the mitochondrial action of alloxan involves oxidation of membrane thiol groups.     

Modulation of Ca2+ efflux and rebounding Ca2+ transport in rat liver mitochondria

The independent pathway for Ca2+ efflux of rat liver mitochondria exhibits a sharp temperature and pH dependence. The Arrhenius plot displays a break at 18 degrees C, activation energy being about 117 kJ/mol below 18 degrees C and 59 kJ/mol above 18 degrees C. The pH profile is bell-shaped, with a broad optimum at pH 7.0. These properties of the efflux pathway, together with the membrane potential modulation recently described (Bernardi, P. and Azzone, G.F. (1983) Eur. J. Biochem. 134, 377-383), suggest an explanation for the phenomenon of rebounding Ca2+ transport. Addition of a Ca2+ pulse to respiring mitochondria causes (i) a phase of rapid Ca2+ uptake, leading to a decrease of extramitochondrial free Ca2+ to a lower level with respect to that maintained before Ca2+ addition, and (ii) a slower phase of net Ca2+ efflux, leading to restoration of the steady-state extramitochondrial free Ca2+ preceeding Ca2+ addition. Evidence is provided that the excess Ca2+ uptake is linked to transient inactivation of the efflux pathway due to membrane depolarization. Conversely, the efflux phase is linked to reactivation of the efflux pathway upon repolarization. The efflux component of the rebound cycle and the isolated efflux pathway exhibit similar dependence on temperature, pH and membrane potential.     

Pathways for Ca2+ efflux in heart and liver mitochondria.

1. Two processes of Ruthenium Red-insensitive Ca2+ efflux exist in liver and in heart mitochondria: one Na+-independent, and another Na+-dependent. The processes attain maximal rates of 1.4 and 3.0 nmol of Ca2+.min-1.mg-1 for the Na+-dependent and 1.2 and 2.0 nmol of Ca2+.min-1.mg-1 for the Na+-independent, in liver and heart mitochondria, respectively. 2. The Na+-dependent pathway is inhibited, both in heart and in liver mitochondria, by the Ca2+ antagonist diltiazem with a Ki of 4 microM. The Na+-independent pathway is inhibited by diltiazem with a Ki of 250 microM in liver mitochondria, while it behaves as almost insensitive to diltiazem in heart mitochondria. 3. Stretching of the mitochondrial inner membrane in hypo-osmotic media results in activation of the Na+-independent pathway both in liver and in heart mitochondria. 4. Both in heart and liver mitochondria the Na+-independent pathway is insensitive to variations of medium pH around physiological values, while the Na+-dependent pathway is markedly stimulated parallel with acidification of the medium. The pH-activated, Na+-dependent pathway maintains the diltiazem sensitivity. 5. In heart mitochondria, the Na+-dependent pathway is non-competitively inhibited by Mg2+ with a Ki of 0.27 mM, while the Na+-independent pathway is less affected; similarly, in liver mitochondria Mg2+ inhibits the Na+-dependent pathway more than it does the Na+-independent pathway. In the presence of physiological concentrations of Na+, Ca2+ and Mg2+, the Na+-independent and the Na+-dependent pathways operate at rates, respectively, of 0.5 and 1.0 nmol of Ca2+.min-1.mg-1 in heart mitochondria and 0.9 and 0.2 nmol of Ca2+.min-1.mg-1 in liver mitochondria. It is concluded that both heart and liver mitochondria possess two independent pathways for Ca2+ efflux operating at comparable rates.     

Inhibition of Na+-dependent Ca2+ efflux from heart mitochondria by amiloride analogues

The Na+-induced release of accumulated Ca2+ from heart mitochondria is inhibited by amiloride, benzamil and several other amiloride analogues. These drugs do not affect uptake or release of Ca2+ mediated by the ruthenium red-sensitive uniporter and their effects, like those of diltiazem and other Ca2+-antagonists, appear to be localized principally at the Na+/Ca2+ antiporter of the mitochondrion. Benzamil inhibits Na+/Ca2+ antiport non-competitively with respect to [Na+] with a Ki of 167 microM. In the presence of 1.5 mM Pi the Ki for benzamil inhibition of this reaction is decreased to 87 microM.     

Age-dependent increase in hydrogen peroxide production by cardiac monoamine oxidase A in rats

Oxidative stress is one of the factors involved in age-related impairment of cardiac function. In the present study, we investigated the role of the catecholamine-degrading enzyme monoamine oxidase (MAO) in H(2)O(2) production in the hearts of young, adult, and old rats. MAO-dependent H(2)O(2) production, measured by a chemiluminescence-based assay, increased with age, reaching the maximum in 24-mo-old rats (7.5-fold increase vs. 1-mo-old rats). The following observations indicate that the age-dependent increase in H(2)O(2) generation was fully related to the MAO-A isoform: 1) at all the ages tested, chemiluminescence production was inhibited by the MAO-A inhibitor clorgyline but not by the MAO-B inhibitor RO-19 6327; 2) enzyme assay, Western blot, and semiquantitative RT-PCR analysis showed an age-dependent increase in cardiac MAO-A activity, immunodetection, and mRNA expression, respectively; and 3) the MAO-B isoform was undetectable by enzyme assay and Western blot analysis. These results suggest that MAO-A could be a major source of H(2)O(2) in the aging heart.     

Hydrogen peroxide depolarizes mitochondria and inhibits IP3-evoked Ca2+ release in the endothelium of intact arteries

Hydrogen peroxide (H₂O₂) is a mitochondrial-derived reactive oxygen species (ROS) that regulates vascular signalling transduction, vasocontraction and vasodilation. Although the physiological role of ROS in endothelial cells is acknowledged, the mechanisms underlying H₂O₂ regulation of signalling in native, fully-differentiated endothelial cells is unresolved. In the present study, the effects of H₂O₂ on Ca²⁺ signalling were investigated in the endothelium of intact rat mesenteric arteries. Spontaneous local Ca²⁺ signals and acetylcholine evoked Ca²⁺ increases were inhibited by H₂O₂. H₂O₂ inhibition of acetylcholine-evoked Ca²⁺ signals was reversed by catalase. H₂O₂ exerts its inhibition on the IP₃ receptor as Ca²⁺ release evoked by photolysis of caged IP₃ was supressed by H₂O₂. H₂O₂ suppression of IP₃-evoked Ca²⁺ signalling may be mediated by mitochondria. H₂O₂ depolarized mitochondria membrane potential. Acetylcholine-evoked Ca²⁺ release was inhibited by depolarisation of the mitochondrial membrane potential by the uncoupler carbonyl cyanide 3-chlorophenylhydrazone (CCCP) or complex 1 inhibitor, rotenone. We propose that the suppression of IP₃-evoked Ca²⁺ release by H₂O₂ arises from the decrease in mitochondrial membrane potential. These results suggest that mitochondria may protect themselves against Ca²⁺ overload during IP₃-linked Ca²⁺ signals by a H₂O₂ mediated negative feedback depolarization of the organelle and inhibition of IP₃-evoked Ca²⁺ release.     

The role of glutathione in the retention of Ca2+ by liver mitochondria

Concentrations of rhein and nitrofurantoin in the micromolar range induce Ca2+ release and the development of increased inner membrane permeability in liver mitochondria. Both compounds inhibit the mitochondrial glutathione reductase causing a depletion of GSH and an accumulation of GSSG in energized mitochondria. Under these conditions, the compounds also alter the oxidation state of pyridine nucleotides, NADH becoming oxidized while NADPH remains reduced. Using rhein or nitrofurantoin, together with t-butyl-hydroperoxide and beta-hydroxybutyrate, it is possible to selectively alter the NAD/NADH, the NADP/NADPH, and the GSSG/GSH ratios and to determine the effect of these different states on the ability of Ca2+ to produce a permeable inner membrane. No correlation between pyridine nucleotide ratios and sensitivity to Ca2+ was observed. Mitochondria are stable to Ca2+ when the GSH content is high, but become permeable when Ca2+ is present and GSH is converted to GSSG. It is proposed that the GSSG/GSH ratio, by controlling the reduction state of critical sulfhydryl groups, regulates lysophospholipid acyltransferase activity and, therefore, the ability of mitochondria to remain impermeable upon activation of the intramitochondrial Ca2+ requiring phospholipase A2.     

The effect of ferric iron complex on Ca2+ transport in isolated rat liver mitochondria

The in vitro effects of iron (III)-gluconate complex on the production of malondialdehyde and on the Ca2+ transport in isolated rat liver mitochondria were studied. A correlation between the concentration of iron added and the formation of malondialdehyde was found. The enhancement by iron of lipid peroxidative process in the mitochondrial membrane brought about the induction of Ca2+ release from mitochondria. Experimental evidence based on the membrane potential pattern of mitochondria pre-loaded with a low pulse of Ca2+ suggested that Ca2+ efflux was not due to a nonspecific increase in the inner membrane permeability, i.e. to a collapse of membrane potential, but rather to the activation of an apparently selective pathway for Ca2+ release.     

Changes in monoamine oxidase activity by mitochondria isolated from late embryos of Bufo bufo

1. Monoamine oxidase activity has been assayed in mitochondria isolated from post-neural embryos (stages 14-25) of Bufo bufo, using 5-HT and PEA as substrates. 2. Mitochondria isolated from stages 19 to 25 show an increasing ability in deaminating monoamines, PEA being metabolized at a higher level with respect to 5-HT. 3. At all the examined stages 5-HT is metabolized by an enzyme corresponding to MAO A, while PEA, from stage 19, is largely deaminated by a semicarbazide-sensitive amine oxidase (SSAO). 4. The effect of Triton X-100 on MAO A activity appears remarkably different in mitochondria isolated from embryos at stages 14 and 25 respectively.     

Parallel efflux of Ca2+ and Pi in energized rat liver mitochondria.

Addition of Ruthenium Red to energized rat liver mitochondria that have previously accumulated Ca2+ and phosphate from the external medium induces a parallel efflux of both these ions. Mersalyl or dithioerythritol, which decrease Ruthenium Red-insensitive Ca2+ efflux, also decrease phosphate efflux to the same extent. Conversely diazenedicarboxylic acid bis(NN-dimethylamide) (DDBA), which increases the Ruthenium Red-induced Ca2+ efflux concurrently increases phosphate release. Dithioerythritol and DDBA, reducing and oxidizing agents of thiol groups respectively, modify Ca2+ and Pi efflux without penetrating the mitochondrial inner membrane. Under all the adopted conditions the membrane potential is preserved. The release of resting respiration and the parallel efflux of Mg2+ and adenine nucleotides, events closely correlated to Ca2+ cycling, are equally prevented either by mersalyl, which inhibits phosphate transport, or dithioerythritol; DDBA has the opposite effect. These findings and the observation that suggest that Ca2+ and phosphate transport in energized liver mitochondria are closely related and dependent on the redox state of membrane-bound thiol groups.     

Hydrogen peroxide constricts rat arteries by activating Na+-permeable and Ca2+-permeable cation channels

Oxidative stress is associated with many cardiovascular diseases, such as hypertension and arteriosclerosis. Oxidative stress reportedly activates the L-type voltage-gated calcium channel (VDCC_L) and elevates [Ca²⁺]_i in many cells. However, how oxidative stress activates VDCC_L under clinical setting and the consequence for arteries are unclear. Here, we examined the hypothesis that hydrogen peroxide (H₂O₂) regulates membrane potential (Em) by altering Na⁺ influx through cation channels, which consequently activates VDCC_L to induce vasoconstriction in rat mesenteric arteries. To measure the tone of the endothelium-denuded arteries, a conventional isometric organ chamber was used. Membrane currents and Em were recorded by the patch-clamp technique. [Ca²⁺]_i and [Na⁺]_i were measured with microfluorometry using Fura2-AM and SBFI-AM, respectively. We found that H₂O₂ (10 and 100 µM) increased arterial contraction, and nifedipine blocked the effects of H₂O₂ on isometric contraction. H₂O₂ increased [Ca²⁺]_i as well as [Na⁺]_i, and depolarised Em. Gd³⁺ (1 µM) blocked all these H₂O₂-induced effects including Em depolarisation and increases in [Ca²⁺]_i and [Na⁺]_i. Although both nifedipine (30?nM) and low Na⁺ bath solution completely prevented the H₂O₂-induced increase in [Na⁺], they only partly inhibited the H₂O₂-induced effects on [Ca²⁺]_i and Em. Taken together, the results suggested that H₂O₂ constricts rat arteries by causing Em depolarisation and VDCC_L activation through activating Gd³⁺-and nifedipine-sensitive, Na⁺-permeable channels as well as Gd³⁺-sensitive Ca²⁺-permeable cation channels. We suggest that unidentified Na⁺-permeable cation channels as well as Ca²⁺-permeable cation channels may function as important mediators for oxidative stress-induced vascular dysfunction.     

Hydrogen peroxide production by roots and its stimulation by exogenous NADH

H₂O₂ production by roots of young seedlings was monitored using a non-destructive in vivo assay at pH 5.0. A particularly high rate of H₂O₂ production was measured in the roots of soybean (Glycine max L. cv. Labrador) seedlings which were used for further investigation of the physiological and enzymological properties of apoplastic H₂O₂ production. In the soybean root H₂O₂ production can be stimulated 10-fold by exogenous NADH or NADPH. This response displays typical features of a peroxidase-catalyzed oxidase reaction using NAD(P)H as electron donor for the reduction of O₂ to H₂O₂. Comparative measurements showed that the NADH-induced H₂O₂ production of the roots resembles the H₂O₂-forming activity of horseradish peroxidase with respect to NADH and O₂ concentration requirements and sensitivity to inhibition by KCN, NaN₃, superoxide dismutase and catalase. NADH-induced H₂O₂ production can be observed with similar intensity in all regions of the root, in agreement with the distribution of apoplastic peroxidase activity. In contrast, the activity responsible for the basal H₂O₂ production in the absence of exogenous NADH was mainly confined to a short subapical zone of the root and differs from the NADH-induced reaction by insensitivity to inhibition by superoxide dismutase and a strikingly lower requirement for O₂. It is concluded that the basal H₂O₂ production of the root is mediated by an enzyme different from peroxidase, possibly a plasma membrane O₂^?-producing oxidase.     

Effect of ruthenium red on the Ca2+ and Sr2+ efflux from rat liver mitochondria: Influence of nupercaine

The rate of ruthenium-red-induced Ca²⁺ efflux depends on the time that the calcium interacts with the mitochondria prior to the addition of the inhibitor. This time-dependency is abolished in the presence of nupercaine; it does not occur in the case of Sr²⁺ efflux from mitochondria in which the endogenous Ca²⁺ has been substituted by strontium (strontium-treated mitochondria, STM). Ruthenium red inhibits the respiratory-inhibitor- or uncoupler-induced Sr²⁺ efflux from STM, but not the Ca²⁺ efilux from standard mitochondria. The influence of the calcium-induced mitochondrial damage upon the effect of ruthenium red is discussed.     

Regulation of Ca2+ efflux from kidney and liver mitochondria by unsaturated fatty acids and Na+ ions.

The effects of fatty acids and monovalent cations on the Ca2+ efflux from isolated liver and kidney mitochondria were investigated by means of electrode techniques. It was shown that unsaturated fatty acids and saturated fatty acids of medium chain length (C12 and C14) induced a Ca2+ efflux from mitochondria which was not inhibited by ruthenium red, but was specifically inhibited by Na+ and Li+. The Ca2+-releasing activity of unsaturated fatty acids did not correlate with their uncoupling activity. In kidney mitochondria a spontaneous, temperature-dependent Ca2+ efflux was observed which was inhibited either by albumin or by Na+. It is suggested that the net Ca2+ accumulation by mitochondria depends on the operation of independent pump and leak pathways. The pump is driven by the membrane potential and can be inhibited by ruthenium red, the leak depends on the presence of unsaturated fatty acids and is inhibited by Na+ and Li+. It is suggested that the unsaturated fatty acids produced by mitochondrial phospholipase A2 can be essential in the regulation of the Ca2+ retention in and the Ca2+ release from the mitochondria.     

Regulation of Ca2+ fluxes in rat liver mitochondria by Ca2+. Effects on Ca2+ distribution

Rat liver mitochondria are able to temporarily lower the steady-state concentration of external Ca²⁺ after having accumulated a pulse of added Ca²⁺. This has been attributed to inhibition of a putative -modulated efflux pathway [Bernardi, P. (1984)Biochim. Biophys. Acta 766, 277–282]. On the other hand, the rebounding could be due to stimulation of the uniporter by Ca²⁺ [Kröner, H. (1987)Biol. Chem. Hoppe-Seyler 369, 149–155]. By measuring unidirectional Ca²⁺ fluxes, it was found that the uniporter was stimulated during the rebounding peak both under Bernardi's and Kröner's conditions, while no effects on the efflux could be demonstrated. The rate of unidirectional efflux of Ca²⁺ was not affected by inhibition of the uniporter. It appears likely that the rebounding is due to stimulation of the uniporter rather than inhibition of efflux.     

Ca2+ releasing effect of perezone on adrenal cortex mitochondria

Ca2+ energy-coupled transport was analized in adrenal cortex mitochondria using the sesquiterpenic drug perezone. Perezone promotes Ca2+ efflux by inducing collapse of the membrane potential and oxidation of pyridine nucleotides. The effect of perezone on mitochondrial Ca2+ release follows a dose-response relationship and is dependent of the reduction of the drug. These data suggest that perezone may produce a cytotoxic effect through an impairment in Ca2+ homeostasis.     

Regulation of Ca2+ efflux in rat liver mitochondria. Role of membrane potential

The paper analyzes the relationship between membrane potential (delta psi), steady state pCao (-log [Ca2+] in the outer aqueous phase) and rate of ruthenium-red-induced Ca2+ efflux in liver mitochondria. Energized liver mitochondria maintain a pCao of about 6.0 in the presence of 1.5 mM Mg2+ and 0.5 mM Pi. A slight depression of delta psi results in net Ca2+ uptake leading to an increased steady state pCao. On the other hand, a more marked depression of delta psi results in net Ca2+ efflux, leading to a decreased steady-state pCao. These results reflect a biphasic relationship between delta psi and pCao, in that pCao increases with the increase of delta psi up to a value of about 130 mV, whereas a further increase of delta psi above 130 mV results in a decrease of pCao. The phenomenon of Ca2+ uptake following a depression of delta psi is independent of the tool used to affect delta psi whether by inward K+ current via valinomycin, or by inward H+ current through protonophores or through F1-ATP synthase, or by restriction of e- flow. The pathway for Ca2+ efflux is considerably activated by stretching of the inner membrane in hypotonic media. This activation is accompanied by a decreased pCao at steady state and by an increased rate of ruthenium-red-induced Ca2+ efflux. By restricting the rate of e- flow in hypotonically treated mitochondria, a marked dependence of the rate of ruthenium-red-induced Ca2+ efflux on the value of delta psi is observed, in that the rate of Ca2+ efflux increases with the value of delta psi. The pCao is linearly related to the rate of Ca2+ efflux. Activation of oxidative phosphorylation via addition of hexokinase + glucose to ATP-supplemented mitochondria, is followed by a phase of Ca2+ uptake, which is reversed by atractyloside. These findings support the view that Ca2+ efflux in steady state mitochondria occurs through an independent, delta psi-controlled pathway and that changes of delta psi during oxidative phosphorylation can effectively modulate mitochondrial Ca2+ distribution by inhibiting or activating the delta psi-controlled Ca2+ efflux pathway.