Inhibitory Properties of Ruthenium Amine Complexes on Mitochondrial Calcium Uptake

The recent finding that the inhibition of Ca²⁺-stimulated respiration by ruthenium red is mainlydue to a binuclear ruthenium complex (Ru₃₆₀) present in the commercial samples of the classicalinhibitor ruthenium red (Ying et. al., 1991), showed that this complex is the more potent andspecific inhibitor of the mitochondrial calcium uniporter. This work was aimed to provideinsights into the mechanism by which Ru₃₆₀ and other ruthenium-related compounds inhibitscalcium uptake. Ruthenium red and a synthesized analog (Rrphen) were compared with Ru₃₆₀.The inhibition by this binuclear complex was noncompetitive, with a K _i of 9.89 nM. Thenumber of specific binding sites for Ru₃₆₀ was 6.2 pmol/mg protein. Ruthenium red and Ru₃₆₀were mutually exclusive inhibitors. Bound La³⁺ was not displaced by Ru₃₆₀. Rrphen was theleast effective for inhibiting calcium uptake. The results support the notion of a specific bindingsite in the uniporter for the polycationic complexes and a negative charged region from thephospholipids in the membrane, closely associated with the uniporter inhibitor-binding site.     

Identification of a 20-kDa protein with calcium uptake transport activity. Reconstitution in a membrane model

This paper presents results of experiments designed to further purify the membrane system involved in mitochondrial calcium transport. A partially purified extract, which transported calcium with a specific activity of 1194 nmol⁴⁵Ca²⁺/mg protein/5 min, was used to obtain mouse hyperimmune serum. This serum inhibited calcium uptake both in mitoplasts and in vesicles reconstituted with mitochondrial proteins containing cytochrome oxidase. Western blot analysis of the semipurified fraction showed that the serum recognized specifically two antigens of 75 and 20 kDa. Both antibodies were purified by elution from the nitrocellulose sheets and their inhibition capacity was analyzed. The antibody that recognized the 20-kDa protein produced a higher degree of inhibition than the other one.     

Polyamines Stimulate Mitochondrial Calcium Transport in Rat Brain

The effects of the polyamines spermine and spermidine on rat brain mitochondrial calcium transport were examined using a variety of techniques for measuring the kinetics of calcium uptake and the buffering capabilities of isolated mitochondria. Spermine both increased the rate of calcium accumulation and decreased the set-point to which isolated mitochondria buffer free calcium concentration. In the presence of physiological concentrations of sodium and magnesium, spermine lowered the extramitochondrial calcium level to approximately 0.3 microM, a value close to the resting intracellular calcium concentration. The effect of polyamines was concentration dependent, with a half-maximal effect of spermine observed at approximately 0.1-0.4 mM (respiratory substrate dependent), whereas spermidine was approximately 10 times less potent. Calcium transport by hippocampal mitochondria was stimulated markedly more by spermine than was calcium transport by mitochondria isolated from brainstem. The stimulatory effect of spermine was not due to an increase in the transport of respiratory substrates inside the mitochondria nor to an effect on the enzymes using these respiratory substrates. An examination of the effect of spermine on the kinetics of calcium uptake indicated that spermine increased calcium uptake maximally at low calcium concentrations. Beyond that level, the stimulatory effect of spermine decreases, and spermine can even inhibit calcium uptake. These results are in good agreement with previous reports on the effects of polyamines on calcium transport in mitochondria from peripheral tissue. They support the hypothesis that spermine increases the rate of calcium uptake by mitochondria by increasing the affinity of the uniporter for calcium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of Protein Synthesis and Amino Acid Transport by Crystal Violet in Trypanosoma cruzi

ABSTRACT. [³⁵S]methionine incorporation into proteins of either T. cruzi epimastigotes or trypomastigotes was drastically inhibited by low concentrations of crystal violet in a dose-dependent manner. This inhibition was not due to ATP depletion since cellular ATP levels did not change significantly after incubation of epimastigotes with 50 μM crystal violet for similar periods of time, and was unaffected by changes in the extracellular free calcium concentration. Although crystal violet was able to inhibit protein synthesis in a cell-free system from T. cruzi epimastigotes, half maximal inhibition was at 1 mM, a concentration three orders of magnitude higher than those that inhibited protein synthesis in intact cells. On the other hand, crystal violet was able to inhibit total [³⁵S]methionine uptake at similar concentrations to those that inhibited protein synthesis while addition of increasing concentrations of cold methionine to the incubation medium protected the cells against crystal violet inhibition. Crystal violet also inhibited total [³H]proline uptake thus indicating that it has a general inhibitory effect upon the transport of amino acids, and not specifically upon methionine. These results indicate that inhibition of protein synthesis by crystal violet is probably due to inhibition of amino acid uptake.     

Inhibition of the mitochondrial calcium uniporter by antibodies against a 40-kDa glycorproteinT

Polyclonal rabbit antibodies against a Ca²⁺-binding mitochondrial glycoprotein were found to inhibit the uniporter-mediated transport of Ca²⁺ in mitoplasts prepared from rat liver mitochondria. Spermine, a modulator of the uniporter, decreased the inhibition. This glycoprotein ofM _r 40,000, isolated from beef heart mitochondria and earlier shown to form Ca²⁺-conducting channels in black-lipid membranes, thus is a good candidate for being a component of the uniporter. Antibody-IgG was found to specifically bind to mitochondria in human fibroblasts.     

The Integration of Mitochondrial Calcium Transport and Storage

The extraordinary capacity of isolated mitochondria to accumulate Ca(2+) has been established for more than 40 years. The distinct kinetics of the independent uptake and efflux pathways accounts for the dual functionality of the transport process to either modulate matrix free Ca(2+) concentrations or to act as temporary stores of large amounts of Ca(2+) in the presence of phosphate. One puzzle has been the nature of the matrix calcium phosphate complex, since matrix free Ca(2+) seems to be buffered in the region of 1-5 microM in the presence of phosphate while millimolar Ca(2+) remains soluble in in vitro media. The key seems to be the elevated matrix pH and the third-power relationship of the PO(4)(3-) concentration with pH. Taking this into account we may now finally have a model that explains the major features of physiological mitochondrial Ca(2+) transport.     

Essential Role of Mitochondrial Ca2+ Uniporter in the Generation of Mitochondrial pH Gradient and Metabolism-Secretion Coupling in Insulin-releasing Cells

In pancreatic β-cells, ATP acts as a signaling molecule initiating plasma membrane electrical activity linked to Ca²⁺ influx, which triggers insulin exocytosis. The mitochondrial Ca²⁺ uniporter (MCU) mediates Ca²⁺ uptake into the organelle, where energy metabolism is further stimulated for sustained second phase insulin secretion. Here, we have studied the contribution of the MCU to the regulation of oxidative phosphorylation and metabolism-secretion coupling in intact and permeabilized clonal β-cells as well as rat pancreatic islets. Knockdown of MCU with siRNA transfection blunted matrix Ca²⁺ rises, decreased nutrient-stimulated ATP production as well as insulin secretion. Furthermore, MCU knockdown lowered the expression of respiratory chain complexes, mitochondrial metabolic activity, and oxygen consumption. The pH gradient formed across the inner mitochondrial membrane following nutrient stimulation was markedly lowered in MCU-silenced cells. In contrast, nutrient-induced hyperpolarization of the electrical gradient was not altered. In permeabilized cells, knockdown of MCU ablated matrix acidification in response to extramitochondrial Ca²⁺. Suppression of the putative Ca²⁺/H⁺ antiporter leucine zipper-EF hand-containing transmembrane protein 1 (LETM1) also abolished Ca²⁺-induced matrix acidification. These results demonstrate that MCU-mediated Ca²⁺ uptake is essential to establish a nutrient-induced mitochondrial pH gradient which is critical for sustained ATP synthesis and metabolism-secretion coupling in insulin-releasing cells.     

Mitochondrial Calcium Transport and Mitochondrial Dysfunction After Global Brain Ischemia in Rat Hippocampus

Here we report effect of ischemia-reperfusion on mitochondrial Ca²⁺ uptake and activity of complexes I and IV in rat hippocampus. By performing 4-vessel occlusion model of global brain ischemia, we observed that 15 min ischemia led to significant decrease of mitochondrial capacity to accumulate Ca²⁺ to 80.8% of control whereas rate of Ca²⁺ uptake was not significantly changed. Reperfusion did not significantly change mitochondrial Ca²⁺ transport. Ischemia induced progressive inhibition of complex I, affecting final electron transfer to decylubiquinone. Minimal activity of complex I was observed 24 h after ischemia (63% of control). Inhibition of complex IV activity to 80.6% of control was observed 1 h after ischemia. To explain the discrepancy between impact of ischemia on rate of Ca²⁺ uptake and activities of both complexes, we performed titration experiments to study relationship between inhibition of particular complex and generation of mitochondrial transmembrane potential (ΔΨ_m). Generation of a threshold curves showed that complex I and IV activities must be decreased by approximately 40, and 60%, respectively, before significant decline in ΔΨ_m was documented. Thus, mitochondrial Ca²⁺ uptake was not significantly affected by ischemia-reperfusion, apparently due to excess capacity of the complexes I and IV. Inhibition of complex I is favourable of reactive oxygen species (ROS) generation. Maximal oxidative modification of membrane proteins was documented 1 h after ischemia. Although enhanced formation of ROS might contribute to neuronal injury, depressed activities of complex I and IV together with unaltered rate of Ca²⁺ uptake are conditions favourable of initiation of other cell degenerative pathways like opening of mitochondrial permeability transition pore or apoptosis initiation, and might represent important mechanism of ischemic damage to neurones.     

Mitochondrial Calcium Transport Systems: Properties, Regulation, and Taxonomic Features

Currently available information on properties and regulation of mitochondrial Ca2+ transporting systems in eukaryotic cells is summarized. We describe in detail kinetic properties and effects of inhibitors and modulators on the energy-dependent Ca2+ uptake through the Ca2+ uniporter, as well as on Na+-dependent and Na+-independent pathways for Ca2+ release in mammalian mitochondria. Special emphasis is placed on Ca2+ transport systems (for ion uptake and release) in mitochondria of higher plants, algae, and yeasts. Potential physiological implications of mitochondrial Ca2+ fluxes (influx and efflux), e.g., regulation of activity of Ca2+-dependent enzymes of the Krebs cycle, maintaining of cellular Ca2+ homeostasis, and engagement in pathophysiological processes, are discussed.     

Advances in the Purification of the Mitochondrial Ca2+ Uniporter Using the Labeled Inhibitor 103Ru360

For many years the calcium uniporter has eluded attempts of purification, partly because of the difficulties inherent in the purification of low-abundance hydrophobic proteins (Reed and Bygrave, 1974). Liquid-phase preparative isoelectric focusing improved the fractionation of mitochondrial membrane proteins. A single 6-h run resulted in a 90-fold increase in specific activity of pooled active fractions over a semipurified fraction, allowing for enrichment of the calcium transport function in cytochrome oxidase vesicles. An additional powerful tool in the isolation of the uniporter was the use of the labeled inhibitor ¹⁰³Ru₃₆₀ as an affinity ligand; by following this procedure a protein of 18 kDa was purified in nondenatured, but rather inactive, form. The labeled protein corresponds to the protein that showed Ca²⁺ transport activity.     

Mitochondrial glycosidic residues contribute to the interaction between ruthenium amine complexes and the calcium uniporter

The role of glycosidic residues in the inhibitory properties of ruthenium complexes on mitochondrial calcium uptake was determined in mitoplasts.Our results showed that the binding and inhibitory properties of ruthenium amine complexes were modified when mitoplasts were exposed to N-glycosidase F action, but calcium uptake was not altered. N-linked proteins of the mitochondrial inner membrane were identified. We detected an 18-kDa protein that binds labeled Ru₃₆₀ under control conditions, but failed to bind the inhibitor after deglycosilation. A relationship between this protein and the action of ruthenium amine inhibitors of the mitochondrial uniporter is proposed.     

A Biophysically Based Mathematical Model for the Kinetics of Mitochondrial Calcium Uniporter

Ca²⁺ transport through mitochondrial Ca²⁺ uniporter is the primary Ca²⁺ uptake mechanism in respiring mitochondria. Thus, the uniporter plays a key role in regulating mitochondrial Ca²⁺. Despite the importance of mitochondrial Ca²⁺ to metabolic regulation and mitochondrial function, and to cell physiology and pathophysiology, the structure and composition of the uniporter functional unit and kinetic mechanisms associated with Ca²⁺ transport into mitochondria are still not well understood. In this study, based on available experimental data on the kinetics of Ca²⁺ transport via the uniporter, a mechanistic kinetic model of the uniporter is introduced. The model is thermodynamically balanced and satisfactorily describes a large number of independent data sets in the literature on initial or pseudo-steady-state influx rates of Ca²⁺ via the uniporter measured under a wide range of experimental conditions. The model is derived assuming a multi-state catalytic binding and Eyring's free-energy barrier theory-based transformation mechanisms associated with the carrier-mediated facilitated transport and electrodiffusion. The model is a great improvement over the previous theoretical models of mitochondrial Ca²⁺ uniporter in the literature in that it is thermodynamically balanced and matches a large number of independently published data sets on mitochondrial Ca²⁺ uptake. This theoretical model will be critical in developing mechanistic, integrated models of mitochondrial Ca²⁺ handling and bioenergetics which can be helpful in understanding the mechanisms by which Ca²⁺ plays a role in mediating signaling pathways and modulating mitochondrial energy metabolism.     

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.     

Growth Phase and the Number of Phosphorylation Sites in the Mitochondrial Electron Transport Chain of Acanthamoeba castellanii

SYNOPSIS. Mitochondria isolated from the soil ameba Acanthamoeba castellanii growing exponentially on complex medium have rotenone-insensitive oxygen uptake and ADP:O ratios which indicate the presence of only 2 phosphorylation sites in the electron transport chain. Stationary phase amebae yield mitochondria which are sensitive to inhibition by rotenone when respiring NAD⁺-Minked substrates and have 3 sites of phosphorylation. The levels of cytochromes (a + a ₃), b , and c are similar in mitochondria isolated from log or stationary phase amebae, and, with the exception of succinate, the respiratory rates obtained with different substrates do not change significantly from log to stationary growth phase.     

Dimerization of MICU Proteins Controls Ca2+ Influx through the Mitochondrial Ca2+ Uniporter

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Irreversible Inhibition of Calcium Uptake in Synaptosomes by Quinacrine Mustard: Relationship to Labeling Sites of Quinacrine Mustard

The sites of interaction of quinacrine with synaptic membranes were labeled with quinacrine mustard. Quinacrine mustard had an inhibitory effect on depolarization-induced calcium uptake by synaptosomes similar to that of quinacrine. The inhibition of depolarization-induced calcium uptake by quinacrine was reduced by 70% after washing, whereas that by quinacrine mustard was not affected. Fluorescence electrophoretograms of the quinacrine mustard-treated synaptic membranes showed that quinacrine mustard specifically labeled two proteins, with corresponding molecular weights of about 37,000 and 32,000.     

Ontogeny of Calcium Antagonist Binding Sites in Chick Brain and Heart

The ontogeny of chick brain and heart ventricle calcium antagonist binding sites was determined, using [3H]nitrendipine ([3H]NDP), as the ligand. The binding of [3H]NDP to adult heart and brain was kinetically very similar, with the former displaying a KD of 0.28 +/- 0.02 nM and a Bmax of 138 +/- 17 fmol/mg protein, and the latter a KD of 0.30 +/- 0.02 nM and a Bmax of 160 +/- 12 fmol/mg protein. The binding site in both brain and heart was highly specific for dihydropyridine calcium antagonists, such as nifedipine, nimodipine, and nisoldipine, since these drugs were several orders of magnitude more potent as inhibitors of [3H]NDP binding than verapamil, methoxyverapamil, or diltiazem. The developmental appearance of [3H]NDP binding sites in brain was rather gradual, with adult levels being attained just prior to birth. This was in contrast to the profile in heart ventricle which showed essentially adult levels at seven days gestation. The acquisition of [3H]NDP binding sites in chick brain roughly paralleled the onset of neuronal maturation and functional activity. In both chick brain and heart, verapamil and methoxyverapamil were weak inhibitors of [3H]NDP binding. However, the inhibition of binding in both tissues was markedly biphasic, with only 50% of the binding sites being susceptible to inhibition by each agent, suggesting that multiple calcium antagonist binding sites may exist in both tissues.