Inhibition of energy-dependent Ca2+ accumulation in fibroblasts by smooth muscle antibodies.

An antibody prepared against smooth muscle myosin interferes with active Ca2+ accumulation of fibroblasts. This provides further evidence for the existence of myosin at the cell surface.     

Calixarene C-91 stimulates Ca2+ accumulation in the myometrium mitochondria

Calixarenes, owing to the ability to form supramolecular complexes with biologically important molecules and ions, can influence a course of biochemical processes and, accordingly, be considered as perspective molecular platforms for creation of physiologically active compounds. The work purpose is to study calixarene C-91 influence on systems of active Ca ions transport which are localized in subcellular membrane structures (mitochondria, sarcoplasmic reticulum, plasma membrane) of myometrial cells. It has been shown, that calixarene C-91 addition to incubation medium led to an increase in Ca2+ accumulation level in mitochondria. The maximal stimulating effect was 173% and it was observed at 100 microM concentration. It is suggested, that calixarene C-91 can enter mitochondria with the subsequent precipitation of Ca ions in a matrix therefore calcium capacity increases, and as a consequence, higher Ca2+ accumulation in these structures is observed. In a wide range of concentration (1-100 microM) calixarene C-91 did not influence a level of Ca2+ accumulation in sarcoplasmic reticulum of myometrial cells. Titration of solubilized Ca2+, Mg2+-ATPase by calixarene C-91 (0,1-100 microM) did not cause changes in its activity. Thus, calixarene C-91 increases Ca2+ accumulation level in mitochondria, but practically does not influence calcium pumps activity of a plasma membrane and sarcoplasmic reticulum of myometrial cells.     

Ca2+-induced accumulation of pyrophosphate in mitochondria during acetate metabolism.

The mechanism of pyrophosphate (PPi) accumulation in rat liver during acetate metabolism was investigated. Perfusion of the liver with acetate in the presence of noradrenaline and glucagon induced marked accumulation of PPi (2 mumol/g of liver, 200 times that of control). In contrast, perfusion with glutamine, which generates PPi only in the cytosol, caused little accumulation of PPi, even in the presence of the two hormones. The site of PPi accumulation was shown to be the mitochondria by the finding that isolated mitochondria from the liver perfused with acetate and the hormones contained 50 nmol of PPi/mg of protein. The addition of an uncoupler to mitochondria with accumulated PPi caused gradual decrease in their PPi content, with concomitant release of a stoichiometric amount of Ca2+. Similar accumulation of PPi was observed when isolated mitochondria were incubated with acetate and Ca2+. These results show that an increase in cytosolic Ca2+ caused by the co-administration of the two hormones induced uptake of the ion into mitochondria, and that PPi accumulated in mitochondria only when it was generated in the organelles with an elevated concentration of Ca2+. High mitochondrial concentrations of Ca2+ are considered to inhibit inorganic pyrophosphatase through the formation of a stable complex, CaPPi-. Mitochondria with accumulated PPi had normal respiratory activities, and their adenine nucleotide concentrations were increased 2-fold rather than being decreased, the increases also being considered to be caused by their high concentration of Ca2+.     

Interaction of Sr2+ with Ca2+-induced Ca2+ release in mitochondria

Respiring rat liver mitochondria are known to spontaneously release the Ca²⁺ taken up when they have accumulated Ca²⁺ over a certain threshold, while Sr²⁺ and Mn²⁺ are well tolerated and retained. We have studied the interaction of Sr²⁺ with Ca²⁺ release. When Sr²⁺ was added to respiring mitochondria simultaneously with or soon after the addition of Ca²⁺, the release was potently inhibited or reversed. On the other hand, when Sr²⁺ was added before Ca²⁺, the release was stimulated. Ca²⁺-induced mitochondrial damage and release of accumulated Ca²⁺ is generally believed to be due to activation of mitochondrial phospholipase A (EC 3.1.1.4.) by Ca²⁺. However, isolated mitochondrial phospholipase A activity was little if at all inhibited by Sr²⁺. The Ca²⁺ -release may thus be triggered by some Ca²⁺ -dependent function other than phospholipase.     

Substrate-dependent effect of phenolic antioxidants on Ca2+ accumulation by rat liver mitochondria

The effect of different phenolic antioxidants on mitochondrial Ca2+ capacity (maximum amount of Ca2+ mitochondria can accumulate) was studied. Butylated hydroxytoluene substantially enhanced the Ca2+ capacity in mitochondria oxidizing succinate, butylated hydroxyanisole had a moderate effect while 2,5-di-(t-butyl)- 1,4 benzohydroquinone did not affect Ca2+ capacity at all. The analysis of Ca2+ accumulation in mitochondria oxidizing succinate in the presence of 2,5-di-(t-butyl)-1,4 benzohydroquinone revealed inhibition of the rate of Ca2+ accumulation. This effect was absent when ATP hydrolysis or NAD+-dependent substrate oxidation supported Ca2+ transport. Direct measurements of oxygen consumption revealed the concentration-dependent inhibition of succinate oxidation by increasing concentrations of 2,5-di-(t-butyl)- 1,4 benzohydroquinone. When succinate was substituted by NAD+-dependent respiratory substrates, the Ca2+ capacity of mitochondria with 2,5-di-(t-butyl)-1,4 benzohydroquinone was even higher than in the presence of butylated hydroxytoluene.     

Stoichiometry of H+ ejection during respiration-dependent accumulation of Ca2+ by rat liver mitochondria.

We have investigated the energy-dependent uptake of Ca2+ by rat liver mitochondria with succinate as respiratory substrate with rotenone added to block NAD-linked electron transport. In the presence of 3-hydroxybutyric or other permeant monocarboxylic acids Ca2+ was taken up to extents approaching those seen in the presence of phosphate. The quantitative relationship between cation and anion uptake was determined from the slope of a plot of 3-hydroxybutyrate uptake against Ca2+ uptake, a method which allowed determination of the stoichiometry without requiring ambiguous corrections for early nonenergized or nonstoichiometric binding events. This procedure showed that 2 molecules of 3-hydroxtbutyrate were accumulated with each Ca2+ ion. Under these conditions close to 2 Ca2+ ions and 4 molecules of 3-hydroxybutyrate were accumulated per pair of electrons per energy-conserving site of the respiratory chain. Since 3-hydroxybutyrate must be protonated to pass the membrane as the undissociated free acid, it is concluded that 4 protons were ejected (and subsequently reabsorbed) per pair of electrons per energy-conserving site, in contrast to the value 2.0 postulated by the chemiosmotic hypothesis.     

Studies on the energy-linked Ca2+ accumulation in pig heart mitochondria - role of Mg2'ons

Comparative intracellular distribution of Ca2+, Mg2+ and adenine nucleotides has been studied in pig heart by differential centrifugation or fractional extraction and has shown that Mg2+ and ATP are associated mainly with soluble fractions whereas Ca2+ and ADP are more tightly bound to subcellular structures. Ca2+ accumulation and Ca2+ stimulated respiration were studied in pig heart mitochondria under different energetic conditions in the absence or presence of phosphate. Ca2+ concentrations of about 1200 nmoles/mg protein inhibit Ca2+ accumulation, site I substrate oxidation and induce an efflux of mitochondrial Mg2+. These deleterious effects of Ca2+ on respiration occur even in the absence of phosphate or oxidizable substrate; they are completely prevented by ruthenium red only, and partially prevented by the addition of M2+ to the medium. The kinetics of Ca2+ uptake become of the sigmoidal type when Mg2+ is present. This cation strongly inhibits the rate of Ca2+ uptake in the presence of added phosphate and decreases the affinity of Ca2+ for its transport system. In the absence of phosphate, Mg2+ has no effect on Ca2+ uptake. The possible physiological implications of these findings are discussed     

Relationships between Ca2+ release, Ca2+ cycling, and Ca2+-mediated permeability changes in mitochondria

Ruthenium red and/or EGTA prevent cyclic uptake and release of Ca2+ in mitochondria. These compounds inhibit but do not prevent the swelling of liver mitochondria induced by Ca2+ plus t-butyl hydroperoxide or Ca2+ plus N-ethylmaleimide. Ruthenium red and/or EGTA have complex effects on the release rate of Ca2+ and other cations induced by t-butyl hydroperoxide or N-ethylmaleimide. To determine the relationship between permeability changes and Ca2+ release in the absence of Ca2+ cycling, a novel method of data collection and analysis is developed which allows the relative time courses of Ca2+ release and Mg2+ release or swelling to be accurately and quantitatively compared. This method eliminates errors in time course comparisons which arise from the aging of mitochondrial preparations and allows data from different preparations to be directly contrasted. Using the method, it is shown that permeability changes caused by Ca2+-releasing agents are not secondary effects arising from Ca2+ cycling between uptake and release carriers. In the absence of Ca2+-cycling inhibitors, Ca2+ release induced by t-butyl hydroperoxide or N-ethylmaleimide is, in part, carrier-mediated. In the presence of EGTA and ruthenium red, Ca2+ release induced by either agent is mediated solely by the permeability pathway. No differences are apparent in the solute selectivity of the inner membrane permeability defect induced by Ca2+ plus t-butyl hydroperoxide or Ca2+ plus N-ethylmaleimide. A novel type of Ca2+ release from energized liver mitochondria is reported. This release is induced by EGTA, occurs in the absence of other releasing agents or nonspecific permeability changes, and is rapid (greater than or equal to 50 nmol/min/mg protein).     

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.     

Ca2+ shuttling between endoplasmic reticulum and mitochondria underlying Ca2+ oscillations

Although many cell functions are regulated by Ca(2+) oscillations induced by a cyclic release of Ca(2+) from intracellular Ca(2+) stores, the pacemaker mechanism of Ca(2+) oscillations remains to be explained. Using green fluorescent protein-based Ca(2+) indicators that are targeted to intracellular Ca(2+) stores, the endoplasmic reticulum (ER) and mitochondria, we found that Ca(2+) shuttles between the ER and mitochondria in phase with Ca(2+) oscillations. Following agonist stimulation, Ca(2+) release from the ER generated the first Ca(2+) oscillation and loaded mitochondria with Ca(2+). Before the second Ca(2+) oscillation, Ca(2+) release from the mitochondria by means of the Na(+)/Ca(2+) exchanger caused a gradual increase in cytoplasmic Ca(2+) concentration, inducing a regenerative ER Ca(2+) release, which generated the peak of Ca(2+) oscillation and partially reloaded the mitochondria. This sequence of events was repeated until mitochondrial Ca(2+) was depleted. Thus, Ca(2+) shuttling between the ER and mitochondria may have a pacemaker role in the generation of Ca(2+) oscillations.     

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.     

Comparative study of the effect of aliphatic alcohols on energy-dependent accumulation of Ca2+ in intracellular membranes of smooth muscle cells

The effects of ethanol and other aliphatic alcohols on energy-dependent Ca2+ transport in endoplasmic reticulum and mitochondria were studied in digitonin-treated myometrium cells. The Ca2+ uptake in mitochondria increased (on 15-20%) with increasing methanol, ethanol and propanol concentrations in medium, whereas further rise of concentration inhibited this process. Treatments of myometrial cells with short-chain alcohols caused an inhibition of calcium uptake in endoplasmic reticulum. Butanol inhibited both calcium uptake in mitochondria and endoplasmic reticulum. Ca2+ accumulation in intracellular pools is inhibited by aliphatic alcohols in the following order of potency: butanol > propanol > ethanol > methanol. It is concluded that modifying effect of aliphatic alcohols on energy dependent calcium accumulation in intracellular membrane structures is defined as on origin of Ca(2+)-transporting system and (or) properties of these membrane structures so on properties of alcohols.     

Activation of oxidative phosphorylation and energy-dependent absorption of Ca2+ and K+ ions by liver mitochondria of hibernating ground squirrels in hypotonic media]

Activation of initially suppressed oxidative phosphorylation and energy-dependent uptake of Ca2+ and K+ ions by liver mitochondria of hibernating gophers which is prevented by phospholipase A2 inhibitors, has been shown to occur in hypotonic media. Partial inhibition of the respiratory chain of liver mitochondria of active gophers by antimycin A which causes a decrease in the uncoupled respiration rate and delta psi down to values typical of mitochondria of hibernating gophers, practically exactly reproduced the suppression of oxidative phosphorylation and energy-dependent uptake of cations observed during hibernation. It was concluded that partial deenergization arising as a result of inhibition of the respiratory chain is the main and unique cause of suppression of energy-dependent functions of liver mitochondria of hibernating gophers.     

Translational suppression by Ca2+ ionophores: Reversibility and roles of Ca2+ mobilization, Ca2+ influx, and nucleotide depletion

The divalent cation selective ionophores A23187 and ionomycin were compared for their effects on the Ca²⁺ contents, nucleotide contents, and protein synthetic rates of several types of cultured cells. Both ionophores reduced amino acid incorporation by approximately 85% at low concentrations (50–300 nmol/L) in cultured mammalian cells without reducing ATP or GTP contents. At these concentrations A23187 and ionomycin each promoted substantial Ca²⁺ efflux, whereas at higher concentrations a large influx of the cation was observed. Ca²⁺ influx occurred at lower ionophore concentrations and to greater extents in C6 glioma and P3X63Ag8 myeloma than in GH₃ pituitary cells. The ATP and GTP contents of the cells and their ability to adhere to growth surfaces declined sharply at ionophore concentrations producing increased Ca²⁺ influx. Prominent reductions of nucleotide contents occurred in EGTA-containing media that were further accentuated by extracellular Ca²⁺. Ionomycin produced more Ca²⁺ influx and nucleotide decline than comparable concentrations of A23187. The inhibition of amino acid incorporation and mobilization of cell-associated Ca²⁺ by ionomycin were readily reversed in GH₃ cells by fatty acid-free bovine serum albumin, whereas the effects of A23187 were only partially reversed. Amino acid incorporation was further suppressed by ionophore concentrations depleting nucleotide contents. Mitochondrial uncouplers potentiated Ca²⁺ accumulation in response to both ionophores. At cytotoxic concentrations Lubrol PX abolished protein synthesis but did not cause Ca²⁺ influx. Nucleotide depletion at high ionophore concentrations is proposed to result from increased plasmalemmal Ca²⁺-ATPase activity and dissipation of mitochondrial proton gradients and to cause intracellular Ca²⁺ accumulation. Increased Ca²⁺ contents in response to Ca²⁺ ionophores are proposed as an indicator of ionophore-induced cytotoxicity.Abbreviations BSA bovine serum albumin - EGTA [ethylenebis(oxyethylenenitrilo)]tetraacetic acid - PKR double-stranded RNA-regulated protein kinase - ER endoplasmic reticulum - eIF eukaryotic initiation factor     

GTP-sensitivity of the energy-dependent Ca2+ storage pool in permeabilized pancreatic acinar cells

Isolated rabbit pancreatic acinar cells, permeabilized by saponin treatment and incubated in the presence of 0.1 microM free Ca2+, accumulated 3.3 nmol of Ca2+/mg of acinar protein in an energy-dependent pool. Part of this energy-dependent pool could be released by GTP in a polyethylene glycol-dependent manner. The kinetics of GTP-induced release of Ca2+ showed a biphasic pattern with an initial rapid phase followed by a sustained slower phase. In contrast, IP3-induced release of Ca2+ was completed within 30 s following addition of IP3. No reuptake of Ca2+ was observed following GTP- or IP3-induced release of Ca2+. The GTP effect was independent of IP3 and not inhibited by Ca2+, indicating that the IP3-operated Ca2+ channel is not involved in GTP-induced release of Ca2+. The size of the IP3-releasable pool was not affected by GTP, indicating that GTP, when added to permeabilized acinar cells, does not promote the coupling between IP3-insensitive and IP3-sensitive Ca2+ accumulating organelles. Thus, in permeabilized acinar cells, GTP and IP3 act on different Ca2+ sequestering pools. Interestingly, however, comparison of the size of the GTP-releasable pool with that of the IP3-releasable pool for the cell preparations used in the present study, revealed an inversed relationship, indicating that at the time of permeabilization the GTP-releasable pool can be coupled to a greater or lesser extent to the IP3-releasable pool. This suggests that, in the intact cell, a GTP-dependent mechanism may exist that controls the size of the IP3-releasable pool by coupling IP3-insensitive to IP3-sensitive organelles. Moreover, this suggests that the extent of coupling is preserved during permeabilization.