Project description:The effects of micromolar concentrations of Mn2+ on the rat liver mitochondrial Ca2+ cycle were investigated. It was found that the addition of Mn2+ to mitochondria which were cycling 45Ca2+ led to a rapid dose dependent decrease in the concentration of extramitochondrial 45Ca2+ of about 1 nmol/mg of protein. The effect was complete within 30 s, was half maximal with 10 microM Mn2+ and was observed in the presence of 3 mM Mg2+ and 1 mM ATP. It occurred over a broad range of incubation temperatures, pH and mitochondrial Ca2+ loads. It was not observed when either Mg2+ or phosphate was absent from the incubation medium, or in the presence of Ruthenium Red. These findings indicate that micromolar concentrations of Mn2+ stimulate the uptake of Ca2+ by rat liver mitochondria, and provide evidence for an interaction between Mg2+ and Mn2+ in the control of mitochondrial Ca2+ cycling.

Project description:The mechanism whereby rat liver mitochondria regulate the extramitochondrial concentration of free Ca(2+) was investigated. At 30 degrees C and pH7.0, mitochondria can maintain a steady-state pCa(2+) (0) (the negative logarithm of the free extramitochondrial Ca(2+) concentration) of 6.1 (0.8mum). This represents a true steady state, as slight displacements in pCa(2+) (0) away from 6.1 result in net Ca(2+) uptake or efflux in order to restore pCa(2+) (0) to its original value. In the absence of added permeant weak acid, the steady-state pCa(2+) (0) is virtually independent of the Ca(2+) accumulated in the matrix until 60nmol of Ca(2+)/mg of protein has been taken up. The steady-state pCa(2+) (0) is also independent of the membrane potential, as long as the latter parameter is above a critical value. When the membrane potential is below this value, pCa(2+) (0) is variable and appears to be governed by thermodynamic equilibration of Ca(2+) across a Ca(2+) uniport. Permeant weak acids increase, and N-ethylmaleimide decreases, the capacity of mitochondria to buffer pCa(2+) (0) in the region of 6 (1mum-free Ca(2+)) while accumulating Ca(2+). Permeant acids delay the build-up of the transmembrane pH gradient as Ca(2+) is accumulated, and consequently delay the fall in membrane potential to values insufficient to maintain a pCa(2+) (0) of 6. The steady-state pCa(2+) (0) is affected by temperature, incubation pH and Mg(2+). The activity of the Ca(2+) uniport, rather than that of the respiratory chain, is rate-limiting when pCa(2+) (0) is greater than 5.3 (free Ca(2+) less than 5mum). When the Ca(2+) electrochemical gradient is in excess, the activity of the uniport decreases by 2-fold for every 0.12 increase in pCa(2+) (0) (fall in free Ca(2+)). At pCa(2+) (0) 6.1, the activity of the Ca(2+) uniport is kinetically limited to 5nmol of Ca(2+)/min per mg of protein, even when the Ca(2+) electrochemical gradient is large. A steady-state cycling of Ca(2+) through independent influx and efflux pathways provides a model which is kinetically and thermodynamically consistent with the present observations, and which predicts an extremely precise regulation of pCa(2+) (0) by liver mitochondria in vivo.

Project description:The impermeability of the mitochondrial inner membrane to the chelator ethanedioxybis(ethylamine)tetra-acetic acid permits discrimination between Ca(2+) which has been transported to the internal (matrix) phase and Ca(2+) which binds to the external surfaces of the mitochondrion. With this technique, it is shown that ;energy-independent high-affinity' binding is a measure of carrier-mediated active Ca(2+) transport in respiration-inhibited mitochondria; the carrier also transports Ca(2+) to the internal phase after treatment with carbonyl cyanide m-chlorophenylhydrazone, but in this case the active-transport component is inhibited. The Ca(2+)-binding sites associated with the external membrane surfaces are similar in concentration and affinity for both inhibited and uncoupled mitochondria; it was not possible to measure external Ca(2+) binding which could be identified as carrier specific. The results are discussed in relation to the mechanism of mitochondrial Ca(2+) transport, and to previous studies of energy-independent Ca(2+) binding.

Project description:1. Liver mitochondria suspended in an iso-osmotic buffered potassium chloride medium containing an oxidizable substrate and phosphate accumulated added Ca(2+). During this process H(+) appeared in the medium and the mitochondrial suspension showed increased light-scattering. Respiration was markedly stimulated. 2. The addition of excess of Ca(2+), respiratory inhibitors or uncoupling agents caused extensive mitochondrial swelling associated with release of Ca(2+) into the suspending medium. When the suspension became anaerobic extensive swelling also occurred. Only under conditions when the addition of uncoupling agents would have produced high rates of electron transport, e.g. in the presence of succinate, was the structural integrity of the mitochondrion maintained after Ca(2+) accumulation. 3. Conditions that prevented respiration-dependent Ca(2+) accumulation also prevented Ca(2+)-induced swelling. Bovine plasma albumin was without effect, indicating that U-factor was not involved. Oligomycin together with ADP or ATP partially stabilized the mitochondria against Ca(2+)-induced swelling. 4. It is suggested that a ;high-energy' intermediate generated by coupled electron transport is required to prevent the mitochondrial swelling that results as a consequence of Ca(2+) accumulation.

Project description:1. The excessive accumulation of Ca(2+) by mitochondria suspended in an iso-osmotic buffered potassium chloride medium containing oxidizable substrate and phosphate led to extensive swelling and release of accumulated Ca(2+) from the mitochondria. When the Ca(2+) 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.

Project description:Substrate-depleted rat liver mitochondria will reaccumulate malate, succinate, oxoglutarate, beta-hydroxybutyrate and glutamate if provided with an energy source and Ca(2+) (or Ca(2+) and Mn(2+)). The energy requirement for ion uptake by fresh mitochondria causes a transient oxidation of their NADH and presumably this leads to an increased oxaloacetate concentration. A consequence is the promotion of formation of citrate, which tends to remain in the particles, provided the pH is above 7. Analyses made of systems blocked with fluorocitrate show that citrate accumulates when Ca(2+) is added with the following substrates; (a) pyruvate in the presence of ATP or malate, (b) palmitoyl-l(-)-carnitine in presence of malate and (c) oxoglutarate. Lowering the pH, even to 6.8, causes the citrate to emerge. This could be the basis of a cellular control mechanism. The generation of citrate in response to Ca(2+) can explain the stoichiometry of one proton ejected per Ca(2+) ion taken up. The new carboxyl group formed from acetyl-CoA when it condenses with oxaloacetate provides an internal anionic charge and a proton to emerge when Ca(2+) enters.

Project description:Ca(2+) uptake and the effect of the uptake inhibitors palmitoyl-CoA and palmitoylcarnitine were examined in two preparations of dog cardiac mitochondria. Mitochondria prepared by using the Nagarse technique was 2.5-fold more active in respiration-dependent Ca(2+) uptake than were mitochondria isolated by using the Polytron procedure. Palmitoyl-CoA and palmitoylcarnitine inhibited Ca(2+) uptake in both preparations uncompetitively, with K(i,app) 0.4 and 20mum. Ca(2+)-uptake rates were related to, or influenced by, the concentration of mitochondrial reduced nicotinamide nucleotides, with uptake slowing as this concentration decreased. When most of the nicotinamide nucleotides was oxidized, Ca(2+) release and respiratory stimulation were observed. In the presence of Ruthenium Red and palmitoyl-CoA, oxidation of nicotinamide nucleotides was abolished and the time to Ca(2+) release was shortened corresponding to the time of onset of nicotinamide nucleotide oxidation in the absence of Ruthenium Red. The results suggest that NAD(P)H oxidation in the presence of rotenone was a consequence of Ca(2+) re-uptake and that net Ca(2+) release could be observed as reduced nicotinamide nucleotide concentrations declined. Although nicotinamide nucleotide oxidation occurred in the presence of rotenone, it was not linked in an apparent manner to acyl-group metabolism (palmitoylcarnitine was less effective than palmitoyl-CoA). Therefore either a by-pass of the rotenone block or a direct interaction of NAD(P)H with the Ca(2+)-uptake process was possible. Loss of NADH occurred before respiratory stimulation, and this loss may relate to decreased coupling efficiency at sites 2 and 3 of the respiratory chain, as suggested by others [Bhuvaneswaran & Wadkins (1978) Biochem. Biophys. Res. Commun.82, 648-654].

Project description:Ca2+ efflux from rat liver mitochondria can occur when endogenous nicotinamide nucleotides are oxidized. It is suggested that nicotinamide nucleotide induced by acetoacetate sensitizes the mitochondria to damaage resulting from the accumulation of Ca2+ in the presence of Pi. Thus, acetoacetate-induced Ca2+ efflux is associated with a loss of respiratory control. Both the effluxes induced by acetoacetate and by high Ca2+ accumulation are prevented by ATP plus oligomycin, although these agents do not prevent the endoagenous nicotinamide nucleotides from becoming oxidized on addition of acetoacetate. Acetoacetate addition only results in Ca2+ release if the Ca2+ and Pi concentration are above a critical value. The acetoacetate-induced Ca2+ effflux is exactly paralled by the virtually complete collapse of the membrane potential. The presence of acetoacetate decreases the concentration of total Ca2+ necessary to induced mitochondrial damage by about 130 nmol of Ca2+/mg of protein. It is concluded that acetoacetate-induced efflux occurs by reversal of the Ca2+ uniporter after the collapse of the membrane potential.

Project description:1. Nupercaine inhibits the Ca2+ efflux from rat liver mitochondria observed in the presence of Ruthenium Red, 50% inhibition being obtained at 80 microM-Nupercaine. 2. Neither the Ruthenium Red-stimulated efflux nor its inhibition by Nupercaine can be directly attributed to effects on mitochondrial stability. 3. Nupercaine perturbs the steady-state external Ca2+ concentration in the absence of Ruthenium Red to an extent that is explicable in terms of the inhibition of Ca2+ efflux. 4. Various factors that are likely to be involved in determining steady-state extra-mitochondrial Ca2+ concentrations are discussed.

Project description:Liver regeneration is regulated by growth factors, cytokines, and other endocrine and metabolic factors. Calcium is important for cell division, but its role in liver regeneration is not known. The purpose of this study was to understand the effects of cytosolic calcium signals in liver growth after partial hepatectomy (PH). The gene encoding the calcium-binding protein parvalbumin (PV) targeted to the cytosol using a nuclear export sequence (NES), and using a discosoma red fluorescent protein (DsR) marker, was transfected into rat livers by injecting it, in recombinant adenovirus (Ad), into the portal vein. We performed two-thirds PH 4 days after Ad-PV-NES-DsR or Ad-DsR injection, and liver regeneration was analyzed. Calcium signals were analyzed with fura-2-acetoxymethyl ester in hepatocytes isolated from Ad-infected rats and in Ad-infected Hela cells. Also, isolated hepatocytes were infected with Ad-DsR or Ad-PV-NES-DsR and assayed for bromodeoxyuridine incorporation. Ad-PV-NES-DsR injection resulted in PV expression in the hepatocyte cytosol. Agonist-induced cytosolic calcium oscillations were attenuated in both PV-NES-expressing Hela cells and hepatocytes, as compared to DsR-expressing cells. Bromodeoxyuridine incorporation (S phase), phosphorylated histone 3 immunostaining (mitosis), and liver mass restoration after PH were all significantly delayed in PV-NES rats. Reduced cyclin expression and retinoblastoma protein phosphorylation confirmed this observation. PV-NES rats exhibited reduced c-fos induction and delayed extracellular signal-regulated kinase 1/2 phosphorylation after PH. Finally, primary PV-NES-expressing hepatocytes exhibited less proliferation and agonist-induced cyclic adenosine monophosphate responsive element binding and extracellular signal-regulated kinase 1/2 phosphorylation, as compared with control cells.Cytosolic calcium signals promote liver regeneration by enhancing progression of hepatocytes through the cell cycle.