Atrial natriuretic peptide attenuates elevations in Ca2+ and protects hepatocytes by stimulating net plasma membrane Ca2+ efflux

Elevations in intracellular Ca(2+) concentration and calpain activity are common early events in cellular injury, including that of hepatocytes. Atrial natriuretic peptide is a circulating hormone that has been shown to be hepatoprotective. The aim of this study was to examine the effects of atrial natriuretic peptide on potentially harmful elevations in cytosolic free Ca(2+) and calpain activity induced by extracellular ATP in rat hepatocytes. We show that atrial natriuretic peptide, through protein kinase G, attenuated both the amplitude and duration of ATP-induced cytosolic Ca(2+) rises in single hepatocytes. Atrial natriuretic peptide also prevented stimulation of calpain activity by ATP, taurolithocholate, or Ca(2+) mobilization by thapsigargin and ionomycin. We therefore investigated the cellular Ca(2+) handling mechanisms through which ANP attenuates this sustained elevation in cytosolic Ca(2+). We show that atrial natriuretic peptide does not modulate the release from or re-uptake of Ca(2+) into intracellular stores but, through protein kinase G, both stimulates plasma membrane Ca(2+) efflux from and inhibits ATP-stimulated Ca(2+) influx into hepatocytes. These findings suggest that stimulation of net plasma membrane Ca(2+) efflux (to which both Ca(2+) efflux stimulation and Ca(2+) influx inhibition contribute) is the key process through which atrial natriuretic peptide attenuates elevations in cytosolic Ca(2+) and calpain activity. Moreover we propose that plasma membrane Ca(2+) efflux is a valuable, previously undiscovered, mechanism through which atrial natriuretic peptide protects rat hepatocytes, and perhaps other cell types, against Ca(2+)-dependent injury.     

Role of Ca2+-dependent metalloprotease-2 in stimulating Ca2+ ATPase activity under peroxynitrite treatment in bovine pulmonary artery smooth muscle membrane

We have determined effect of the oxidant peroxynitrite (ONOO-) on Ca2+-dependent matrix metalloprotease-2 (MMP-2) activity and the role of the protease on Ca2+ ATPase activity in bovine pulmonary vascular smooth muscle plasma membrane under ONOO- -triggered conditions. The smooth muscle plasma membrane possesses a 72-kDa protease activity in a gelatin-containing zymogram. The 72-kDa protease activity has been found to be inhibited by tissue inhibitor of metalloprotease-2 (TIMP-2), indicating that the protease is the matrix metalloprotease-2 (MMP-2). Treatment of the membrane suspension with ONOO- caused stimulation of the MMP-2 activity (as evidenced by 14C-gelatin degradation) and also increased Ca2+ ATPase activity. The ONOO- -triggered protease activity and the Ca2+ ATPase activity were found to be inhibited by the antioxidants: vitamin E, thiourea, and mannitol. Pretreatment with catalase and superoxide dismutase did not significantly alter ONOO- -stimulated MMP-2 activity and Ca2+ATPase activity, indicating that peroxide and superoxide are not present in appreciable amount in ONOO-. Under both basal and ONOO- triggered conditions, the MMP-2 activity and the Ca2+ ATPase activity were also inhibited by EGTA, 1:10-phenanthroline, and TIMP-2. However, the ONOO- -stimulated MMP-2 activity and the Ca2+ ATPase activity were found to be insensitive to phenylmethylsulfonylfluoride, Bowman-Birk inhibitor, chymostatin, leupeptin, antipain, N-ethylmaleimide, and pepstatin. These results suggest that ONOO- caused stimulation of MMP-2 activity and that the increased MMP-2 activity subsequently played a pivotal role in stimulating Ca2+ ATPase activity in bovine pulmonary vascular smooth muscle plasma membrane.     

Spatio-temporal modelling explains the effect of reduced plasma membrane Ca2+ efflux on intracellular Ca2+ oscillations in hepatocytes

In many non-excitable eukaryotic cells, including hepatocytes, Ca²⁺ oscillations play a key role in intra- and intercellular signalling, thus regulating many cellular processes from fertilisation to death. Therefore, understanding the mechanisms underlying these oscillations, and consequently understanding how they may be regulated, is of great interest. In this paper, we study the influence of reduced Ca²⁺ plasma membrane efflux on Ca²⁺ oscillations in hepatocytes. Our previous experiments with carboxyeosin show that a reduced plasma membrane Ca²⁺ efflux increases the frequency of Ca²⁺ oscillations, but does not affect the duration of individual transients. This phenomenon can be best explained by taking into account not only the temporal, but also the spatial dynamics underlying the generation of Ca²⁺ oscillations in the cell. Here we divide the cell into a grid of elements and treat the Ca²⁺ dynamics as a spatio-temporal phenomenon. By converting an existing temporal model into a spatio-temporal one, we obtain theoretical predictions that are in much better agreement with the experimental observations.     

Epitope mapping of monoclonal antibodies to human plasma membrane Ca2-ATPase

Overlapping fragments of the fourth isoform of human plasma membrane Ca(2+)-ATPase (hPMCA4) and several fragments of hPMCA1 were expressed in bacterial cells and purified by metal affinity chromatography. Enzyme immunoassays of the fragments helped map epitopes for 4 monoclonal antibodies (2D8, 8B8, 7C8 and 5E6). The epitope for 2D8 was localized within the 222-249 site (i.e., in the putative transduction domain), the epitopes for 8B8 and 7C8 were localized within the 330-353 site, in which phospholipids are presumably bound, and the 5E6 epitope was found within the 791-843 site, where the putative hinge region is situated. 2D8 recognizes hPMCA1 and hPMCA4 isoforms, while 8B8 and 7C8 are specific for hPMCA4. The amino acid sequences of these epitopes and phage-displayed mimotopes were compared.     

Ca2+ transport by the synaptosomal plasma membrane Ca2+-ATPase and the effect of thioridazine

Thioridazine inhibits the activity of the synaptic plasma membrane Ca(2+)-ATPase from pig brain and slightly decreases the rate of Ca(2+) accumulation by synaptic plasma membrane vesicles in the absence of phosphate. However, in the presence of phosphate, thioridazine increases the rate of Ca(2+) accumulation into synaptic plasma membrane vesicles. Phosphate anions diffuse through the membrane and form calcium phosphate crystals, reducing the free Ca(2+) concentration inside the vesicles and the rate of Ca(2+) leak. The higher levels of Ca(2+) accumulation obtained in the presence of thioridazine could be explained by a reduction of the rate of slippage on the plasma membrane ATPase.     

The effect of D20 on Ca2+-ATPase in the cell membrane]

The effect of D2O on Ca(2+)-ATPase activity of the meat cattle thymocytes plasma membranes was studied. Kinetic and thermodynamic parameters of Ca(2+)-ATPase reaction were calculated.     

The effect of alkanols on Ca2+ transport in brain mitochondria.

Ethanol stimulates the Na(+)-dependent Ca2+ efflux in brain mitochondria and inhibits the Na(+)-independent Ca(2+)-efflux. Here, we studied the effects of n-alkanols on the various Ca2+ transport processes in brain mitochondria. Only short-chain alcohols (i.e. methanol, ethanol and propanol) stimulated Na+/Ca2+ exchange. The inhibition of H+/Ca2+ exchange was significant only with ethanol. Short-chain alcohols inhibit while long-chain alcohols activate the cyclosporin-sensitive Ca(2+)-efflux. These data suggest that the mechanism of the alkanols' effects on Na+/Ca2+ exchange, H+/Ca2+ exchange and the cyclosporin sensitive pore are entirely different. Alkanols have no effect on the electrogenic Ca2+ uniporter. Ethanol did not affect the apparent K0.5 for Na+ (7.5 mM) of the Na+/Ca2+ exchange. Similarly, the magnitude of the effect of ethanol did not depend on matrix Ca2+ concentration, suggesting that short-chain alkanols do not stimulate the rate of Na+/Ca2+ exchange by increasing the affinity of the carrier to Ca2+in or Na+out. High concentrations of K+, Mg2+ and Ca2+ enhanced the ethanol effect. It is possible that high surface potential attenuates the effect of ethanol. It is suggested that ethanol stimulation of Na+/Ca2+ exchange depends on the modulation of the surface dielectric constant.     

The effect of spermine on transport of Ca2+ ions in brain mitochondria

The effect of spermine (50-400 microM) on the Ca-transporting system of brain mitochondria was studied. In a medium containing Mg2+ and ATP, spermine facilitates the accumulation of Ca2+ by decreasing Km of the uniporter. Spermine inhibits Na-stimulated Ca2+ efflux; this effect is dependent on the ionic strength of the medium--it is decreased when KCl concentration is increased from 20 to 120 mM. Spermine (200 microM) decreases (by 50%) the steady state concentration of Ca2+ maintained by mitochondria. The importance of spermine as a regulator of Ca2+-transport in brain mitochondria is discussed.     

Ca2+-activated Cl- current from human bestrophin-4 in excised membrane patches

Bestrophins are a newly discovered family of Cl(-) channels, some members of which are activated by intracellular Ca(2+). So far, all studies were carried out with whole-cell recordings from plasmid-transfected cultured cells, so it is unclear whether Ca(2+) activates bestrophin through a metabolic mechanism or in a more direct way. We report here experiments that addressed this question with excised, inside-out membrane patches. We chose human bestrophin-4 (hBest4) for heterologous expression because it gave particularly large Cl(-) currents when expressed, thus allowing detection even in excised membrane patches. hBest4 gave a negligible Cl(-) current in a Ca(2+)-free solution on the cytoplasmic (bath) side, but produced a Cl(-) current that was activated by Ca(2+) in a dose-dependent manner, with a K(1/2) of 230 nM. Thus, Ca(2+) appears to activate the bestrophin Cl(-) channel without going through a freely diffusible messenger or through protein phosphorylation. Because the activation and deactivation kinetics were very slow, however, we cannot exclude the involvement of a membrane-associated messenger.     

Distribution of plasma membrane Ca2+ pump (PMCA) isoforms in the gerbil brain: effect of ischemia-reperfusion injury.

Non-species isoform-specific antibodies against three isoforms of the plasma membrane Ca2+ pump (PMCA) were used for immuno-localization of PMCA by Western blot analysis in membrane preparations isolated from different regions of gerbil brain. All three gene products were detected in the membranes from hippocampus, cerebral cortex and cerebellum. However, they showed a distinct distribution pattern. Two proteins were revealed in the case of PMCA1 with molecular masses 129 and 135 kDa. The antibody against PMCA2 recognized three proteins of about 130-137 kDa. Only one protein was detected with the anti-PMCA3 antibody. Levels of immuno-signal for the PMCA isoforms varied significantly among the different brain regions. The PMCA1 is the most abundant in the cerebro-cortical and hippocampal membrane preparations. The PMCA2 was detected in a lesser amount comparing to PMCA1 and was highest in the membrane preparations from cerebellum and in a slightly lesser amount from cerebral cortex. Anti-PMCA3 antibody stained weakly and was localized in the cerebellar and hippocampal membrane preparations. Transient forebrain ischemia (10 min) and reperfusion (for a prolonged period up to 10 d) leads to a significant decrease of PMCA immuno-signal. This decrease could be ascribed to the loss of PMCA1 signal, especially in hippocampal membrane preparations.     

Heparin inhibits the reconstituted plasma membrane Ca2+-ATPase from porcine brain synaptosome

Heparin has been shown to be involved in the regulation of cellular Ca(2+) by binding to many proteins with high affinity. Here we examined the effects of heparin on the plasma membrane Ca(2+)-ATPase from porcine brain synaptosome. Our results showed that heparin dramatically inhibited the ATP hydrolysis and Ca(2+) uptake in the presence and absence of calmodulin. Together with controlled proteolysis by trypsin, we concluded that the calmodulin-binding domain of the plasma membrane Ca(2+)-ATPase was less important for the heparin inhibition. Excess phosphatidylserine was able to eliminate the heparin inhibition. We observed that Ca(2+) affinity kept no obvious changes, but the ATP affinity of plasma membrane Ca(2+)-ATPase was apparently decreased in the presence of heparin. Our results indicated that heparin had little effects on ATP or Ca(2+) binding sites of the enzyme.     

Mechanisms of Ca2+ signalling in cells

The review summarizes recent data and current opinions of the Ca2+ signal formation in cells. Mechanisms of Ca2+ mobilization from the intracellular Ca2+ stores are discussed along with the pathways of Ca2+ entry from the external medium.     

The effect of peripheral proteins on the activity of Ca2+-ATPase in the thymocyte plasma membrane

Effect of peripheral proteins on the activity of Ca2+ of ATRase in plasmic membranes of cattle thymocytes has been studied. Kinetic parameters of ATPase reaction have been calculated. The role of the membrane surface charge in realization of the enzyme activity changes in discussed.     

Effect of maitotoxin on cytosolic Ca2+ levels and membrane potential in purified rat brain synaptosomes

In this study, the effects of the marine toxin maitotoxin on cytosolic Ca2+ levels and membrane potential in rat brain synaptosomes were evaluated. Maitotoxin (10 ng/ml) caused a remarkable increase of intrasynaptosomal Ca2+ levels monitored by the fluorescent probe fura-2. This increase was prevented by the removal of external Ca2+ ions. Tetrodotoxin, as well as the removal of extracellular Na+ ions, failed to affect maitotoxin-induced increase of intrasynaptosomal Ca2+ levels. Also the complete removal of all monovalent and divalent cations, except Ca2+ ions, from the incubation medium (0.32 M sucrose substitution), was unable to prevent the effect of maitotoxin on intrasynaptosomal Ca2+ levels. Maitotoxin (0.3-10 ng/ml), produced a dose-dependent depolarization of synaptosomal membranes, which required the presence of extracellular Ca2+ ions. The substitution of extracellular Na+ with choline or the removal of all cations from the incubation medium and their replacement with an isotonic concentration of sucrose (0.32 M), did not prevent the depolarizing effect exerted by maitotoxin. Also under these two ionic conditions, the effect of maitotoxin on membrane potential was critically dependent on the presence of 1 mM extracellular Ca2+. The depolarizing effect exerted by maitotoxin on synaptosomal membrane potential was also observed when extracellular Ca2+ ions were substituted with an equimolar concentration of Ba2+ or Sr2+ ions. In summary, these results appear to suggest that, in presence of 1 mM extracellular Ca2+ ions, maitotoxin depolarizes synaptosomal plasmamembrane by promoting the influx of extracellular Ca2+ ions. This enhanced influx of Ca2+ causes an increase of intrasynaptosomal Ca2+ levels.     

Effects of plasma membrane oxidoreductases on Ca2+ mobilization and protein phosphorylation in rat brain synaptosomes

We have investigated the possible role of plasma membrane oxidoreductases in the Ca²⁺ export mechanisms in rat brain synaptic membranes. Ca²⁺ efflux in nerve terminals is controlled both by a high-affinity/low capacity Mg-dependent ATP-stimulated Ca²⁺ pump and by a low affinity/high capacity ATP-independent Na⁺-Ca²⁺ exchanger. Both Ca²⁺ efflux mechanisms were strongly inhibited by pyridine nucleotides, in the order NADP>NAD>NADPH>NADH with IC₅₀ values of ca. 10 mM for NADP and ca. 3 mM for the other agents in the case of the ATP-driven Ca²⁺ pump and with IC₅₀ values between 8 and 10 mM for the Na⁺-Ca²⁺ exchanger. Oxidizing agents such as DCIP and ferricyanide inhibited the ATP-driven Ca²⁺ efflux mechanism but not the Na⁺-Ca²⁺ exchanger. In addition, full activation of plasma membrane oxidoreductases requires both an acceptor and an electron donor; therefore the combined effects of both substrates added together were also studied. When plasma membrane oxidoreductases of the synaptic plasma membrane were activated in the presence of both NADH (or NADPH) and DCIP or ferricyanide, the inhibition of the ATP-driven Ca²⁺ pump was optimal; by contrast, the pyridine nucleotide-mediated inhibition of the Na⁺-Ca²⁺ exchanger was partially released when both substrates of the plasma membrane oxidoreductases were present together. Furthermore, the activation of plasma membrane oxidoreductases also strongly inhibited intracellular protein phosphorylation in intact synaptosomes, mediated by eithercAMP-dependent protein kinase, Ca²⁺ calmodulin-dependent protein kinases, or protein kinase C.Abbreviations Hepes 4-(2-hydroxyethyl)-1-piperazine ethanesulfonic acid - SDS sodium dodecyl sulfate - EGTA ethylenglycol-bis(-aminoethylether)-N,N,N,N-tetraacetic acid - DCIP dichlorophenol-indophenol     

Synchronized Ca2+ signals mediated by Ca2+ action potentials in the hippocampal neuron network in vitro

Periodic, synchronized Ca2+ signals appeared 30-120 min after the application of tetrodotoxin, 4-aminopyridine and Cs+, and became stable in interval (6-47s) for hours. The Ca2+ signals were accompanied by excitatory or inhibitory postsynaptic potentials (excitatory postsynaptic currents (EPSCs) for the former) and blocked by the simultaneous application of 6-cyano-7-nitroquinoxaline-2,3-dione and 3-((RS)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid or treatment with Ca2+ -free solution, nicardipine, or omega-conotoxin MVIIC (omegaCTX), but not with ryanodine, caffeine, thapsigargin or CPP alone. Nicardipine largely, but omegaCTX less, blocked Ca2+ action potentials or voltage pulse-induced Ca2+ currents at the cell soma, while omegaCTX completely blocked autaptic EPSCs. Ca2+ signals within a neuron occurred almost simultaneously in the cell soma and all the processes (> 200 microm), while the latency between Ca2+ signals of neighbouring neurons varied over hundreds of ms like that of Ca2 action potential induction from EPSPs. Ca2+ signals propagated in random directions throughout neural circuits. Thus, when Na+ and K+ channels are blocked, Ca2+ action potentials spontaneously occur somewhere in a neuron, eventually propagate via the cell soma to the presynaptic terminals and activate excitatory synaptic transmission, causing synchronized Ca2+ signals. The results further suggest that the axon of hippocampal neurones have the potential ability to convey coded information via Ca2+ action potentials.