Inhibitory effects of cocaine on Ca2+ transients and contraction in single cardiomyocytes.

The effects of cocaine on the Ca2+ transient responsible for excitation-contraction coupling were studied in single rat heart cells loaded with the fluorescent Ca2+ indicator fura 2. A high-speed imaging technique using a charge-coupled device as detector and transient image store [O'Rourke et al., Am. J. Physiol. 259 (Heart Circ. Physiol. 28): H230-H242, 1990] was used to measure cytosolic free Ca2+ concentration ([Ca2+]i) and contraction simultaneously from the images of fluorescence. Cardiomyocytes maintained a basal [Ca2+]i of approximately 140 nM in presence or absence of cocaine. After electrical field stimulation, [Ca2+]i increased to a peak of 498 +/- 25 nM under control conditions. This was reduced to a peak [Ca2+]i of 389 +/- 25 nM after treatment with 50 microM cocaine. Cocaine also reduced the rate of rise of [Ca2+]i but did not affect the time to peak or the half time for resequestration of the released Ca2+. The rate and extent of cell shortening was reduced by cocaine in parallel with the inhibition of the [Ca2+]i transient. Cocaine had no effect on the half time for relaxation. Cocaine did not modify the relationship between contraction and the elevation of [Ca2+]i over a range of extracellular Ca2+ concentrations. The intracellular pool of Ca2+ releasable by caffeine was also unaffected by cocaine. In the presence of the beta-adrenergic agonist isoproterenol, which caused a large enhancement of peak [Ca2+]i and contraction, cocaine still inhibited both parameters. However, cocaine did not reverse the ability of isoproterenol to enhance the rate of Ca2+ reuptake and cell relaxation. Whole cell voltage-clamp studies showed that 50 microM cocaine reduced both the Na+ current (50%) and the Ca2+ current (30%). These data suggest that sarcolemmal ion channels are the primary site that, in cardiac muscle, mediate the negative inotropic effects and the suppression of [Ca2+]i transients by cocaine.

Effects of ethanol on the contractile function of the heart: a review.

Chronic ethanol consumption leads to a number of alterations in the contractile function of the heart and is a leading cause of cardiomyopathy. Ethanol also has an acute negative inotropic effect mediated by direct interaction with cardiac muscle cells, although this action is often masked by indirect actions resulting from enhanced release of catecholamines in vivo. This article reviews the effects of ethanol on the contractile function of the heart. The specific targets affected by ethanol in cardiac muscle cells are discussed in terms of potential mechanisms underlying the depressions of contractility resulting from both acute and chronic actions of ethanol.

Oxidized glutathione causes sensitization of calcium release to inositol 1,4,5-trisphosphate in permeabilized hepatocytes.

The effects of GSSG on Ca2+ mobilization by Ins(1,4,5)P3 were studied in permeabilized rat hepatocytes. Incubation with GSSG (2 mM) increased the sensitivity to Ins(1,4,5)P3 for Ca2+ release, with no effect on the size of the Ca2+ pool that could be released with maximal concentrations of Ins(1,4,5)P3. GSSG decreased the EC50 for Ins(1,4,5)P3 from a control value of 578 +/- 23 nM to 137 +/- 21 nM. GSSG had no effect on the metabolism of Ins(1,4,5)P3 in permeabilized cells, and sensitization of Ca2+ release was still observed when the poorly metabolizable analogue inositol 1,4,5-trisphosphorothioate was used. GSSG did not affect the ATP-dependent Ca2+ pump or the extent of loading of intracellular Ca2+ pools. In addition, the enhancement of Ins(1,4,5)P3-sensitivity by GSSG occurred under conditions where the Ca2+ pumps were blocked with thapsigargin or by chelation of medium Ca2+ just before Ins(1,4,5)P3 addition. The effect of GSSG was time- and dose-dependent, maximal effects being observed after 5 min incubation with 2 mM-GSSG. Cystine mimicked the GSSG-induced increase in Ins(1,4,5)P3-sensitivity, and the effects could be reversed by dithiothreitol (DTT). DTT, GSH glutathione and cysteine had no effect when added alone. Other agents known to react with protein thiols, including N-ethylmaleimide, p-chloromercuribenzoic acid and Ag+, did not affect the sensitivity to Ins(1,4,5)P3, but were inhibitors of ATP-dependent Ca2+ uptake. The data suggest that the sensitivity of the intracellular Ca2+ pools to release by Ins(1,4,5)P3 can be modulated by the formation of mixed disulphides with GSSG or other oxidized thiols.

Modified kinetics of platelet-derived growth factor-induced Ca2+ increases in NIH-3T3 cells overexpressing phospholipase C gamma 1.

The effects of platelet-derived growth factor (PDGF) on cytosolic free Ca2+ concentration ([Ca2+]i) and inositol phosphates were studied in NIH-3T3 fibroblasts transfected with cDNA for phospholipase C gamma 1 (PLC gamma 1) to yield a 7-fold overexpression of this enzyme, compared with cells containing normal levels of PLC gamma 1. In a study published recently [Margolis, Zilberstein, Franks, Felder, Kremer, Ullrich, Rhee, Skorecki & Schlessinger (1990) Science 248, 607-610] it was reported that this overexpression of PLC gamma 1 caused a specific potentiation of the inositol phosphate response to PDGF, but this was not associated with an enhancement of the [Ca2+]i response. In the present study, measurements of the time course and isomeric profile of PDGF-induced inositol phosphate formation demonstrated that the initial rate of Ins(1,4,5)P3 formation was also enhanced in the PLC gamma 1-overexpressing cells, yielding a 10-fold greater increase at 1 min compared with the parental NIH-3T3 cells. By contrast, bradykinin-induced phosphoinositide metabolism was unchanged in PLC gamma 1-transfected cells. Measurements of [Ca2+]i in cell populations and single cells showed a significant latent period following PDGF addition prior to the [Ca2+]i increases in both cell lines, which decreased in a dose-dependent manner with increasing PDGF concentration. The duration of the latent period was decreased and the maximal rate of [Ca2+]i rise was increased in the PLC gamma 1-overexpressing cells at all doses of PDGF examined. In single-cell measurements these cells also responded to PDGF with a greater peak amplitude of [Ca2+]i. Both intracellular Ca2+ mobilization and Ca2+ influx across the plasma membrane were enhanced in the PLC gamma 1-overexpressing cells. There was no difference between the two cell lines in either the latency or the magnitude of the [Ca2+]i increases induced by bradykinin. These data provide further evidence that PLC gamma 1 is responsible for the PDGF-induced stimulation of Ins(1,4,5)P3 formation. Moreover, in contrast to earlier conclusions, the modified kinetics of the [Ca2+]i changes in PLC gamma 1-overexpressing cells suggest that Ins(1,4,5)P3 does play a predominant second messenger role in the PDGF-induced [Ca2+]i increases. The data also indicate that the latent period may be a function of the time required to reach a threshold level of Ins(1,4,5)P3, rather than an intrinsic property of the PDGF receptor.

Oscillatory cytosolic calcium waves independent of stimulated inositol 1,4,5-trisphosphate formation in hepatocytes.

The mechanisms underlying agonist-induced oscillations in intracellular free calcium ion concentration ([Ca2+]i) in hepatocytes were investigated by utilizing tert-butyl hydroperoxide (TBHP) as a tool to perturb hepatocyte Ca2+ homeostasis independent of receptor activation. In permeabilized hepatocytes, TBHP inhibited Ca2+ uptake into the inositol 1,4,5-trisphosphate (InsP3)-sensitive Ca2+ pool and increased the sensitivity to InsP3 for Ca2+ release. The effects of TBHP could be mimicked by addition of oxidized glutathione (GSSG) and reversed by pretreatment with dithiothreitol. TBHP and GSSG had no effect on the metabolic degradation of [3H]InsP3 in permeabilized cells. The effect of TBHP on [Ca2+]i in intact cells was investigated by digital imaging fluorescence microscopy of Fura-2-loaded primary cultured hepatocytes. TBHP treatment initiated a series of [Ca2+]i oscillations similar to those caused by Ca2(+)-mobilizing hormones. Moreover, in common with the actions of hormones in these cells (Rooney, T.A., Sass, E., and Thomas, A,P. (1990) J. Biol. Chem. 265, 10792-10796), the [Ca2+]i oscillations induced by TBHP propagated through the cell as Ca2+ waves, originating from a discrete subcellular locus identical to that for phenylephrine-induced [Ca2+]i oscillations. The Ca2+ waves induced by TBHP had similar rates of progress (24-27 microns.s-1) to those generated by phenylephrine. Removal of extracellular Ca2+ increased the initial latency of the TBHP responses, but had no effect on the amplitude or rate of propagation of the Ca2+ waves. Addition of TBHP to cells in the presence of phenylephrine converted the oscillatory phenylephrine [Ca2+]i response into a sustained [Ca2+]i increase. The effects of TBHP in intact cells occurred in the absence of any stimulated inositol polyphosphate formation as measured in populations of [3H]inositol-labeled hepatocytes. The data indicate that spatially organized [Ca2+]i oscillations in intact hepatocytes can occur without any requirement for phospholipase C activation. Furthermore, for agents that act by mobilizing Ca2+ from the InsP3-sensitive pool, the kinetics of the Ca2+ release phase of the [Ca2+]i oscillations appears to be independent of the nature of the stimulus.

Spatial and temporal organization of calcium signalling in hepatocytes.

Treatment of hepatocytes with agonists which act via the second messenger inositol 1,4,5-trisphosphate (Ins(1,4,5)P3), results in increases of cytosolic free Ca2+ [( Ca2+]i) which are manifest as a series of discrete [Ca2+]i transients or oscillations. With increasing agonist dose [Ca2+]i oscillation frequency increases and the initial latent period decreases, but the amplitude of the [Ca2+]i oscillations remains constant. Studies of these [Ca2+]i oscillations at the subcellular level have indicated that the [Ca2+]i changes do not occur synchronously throughout the cell, but initiate at a specific subcellular domain, adjacent to a region of the plasma membrane, and then propagate through the cell as a [Ca2+]i wave. For a given ceil, the locus of [Ca2+]i wave initiation is constant for every oscillation in a series and is also identical when the cell is sequentially stimulated with different agonists or when the phospholipase C-linked G protein is activated directly using AIF4-. The kinetics of the [Ca2+]i waves indicate that a Ca(2+)-activated mechanism is involved in propagating the oscillatory [Ca2+]i increases throughout the cell, and the data appear to be most consistent with a process of Ca(2+)-induced Ca2+ release. It is proposed that the ability to propagate [Ca2+]i oscillations into regions of the cell distal to the region in which the signal transduction apparatus is localized could serve an important function in allowing all parts of the cell to respond to the stimulus.