[Ethanol and synaptosomal calcium binding]

The effect of ethanol and calcium channel antagonists on rabbit EEG

The influence of nifedipine, verapamil, and cinnarizine on the effect of ethanol on EEG of rabbits (frontal cortex, hippocampus, MRF) was tested. Nifedipine (1.75 mg/kg, IP) and cinnarizine (7.5 mg/kg, IP) were given 30 min before ethanol administration. Verapamil (0.2 mg/kg, IV) was given 15 min before ethanol injection in a dose of 0.8 g/kg IV. Ethanol caused the increase of the frequencies 0.5-4 cps in the recording, as well as a marked decrease of the fastest frequencies. Verapamil prevented ethanol's effect on EEG recording. Cinnarizine antagonized this action to a smaller extent and the influence of nifedipine is transitory and less pronounced.

The role of neuronal calcium channels in dependence on ethanol and other sedatives/hypnotics

This review discusses the importance of neuronal calcium currents in dependence on ethanol, barbiturates, benzodiazepines and opiates. The main sections describe the actions of ethanol on control of intracellular calcium and on calcium and calcium-dependent conductance mechanisms. In particular, the effects of both acute and chronic ethanol treatment on dihydropyridine-sensitive, voltage-dependent, calcium channels are described. The later sections cover the effects of barbiturates, benzodiazepines and opiates on these systems. The conclusions suggest that dihydropyridine calcium channel antagonists may offer a new therapeutic approach to the treatment of ethanol and opiate dependence.

Decreased alcohol consumption by verapamil in alcohol preferring rats

1. Calcium channel blockers have been proposed, in addition to inhibiting the influx of Ca++ into the cells, to possess a wide variety of pharmacological effects, including interference with certain neurotransmitters involved in mood, mental disorders and alcohol craving. Further, it has been documented that certain neurotransmitters are involved in alcohol craving both in animals and humans. 2. To investigate the effects of Ca(++)-channel antagonist on alcohol preference, verapamil in three doses (5, 10 and 15 mg/kg) was injected (S.C.) twice daily over a period of one day in alcohol-preferring (P) and alcohol non-preferring (NP) rats at 9:00 a.m. and 4:00 p.m. 3. Water, alcohol and food intake were monitored. 4. Our results show that verapamil in doses of 10 and 15 mg/kg significantly (p less than 0.02 and 0.01, respectively) reduced the intake of ethanol and increased the intake of water by P rats. However, injection of an equal volume of saline did not change the pattern of alcohol intake. 5. These results suggest that a (++(+)-channel blocker such as verapamil, could, at least partially, attenuate alcohol preference in alcohol preferring rats. It is possible that verapamil exerts an inhibitory effect on alcohol preference by interfering with Ca++ channels, blocking serotonin uptake or through another mechanism(s).

Prostaglandin E2 and leukotriene B4 synthesis by peripheral leucocytes in alcoholics

Alcohol inhibits phospholipase (PL) activity in a number of animal models. We have therefore measured prostaglandin E2 (PGE2) and leukotriene B4 (LTB4), liberated by stimulated peripheral blood mononuclear cells (PBMC) and neutrophils respectively in chronic alcoholics and in control subjects. Peripheral blood mononuclear cells from alcoholics produced less PGE2 (p less than 0.01) and neutrophils produced less LTB4 (p less than 0.025). Reduced PGE2 production by PBMC of alcoholics was corrected by the addition of exogenous arachidonic acid (p less than 0.005) whilst neutrophil LTB4 production remained lower in the alcoholics (p less than 0.01). Percutaneous liver biopsies were undertaken in the 20 alcoholics having abnormal liver function tests. Prostaglandin E2 biosynthesis was lower in PBMC from patients with alcoholic hepatitis than with alcoholic cirrhosis (p less than 0.05). Analysis of PBMC fatty acid composition demonstrated that endogenous arachidonate and linoleate contents were not significantly different in alcoholics and controls. Cells from controls and alcoholics were incubated with 0, 50 and 150 mmol/l ethanol for two hours but there was no alteration in PGE2 or LTB4 biosynthesis. In summary, we found reduced eicosanoid production by peripheral leucocytes in alcoholics, supporting the hypothesis that chronic alcohol consumption either inhibits membrane bound phospholipase activity or enhances, alternatively, catabolism of eicosanoids. This phenomenon is more marked in alcoholic patients with hepatitis than in those with cirrhosis alone.

Different effect of diltiazem and nifedipine on some central actions of ethanol in the rat

The effect of two Ca2+ channel inhibitors (CCIs) on ethanol-induced hypothermia and hypnosis, on tolerance formation to both effects, and on audiogenic convulsions during ethanol withdrawal was studied in rats. Nifedipine, 2 and 5 mg/kg IP, significantly augmented the hypnotic action of ethanol without affecting hypothermia. Diltiazem failed to influence either effect of the toxin. Rectal temperature did not change in ethanol-naive rats after acute injection of diltiazem or nifedipine. Both drugs dose-dependently suppressed the development of tolerance to the hypothermic effect of ethanol without affecting the tolerance to the hypnotic action. Only nifedipine markedly suppressed the audiogenic seizure response in ethanol withdrawn animals. These data suggest that Ca2+ channels play a role in both acute and chronic effects of ethanol while pointing to certain differences in behavioral effects of various CCIs.

Calcium differentially alters behavioral and electrophysiological responses to ethanol in selectively bred mouse lines

Sensitivity to the hypnotic action of ethanol has been found to increase in SS/Ibg (SS) but not in LS/Ibg (LS) mice after intracerebroventricular (icv) administration of calcium. In the present investigation, a correlation was found between calcium-induced changes in behavioral sensitivity and in the sensitivity of cerebellar Purkinje neurons to the depressant effects of locally applied ethanol. Cerebellar Purkinje neuron sensitivity was measured as the dose of ethanol pressure ejected from a multibarreled micropipette required to produce a 50% depression of spontaneous firing rate of single neurons. Administration of 0.2-0.4 mumol calcium chloride into the lateral ventricle of the brain increased the sensitivity of SS but not LS mice to the hypnotic behavioral effect of systemically administered ethanol. Similarly, Purkinje neuron sensitivity to locally applied ethanol was also enhanced in SS but not in LS mice 15 min following administration of calcium (0.25 mumol) icv. Furthermore, locally applied ethanol was more effective in depressing spontaneous Purkinje neuron discharge in SS mice when a 1 mM calcium solution was concomitantly pressure ejected with ethanol from the micropipette. Magnesium chloride did not mimic the effects of calcium on either behavioral or electrophysiological effects of ethanol, suggesting that the action of calcium is not a nonspecific effect of divalent cations. These data suggest that calcium-dependent processes may be involved in behavioral and electrophysiological effects associated with ethanol intoxication. Further research will be required to determine if the genetically selected difference in ethanol sensitivity expressed in LS and SS mice is regulated by calcium mechanisms.

Altered calcium signal transduction after chronic ethanol consumption

Calcium and calcium-calmodulin dependent phosphorylation of several protein bands was found altered in synaptosomal membranes prepared from ethanol treated rats. The ethanol induced effect on Ca++ and Ca++-calmodulin phosphorylation presented regional differences. In particular 32P incorporation was lower in the striatum and cerebellum, higher in the hippocampus and unmodified in the cortex. Part of the phosphorylated bands had an apparent molecular weight similar to that of the phosphoproteins involved in neurotransmission. These results extend previous observations indicating that calcium movement control is modified during chronic ethanol consumption and suggest that ethanol may interfere at various steps in the calcium-promoted events.

Central Ca++-channel blockade reverses ethanol-induced poikilothermia in the rat

Two series of experiments were performed to determine the possible involvement of Ca++ channels in the thermolytic action of ethanol administered at a room temperature of 22 degrees C. In one group of 11 adult female Sprague-Dawley rats, stainless steel guide cannulae were implanted stereotaxically above the lateral cerebral ventricle. Prior to an experiment, a thermistor probe was inserted into the colon so that core temperature could be monitored continuously for up to six hours or until the temperature had returned to a previous baseline level. When the animal's body temperature had stabilized, a dose of 4.0 g/kg in a v/v solution of 20% ethanol was given by intragastric gavage. After the body temperature had declined by about 2.0 degrees C, ordinarily 30 min after ethanol administration, either control CSF or the vehicle plus one of four doses of verapamil (8.3, 25, 50 and 100 micrograms) was infused intracerebroventricularly (ICV) in a volume of 10 microliter. In a second group of 7 unoperated rats, either 4.0 g/kg ethanol or a physiological saline control solution was administered isovolumetrically by intragastric gavage; then, 30 min later, either 3.0 or 10.0 mg/kg verapamil was injected intraperitoneally. At an ambient temperature of 22 degrees C, ethanol gavage produced a significant decline in colonic temperature which was unaffected by physiological saline given by the same route. Although the CSF control vehicle was without effect, verapamil administered ICV attenuated the thermolytic action of ethanol in all doses tested; however, the lowest dose exerted its antagonist effect but with a longer latency. Conversely, when verapamil was given systemically, the hypothermic action of ethanol was significantly potentiated in a dose-dependent manner.(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic ethanol administration inhibits calmodulin-dependent Ca++ uptake in synaptosomal membranes

Chronic ethanol administration inhibits ATP-dependent Ca++ uptake in a preparation of synaptic membranes prepared from mice following 1, 4 and 7 days of ethanol exposure in a liquid diet. Addition of calmodulin (2.5 micrograms) to membranes from mice receiving the control diet produced a slight stimulation of ATP dependent Ca++ uptake. Membranes from ETOH treated mice exhibited reduced capacity to take up Ca++ in ATP-dependent fashion. When calmodulin was added to membranes isolated from mice receiving ETOH on Days 1, 4 and 7 ATP-dependent Ca++ uptake was significantly stimulated (p less than 0.01) compared to (1) ETOH treated membranes in absence of calmodulin, and (2) control membranes. Behavioral tolerance as estimated by bar holding technique was found to be 25, 65 and 91 percent complete for Days 1, 4 and 7 respectively. These studies demonstrate that continued exposure of mice to ethanol via consumption of an ethanol containing liquid diet inhibits one of the mechanisms involving the cytosolic buffering of intracellular Ca++ in nerve terminals. This biochemical effect seen in parallel with the development of tolerance to ethanol impairment of bar holding suggests that increased cytosolic Ca++ may aid in central nervous system adaptation to ethanol.

Calcium influence on neuronal sensitivity to ethanol in selectively bred mouse lines

Sensitivity to ethanol, as measured by blood ethanol concentration at loss of righting reflex, was increased significantly in SS but not LS mice following intracerebroventricular (ICV) administration of calcium chloride or A23187, a calcium ionophore. Magnesium chloride or lanthanum chloride, ICV, did not alter sensitivity to ethanol in either SS or LS mice, further indicating a specificity for calcium cation. Calcium was without effect on sensitivity to halothane narcosis in LS or SS mice. Endogenous brain calcium content was similar in these mouse lines, and ethanol administration either in vivo or in vitro did not alter brain calcium concentration. These results indicate that differences in brain sensitivity to ethanol are mediated, in part, by genetic differences in calcium-related processes and support the hypothesis that ethanol-induced narcosis may be due to alterations in calcium metabolism in the CNS.

Inhibition by ethanol and mepacrine of phospholipase-dependent prostaglandin release from the isolated perfused rat lung

To investigate the possibility that millimolar concentrations of ethanol have a membrane-directed inhibitory effect on phospholipase A2 and prostanoid generation (suggested from previous platelet experiments), we studied the release of prostacyclin, thromboxane A2 and prostaglandin E2 from isolated perfused rat lung. Prostanoid release was evoked by arachidonic acid, bradykinin and ionophore A23187 and was measured after extraction by radioimmunoassay. In these experiments, prostanoid release is dependent upon biosynthesis from fatty acid precursors as there is no endogenous prostanoid storage pool. Arachidonic acid and bradykinin caused enhanced release of more prostacyclin than thromboxane A2 with much less prostaglandin E2 and no detectable prostaglandin F2 alpha, whereas A23187 released equal proportions of prostacyclin and thromboxane A2 with less prostaglandin E2. Ethanol at 50 mM resembled mepacrine (46 microM) in that prostanoid release in response to bradykinin and A23187 was highly significantly reduced with little effect on release induced by arachidonic acid. We suggest that ethanol, like mepacrine, interferes with prostaglandin generation by an action at the phospholipase step. This may be secondary to a physical effect on membrane configuration.

EGTA-extractable calmodulin in platelet membrane is lower in alcoholics than in controls

The purpose of this study was to determine calmodulin distribution in platelets of alcoholics. Eight alcoholics were diagnosed by DSM-III (Diagnostic and Statistical Manual of Mental Disorders, 3rd edition) criteria prior to admission to the Alcohol Unit, VA Hospital, San Antonio, TX. Whole blood was drawn after a five day washout period, and again after 30 days of disulfiram treatment. Platelets were prepared from the whole blood, suspended in Ringer's-citrate-dextrose buffer (RCD), divided into 2 aliquots, then sonicated and centrifuged (100K X g). Supernatants were assayed for calmodulin content by RIA. The pellets were resuspended by sonication in 1 mM EGTA in RCD or 1% (w/v) Lubrol-PX in RCD, then centrifuged at 100K X g. Calmodulin was measured in the EGTA and Lubrol supernatants. EGTA-extractable calmodulin in pre-disulfiram, post-disulfiram, and control subjects was 5.07 +/- 2.2 (SD), 5.19 +/- 1.7 (SD), and 10.5 +/- 6.7 (SD) ng calmodulin/mg whole platelet protein. The EGTA-extractable calmodulin was significantly lower in alcoholics pre- or post-disulfiram than in controls (p less than 0.025). These preliminary results suggest an alteration in platelet membranes of alcoholics that affects the binding of calmodulin.

Membrane disordering by anesthetic drugs: relationship to synaptosomal sodium and calcium fluxes

The effects of membrane perturbants (ethanol, pentobarbital, chloroform, diethylether, phenytoin, cis-vaccenic acid methylester, and cis-vaccenoyl alcohol) on the lipid order of mouse brain synaptic plasma membranes (SPM) were tested by fluorescence polarization using 1,6-diphenyl-1,3,5-hexatriene (DPH) as a probe of the membrane core and 1-[4-(trimethylammonium)phenyl]-6-phenyl-1,3,5-hexatriene (TMA-DPH) as a probe of the membrane surface. The compounds decreased the fluorescence polarization of both probes, indicating that they disordered the membrane lipids. The decrease in polarization was, however, greater for DPH than for TMA-DPH, suggesting a greater effect on the membrane core than on the membrane surface. The voltage-dependent uptake of 24Na and 45Ca was studied in isolated mouse brain synaptosomes as a measure of membrane function. All of the compounds inhibited sodium influx, and their potencies for decreasing sodium uptake and fluorescence polarization of DPH were linearly correlated (r = 0.91). The relationship between changes in sodium influx and TMA-DPH polarization was less consistent (r = 0.66). Synaptosomal calcium uptake was inhibited by most, but not all, of the perturbants, but this inhibition was poorly correlated with changes in fluorescence polarization of DPH (r = 0.36) or TMA-DPH (r = 0.26). These results indicate that the function of synaptic sodium channels is correlated with lipid order in the hydrophobic core of the membrane and that the inhibitory effects of intoxicant-anesthetic drugs on neuronal sodium fluxes may be the result of their capacity to disorder these lipids. In contrast, the effects of drugs on voltage-dependent calcium channels were not clearly related to the capacity of these agents to disorder membrane lipids.

Differential effects of ethanol on two synaptic membrane Ca2+ transport systems

The Na+-Ca2+ exchange activity in synaptic plasma membranes is inhibited by very low concentrations of ethanol (less than 25 mM). The high affinity Mg2+- and ATP-dependent Ca2+ transport in highly purified synaptic membranes is much less sensitive to inhibition by ethanol, with no statistically significant inhibition observed until an ethanol concentration of nearly 800 mM was used. Manipulations of the lipid environment designed to increase membrane fluidity enhanced the activity of the Na+-Ca2+ exchange system but inhibited the ATP-dependent Ca2+ pump. The differential responses of the two synaptic plasma membrane Ca2+ transporting systems to such modifications of membrane structure suggest that these two ion transport processes differ in the extent to which their activity is dependent on the lipid microenvironment in which they reside. Thus, the effects of ethanol on the Na+-Ca2+ antiporter may represent a fairly selective inhibitory process.

Calcium-dependent 86 Rb efflux and ethanol intoxication: studies of human red blood cells and rodent brain synaptosomes

Effects of ethanol on calcium-dependent potassium efflux were investigated in red blood cells (RBC) from humans and brain synaptosomes from rats and mice. 86 Rb was used as a tracer for potassium. Synaptosomes and RBC were lysed and resealed with 86 Rb and calcium-EGTA buffers to regulate intracellular levels of ionized calcium. In vitro addition of ethanol (100 mM) stimulated the calcium-dependent 86 Rb efflux of synaptosomes. This stimulation was blocked by apamin, an inhibitor of the calcium-dependent potassium current of nerve cells. In addition, intracerebroventricular injection of apamin inhibited ethanol-induced narcosis in mice, providing behavioral evidence for the importance of calcium-stimulated potassium efflux in alcohol intoxication. In vitro addition of ethanol, propanol or butanol increased calcium-dependent 86 Rb efflux of human RBC at low concentrations of free calcium, but did not change the calcium-independent efflux of 86 Rb. These results suggest that the calcium-dependent 86 Rb efflux of nerve endings may have an important role in the pharmacological and toxicological effects of ethanol.