Veratridine activates a silent sodium channel in rat isolated aorta.

To investigate the existence of silent Na+ channels, isolated rat aorta was treated with veratridine (0.1 mM) and the resulting Ca2+ uptake was determined. After 30-min incubation the total tissue uptake of Ca2+ and Ca2+ uptake increased from 2.325 +/- 0.017 to 2.614 +/- 0.080 nmol/mg wet weight (ww) and from 162.6 +/- 9.7 to 218.1 +/- 13.0 pmol/mg ww, respectively. The veratridine-induced Ca2+ uptake was blocked by tetrodotoxin (1 microM; to 17 +/- 5%) but not altered by amiloride (10 microM-1 mM). Activation of Na+/Ca2+ exchange by Na+ removal increased Ca2+ uptake from 74.2 +/- 4.5 to 97.3 +/- 5.3 pmol/mg ww, which was suppressed by amiloride (10 microM-1 mM). Nifedipine (10 nM) and verapamil (0.1 microM) at concentrations at which depolarization-induced Ca2+ uptake was diminished did not attenuate veratridine-induced Ca2+ uptake. Phenytoin at 0.1 mM reduced the Ca2+ uptake induced by veratridine or by depolarization. R 56865 (0.1 microM) and R 59494 (1 microM), novel anti-ischemic compounds inhibiting slowly inactivating Na+ channels, suppressed the veratridine-induced but not the depolarization-induced Ca2+ uptake. Guanidinium uptake was increased by veratridine (0.1 mM) from 371.2 +/- 7.2 to 574.8 +/- 45.9 pmol/mg ww. These results suggest that the rat aorta possesses a Na+ channel which is electrically silent under normal conditions but could be activated by veratridine.     

Tetrodotoxin-sensitive and tetrodotoxin-resistant Na+ channels differ in their sensitivity to Cd2+ and Zn2+

The sensitivity of Na+ channels to inhibition by Cd2+ and Zn2+ was studied in 22Na+ uptake experiments after stabilization of an open conformation of the Na+ channels with different neurotoxins and in voltage clamp experiments. Six different cell types of neuronal, cardiac or skeletal muscle origin were surveyed. Three cell types possess Na+ channels that are highly sensitive to tetrodotoxin (TTX) (Kd = 1-5 nM) and three possess Na+ channels that are resistant to TTX (Kd = 0.3-1 microM). The 22Na+ uptake experiments using veratridine or batrachotoxin to activate Na+ channels indicated that TTX-resistant Na+ channels are more sensitive to the inhibitory action of Cd2+ (IC50(Cd2+) = 0.2 mM) and of Zn2+ (IC50(Zn2+) = 50 microM) than TTX-sensitive Na+ channels (IC50(Cd2+) = 5 mM, IC50(Zn2+) = 2 mM). Electrophysiological experiments showed that high concentrations of Cd2+ (IC50 = 2 mM) are necessary to inhibit both TTX-sensitive and TTX-insensitive Na+ channels when the channels are activated by voltage steps. The results suggest that Cd2+ acts competitively with veratridine or batrachotoxin and that the difference in the effects of Cd2+ and Zn2+ on 22Na+ fluxes in TTX-sensitive and TTX-resistant cells is related to differences at the site of action of alkaloid neurotoxins.     

Effects of propranolol and a number of its analogues on sodium channels

To assess the relative contributions that the sodium channel blocking activity of propranolol may play in a variety of its therapeutic applications, its effects were examined in vitro with a sodium channel specific 22Na+ uptake system, using rat brain membranes. Propranolol inhibited 22Na+ uptake in the rat brain membrane preparation by acting as a competitive inhibitor of the binding of the sodium channel opening agent veratridine, with an IC50 for this action of 6.5 microM. This is approximately one order of magnitude higher in concentration than that necessary for expression of the beta-adrenergic antagonism of propranolol. The binding of propranolol and its action to block sodium channels were demonstrably different from those of the neurotoxins tetrodotoxin and saxitoxin. Propranolol had effects on sodium channels that are similar, although not identical to those of the local anesthetics procaine and lidocaine. The concentrations of propranolol and a number of its analogues which produced 50% inhibition of 22Na+ uptake (IC50 values ranging from 4 to greater than 100 microM) were similar to the concentrations of these same analogues which were required to produce negative inotropic and antiarrythmic effects (ED40) on isolated rabbit atria [D. O. Rauls and J. K. Baker, J. med. Chem, 22, 81 (1979)]. These effects showed correlations of 0.945 and 0.936, respectively, with the 22Na+ uptake inhibition. It is concluded from this information that a substantial proportion of the negative inotropic and antiarrythmic effects of propranolol is due to its action on sodium channels.     

14C]guanidinium ion influx into Na+ channel preparations from mouse cerebral cortex

[14C]Guanidinium ion influx into Na+ channel preparations from mouse and rat cerebral cortex (purified synaptosomes, and synaptoneurosomes) was characterized and its properties were compared with those for 22Na+ influx. Tetrodotoxin-sensitive influx of [14C]guanidinium ion was stimulated by aconitine, veratridine, and batrachotoxin with a K0.5 of 7, 5 and 0.3 microM, respectively, the maximal influx being the same with all toxins. Scorpion venom shifted the activation curve of veratridine to the left, but did not increase the maximal influx. The potency of the local anesthetic drugs cocaine and tetracaine in inhibiting [14C]guanidinium ion influx depended upon the concentration of veratridine used to activate the Na+ channels. The mechanism of inhibition was of a competitive nature. Other local anesthetic drugs and cocaine congeners inhibited [14C]guanidinium ion influx with potencies very similar to those for inhibition of 22Na+ influx. The results show that [14C]guanidinium ion influx is a valid model for 22Na+ influx through voltage-dependent Na+ channels although there are some differences between the two influx assays. The guanidinium ion assay offers the convenience of the 14C isotope as compared with the strongly radiating 22Na+ isotope.     

Sodium-dependence of the saturability of carrier-mediated noradrenaline efflux from noradrenergic neurones in the rat vas deferens

The carrier-mediated transport of 3H-noradrenaline out of noradrenergic neurones was studied in vasa deferentia obtained from rats after pretreatment with reserpine and pargyline (to inhibit vesicular storage and monoamine oxidase, respectively). The tissue was first preincubated with various concentrations of 3H-noradrenaline (0.3--100 mumol/1; 30 min) and then washed out for 110 min with amine-free medium. During the last 10 min of washout, carrier-mediated neuronal efflux of 3H-noradrenaline was elicited by exposure to either Na+-free medium or 100 mumol/l veratridine; it was measured at 1-min intervals. While the peak rates of carrier-mediated 3H-noradrenaline efflux elicited by Na+-free medium were linearly related to the 3H-noradrenaline content of the tissue (which cannot be raised beyond a certain maximal value, since uptake is saturable), those evoked in response to veratridine approached saturation as the 3H-noradrenaline level in the tissue was raised. Hence, saturation of 3H-noradrenaline outward transport was demonstrated at high (exposure to veratridine), but not at low (exposure to Na+-free medium) intraneuronal Na+ concentrations. The results indicate that the Km for the mediated outward transport of noradrenaline across the plasma membrane of noradrenergic neurones is inversely related to the internal Na+ concentration, just as the Km for the mediated inward transport of noradrenaline (i.e., the neuronal noradrenaline uptake) is inversely related to the external Na+ concentration.     

Inhibition of synaptosomal uptake of 3H-L-glutamate and 3H-GABA by hyperforin, a major constituent of St. John's Wort: the role of amiloride sensitive sodium conductive pathways.

Extracts of St. John's Wort are widely used for the treatment of depressive disorders. The active principles have not yet been finally elucidated. We have recently shown that hyperforin, a major active constituent of St. John's Wort, not only inhibits the neuronal uptake of serotonin, norepinephrine and dopamine, but also that of L-glutamate and GABA. No other antidepressant compound exhibits a similar broad uptake inhibiting profile. To investigate this unique kind of property, kinetic analyses were performed regarding the uptake of 3H-L-glutamate and 3H-GABA into synaptosomal preparations of mouse brain. Michaelis-Menten kinetics revealed a reduction of Vmax (8.27 to 1.80 pmol/mg/min for 3H-L-glutamate, 2.76 to 0.77 pmol/mg/min for 3H-GABA) while Km was nearly unchanged in both cases, suggesting non-competitive inhibition. The unselective uptake inhibition by hyperforin could be mimicked by the Na+-ionophore monensin and by the Na+-K+-ATPase inhibitor ouabain. However, both mechanisms can be discarded for hyperforin. Several amiloride derivatives known to affect sodium conductance significantly enhance 3H-GABA and 3H-L-glutamate uptake and inhibit the uptake inhibition by hyperforin, while monensin or ouabain inhibition were not influenced. Selective concentrations of benzamil for amiloride sensitive Na+-channels and selective concentrations of 5'-ethylisopropylamiloride (EIPA) for the Na+-H+-exchangers both had an attenuating effect on the hyperforin inhibition of L-glutamate uptake, suggesting a possible role of amiloride sensitive Na+-channels and Na+-H+-exchangers in the mechanism of action of hyperforin.     

Anaesthetic properties of phencyclidine (PCP) and analogues may be related to their interaction with Na+ channels

Among other properties, phencyclidine (PCP) and analogues display anaesthetic and anticonvulsant properties. Interaction of PCP and some analogues with the voltage-sensitive Na+ channels have been investigated and compared with their interaction with the PCP receptor. PCP and TCP inhibit apparently in a competitive manner the veratridine stimulated 22Na+ synaptosomal uptake with Ki values of 8.6 and 12.7 microM, respectively, close to those obtained in the inhibition of [3H]BTX-B binding (IC50 = 4.1 and 3.8 microM, respectively). The specific [3H]TCP binding to synaptosomes in ionic near physiological conditions is inhibited by PCP and TCP with IC50 values of 1.25 and 0.29 microM, respectively. Other PCP derivatives (GK3 and GK4) and PCP-like drugs (ketamine and MK801) inhibit 22Na+ uptake in an order of potency (GK3 greater than GK4 greater than PCP greater than TCP greater than MK801 greater than ketamine) which is different from that obtained in the inhibition of [3H]TCP binding (MK801 greater than TCP greater than PCP greater than ketamine greater than GK4 greater than GK3). Ketamine inhibits the veratridine-stimulated Na+ uptake at a concentration where its anesthetic effect occurs. It was concluded that the interaction of these drugs with the Na+ channel may reflect their anaesthetic properties while the interaction with the PCP receptors may be mainly related to their anticonvulsant and ataxic properties.     

Antioxidant action of the antiarrhythmic drug mexiletine in brain membranes

Mexiletine is a class Ib antiarrhythmic drug used in the treatment of ventricular arrhythmias. The Na+ channel blocker mexiletine inhibits calcium influx in cells via decreasing reverse operation of the Na+-Ca2+ exchanger. Thus this drug is shown to protect the CNS white matter against anoxic/ischemic injury. The aim of our study was to investigate if this drug could act as an antioxidant drug as well. The antioxidant action of this drug was studied under different oxidant conditions in vitro, and thiobarbituric acid-reactive substances were measured to follow lipid peroxidation. Mexiletine inhibited iron-ascorbate-H2O2-induced lipid peroxidation in brain membranes, liver microsomes and phospholipid liposomes, being most effective in brain membranes. The inhibition was dose- and time-dependent. Mexiletine also inhibited copper-ascorbate-H2O2-induced lipid peroxidation but to a lesser extent. It is concluded that mexiletine has a dual effect toward oxidative injury in brain, both by inhibiting Na+-Ca2+ exchanger-dependent Ca2+ influx and by acting as an inhibitor of lipid peroxidation. However, as this drug is effective at millimolar concentrations, it should be considered less active than natural antioxidants that are effective at micromolar concentrations.     

Comparative radical scavenging and antidiabetic activities of methanolic extract and fractions from Achillea ligustica ALL

The yield of methanolic extract and total phenol and non polar content of flowered parts from Achillea ligustica ALL. are reported. GC-MS analysis of the non polar fraction showed that the triterpene moretenol was the major constituent (17.228%) followed by stigmast-6-en-3beta-ol, veridiflorol and beta-amyrin (7.524%, 5.078% 4.470%, respectively). The antioxidant activities of the methanolic extract and its fractions from A. ligustica were carried out using two different in vitro assays, 2,2-diphenyl-1-picrylhydrazyl (DPPH) test and lipid peroxidation of liposomes assay. Methanolic extract showed higher radical scavenging activity on DPPH (IC50 of 50 microg/ml). This activity is probably due to the phenolic fraction which shown an IC50 value of 22 microg/ml. A different result was obtained from the methanolic extract on the lipid peroxidation of liposomes (IC50 of 416 microg/ml). The alpha-amylase inhibition assay was applied to evaluate antidiabetic activity. The methanolic extract showed weak activity (28.18% at 1 mg/ml) while the n-hexane fraction showed 74.96% inhibition at 250 microg/ml.     

Sodium-dependence of the potency of inhibitors of the neuronal noradrenaline carrier in the rat vas deferens

Vasa deferentia obtained from reserpine-pretreated rats were incubated (monoamine oxidase and catechol-O-methyltransferase inhibited) in media containing various concentrations of 3H-(-)noradrenaline and Na+ and initial rates of the neuronal uptake of 3H-noradrenaline measured both in the absence and presence of uptake inhibitors after 1 min of incubation. When rates of uptake were determined at various 3H-noradrenaline (1.0-12.2 mumol/l) and two fixed Na+ concentrations (25 and 140 mmol/l), the inhibition of uptake produced by (+)amphetamine, (-)metaraminol, desipramine, nomifensine and cocaine was competitive with respect to 3H-noradrenaline at both Na+ concentrations. While the Ki for (+)amphetamine, (-)metaraminol desipramine and nomifensine increased when the Na+ concentration was lowered, that for cocaine decreased. When the Na+ concentration was varied (10-140 mmol/l) and the 3H-noradrenaline concentration held constant (1.2 mumol/l), (+)amphetamine, (-)metaraminol, nomifensine and desipramine acted as mixed-type inhibitors with respect to Na+, and the inhibition of uptake produced by these drugs was the more pronounced, the higher the Na+ concentration. On the other hand, cocaine was competitive with Na+ and the inhibition produced by this drug was the more pronounced, the lower the Na+ concentration. It is concluded that the inhibitors of neuronal uptake tested here act in dependence on the external Na+ concentration. Desipramine and nomifensine resemble alternative amine substrates in being more potent at high than at low Na+ concentrations. On the other hand, cocaine is more potent at low than at high Na+ concentrations.     

Failure of K+ to affect the potency of inhibitors of the neuronal noradrenaline carrier in the rat vas deferens

To examine whether K+ affects the potency of inhibitors of neuronal uptake, experiments were carried out in the rat vas deferens after pretreatment of the animals with reserpine and after inhibition of monoamine oxidase and catechol-O-methyltransferase. Initial rates of the neuronal uptake of 3H-noradrenaline and IC50 values for uptake inhibition by desipramine, cocaine and (-)metaraminol were determined in the presence of various concentrations of external K+ (5-45 mmol/l), both at 100 mmol/l Na+ and 50 mmol/l Na+. When measured at the 3H-noradrenaline concentration used to determine IC50 values (0.024 mumol/l), neuronal uptake was progressively impaired by increasing K+ concentrations at 50, but not at 100 mmol/l Na+. Neither at 100 mmol/l Na+ nor at 50 mmol/l Na+ was there any consistent, concentration-dependent effect of K+ on the IC50 values of desipramine, cocaine and (-)metaraminol. The analysis of the saturation kinetics of 3H-noradrenaline uptake (determined in the presence of 50 mmol/l Na+ at 5 mmol/l K+ or 45 mmol/l K+) showed that high K+ concentrations inhibit neuronal uptake by decreasing Vmax without any change in Km. The results indicate that K+ does not competitively interact with Na+ at sites on the noradrenaline carrier which mediate the transport-stimulating properties of Na+. Hence, the inhibition of neuronal uptake produced by high K+ concentrations is probably due to membrane depolarization which simply reduces Vmax.     

Pyrethroid insecticides and DDT modify alkaloid-dependent sodium channel activation and its enhancement by sea anemone toxin

The effects of saturating concentrations of DDT [1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane] and the pyrethroid insecticides cismethrin and deltamethrin on alkaloid-dependent activation of the voltage-sensitive sodium channel were studied using measurements of 22Na+ uptake into mouse brain synaptosomes. In survey experiments, these compounds enhanced sodium uptake stimulated by veratridine and batrachotoxin, but inhibited uptake stimulated by aconitine. Concentration response curves for aconitine run in the absence and presence of 10 microM cismethrin demonstrated that the inhibition was noncompetitive. This unanticipated inhibitory effect of insecticides on aconitine-dependent sodium uptake suggests a possible overlap or negative allosteric coupling between the binding sites for insecticides and aconitine and reveals unique characteristics of the action of aconitine that are not shared by veratridine and batrachotoxin. More detailed studies of the effects of insecticides on veratridine- or batrachotoxin-stimulated uptake found small insecticide-dependent increases in the potency of these activators. In addition to this effect, DDT and deltamethrin also enhanced maximal uptake stimulated by veratridine. Possible mechanisms underlying these effects of insecticides on alkaloid-dependent uptake are discussed in light of a qualitative model formulated from these results and previous biochemical and electrophysiological studies. Additional experiments were designed to assess the interactions of insecticides and toxin II of the sea anemone Anemonia sulcata (ATX II) as modifiers of alkaloid-dependent uptake. DDT and ATX II acted synergistically to increase uptake stimulated by veratridine. Moreover, DDT shifted the potency of ATX II for enhancing veratridine-dependent uptake to 5-fold lower concentrations. In contrast, DDT and subsaturating concentrations of ATX II acted independently in their enhancement of sodium channel activation by batrachotoxin. Mutually exclusive effects on veratridine-dependent uptake were observed when cismethrin was co-applied with ATX II. However, independent effects of cismethrin and ATX II were found with aconitine-modified channels, in that cismethrin was able to inhibit ATX II-enhanced aconitine-dependent sodium flux. Thus, the interactions between insecticides and ATX II as modifiers of alkaloid-dependent uptake are complex and depend on the insecticide-activator combination under study.     

Liposomes from hydrogenated egg yolk lecithin

Egg yolk lecithin is a lipid, frequently been used for the liposome preparation. Such liposomes, however, are sensitive to oxidation and relatively permeable to encapsulated substances. The catalytic hydrogenation of egg yolk lecithin is one possibility to modify the properties mentioned. The authors deal with preparation and characterization of hydrogenated egg yolk lecithin. Liposomes from native and hydrogenated egg yolk lecithin--also in combination with cholesterol--are compared. Liposomes with hydrogenated egg yolk lecithin as phospholipid component exhibit a significantly increased encapsulation capacity and an essentially improved stability. The permeation of electrolytes, carboxyfluorescein and of the cytostatic drug daunorubicin is studied.     

Interaction of pumiliotoxin B with an "alkaloid-binding domain" on the voltage-dependent sodium channel.

The alkaloid pumiliotoxin B (PTX-B) "activates" voltage-dependent sodium channels in synaptoneurosomes and neuroblastoma cells. It appears that PTX-B activates sodium channels by interacting with a site that is allosterically coupled to other sites on the sodium channel, namely two scorpion toxin sites and the brevetoxin site. In guinea pig cortical synaptoneurosomes, alpha-scorpion toxin, beta-scorpion toxin, and brevetoxin induce a dose-dependent potentiation of PTX-B-induced 22Na+ influx. The synergism with beta-scorpion toxin differentiates PTX-B from the alkaloid veratridine, which induces an activation of sodium channels that is not affected by beta-scorpion toxin. PTX-B does not inhibit [3H]batrachotoxinin-A benzoate ([3H]BTX-B) binding to the alkaloid site on sodium channels. On the other hand, aconitine, which activates sodium channels and inhibits [3H]BTX-B binding, induces a 22Na+ influx that, like PTX-B-induced 22Na+ influx, is potentiated by alpha-scorpion toxin, beta-scorpion toxin, and brevetoxin. Inhibition of [3H]BTX-B binding by aconitine is reduced in the presence of PTX-B. Both a type I pyrethroid (allethrin) and a type II pyrethroid (fenvalerate) inhibit PTX-B- and PTX-B/alpha-scorpion toxin-mediated 22Na+ influx. Allethrin and fenvalerate also inhibit aconitine-mediated 22Na+ flux but not BTX-mediated 22Na+ influx. It is proposed that on the sodium channel there is an "alkaloid-binding domain" at which alkaloids exert stimulatory actions. However, depending on the region on the domain to which the binding occurs, different allosteric interactions with other sites can be observed. PTX-B is proposed to interact with a part of the alkaloid-binding domain that is shared by aconitine but not by batrachotoxin or veratridine, whereas aconitine interacts with a part of the domain shared by PTX-B and by batrachotoxin/veratridine.     

Cellular Uptake of a Fluid-Phase Marker by Human Neutrophils from Solutions and Liposomes

In assessing the feasibility of utilizing the phagocytic activity of polymorphonuclear leukocytes (PMNs) for a more efficient drug delivery to the cell, the uptake of the fluid-phase marker lucifer yellow CH (LY) at 37°C by human PMNs from LY-containing liposomes was compared with that from solutions. In the presence of 10% autologous serum, the LY uptake at 37°C via phagocytosis of LY-containing liposomes was generally two orders of magnitude greater than that via pinocytosis for a given PMN source when the concentrations of PMN, LY, and total lipid were in the range of 10⁷ cells/ml, 0.5 mg/ml, and 50 µmol/ml, respectively. As expected, the LY uptake via phagocytosis was critically dependent upon the LY entrapment efficiency in the liposome preparation. Interestingly, little LY uptake was found when the serum was heat inactivated (56°C × 30 min). The serum effect was upon liposome vesicles rather than upon the cells. The present study demonstrates that the use of particular drug carriers for targeted drug delivery to PMNs and possibly to an extravascular site mediated by the cell infiltration is a viable approach.     

Interactions of cocaine and cocaine congeners with sodium channels

To assess the role that action on sodium channels may play in the physiological effects of cocaine and to obtain information on the structure-activity relationships of this action, cocaine, norcocaine, N-allynorcocaine, (+)-pseudococaine, (-)-pseudococaine, (+/-)-allococaine, (+/-)-allopseudococaine, ecgonine, ecgonine methyl ester, O-benzoylecgonine and atropine were tested for their effects on sodium channels. The method employed was a sodium channel specific equilibrium 22Na+ uptake assay with rat brain membrane homogenates. All of the compounds listed with the exception of the ecgonines were found to be single affinity competitive inhibitors of veratridine activation of sodium channels. Ecgonine showed no inhibition at concentrations as high as 10(-3) M while ecgonine methyl ester and O-benzoylecgonine showed inhibition only at very high concentrations. The order of inhibition potencies was found to (+)-pseudococaine congruent to norcocaine congruent to N-allynorcocaine greater than cocaine greater than (-)-pseudococaine congruent to (+/-)-allopseudococaine greater than (+/-)-allococaine greater than atropine greater than O-benzoylecgonine greater than ecgonine methyl ester greater than ecgonine. This ordering of potencies is in good agreement with published reports of the local anesthetic potencies of these agents.     

Inhibition by selenium compounds of catecholamine secretion due to inhibition of Ca2+ influx in cultured bovine adrenal chromaffin cells

Selenium is an essential trace metal element, whereas large doses of selenium exert adverse effects to the human body. We examined the effects of selenium compounds, sodium selenite (Na2SeO3) and sodium selenate (Na2SeO4), on catecholamine secretion from cultured bovine adrenal chromaffin cells. Treatment of chromaffin cells with sodium selenite for 72, 48, and 24 h caused decreases in protein and catecholamine contents, in association with cell damage, at concentrations over 30, 300, and 300 microM, respectively. The cells treated with subtoxic conditions (<100 microM, 48 h) of sodium selenite were used for further experiments. Sodium selenite treatment for 48 h inhibited carbachol (CCh)-induced catecholamine secretion in a concentration-dependent and non-competitive manner, while it did not affect high K+- and veratridine-induced catecholamine secretion. Sodium selenite (100 microM) did not affect CCh- and veratridine-induced 22Na+ influx, while the compound inhibited 45Ca2+ influx induced only by CCh, but not high K+ and veratridine. Sodium selenate even at higher concentrations (1000 microM) did not affect any stimulus-induced catecholamine secretion and 45Ca2+ influx. Thus, sodium selenite may specifically exert adverse effects, such as inhibition of physiological stimulus-induced catecholamine secretion from adrenal chromaffin cells due to inhibition of Ca2+ influx.     

Role of sodium ion influx in depolarization-induced neuronal cell death by high KCI or veratridine.

Intracellular Na+ concentration plays an important role in the regulation of cellular energy metabolism; i.e., increased intracellular Na+ concentration stimulates glucose utilization both in cultured neurons and astrocytes. Both high KCI and veratridine, which have been known to cause neuronal damage, elicit increased glucose utilization, presumably via increased intracellular Na+ concentration. In the present study, we examined the role of intracellular Na+ influx in the mechanisms of neuronal cell damage induced by high KCl or veratridine assayed by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) colorimetric method. Rat primary cultures of striatal neurons were incubated with high KCl (final concentrations: 25, 50 mM) or veratridine (0.1-100 microM) with or without various inhibitors. High KCl depolarizes cell membrane, thus, leading to Na+ influx through an activation of voltage-sensitive Na+ channels, while veratridine elicits Na+ influx by directly opening these channels. After 24-h incubation with elevated [K+]o or veratridine, glucose contents in the medium decreased significantly (approximately by 7 mM), but remained higher than 18 mM. High [K+]o reduced percent cell viability significantly (approximately 50% at 25 mM, approximately 40% at 50 mM [K+]o, P<0.01), but tetrodotoxin (100 nM) had no protective effect, indicating that Na+ influx was not essential to high K+ -induced cell death. DL-2-Amino-5-phosponovaleric acid (APV) (1 mM) completely blocked cell death induced by elevated [K+]o, while 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) (10 microM) did not. In contrast, veratridine (>10 microM) caused cell damage in a dose-dependent and tetrodotoxin-sensitive manner, but none of APV, CNQX, or bepridil (Na+ -Ca2+ exchanger blocker) had any protective effect. Nifedipine (50 approximately 100 microM), however, reduced percent cell damage induced by veratridine.     

Inhibition of nicotinic acetylcholine receptor-mediated secretion and synthesis of catecholamines by sea urchin toxin in cultured bovine adrenal medullary cells.

We previously reported the partial purification and characterization of a toxic substance (sea urchin toxin) isolated from the pedicellariae of the sea urchin Toxopneustes pileolus (Nakagawa and Kimura, Jpn J Pharmacol 32: 966-968, 1982). In the present study, we examined the effect of sea urchin toxin on catecholamine secretion and synthesis in cultured bovine adrenal medullary cells. Sea urchin toxin inhibited the secretion of catecholamines stimulated by carbachol and nicotine but not by veratridine or a high concentration of K+. The toxin inhibited the carbachol-evoked influx of 22Na+ and 45Ca2+ at concentrations similar to those for catecholamine secretion. The inhibition of catecholamine secretion by sea urchin toxin was not overcome by increasing the concentration of carbachol. Preincubation of cells with the toxin caused a time-dependent inhibition in the secretion stimulated by carbachol even when the toxin was removed from the incubation medium. The toxin suppressed catecholamine synthesis and tyrosine hydroxylase activity in carbachol-stimulated cells. In addition, sea urchin toxin inhibited [3H]phencyclidine binding to adrenal medullary cells whereas it did not alter cyclic GMP accumulation caused by muscarine. Further purified fractions from sea urchin toxin by concanavalin A affinity column chromatography also inhibited carbachol-evoked secretion of catecholamines. These results suggest that sea urchin toxin inhibits carbachol-enhanced secretion and synthesis of catecholamines by suppression of nicotinic acetylcholine receptor-mediated Na+ influx and subsequent Ca2+ influx in cultured adrenal medullary cells.     

Stability of liposomes on long term storage

The effect of the lipid composition of liposomes on their storage for up to one year under different environmental conditions has been examined using 5,6-carboxyfluorescein as a model drug. When cholesterol and/or alpha-tocopherol were included in the liposomes, a significantly greater amount of dye was retained. The presence of alpha-tocopherol decreased the breakdown of phosphatidylcholine to lysophosphatidylcholine and also reduced the level of peroxidation. Carboxyfluorescein retention was further enhanced when liposomes were stored at 4 degrees C or at room temperature (20 degrees C) in an O2-free atmosphere. Lysophosphatidylcholine formation also slowed when the liposomes were kept at 4 degrees C, or in an O2-free atmosphere. It is concluded that egg yolk lecithin liposomes may be stored for long periods at low temperature in an O2-free atmosphere or with added stabilizers such as cholesterol and alpha-tocopherol.