Barbiturates inhibit intracellular Ca2+ rise induced by thrombin in rat platelets

The effects of a number of barbiturates (anesthetic as well as anticonvulsant) on thrombin-induced calcium mobilization were tested in rat platelets using the fluorescent Ca2+ probe Fura-2. All drugs, except barbituric acid and Na-barbital, inhibited the thrombin-induced intracellular Ca2+ rise. Both the uptake of extracellular Ca2+ and the release of calcium from intracellular organelles were affected but influx was inhibited more strongly and at lower concentrations of the drugs (e.g. IC50 of thiopental was 0.83 mM for influx and 1.2 mM for intracellular release). Inhibitory potencies of the various barbiturates were markedly different. Thiopental was the most and barbital the least potent inhibitor. The order of inhibitory potency of the drugs appeared generally to follow their lipid solubility and the order of their hypnotic efficiency, with hexobarbital as the most conspicuous exception. Therefore, barbiturate treatment of cells perturbs agonist-induced calcium mobilization. This effect may be partially linked to their previously reported inhibitory action on two kinases, protein kinase C and phosphatidylinositol 4-phosphate kinase [1, 2].     

Inhibition of Ca2+-transport ATPase from synaptosomal vesicles by flavonoids

The inhibitory action of the flavonoid quercetin has been examined on the calcium-transport ATPase of synaptosomal vesicles and compared to that of two other flavonoids, morin and rutin. We have found that while quercetin caused a 50% inhibition of calcium transport at a concentration of 15 microM, morin and rutin had similar effects at concentrations of about 200 microM. A similar order of potency was observed also for ATP hydrolysis, though at higher concentrations. Quercetin also strongly inhibited phosphorylation of membrane proteins by ATP in synaptosomal vesicles. Rutin and morin had an almost negligible effect on membrane protein phosphorylation. The order of inhibitory potency of the flavonoids on the Ca2+-transport ATPase from synaptosomal vesicles: quercetin greater than morin greater than rutin, could be linked to their possible solubility in the membrane lipid phase since: (1) it paralleled their partitioning between a mixture of oil and water; (2) it paralleled their uptake from the reaction mixture by synaptosomal vesicles and phosphatidylcholine liposomes; (3) they had almost equal potency as inhibitors of the water soluble system of histone phosphorylation by protein kinase.     

Inhibition of Ca2+-transport ATPase from synaptosomal vesicles by flavonoids

The inhibitory action of the flavonoid quercetin has been examined on the calcium-transport ATPase of synaptosomal vesicles and compared to that of two other flavonoids, morin and rutin. We have found that while quercetin caused a 50% inhibition of calcium transport at a concentration of 15 μM, morin and rutin had similar effects at concentrations of about 200 μM. A similar order of potency was observed also for ATP hydrolysis, though at higher concentrations. Quercetin also strongly inhibited phosphorylation of membrane proteins by ATP in synaptosomal vesicles. Rutin and morin had an almost negligible effect on membrane protein phosphorylation. The order of inhibitory potency of the flavonoids on the Ca²⁺-transport ATPase from synaptosomal vesicles: quercetin > morin > rutin, could be linked to their possible solubility in the membrane lipid phase since: (1) it paralleled their partitioning between a mixture of oil and water; (2) it paralleled their uptake from the reaction mixture by synaptosomal vesicles and phosphatidylcholine liposomes; (3) they had almost equal potency as inhibitors of the water soluble system of histone phosphorylation by protein kinase.     

Inhibition of Ca-transport ATPase from synaptosomal vesicles by flavonoids

The inhibitory action of the flavonoid quercetin has been examined on the calcium-transport ATPase of synaptosomal vesicles and compared to that of two other flavonoids, morin and rutin. We have found that while quercetin caused a 50% inhibition of calcium transport at a concentration of 15 μM, morin and rutin had similar effects at concentrations of about 200 μM. A similar order of potency was observed also for ATP hydrolysis, though at higher concentrations. Quercetin also strongly inhibited phosphorylation of membrane proteins by ATP in synaptosomal vesicles. Rutin and morin had an almost negligible effect on membrane protein phosphorylation. The order of inhibitory potency of the flavonoids on the Ca²⁺-transport ATPase from synaptosomal vesicles: quercetin > morin > rutin, could be linked to their possible solubility in the membrane lipid phase since: (1) it paralleled their partitioning between a mixture of oil and water; (2) it paralleled their uptake from the reaction mixture by synaptosomal vesicles and phosphatidylcholine liposomes; (3) they had almost equal potency as inhibitors of the water soluble system of histone phosphorylation by protein kinase.     

Alcohol's effects on lipid bilayer properties

Alcohols are known modulators of lipid bilayer properties. Their biological effects have long been attributed to their bilayer-modifying effects, but alcohols can also alter protein function through direct protein interactions. This raises the question: Do alcohol''s biological actions result predominantly from direct protein-alcohol interactions or from general changes in the membrane properties? The efficacy of alcohols of various chain lengths tends to exhibit a so-called cutoff effect (i.e., increasing potency with increased chain length, which that eventually levels off). The cutoff varies depending on the assay, and numerous mechanisms have been proposed such as: limited size of the alcohol-protein interaction site, limited alcohol solubility, and a chain-length-dependent lipid bilayer-alcohol interaction. To address these issues, we determined the bilayer-modifying potency of 27 aliphatic alcohols using a gramicidin-based fluorescence assay. All of the alcohols tested (with chain lengths of 1–16 carbons) alter the bilayer properties, as sensed by a bilayer-spanning channel. The bilayer-modifying potency of the short-chain alcohols scales linearly with their bilayer partitioning; the potency tapers off at higher chain lengths, and eventually changes sign for the longest-chain alcohols, demonstrating an alcohol cutoff effect in a system that has no alcohol-binding pocket.     

Surface potential changes in lipid monolayers and the 'cut-off' in anaesthetic effects of N-alkanols

The effects of 0.09 saturated solutions of the n-alkanols n-hexanol to n-tridecanol on the surface (compensation) potential of lipid monolayers have been examined. Actions on monolayers spread from pure egg phosphatidylcholine have been compared with effects on a system containing 2:1 mole ratio of egg phosphatidylcholine and cholesterol. The mean compensation potential for the pure phospholipid system was 475 +/- 9 mV; addition of cholesterol increased the potential to 503 +/- 10 mV. All n-alkanols tested reduced the surface potential in both systems. The reduction was larger in the pure phospholipid system but the difference in effect between lipid systems declined as the n-alkanol chainlength increased, becoming negligible by n-tridecanol. These results are considered in relation to the 'cut-off' in biological activity of n-alkanols around n-tridecanol.     

Alcohol action on membrane ion channels gated by extracellular ATP (P2X receptors).

Extracellular adenosine 5'-triphosphate (ATP) has been reported to produce excitatory actions in the nervous system, such as excitatory postsynaptic potentials or currents in both central and peripheral neurons, via activation of a class of ATP-gated membrane ion channels designated P2X receptors. This article reviews studies of alcohol effects on these receptor-channels. Ethanol has been found to inhibit ATP-gated ion channel function by shifting the agonist concentration-response curve to the right in a parallel manner, increasing the EC50 without affecting Emax of this curve. To distinguish whether this inhibition involves competitive antagonism of agonist action or a decrease in the affinity of the agonist binding site, the kinetics of activation and deactivation of agonist-activated current were studied. Ethanol was found to decrease the time-constant of deactivation of ATP-gated ion channels without affecting the time-constant of activation, indicating that ethanol inhibits the function of these receptors by an allosteric decrease in the affinity of the agonist binding site. The inhibition of ATP-gated ion channel function by a number of alcohols was found to exhibit a distinct cutoff effect that appeared to be related to the molecular volume of the alcohols. For alcohols with a molecular volume of < or = 42.2 ml/mol, potency for inhibiting ATP-activated current was correlated with lipid solubility (order of potency: 1-propanol = trifluoroethanol > monochloroethanol > ethanol > methanol). However, despite increased lipid solubility, alcohols with a molecular volume of > or = 46.1 ml/mol (1-butanol, 1-pentanol, trichloroethanol, and dichloroethanol) were without effect on the ATP-activated current. This cutoff effect has been interpreted as evidence that alcohols inhibit the function of ATP-gated ion channels by interacting with a hydrophobic pocket of circumscribed dimensions on the receptor protein. To evaluate the localization of this presumed alcohol binding site, the effect of the intracellular application of ethanol was studied on the inhibition of ATP-activated current by extracellularly applied ethanol. The intracellular application of 100 mM ethanol did not affect the inhibition of current by 100 mM extracellular ethanol, suggesting that the alcohol inhibition of ATP-gated ion channel function involves the extracellular domain of the receptor. Finally, recent studies suggest that the alcohol sensitivity of ATP-gated channels may be regulated by physiological mechanisms.     

Discovery of glycine hydrazide pore-occluding CFTR inhibitors: mechanism, structure-activity analysis, and in vivo efficacy

The cystic fibrosis transmembrane conductance regulator (CFTR) protein is a cAMP-regulated epithelial Cl- channel that, when defective, causes cystic fibrosis. Screening of a collection of 100,000 diverse small molecules revealed four novel chemical classes of CFTR inhibitors with Ki < 10 microM, one of which (glycine hydrazides) had many active structural analogues. Analysis of a series of synthesized glycine hydrazide analogues revealed maximal inhibitory potency for N-(2-naphthalenyl) and 3,5-dibromo-2,4-dihydroxyphenyl substituents. The compound N-(2-naphthalenyl)-[(3,5-dibromo-2,4-dihydroxyphenyl)methylene]glycine hydrazide (GlyH-101) reversibly inhibited CFTR Cl- conductance in <1 min. Whole-cell current measurements revealed voltage-dependent CFTR block by GlyH-101 with strong inward rectification, producing an increase in apparent inhibitory constant Ki from 1.4 microM at +60 mV to 5.6 microM at -60 mV. Apparent potency was reduced by lowering extracellular Cl- concentration. Patch-clamp experiments indicated fast channel closures within bursts of channel openings, reducing mean channel open time from 264 to 13 ms (-60 mV holding potential, 5 microM GlyH-101). GlyH-101 inhibitory potency was independent of pH from 6.5-8.0, where it exists predominantly as a monovalent anion with solubility approximately 1 mM in water. Topical GlyH-101 (10 microM) in mice rapidly and reversibly inhibited forskolin-induced hyperpolarization in nasal potential differences. In a closed-loop model of cholera, intraluminal GlyH-101 (2.5 microg) reduced by approximately 80% cholera toxin-induced intestinal fluid secretion. Compared with the thiazolidinone CFTR inhibitor CFTR(inh)-172, GlyH-101 has substantially greater water solubility and rapidity of action, and a novel inhibition mechanism involving occlusion near the external pore entrance. Glycine hydrazides may be useful as probes of CFTR pore structure, in creating animal models of CF, and as antidiarrheals in enterotoxic-mediated secretory diarrheas.     

Ganglioside-dependent factor inhibiting lipid peroxidation in synaptosomal membranes

The inhibitory effect of exogenous monosialoganglioside GM1 on lipid peroxidation was studied in synaptosomal membranes from rat brain. When this effect was studied over a wide GM1 concentration range, the biphasic kinetics was observed, the highest per cent of inhibition (70%) was found at GM1 concentration of 10(-9)- 10(-8) M. In liposomes made from lipids isolated from rat synaptosomal membranes the inhibition of lipid peroxidation by exogenous GM1 was much less pronounced (25% at maximum) it reached the saturation at ganglioside concentration of 10(-8)-10(-6) M. The thermal denaturation (90 degrees C), storage at 0 degrees C, addition of polymyxin B result in considerable decrease of inhibitory effect of GM1 on lipid peroxidation in synaptosomal membranes. On the contrary phorbol-12-myristate-13-acetate (10(-6)M) or Ca2+ (2.10(-3)M) inhibit lipid peroxidation in synaptosomal membranes, the presence of exogenous GM1 in incubation medium having additional inhibitory effect. Possible mechanisms of ganglioside participation in regulation of functional activity of excitatory membranes are discussed.     

Effect of short-chain primary alcohols on fluidity and activity of sarcoplasmic reticulum membranes

Intramolecular excimer formation with the fluorescent probe 1,3-di(1-pyrenyl)propane, differential scanning calorimetry, and X-ray diffraction were used to assess the effect of ethanol, 1-butanol, and 1-hexanol on the bilayer organization in model membranes, sarcoplasmic reticulum (SR) lipids and native SR membranes. These alcohols have fluidizing effects on membranes and lower the main transition temperature of dimyristoylphosphatidylcholine (DMPC), but only 1-hexanol alters the cooperativity of the phase transition and significantly increases the thickness of DMPC bilayers. The interaction of the three alcohols with the SR Ca2+ pump was also investigated. Hydrolysis of ATP and coupled Ca2+ uptake are differently sensitive to the three alcohols. Whereas ethanol and 1-butanol inhibited the Ca2+ uptake, 1-hexanol stimulated it. Nevertheless, the energetic efficiency of the pump (Ca2+/ATP) is not significantly affected by ethanol or 1-hexanol, but uncoupling was observed with 1-butanol at high concentrations. The different effects of alcohols on the activity of SR membranes rule out an unitary mechanism of action on the basis of fluidity changes induced in the lipid bilayer. Depending on the chain length, the alcohols interact with the SR membranes in different domains, perturbing differently the Ca2+-pump activity.     

The nature of the hydrophobic n-alkanol binding site within the C1 domains of protein kinase Calpha

The activator-binding sites within the C1 domains of protein kinase C (PKC) are also able to bind alcohols and anesthetics. In this study, the nature of the interaction of these agents with the hydrophobic region within the C1 domains was investigated and a structure-activity relationship for the alcohol effects was obtained. The effects of a series of n-alkanols on PKCalpha activity, determined using an in vitro assay system that lacked lipids, were found to be a nonlinear function of the chain length. In the absence of phorbol ester or diacylglycerol, 1-octanol potently activated PKCalpha in a concentration-dependent manner, while 1-heptanol was completely without effect, despite differing by one methylene unit. The minimal structural requirement for the activating effect corresponded to R-CH(OH)-(CH(2))(n)-CH(3), where R = H or an alkyl group and n >or= 6. Consistent with this, 2-octanol, for which n = 5, was without effect on the activity, even though this alcohol is only marginally less hydrophobic than 1-octanol, whereas 2-nonanol, for which n = 6, was able to produce activity. Importantly, it was found that PKCalpha was activated to a greater extent by R-2-nonanol than by the S enantiomer. The potentiation of phorbol ester-induced, membrane-associated PKCalpha activity by long-chain n-alkanols reported previously (Slater, S. J., Kelly, M. B., Larkin, J. D., Ho, C, Mazurek, A, Taddeo, F. J., Yeager, M. D., Stubbs, C. D. (1997) J. Biol. Chem. 272, 6167-6173), was also found here for nonmembrane associated PKC, indicating that this effect is an intrinsic property of the enzyme rather than a result of membrane perturbation. Overall, the results suggest that the alcohol-binding sites within the C1 domains of PKCalpha contain spatially distinct hydrophilic and hydrophobic regions that impose a high degree of structural specificity on the interactions of alcohols and other anesthetic compounds, as well as diacylglycerols and phorbol esters.     

Effect of silybin on phorbol myristate actetate-induced protein kinase C translocation, NADPH oxidase activity and apoptosis in human neutrophils.

Mechanism of the action of silybin (1) and its derivatives (2-4), possessing different lipid solubility in PMA-stimulated neutrophils was evaluated. Silybin (1) inhibited the calcium, phosphatidylserine- and diacylglycerol-dependent protein kinase C translocation and the NADPH oxidase activity in PMA-stimulated neutrophils and resulted in decreased apoptosis. Furthermore, silybin (1) inhibited xanthine oxidase activity and hem-mediated oxidative degradation of low-density lipoprotein, as well. Its derivatives (2-4), possessing different lipid-solubility, affected all the studied parameters. The lipid solubility of silybin (1) was enhanced by methylation (5'7'4'trimethylsilybin: 2), whereas a decrease in lipid-solubility by acetylation of compound 2 (5',7,'4"-trimethylsilybin-acetate: 3) or all the hydroxyl groups of silybin (peracetyl-silybin: 4) attenuated the antioxidant capacity by decreasing the inhibition in PKC translocation and NADPH oxidase activation. All the derivatives of silybin (2-4) showed no inhibition in cell free systems; e.g. did not alter the xanthine oxidase activity and the hem-mediated oxidative degradation of LDL. In conclusion, the antioxidant activity of (1) might be due to its ability to inhibit PKC translocation and NADPH oxidase activation in PMA-stimulated neutrophils. The increase of lipid solubility of silybin (1) supports its penetration through cell membrane and enhances its inhibitory effects. This structural modification of (1) might have pharmacological consequences.     

Long-acting oxytocin antagonists: effects of 2-D-stereoisomer substitution on antagonistic potency and duration of action

Recently we reported the discovery of a series of 2-O-alkyltyrosine- (or 2-p-alkylphenylalanine), 4-threonine-, and 8-ornithine-substituted analogs of [1-penicillamine]oxytocin [( Pen1]OT) which possess prolonged anti-OT activity. In this study, we attempt to improve the potency and the duration of action of this series of OT antagonists by exploring the effects of D-stereoisomer substitution in the 2 position. We compare the in vitro anti-OT potency, expressed in pA2 values, and the duration of in vivo inhibitory action, expressed in recovery t1/2, of [Pen1]OT, [Pen1,Orn8]OT, [Pen1,Thr4]OT, [Pen1,Tyr(OMe)2,Thr4, Orn8]OT, [Pen1, Tyr(OEt)2,Thr4,Orn8]OT, [Pen1,D-Tyr(OEt)2,Thr4,Orn8]OT, [Pen1,Phe2,Thr4]OT, [Pen1,Phe(Me)2,Thr4,Orn8]OT, [Pen1,D-Phe(Me)2,Thr4,Orn8]OT, [Pen1,Phe(Et)2,Thr4,Orn8]OT, and [Pen1,D-Phe(Et)2,Thr4,Orn8]OT. The results show that modifications of the amino acid in position 2 by alkylation of the aromatic ring and use of D-stereoisomerism produce nonparallel effects on the in vitro potency and duration of action of OT antagonists. Time-action curve determinations show that long-acting OT antagonists exhibit delayed peak inhibitory action. Long action is not coupled with high potency in all cases. This dissociation between potency and duration of action gives support to our hypothesis that the potency and duration of action of these peptides may each have different conformational structure requirements.     

The pH-dependent rate of action of local anesthetics on the node of Ranvier

Local anesthetic solutions were applied suddenly to the outside of single myelinated nerve fibers to measure the time course of development of block of sodium channels. Sodium currents were measured under voltage clamp with test pulses applied several times per second during the solution change. The rate of block was studied by using drugs of different lipid solubility and of different charge type, and the external pH was varied from pH 8.3 to pH 6 to change the degree of ionization of the amine compounds. At pH 8.3 the half-time of action of amine anesthetics such as lidocaine, procaine, tetracaine, and others was always less than 2 s and usually less than 1 s. Lowering the pH to 6.0 decreased the apparent potency and slowed the rate of action of these drugs. The rate of action of neutral benzocaine was fast (1 s) and pH independent. The rate of action of cationic quaternary QX-572 was slow (greater than 200 s) and also pH independent. Other quaternary anesthetic derivatives showed no action when applied outside. The result is that neutral drug forms act much more rapidly than charged ones, suggesting that externally applied local anesthetics must cross a hydrophobic barrier to reach their receptor. A model representing diffusion of drug into the nerve fiber gives reasonable time courses of action and reasonable membrane permeability coefficients on the assumption that the hydrophobic barrier is the nodal membrane. Arguments are given that there may be a need for reinterpretation of many published experiments on the location of the anesthetic receptor and on which charge form of the drug is active to take into account the effects of unstirred layers, high membrane permeability, and high lipid solubility.     

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.     

Channel gating of the glycine receptor changes accessibility to residues implicated in receptor potentiation by alcohols and anesthetics

The glycine receptor is a target for both alcohols and anesthetics, and certain amino acids in the alpha1 subunit transmembrane segments (TM) are critical for drug effects. Introducing larger amino acids at these positions increases the potency of glycine, suggesting that introducing larger residues, or drug molecules, into the drug-binding cavity facilitates channel opening. A possible mechanism for these actions is that the volume of the cavity expands and contracts during channel opening and closing. To investigate this hypothesis, mutations for amino acids in TM1 (I229C) and TM2 (G256C, T259C, V260C, M263C, T264C, S267C, S270C) and TM3 (A288C) were individually expressed in Xenopus laevis oocytes. The ability of sulfhydryl-specific alkyl methanethiosulfonate (MTS) compounds of different lengths to covalently react with introduced cysteines in both the closed and open states of the receptor was determined. S267C was accessible to short chain (C3-C8) MTS in both open and closed states, but was only accessible to longer chain (C10-C16) MTS compounds in the open state. Reaction with S267C was faster in the open state. I229C and A288C showed state-dependent reaction with MTS only in the presence of agonist. M263C and S270C were also accessible to MTS labeling. Mutated residues more intracellular than M263C did not react, indicating a floor of the cavity. These data demonstrate that the conformational changes accompanying channel gating increase accessibility to amino acids critical for drug action in TM1, TM2, and TM3, which may provide a mechanism by which alcohols and anesthetics can act on glycine (and likely other) receptors.     

Frequency-dependent blockade of T-type Ca2+ current by efonidipine in cardiomyocytes

Efonidipine is a dihydropyridine Ca2+ antagonist with inhibitory effects on both L-type and T-type Ca2+ channels and potent bradycardiac activity especially in patients with high heart rate. In the present study, we examined the frequency dependence of efonidipine action on the T-type Ca2+ channel in isolated guinea-pig ventricular myocytes. The potency of efonidipine to inhibit the T-type Ca2+ current was higher under higher stimulation frequencies. The IC50 values were 1.3 x 10(-8), 2.0 x 10(-6) and 6.3 x 10(-6) M under stimulation frequencies of 1, 0.2 and 0.05 Hz, respectively. The reduction of T-type Ca2+ current amplitude was not accompanied by change in the time course of current decay. Efonidipine (10 microM) inhibited T-type Ca2+ current elicited by depolarization from holding potentials ranging from -90 to -30 mV by about 30%; the voltage-dependence of steady-state inactivation was not changed by the drug. Efonidipine slowed the recovery from inactivation following an inactivating prepulse. In conclusion, efonidipine was shown to have frequency-dependent inhibitory effects on the T-type Ca2+ channel, which could be explained by slow dissociation of the drug from the inactivated state of the channel.     

The actions of intermediate and long-chain n-alkanols on unitary NMDA currents in hippocampal neurons.

The actions of the n-alkanols butanol, pentanol, and octanol on unitary currents passing through N-methyl-D-aspartate (NMDA) ion channels have been studied in cultured CA1 hippocampal neurons. The cell-attached patch clamp method, with L-homocysteic acid included in the patch pipette, was used to record single channel NMDA currents at the cell resting potential or for hyperpolarizing patch potentials. With the n-alkanols added to the bath solution, the mean open times for the NMDA channel were diminished and the channel conductance was unchanged. A decrease in mean open time to about 70% of control value was found with butanol (3 mM), pentanol (1 mM), and octanol (0.02 mM). In addition the n-alkanols had small effects to decrease the frequency of channel openings and to increase the amplitude of the unitary currents. The effects of the alcohols on intracellular calcium levels, during NMDA applications, were also measured using the fluorescent dye FURA II.     

Effects of a series of alcohols on the binding of a fluorescent dye to erythrocyte membranes.

1. The effects of a series of aliphatic alcohols (methanol to octanol) on membrane proteins of erythrocytes were studied by monitoring the flueorescence of a dye (1-anilino-8-naphthalenesulfonic acid (ANS)) that adsorbs to erythrocyte ghost membranes. Low concentrations of all the alcohols reduced the ANS fluorescence of the membrane-ANS suspensions; lent to those which protect against hypotonic hemolysis on intact erythrocytes; higher concentrations markedly increased the fluorescence. Ethanol and methanol decreased ANS fluorescence at all concentrations. 2. Lytic concentrations of saponin did not increase ANS fluorescence and did not modify the membrane action of the alcohols. 3. None of these effects were observed in liposomes prepared from lipid extracts of the erythrocyte membrane. 4. Since the apparent dissociation constant for the ANS-membrane interaction was unchanged in the presence of the alcohols, it was assumed that the fluorescence changes anesthetic concentration of the alcohols alter the conformation of membrane proteins, as indicated by the decreased number of ANS binding sites.     

Antioxidant action of ubiquinol homologues with different isoprenoid chain length in biomembranes

Ubiquinones (CoQn) are intrinsic lipid components of many membranes. Besides their role in electron-transfer reactions they may act as free radical scavengers, yet their antioxidant function has received relatively little study. The efficiency of ubiquinols of varying isoprenoid chain length (from Q0 to Q10) in preventing (Fe2+ + ascorbate)-dependent or (Fe2+ + NADPH)-dependent lipid peroxidation was investigated in rat liver microsomes and brain synaptosomes and mitochondria. Ubiquinols, the reduced forms of CoQn, possess much greater antioxidant activity than the oxidized ubiquinone forms. In homogenous solution the radical scavenging activity of ubiquinol homologues does not depend on the length of their isoprenoid chain. However in membranes ubiquinols with short isoprenoid chains (Q1-Q4) are much more potent inhibitors of lipid peroxidation than the longer chain homologues (Q5-Q10). It is found that: i) the inhibitory action, that is, antioxidant efficiency of short-chain ubiquinols decreases in order Q1 greater than Q2 greater than Q3 greater than Q4; ii) the antioxidant efficiency of long-chain ubiquinols is only slightly dependent on their concentrations in the order Q5 greater than Q6 greater than Q7 greater than Q8 greater than Q9 greater than Q10 and iii) the antioxidant efficiency of Q0 is markedly less than that of other homologues. Interaction of ubiquinols with oxygen radicals was followed by their effects on luminol-activated chemiluminescence. Ubiquinols Q1-Q4 at 0.1 mM completely inhibit the luminol-activated NADPH-dependent chemiluminescent response of microsomes, while homologues Q6-Q10 exert no effect. In contrast to ubiquinol Q10 (ubiquinone Q10) ubiquinone Q1 synergistically enhances NADPH-dependent regeneration of endogenous vitamin E in microsomes thus providing for higher antioxidant protection against lipid peroxidation. The differences in the antioxidant potency of ubiquinols in membranes are suggested to result from differences in partitioning into membranes, intramembrane mobility and non-uniform distribution of ubiquinols resulting in differing efficiency of interaction with oxygen and lipid radicals as well as different efficiency of ubiquinols in regeneration of endogenous vitamin E.