On the inhibition of muscle membrane chloride conductance by aromatic carboxylic acids.

25 aromatic carboxylic acids which are analogs of benzoic acid were tested in the rat diaphragm preparation for effects on chloride conductance (G(Cl)). Of the 25, 19 were shown to reduce membrane G(Cl) with little effect on other membrane parameters, although their apparent K(i) varied widely. This inhibition was reversible if exposure times were not prolonged. The most effective analog studied was anthracene-9-COOH (9-AC; K(i) = 1.1 x 10(-5) M). Active analogs produced concentration-dependent inhibition of a type consistent with interaction at a single site or group of sites having similar binding affinities, although a correlation could also be shown between lipophilicity and K(i). Structure-activity analysis indicated that hydrophobic ring substitution usually increased inhibitory activity while para polar substitutions reduced effectiveness. These compounds do not appear to inhibit G(Cl) by altering membrane surface charge and the inhibition produced is not voltage dependent. Qualitative characteristics of the I-V relationship for Cl(-) current are not altered. Conductance to all anions is not uniformly altered by these acids as would be expected from steric occlusion of a common channel. Concentrations of 9-AC reducing G(Cl) by more than 90 percent resulted in slight augmentation of G(I). The complete conductance sequence obtained at high levels of 9-AC was the reverse of that obtained under control conditions. Permeability sequences underwent progressive changes with increasing 9-AC concentration and ultimately inverted at high levels of the analog. Aromatic carboxylic acids appear to inhibit G(Cl) by binding to a specific intramembrane site and altering the selectivity sequence of the membrane anion channel.

Alteration of synaptosomal plasma membrane cholesterol content: membrane physical properties and cation transport proteins.

The level of nerve membrane cholesterol was altered by in vitro incubation of rat brain synaptosomal plasma membrane with liposomes having varying cholesterol contents. The normal plasma membrane cholesterol/phospholipid ratio of 0.3-0.4 (mol/mol) could be decreased by about one-half or increased more than 100%. Fluorescence polarization measurements were made using the probe 1,6-diphenyl-1,3,5-hexatriene. At temperatures below 35 percent C, lowering membrane cholesterol led to increased apparent microviscosity, while raising cholesterol content produced little change. However, at 45 percent C a continuous direct relationship existed between experimental membrane cholesterol/phospholipid ratio (ranging from 0.18 to 0.73) and apparent microviscosity. Under standard liposome-synaptosomal plasma membrane exchange conditions, 80% of the initial specific [(3)H]saxitoxin binding activity to the voltage-dependent sodium channel and at least 95% of the (Mg2+,K+)-p-nitrophenylphosphatase activity were preserved. Our results indicate that neither the characteristics of toxin binding nor the kinetics of this enzyme activity is dependent upon membrane cholesterol content.

Estimate of the molecular weight of the sarcolemmal sodium channel using H2O-D2O centrifugation.

The sodium channel saxitoxin binding component from rat sarcolemma was solubilized with NP-40 and centrifuged on sucrose gradients constructed in either D2O or H2O. When compared with a series of standard proteins the sedimentation behavior of the solubilized channel complex changed from an apparent S20,w of 9.1 in H2O to 6.1 in D2O. From these observations, a true partial specific volume of 0.83 ml/g was calculated for the complex. A Stokes radius of 8.6 nm was estimated from Sepharose 6-B chromatography in NP-40. The calculated protein molecular weight of the lipid-protein-detergent complex based on these data is 560,000. The complex contains about 56% protein, and the calculated molecular weight of this component is 314,000 if a v for the protein of 0.74 ml/g is assumed.

Functional reconstitution of the purified sodium channel protein from rat sarcolemma.

The purified saxitoxin (STX) binding component of the rat sarcolemmal sodium channel (SBC) has been reconstituted into phospholipid vesicles. The reconstituted SBC displays the pharmacological properties and the ability to control sodium fluxes expected of a functional sodium channel. Batrachotoxin (BTX) increases 22Na+ influx into reconstituted SBC vesicles by greater than 100% over control at early time points. The BTX-stimulated 22Na+ influx is specifically and quantitatively blocked by STX. Veratridine and aconitine also stimulate Na+-flux--although less effectively than BTX--in the order: BTX greater than veratridine greater than aconitine. The logarithmic dose--response curves for BTX and veratridine are sigmoidal with a K0.5 of 1.5 microM and 35 microM, respectively. Vesicles containing the reconstituted SBC demonstrate 3H-labeled STX binding to a single class of high affinity sites witha Kd of 5--7 nM at 0 degrees C; the thermal stability of the STX receptor is markedly enhanced by reconstitution. Our results confirm that the purified STX binding component from rat sarcolemma constitutes the sodium channel itself and contains at least those components sufficient for channel activation, transmembrane ion movement, and inhibition by STX.

Purification and functional reconstitution of the voltage-sensitive sodium channel from rabbit T-tubular membranes.

The voltage-sensitive sodium channel has been purified from rabbit T-tubular membranes and reconstituted into defined phospholipid vesicles. Membranes enriched in T-tubular elements (specific [3H]nitrendipine binding = 41 +/- 9 pmol/mg of protein, n = 7) were isolated from fast skeletal muscle. After solubilization with Nonidet P-40, the sodium channel protein was purified to greater than 95% of theoretical homogeneity based on the specific activity of [3H]saxitoxin binding. Two subunits of Mr approximately 260,000 and 38,000 were found; these bands co-distributed with the peak of [3H]saxitoxin binding on sucrose gradients. The purified protein was reconstituted into egg phosphatidylcholine vesicles and retained the ability to gate specific 22Na+ influx in response to activation by batrachotoxin or veratridine. All activated fluxes were blocked by saxitoxin and tetrodotoxin. On sucrose gradients, the distribution of protein capable of functional channel activity paralleled the distribution of specific [3H]saxitoxin binding and of the Mr 260,000 and 38,000 components. The cation selectivity for the reconstituted, batrachotoxin-activated channel was Na+ greater than K+ greater than Rb+ greater than Cs+, with flux ratios of 1:0.13:0.02:0.008. Nine of 25 monoclonal antibodies raised against the rat sarcolemmal sodium channel cross-reacted with the rabbit T-tubular sodium channel in a solid-phase radioimmunoassay. Six of these antibodies showed specific binding to immunoblot transfers of T-tubular membrane proteins. Each labeled a single band at Mr approximately 260,000 corresponding in mobility to the large subunit of the sodium channel.