Large-scale purification of the acetylcholine-receptor protein in its membrane-bound and detergent-extracted forms from Torpedo marmorata electric organ

Acetylcholine receptor site density affects the rising phase of miniature endplate currents

The relationship between acetylcholine receptor (AcChoR) site density (sigma) and the rising phase of the miniature endplate current was determined in esterase-inactivated lizard intercostal neuromuscular junctions. The currents were recorded by using a voltage clamp. The receptor site density was determined by electron microscope autoradiography after labeling with 125I-labeled alpha-bungarotoxin in normal endplates and in those partially inactivated with nonradioactive alpha-bungarotoxin. We found that as sigma is decreased the rise time in increased and the amplitude is decreased. These results are compatible with a previously stated "saturating disk" model, which suggests that a quantum of acetylcholine (AcCho) acts on a small postsynaptic area at saturating concentration. We conclude that in the normal neuromuscular junction the most likely number of AcCho molecules needed to open an ion channel is 2, and that the 20--80% rise time of < 100 musec is influenced both by the sigma-dependent factors such as diffusion and binding of AcCho to AcChoR and by the sigma-independent time delays such as the conformation change time to open the ion channels. From our data we calculate the lower limits to the forward rate constant of AcCho binding to AcChoR greater than or equal to 3 X 10(7) M-1 sec-1 and the diffusion constant for AcCho in the cleft greater than or equal to 4 X 10(-6) cm2 sec-1.

Phosphorylation in vitro of membrane fragments from Torpedo marmorata electric organ. Effect on membrane solubilization by detergents

Acetylcholine receptor-rich membrane fragments purified from Torpedo marmorata electric organ were phosphorylated, in vitro, by endogenous protein kinases. The 40 000-Mr chain, which carries the acetylcholine receptor site, was never labelled; on the other hand, protein bands of apparent molecular weights 43 000, 50 000 and 66 000, which are present in the acetylcholine receptor-rich membranes, were repeatedly phosphorylated. The phosphorylation of these three peptides required the presence of divalent cations, such as Mg2+ or Mn2+, and was, in addition, stimulated up to 3--5-fold by K+. The effect of Na+ ions appeared less specific since Na+ ions reduced the labelling of all the polypeptides susceptible to phosphorylation. Cholinergic agonists and antagonists, local anesthetics and cyclic nucleotides did not affect the phosphorylation of the receptor-rich membranes. Phosphorylation selectively modified the solubilization of several polypeptides by nondenaturing detergents: phosphorylated 43 000-Mr, 50 000-Mr and 66 000-Mr polypeptides were solubilized at lower concentrations of detergent than their non-phosphorylated counterparts. Two-dimensional gels revealed the existence of a charge heterogeneity of the 40 000-Mr and 43 000-Mr chains. The microheterogeneity of the 43 000-Mr chain, but not that of the 40 000-Mr chain, might result from a selective phosphorylation of this particular chain.

Purification of Torpedo californica post-synaptic membranes and fractionation of their constituent proteins

A rapid methof for preparation of membrane fractions highly enriched in nicotinic acetylcholine receptor from Torpedo californica electroplax is described. The major step in this purification involves sucrose-density-gradient centrifugation in a reorienting rotor. Further purification of these membranes can be achieved by selective extraction of proteins by use of alkaline pH or by treatment with solutions of lithium di-idosalicylate. The alkali-treated membranes retain functional characteristics of the untreated membranes and in addition contain essentially only the four polypeptides (mol.wts. 40000, 50000, 60000 and 65000) characteristic of the receptor purified by affinity chromatography. Dissolution of the purified membranes or of the alkali-treated purified membranes in sodium cholate solution followed by sucrose-density-gradient centrifugation in the same detergent solution yields solubilized receptor preparations comparable with the most highly purified protein obtained by affinity-chromatographic procedures.

Endogenous and exogenous proteolysis of the acetylcholine receptor from Torpedo californica

Purified acetylcholine receptor reconstituted into liposomes catalyzes carbamylcholine-dependent ion flux [10]. An endogenous protease activated by Ca2+ gives rise to an acrylamide gel pattern of the receptor with the 40,000-dalton subunit apparently as the major component. Exogenous proteases nick the proteins so extensively that the acrylamide gel pattern reveals polypeptides of 20,000 daltons or less. In either case the receptor sediments at 9S, indicating that the polypeptide chains remain associated. Moreover, the nicked receptors bind alpha-bungarotoxin and catalyze carbamylcholine-dependent ion flux after reconstitution.

Activation of the frog sartorius acetylcholine receptor by a covalently attached group

The frog sartorius motor endplate was treated with the specific disulfide bond reducing agent dithiothreitol and subsequently exposed to a covalently reacting compound (the nitrophenyl ester of p-carboxyphenyltrimethylammonium iodide, NPTMB) known to activate the dithiothreitol-reduced acetylcholine receptor in Electrophorus electroplax. NPTMB causes a maximum depolarization of about 35 mV when applied to the dithiothreitol-treated sartorious motor endplate. It is ineffective on postjunctional membrane prior to disulfide bond reduction and on extrajunctional regions, reduced or unreduced. High concentrations of a competitive antagonist such as (+)-tubocurarine prevent reaction between NPTMB and the reduced receptor and cause a repolarization of the membrane when applied to the already-depolarized preparation. We conclude that in frog muscle, as in electroplax, the attached activator bridges the acetylcholine binding site of the reduced receptor between a sulfhydryl group, to which it is covalently bound, and a negative subsite, with which it forms a reversible ionic band.

Postsynaptic effects of crotoxin and of its isolated subunits

Crotoxin is a potent neurotoxin from the venom of Crotalus durissus terrificus. It is composed of two subunits: a basic phospholipase A2 with low toxicity (component B) and an acidic protein seemingly devoid of intrinsic biological activity (component A). Crotoxin and its isolated phospholipase subunit block the depolarisation caused by cholinergic agonists on the isolated electroplaque from Electrophorus electricus. The other component, which is inactive when applied alone, enhances the pharmacological activity of the phospholipase when the two components are used together. Crotoxin also blocks the increase of 22Na+ efflux caused by carbamylcholine from excitable microsacs prepared from Torpedo marmorata electric organ. Crotoxin therefore acts postsynaptically, but does not interfere with the binding of alpha-toxin from Naja nigricollis to the nicotinic cholinergic receptor site. Instead, like local anesthetics, it stabilizes a desensitized form of the acetylcholine receptor characterized by its high affinity for agonists. The phospholipase component B binds in a non-saturable manner to receptor-rich membranes. In contrast, component A does not bind to acetylcholine receptor-rich membranes, but completely prevents the non-saturable binding of component B. When the two components are applied together, a saturable binding of the latter is observed with the acetylcholine receptor-rich membranes.

alpha-Bungarotoxin binding properties of a central nervous system nicotinic acetylcholine receptor

High-affinity, specific binding of radiolabeled alpha-bungarotoxin to particulate fractions derived from rat brain shows saturability (Bmax approximately 37fmol/mg, KDapp = 1.7 nM) and insenstivity to ionic strength, and is essentially irreversibel (Kon = 5 . 10(6) min-1 . mol-1; Kdisplacement = 1.9 . 10(-4) min-1, tau1/2 = 62 h). Subcellular distribution of specific sites is consistent with their location on synaptic junctional complex and post-synaptic membranes. These membrane-bound binding sites exhibit unique sensitivity to cholinergic ligands; pretreatment of membranes with cholinerin binding sites to a high affinity form toward agonist. The effect is most marked for the natural agonist, acetylcholine. These results strongly support the notion that the entity under study is an authentic nicotinic acetylcholine receptor.

Interaction of the acetylcholine (nicotinic) receptor protein from Torpedo marmorata electric organ with monolayers of pure lipids

Membrane fragments rich in cholinergic (nicotinic) receptor protein were purified from the electric organ of Torpedo marmorata. Their lipid composition is essentially characterized by the prominence of cholesterol, phosphatidylethanolamine and phosphatidylcholine, long-chain fatty acyl constituents, and the absence of sphingomyelin. Solubilised receptor was purified from these fragments and the concentration of sodium cholate lowered by dialysis to 0.01% (w/v). When this preparation was injected under a lipid monolayer, an increase of surface pressure developed, which was not observed with the detergent alone nor in the absence of lipid film. When covalently radiolabelled receptor preparations were injected at a constant surface pressure the radioactivity recovered with the film was proportional to the increase in area. It is concluded that the pressure or area increases are due to the penetration of the cholinergic receptor protein into the lipid film. Incorporation experiments into films formed from various pure lipids showed that the protein interacts more readily with cholesterol than with ergosterol, phosphatidylcholine, or other phospholipids. Its affinity is also higher for long-chain phosphatidylcholines than for short-chain ones. The degree of unsaturation and fluidity of the 3-sn-phosphatidylcholine (lecithin) films are of secondary importance. Parallel experiments with covalently and non-covalently labelled receptor preparations showed that part of the protein recovered with the film lost its alpha-toxin binding ability during the penetration. Similar data were obtained with the receptor purified from Electrophorus electricus electric organ.