Functional equivalence of monomeric and dimeric forms of purified acetylcholine receptors from Torpedo californica in reconstituted lipid vesicles

Acetylcholine receptors from Torpedo californica electric organ were solubilized and purified under conditions which prevent inactivation of the agonist-regulated cation channels. The dimer form of the receptors was preserved during purification. Treatment with reducing agents converted dimers into monomers. Receptor monomers and dimers were separately reconstituted into soybean lipid vesicles by the cholate dialysis technique. Reconstituted monomers and dimers were functionally equivalent with respect to their carbamylcholine-induced dose-dependent uptake of 22Na+, the total flux of 22Na+ per receptor during the permeability response, and the occurrence of desensitization. Evidence against non-covalent association of monomers to produce dimeric functional units was obtained using glutaraldehyde as a crosslinking agent. These results show that both the acetylcholine-binding sites and the agonist-regulated cation-specific channel are contained within the alpha 2 beta gamma delta subunit structure of the acetylcholine receptor monomer.     

Affinity-labeling of purified acetylcholine receptor from Torpedo californica

The receptor for acetylcholine purified from electric tissue of $\text{Torpedo californica}$ has been assayed both by affinity-alkylation and by neurotoxin binding. The specific activity by the latter method is about twice that by the former. Four major components of apparent molecular weights of 39,000, 48,000, 58,000 and 64,000 are separated by dodecyl sulfate-acrylamide gel electrophoresis. Reduction and affinity-alkylation of the receptor with a tritiated quaternary ammonium maleimide derivative results in the exclusive labeling of the 39,000 dalton subunit. This subunit, it is concluded, contains all or part of the acetylcholine binding site.     

Channel properties of the purified acetylcholine receptor from Torpedo californica reconstituted in planar lipid bilayer membranes

The electrophysiological properties of the cation channel of the purified nicotinic acetylcholine receptor (AChR) reconstituted in planar lipid bilayers were characterized. Single-channel currents were activated by acetylcholine, carbamylcholine and suberyldicholine. The single channel conductance (28 pS in 0.3 M NaCl) was ohmic and independent of the agonist. Single channel currents increased with Na+ concentration to a maximum conductance of 95 pS and showed a half-saturation point of 395 mM. The apparent ion selectivity sequence, derived from single-channel current recordings, is: NH+4 greater than Cs+ greater than Rb+ greater than or equal to Na+ Cl-, F-, SO2-(4). The distribution of channel open times was fit by a sum of two exponentials, reflecting the existence of at least two distinct open states. The time constants depend on the choice of agonist, being consistently longer for suberyldicholine than for carbamylcholine. Similar channel properties were recorded in bilayers formed from monolayers at the tip of patch pipets . Single-channel currents occur in paroxysms of channel activity followed by quiescent periods. This pattern is more pronounced as the agonist concentration increases, and is reflected in histograms of channel-opening frequencies. Computer simulations with a three-state model, consisting of two closed (unliganded and liganded) and one open state, do not resemble the recorded pattern of channel activity, especially at high agonist concentration. Inclusion of a desensitized liganded state reproduces the qualitative features of channel recordings. The occurrence of paroxysms of channel activity thus seems to result from the transit of AChR through its active conformation, from which it can open several times before desensitizing.     

Effects of carboxymethylation by a purified Torpedo californica methylase on the functional properties of the acetylcholine receptor in reconstituted membranes

The functional effects of carboxymethylation of Torpedo californica acetylcholine receptor by an endogenous Torpedo methylase were examined. Both the receptor and the methylase were purified to increase the level of methylation and the sensitivity of the functional assays. The methylase catalyzed the carboxymethylation of all four receptor subunits (alpha, beta, gamma, delta) with preferential labeling of the alpha and gamma subunits. For all the reactions, S-adenosylmethionine was used as the methyl donor. Functional effects of methylation were assessed by measuring ligand binding and ligand-activated ion permeability responses in reconstituted membranes containing purified acetylcholine receptors. Methylation of receptor to a level of 20 mol% had no significant effect on agonist or antagonist binding nor did methylation affect the transition from low-to-high affinity binding triggered by agonists. In contrast, 20% methylation led to a 20% reduction in the agonist-stimulated flux of cations across the receptor-containing membranes. The results suggest that methylation inhibits the ion permeability control properties of acetylcholine receptors.     

Phospholipase A inhibition of acetylcholine receptor function in Torpedo californica membrane vesicles

A protein isolated from $\text{Naja naja siamensis}$ venom on the basis of its phospholipase A activity inhibits acetylcholine receptor function in post-synaptic membrane vesicles from $\text{Torpedo californica}$. Specifically, the phospholipase A prevents the large increase in sodium efflux that can normally be induced by carbamylcholine, a receptor agonist. The phospholipase A inhibition shows the following properties: 1) it occurs at concentrations 50 times lower than the concentrations required for inhibition by α-neurotoxins; 2) the phospholipase A has no effect on the binding properties of the receptor; 3) the inhibition is abolished by removal of calcium ions; and 4) some phospholipid hydrolysis accompanies inhibition. It is suggested that the phospholipase A acts enzymatically to uncouple ligand binding from ion permeability in the receptor containing membrane vesicles.     

Activation and inactivation kinetics of Torpedo californica acetylcholine receptor in reconstituted membranes

By use of a quench-flow technique to measure tracer ion flux rates in a physiologically significant time domain, the kinetics of activation and inactivation of purified reconstituted acetylcholine receptor (AChR) were investigated. After solubilization in sodium cholate, purification by affinity chromatography, and reconstitution into soybean lipids, the AChR from Torpedo californica displayed a characteristically fast rate of ion influx measured with 86Rb+. At 4 degrees C 1 mM carbamoylcholine (Carb) stimulated a fast (t1/2 = 7 ms) first-order filling of vesicle internal volume that presented a 10(4)-fold stimulation of ion flux rate by Carb. The concentration dependence of activation was sigmoidal with a half-maximal value at 3 X 10(-4) M Carb. In the presence of Carb, the purified AChR also underwent a two-step inactivation (desensitization) process. Inactivation was measured by preincubating AChR with Carb for various times (milliseconds to minutes) and then measuring the 86Rb+ influx rate. The two inactivation processes were each characterized by a distinct maximum rate (5.3 and 0.10 s-1) and by a different dependence on Carb concentration. The slow phase of inactivation gave a half-maximal rate at 2.5 X 10(-4) M Carb, and the fast inactivation was half-maximal at 1.3 X 10(-3) M Carb. The concentration dependence curves for both inactivation processes were approximately hyperbolic. The results are discussed in terms of models that describe the relationship between ligand binding and the processes of channel activation and desensitization.     

Monovalent ion effects on acetylcholine receptor from Torpedo californica

The effects of the five Group I monovalent ions, Li, Na, K, Rb, and Cs, on [³H]acetylcholine binding to Triton X-100 solubilized acetylcholine receptor from Torpedo californica electroplax were examined. Acetylcholine binding was not greatly affected by Li or Na, but was inhibited by the other ions in the order Cs > Rb > K. The inhibition by K appeared to occur by a mechanism identical to that for d-tubocurarine inhibition of acetylcholine binding.     

Preparation of right-side-out, acetylcholine receptor enriched intact vesicles from Torpedo californica electroplaque membranes.

Intact vesicles enriched in acetylcholine receptor from Torpedo californica electroplaque membranes can be separated from collapsed or leaky vesicles and membrane sheets on sucrose density gradients. alpha-Bungarotoxin binding in intact vesicles reveals that approximately 95% of the acetylcholine receptor containing vesicles are formed outside-out (with the synaptic membrane face exposed on the vesicle exterior). The binding data also indicated that only 5% or less of the sites for alpha-bungarotoxin binding to synaptic membranes are located on the interior, cytoplasmic face. Intact vesicles are stable to gentle pelleting and resuspension but are easily osmotically shocked. The vesicles are impermeable to sucrose and Ficoll, but glycerol readily transverses to membrane barrier. Intact vesicles provide a sealed, oriented membrane preparation for studies of vectorial acetylcholine receptor mediated processes.     

Carbamylcholine-induced rapid cation efflux from reconstituted membrane vesicles containing purified acetylcholine receptor.

Membrane preparations containing essentially only the four polypeptides considered to constitute the acetylcholine receptor are purified from $\text{Torpedo}\text{californica}$ electroplax. Treatment of these membranes with 2% ($\text{w}\text{v}$ aqueous sodium cholate followed by removal of all insoluble matter results in a solubilized purified receptor preparation that can be reassociated with phospholipids during dialysis to remove the detergent. Such reconstituted receptor is shown to retain the capability of translocating ²²Na⁺ across the membrane in response to carbamylcholine binding in a highly reproducible manner. The dose response for this effect is similar to that observed for the original electroplax membrane preparation and the carbamylcholine induced signal is completely blocked by α-bungarotoxin.     

Studies of the composition of purified Torpedo californica acetylcholine receptor and of its subunits.

Under conditions that limit proteolytic degradation, the detergent-solubilized purified receptor protein from Torpedo californica exists in monomeric and dimeric forms. The purified receptor complex is composed of four different polypeptide subunits of apparent molecular weights 40 000, 50 000, 60 000, and 65 000. The individual polypeptides have been purified and their amino acid compositions have shown them to be relatively hydrophobic. In addition, the carbohydrate composition of the intact receptor complex and of the individual polypeptides has been determined. Amino acid analysis provided evidence for the occurrence of a component with chromatographic properties similar to those of phosphoserine. Treatment of receptor with CH3NH2 in base, a condition which provided quantitative modification of O-phosphoserine residues in beta-casein, completely eliminated the peak corresponding to phosphoserine following mild acid hydrolysis. We conclude that the receptor contains O-phosphoserine residues to the extent of approximately seven residues per molecule and these residues occur in all constituent polypeptides. Other forms of O-substituted serine and threonine were also shown to occur, most likely as glycosylated residues.     

The antigenic structure of the acetylcholine receptor from Torpedo californica

The immunological structure of the acetylcholine receptor (AChR) from the electric organ of Torpedo californica was studied using a large number of monoclonal antibodies which were initially selected for their abilities to bind to intact AChRs. The monoclonal antibodies were tested for their ability to bind to denatured AChR subunits labeled with 125I. Antibodies derived from rats immunized with individual denatured subunits or a mixture of subunits of Torpedo AChR reacted well in the assay. A much smaller proportion of antibodies derived from rats immunized with native Torpedo AChR or native AChR from Electrophorus electricus electric organ, bovine muscle, or human muscle reacted with denatured subunits of Torpedo AChR. Many monoclonal antibodies reacted with more than one subunit, but they always reacted best with the subunit used for immunization. Those monoclonal antibodies that bound to intact subunits were mapped more precisely by their ability to bind characteristic fragments of each subunit generated by proteolysis with Staphylococcal V8 protease. These fragments were analyzed by SDS polyacrylamide gel electrophoresis, and monoclonal antibodies that precipitated the same fragment pattern were placed in groups. By this method, we define a minimum of 28 determinants on Torpedo AChR.     

Acetylcholine receptor in planar lipid bilayers. Characterization of the channel properties of the purified nicotinic acetylcholine receptor from Torpedo californica reconstituted in planar lipid bilayers

The properties of the channel of the purified acetylcholine receptor (AChR) were investigated after reconstitution in planar lipid bilayers. The time course of the agonist-induced conductance exhibits a transient peak that relaxes to a steady state value. The macroscopic steady state membrane conductance increases with agonist concentration, reaching saturation at 10(-5) M for carbamylcholine (CCh). The agonist-induced membrane conductance was inhibited by d-tubocurarine (50% inhibition, IC50, at approximately 10(-6) M) and hexamethonium (IC50 approximately 10(-5) M). The single channel conductance, gamma, is ohmic and independent of the agonist. At 0.3 M monovalent salt concentrations, gamma = 28 pS for Na+, 30 pS for Rb+, 38 pS for Cs+, and 50 pS for NH+4. The distribution of channel open times was fit by a sum of two exponentials, reflecting the existence of two distinct open states. tau o1 and tau o2, the fast and slow components of the distribution of open times, are independent of the agonist concentration: for CCh this was verified in the range of 10(-6) M less than C less than 10(-3)M. tau 01 and tau o2 are approximately three times longer for suberyldicholine ( SubCh ) than for CCh. tau o1 and tau o2 are moderately voltage dependent, increasing as the applied voltage in the compartment containing agonist is made more positive with respect to the other. At desensitizing concentrations of agonist, the AChR channel openings occurred in a characteristic pattern of sudden paroxysms of channel activity followed by quiescent periods. A local anesthetic derivative of lidocaine ( QX -222) reduced both tau o1 and tau o2. This effect was dependent on both the concentration of QX -222 and the applied voltage. Thus, the AChR purified from Torpedo electric organ and reconstituted in planar lipid bilayers exhibits ion conduction and kinetic and pharmacological properties similar to AChR in intact muscle postsynaptic membranes.     

Electrogenic behavior of synaptic vesicles from Torpedo californica.

Electrical potential changes in pure synaptic vesicles from Torpedo californica were monitored with the fluorescent dye 3,3'-dipropylthiadicarbocyanine iodide. Vesicles resuspended in variable external sodium ion in the presence of gramicidin established sodium ion membrane diffusion potentials. Vesicles resuspended in choline or acetylcholine chloride became hyperpolarized upon addition of gramicidin. Hyperpolarization was subsequently partially reversed spontaneously by choline or acetylcholine influx, which was confirmed by gel filtration, to yield a new, less negative, stable membrane potential. Thus, acetylcholine and choline are taken up electrogenically by synaptic vesicles.     

Protease effects on the structure of acetylcholine receptor membranes from Torpedo californica

Protease digestion of acetylcholine receptor-rich membranes derived from Torpedo californica electroplaques by homogenization and isopycnic centrifugation results in degradation of all receptor subunits without any significant effect on the appearance in electron micrographs, the toxin binding ability, or the sedimentation value of the receptor molecule. Such treatment does produce dramatic changes in the morphology of the normally 0.5- to 2-microns-diameter spherical vesicles when observed by either negative-stain or freeze-fracture electron microscopy. Removal of peripheral, apparently nonreceptor polypeptides by alkali stripping (Neubig et al. 1979, Proc. Natl. Acad. Sci. U. S. A. 76:690-694) results in increased sensitivity of the acetylcholine receptor membranes to the protease trypsin as indicated by SDS gel electrophoretic patterns and by the extent of morphologic change observed in vesicle structure. Trypsin digestion of alkali- stripped receptor membranes results in a limit degradation pattern of all four receptor subunits, whereupon all the vesicles undergo the morphological transformation to minivesicles. The protein-induced morphological transformation and the limit digestion pattern of receptor membranes are unaffected by whether the membranes are prepared so as to preserve the receptor as a disulfide bridged dimer, or prepared so as to generate monomeric receptor.     

Docosahexaenoic acid-containing phosphatidylcholine affects the binding of monoclonal antibodies to purified Kb reconstituted into liposomes

Class I major histocompatibility complex (MHC I) molecules are transmembrane proteins that bind and present peptides to T-cell antigen receptors. The role of membrane lipids in controlling MHC I structure and function is not understood, although membrane lipid composition influences cell surface expression of MHC I. We reconstituted liposomes with purified MHC I (Kb) and probed the effect of lipid composition on MHC I structure (monoclonal anti-MHC I antibody binding). Four phospholipids were compared; each had a phosphocholine head group, stearic acid in the sn-1 position, and either oleic, alpha-linolenic, arachidonic, or docosahexaenoic acid (DHA) in the sn-2 position. The greatest binding of monoclonal antibody AF6-88.5, which detects a conformationally sensitive epitope in the extracellular region of the MHC I alpha-chain, was achieved with DHA-containing proteoliposomes. Other epitopes (CTKb, 5041.16.1) showed some sensitivity to lipid composition. The addition of beta2-microglobulin, which associates non-covalently with the alpha-chain and prevents alpha-chain aggregation, did not equalize antibody binding to proteoliposomes of different lipid composition, suggesting that free alpha-chain aggregation was not responsible for disparate antibody binding. Thus, DHA-containing membrane lipids may facilitate conformational change in the extracellular domains of the alpha-chain, thereby modulating MHC I function through effects on that protein's structure.     

Effects of lipids and detergents on the conformation of the nicotinic acetylcholine receptor from Torpedo californica.

The hydrophobic, photoreactive probe 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID) was used to characterize the effects of lipids and detergents on acetylcholine receptor (AChR) conformation. Affinity purified AChR reconstituted into dioleoylphosphatidylcholine (DOPC), dioleoylphosphatidic acid (DOPA), and cholesterol showed the same pattern of [125I]TID-labeling and demonstrated the same reduction in labeling of all four subunits upon desensitization by the agonist carbamylcholine, as partially purified AChR in native lipids. On the basis of the patterns of [125I]TID incorporation, reconstitution into DOPC/DOPA also appeared to stabilize the resting (functional) conformation of the AChR, while reconstitution in DOPC/cholesterol or DOPC alone largely desensitized the AChR. The effects of lipids on the functional state of the AChR was determined independently by measuring the ability of AChR reconstituted into different lipid combinations to undergo the change in affinity for agonist diagnostic of desensitization. The dramatic reduction in the apparent levels of [125I]TID associated with the subunits of the AChR observed upon agonist-induced desensitization was shown not to be due to a change in affinity for tightly bound lipid. Solubilization of affinity purified AChR reconstituted into DOPC/DOPA/cholesterol by the non-ionic detergents octyl glucoside, Triton X-100, and Tween 20 (final detergent concentration = 1%) was shown to produce the same pattern of [125I]TID-labeling as desensitization by agonist, while solubilization in 1% sodium cholate appeared to stabilize a conformation of the AChR more similar to the resting state.     

Reaction of quinacrine mustard with the acetylcholine receptor from Torpedo californica

Amines with local anesthetic activity are typically also noncompetitive inhibitors of the agonist-induced increase in cation permeability mediated by the nicotinic acetylcholine receptor. Quinacrine is such an agent, and we have synthesized tritiated quinacrine mustard, a derivative capable of reacting with nucleophiles. Quinacrine mustard was reacted with receptor-rich membrane from torpedo electric tissue, excess reagent was removed by partition into liposomes, and the modified receptor was extracted and reconstituted with exogenous phospholipid. After reaction of the native membrane with 10 microM quinacrine mustard for 5 min, binding of cobratoxin to the acetylcholine binding sites is inhibited 15%; in contrast, receptor-mediated 86Rb uptake in the reconstituted vesicles is inhibited 70%. When the reaction with quinacrine mustard is carried out in the presence of 10 microM carbamylcholine or 10 microM d-tubocurarine, there is no block of the acetylcholine binding sites; nevertheless, the inhibition of Rb uptake is greater than that resulting from reaction in the absence of acetylcholine binding site ligands. Conversely, when the reaction is carried out in the presence of either 100 microM quinacrine or 100 microM proadifen (also a potent noncompetitive inhibitor), either with or without carbamylcholine or d-tubocurarine, the inhibition of 86Rb uptake is about 70% smaller. Under the same conditions that we used in the functional studies, quinacrine mustard reacts with the four types of chains that constitute the receptor complex, alpha 2 beta gamma delta. The presence of the acetylcholine binding site ligands, however, results in increased reaction with the alpha and beta chains, while the presence of the noncompetitive inhibitors, with or without the acetylcholine binding site ligands, results in decreased reaction with the alpha and beta chains. We conclude that the alpha and beta chains contribute to one or more functionally significant binding sites for noncompetitively inhibiting amines.     

Isolation of acetylcholine receptor-- -bungarotoxin complexes from Torpedo californica electroplax

Affinity chromatography has been utilized to purify acetylcholine receptors from Torpedo californica electroplax membranes. These have been isolated as their [¹²⁵I]α-bungarotoxin complexes. The major protein subunit found had a molecular weight of 3.5–4.5 × 10⁴ on gel electrophoresis under denaturing conditions. Other components of higher molecular weight were also present in smaller amounts even in the best preparations. This is interpreted as most likely due to either a multiple subunit structure or to more than one type of receptor in the tissue used.