Primary structure and functional expression of the alpha-, beta-, gamma-, delta- and epsilon-subunits of the acetylcholine receptor from rat muscle.

The isolation and characterization of five clones carrying sequences of the alpha-, beta-, gamma-, delta- and epsilon-subunit precursors of the rat muscle acetylcholine receptor (AChR) are described. The deduced amino acid sequences indicate that these polypeptides contain 457-519 amino acids and reveal the structural characteristics common to subunits of ligand-gated ion channels. The pattern of subunit-specific mRNA levels in rat muscle shows characteristic changes during development and following denervation, suggesting that innervation of muscle reduces the expression of the alpha-, beta- and delta-subunit mRNAs, suppresses the expression of the gamma-subunit mRNA, and induces expression of epsilon-subunit mRNA. Subunit-specific cRNAs generated in vitro were injected into Xenopus laevis oocytes, resulting in the assembly of two functionally different AChR channel subtypes. The AChR gamma, composed of the alpha-, beta-, gamma- and delta-subunits, has functional properties similar to those of the native AChRs in fetal muscle. The AChR epsilon, composed of alpha-, beta-, delta- and epsilon-subunits, corresponds to the end-plate channel of the adult muscle. Thus in rat skeletal muscle the motor nerve regulates the expression of two functionally different AChR subtypes with different molecular composition by the differential expression of subunit-specific mRNAs.     

Gamma- and delta-subunits regulate the affinity and the cooperativity of ligand binding to the acetylcholine receptor.

The acetylcholine receptor (AChR) from vertebrate skeletal muscle is a pentamer composed of two ligand-binding alpha-subunits and one beta-, gamma-, and delta-subunit. To examine the functional roles of the non-alpha-subunits, we have expressed, in stable cell lines, AChRs lacking either a gamma- or a delta-subunit. Most previous work has examined how these changes in subunit composition affect single channel properties. Here, we take advantage of the stable expression system to produce large amounts of AChR and, for the first time, examine ligand binding to altered AChRs on intact cells. The changes in subunit composition affect both ligand affinity and cooperativity of the receptor, suggesting important roles for the gamma- and delta-subunits, both in shaping the ligand binding site and maintaining cooperative interactions between alpha-subunits.     

Agonist-induced changes in the structure of the acetylcholine receptor M2 regions revealed by photoincorporation of an uncharged nicotinic noncompetitive antagonist.

To characterize structural changes induced in the nicotinic acetylcholine receptor (AChR) by agonists, we have mapped the sites of photoincorporation of the cholinergic noncompetitive antagonist 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (]125I]TID) in the presence and absence of 50 microM carbamylcholine. [125I]TID binds to the AChR with similar affinity under both these conditions, but agonist inhibits photoincorporation into all subunits by greater than 75% (White, B. H., Howard, S., Cohen, S. G., and Cohen, J. B. (1991) J. Biol. Chem. 266, 21595-21607). [125I]TID-labeled sites on the beta- and delta-subunits were identified by amino-terminal sequencing of both cyanogen bromide (CNBr) and tryptic fragments purified by Tricine sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by reversed-phase high-performance liquid chromatography. In the absence of agonist, [125I]TID specifically labels homologous aliphatic residues (beta L-257, delta L-265, beta V-261, and delta V-269) in the M2 region of both subunits. In the presence of agonist, labeling of these residues is reduced approximately 90%, and the distribution of labeled residues is broadened to include a homologous set of serine residues at the amino terminus of M2. In the beta-subunit residues beta S-250, beta S-254, beta L-257, and beta V-261 are all labeled in the presence of carbamylcholine. This pattern of labeling supports an alpha-helical model for M2 with the labeled face forming the ion channel lumen. The observed redistribution of label in the resting and desensitized states provides the first direct evidence for an agonist-dependent rearrangement of the M2 helices. The efficient labeling of the resting state channel in a region capable of structural change also suggests a plausible model for AChR gating in which the aliphatic residues labeled by [125I]TID form a permeability barrier to the passage of ions. We also report increased labeling of the M1 region of the delta-subunit in the presence of agonist.     

Correspondence of minor subunits of plant mitochondrial F1ATPase to F1F0ATPase subunits of other organisms

In addition to two major alpha- and beta-subunits, the soluble oligomycin-insensitive F1ATPase purified from sweet potato root mitochondria contains four different minor subunits of gamma (Mr = 35,500), delta (Mr = 27,000), delta' (Mr = 23,000), and epsilon (Mr = 12,000) (Iwasaki, Y., and Asashi, T. (1983) Arch. Biochem. Biophys. 227, 164-173). Among these minor subunits, the delta-subunit specifically cross-reacted with an antibody against the delta-subunit of maize mitochondrial F1 which contains only three minor gamma-, delta- and epsilon-subunits like F1ATPases from other organisms, indicating that the delta'-subunit is an extra subunit of sweet potato F1 which is absent in the maize F1. All of the four minor subunits of sweet potato F1 were purified and their N-terminal amino acid sequences of 30-36 residues were determined. The N-terminal sequence of gamma-subunit was homologous to those of the gamma-subunits of bacterial F1 and mammalian mitochondrial F1. The N-terminal sequence of the delta-subunit was homologous to those of the delta-subunits of bacterial F1, chloroplast CF1, and oligomycin sensitivity conferring protein of bovine mitochondrial F1F0. A sequence homology was also observed between the sweet potato epsilon-subunit and the epsilon-subunit of bovine mitochondrial F1. The N-terminal sequence of the delta'-subunit did not show any significant sequence homology to known protein sequences. These subunit correspondences place plant mitochondrial F1 at an unique position in the evolution of F1ATPase.     

Primary structure and subunit stoichiometry of F1-ATPase from bovine mitochondria

The enzyme complex F1-ATPase has been isolated from bovine heart mitochondria by gel filtration of the enzyme released by chloroform from sub-mitochondrial particles. The five individual subunits alpha, beta, gamma, delta and epsilon that comprise the complex have been purified from it, and their amino acid sequences determined almost entirely by direct protein sequence analysis. A single overlap in the gamma-subunit was obtained by DNA sequence analysis of a complementary DNA clone isolated from a bovine cDNA library using a mixture of 32 oligonucleotides as the hybridization probe. The alpha, beta, gamma, delta and epsilon subunits contain 509, 480, 272, 146 and 50 amino acids, respectively. Two half cystine residues are present in the alpha-subunit and one in each of the gamma- and epsilon-chains; they are absent from the beta- and delta-subunits. The stoichiometry of subunits in the complex is estimated to be alpha 3 beta 3 gamma 1 delta 1 epsilon 1 and the molecular weight of the complex is 371,135. Mild trypsinolysis of the F1-ATPase complex, which has little effect on the hydrolytic activity of the enzyme, releases peptides from the N-terminal regions of the alpha- and beta-chains only; the C-terminal regions are unaffected. Sequence analysis of the released peptides demonstrates that the N terminals of the alpha- and beta-chains are ragged. In 65% of alpha-chains, the terminus is pyrrolidone carboxylic acid; in the remainder this residue is absent and the chains commence at residue 2, i.e. lysine. In the beta-subunit a minority of chains (16%) have N-terminal glutamine, or its deamidation product, glutamic acid (6%), or the cyclized derivative, pyrrolidone carboxylic acid (5%). A further 28% commence at residue 2, alanine, and 45% at residue 3, serine. The delta-chains also are heterogeneous; in 50% of chains the N-terminal alanine residue is absent. The sequences of the alpha- and beta-chains show that they are weakly homologous, as they are in bacterial F1-ATPases. The sequence of the bovine delta-subunit of F1-ATPase shows that it is the counterpart of the bacterial epsilon-subunit. The bovine epsilon-subunit is not related to any known bacterial or chloroplast H+-ATPase subunit, nor to any other known sequence. The counterpart of the bacterial delta-subunit is bovine oligomycin sensitivity conferral protein, which helps to bind F1 to the inner mitochondrial membrane.(ABSTRACT TRUNCATED AT 400 WORDS)     

Neural factors regulate AChR subunit mRNAs at rat neuromuscular synapses

To elucidate the nature of signals that control the level and spatial distribution of mRNAs encoding acetylcholine receptor (AChR), alpha-, beta-, gamma-, delta- and epsilon-subunits in muscle fibers chronic paralysis was induced in rat leg muscles either by surgical denervation or by different neurotoxins that cause disuse of the muscle or selectively block neuromuscular transmission pre- or postsynaptically and cause an increase of AChRs in muscle membrane. After paralysis, the levels and the spatial distributions of the different subunit-specific mRNAs change discoordinately and seem to follow one of three different patterns depending on the subunit mRNA examined. The level of epsilon-subunit mRNA and its accumulation at the end-plate are largely independent on the presence of the nerve or electrical muscle activity. In contrast, the gamma-subunit mRNA level is tightly coupled to innervation. It is undetectable or low in innervated normally active muscle and in innervated but disused muscle, whereas it is abundant along the whole fiber length in denervated muscle or in muscle in which the neuromuscular contact is intact but the release of transmitter is blocked. The alpha-, beta-, and delta-subunit mRNA levels show a different pattern. Highest amounts are always found at end-plate nuclei irrespective of whether the muscle is innervated, denervated, active, or inactive, whereas in extrasynaptic regions they are tightly controlled by innervation partially through electrical muscle activity. The changes in the levels and distribution of gamma- and epsilon-subunit-specific mRNAs in toxin-paralyzed muscle correlate well with the spatial appearance of functional fetal and adult AChR channel subtypes along the muscle fiber. The results suggest that the focal accumulation at the synaptic region of mRNAs encoding the alpha-, beta-, delta-, and epsilon-subunits, which constitute the adult type end-plate channel, is largely determined by at least two different neural factors that act on AChR subunit gene expression of subsynaptic nuclei.     

Factors determining the subunit composition of tropomyosin in mammalian skeletal muscle.

Adult rat fast-twitch skeletal muscle such as extensor digitorum longus contains alpha- and beta-tropomyosin subunits, as is the case in the corresponding muscles of rabbit. Adult rat soleus muscle contains beta-, gamma- and delta-tropomyosins, but no significant amounts of alpha-tropomyosin. Evidence for the presence of phosphorylated forms of at least three of the four tropomyosin subunit isoforms was obtained, particularly in developing muscle. Immediately after birth alpha- and beta-tropomyosins were the major components of skeletal muscle, in both fast-twitch and slow-twitch muscles. Differentiation into slow-twitch skeletal muscles was accompanied by a fall in the amount of alpha-tropomyosin subunit and its replacement with gamma- and delta-subunits. After denervation and during regeneration after injury, the tropomyosin composition of slow-twitch skeletal muscle changed to that associated with fast-twitch muscle. Thyroidectomy slowed down the changes in tropomyosin composition resulting from the denervation of soleus muscle. The results suggest that the 'ground state' of tropomyosin-gene expression in the skeletal muscle gives rise to alpha- and beta-tropomyosin subunits. Innervation by a 'slow-twitch' nerve is essential for the expression of the genes controlling gamma- and delta-subunits. There appears to be reciprocal relationship between expression of the gene controlling the synthesis of alpha-tropomyosin and those controlling the synthesis of gamma- and delta-tropomyosin subunits.     

Stable expression of the mouse nicotinic acetylcholine receptor in mouse fibroblasts. Comparison of receptors in native and transfected cells.

A stable cell line expressing mouse acetylcholine receptors (AChRs), named AM4, was established by cotransfecting into NIH 3T3 fibroblasts, alpha-, beta-, gamma-, and delta-subunit cDNAs plus the neor gene by calcium phosphate precipitation. Surface AChRs on AM4 cells contain all four subunits, sediment as a single approximately 9 S peak on sucrose gradients, and have the same ratio of alpha- to beta-subunits as surface AChRs from mouse BC3H-1 cells. The surface AChRs exhibit pharmacological properties identical to those obtained for BC3H-1 cells, including the association and dissociation rates of alpha-bungarotoxin, a low affinity and cooperative instantaneous dose-response curve, cooperative steady state agonist binding and desensitization, cooperative enhancement of agonist binding affinity by local anesthetics, and distinct affinities for curariform antagonists. Patch clamp measurements on AM4 cells reveal AChR single channel properties identical to those obtained from BC3H-1 cells, including a single class of channels with a conductance of 56 pS, short and long duration openings at low and high agonist concentrations, brief and intermediate closed duration components at low agonist concentrations, and six distinct closed duration components at high agonist concentrations. The biochemical, pharmacological, and single channel measurements indicate at least 95% of the surface AChRs on AM4 cells are alpha 2 beta gamma delta pentamers.     

Revised assignments for the beta-, gamma- and delta-subunits of the acetylcholine receptor structural model

Revised assignments for the bilayer helices of the beta-, gamma- and delta-subunits of the acetylcholine receptor are presented. A new feature of the model is extensive charge matching between the polar groups of the ion channel elements of different subunits.     

Induction of phosphorylation and cell surface redistribution of acetylcholine receptors by phorbol ester and carbamylcholine in cultured chick muscle cells

We have investigated the mechanisms regulating the clustering of nicotinic acetylcholine receptor (AChR) on the surface of cultured embryonic chick muscle cells. Treatment of these cells with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), a potent activator of protein kinase C, was found to cause a rapid dispersal of AChR clusters, as monitored by fluorescence microscopy of cells labeled with tetramethylrhodamine-conjugated alpha-bungarotoxin. The loss of AChR clusters was not accompanied by an appreciable change in the amount of AChR on the surface of these cells, as measured by the specific binding of [125I]Bgt. Analysis of the phosphorylation pattern of immunoprecipitable AChR subunits showed that the gamma- and delta-subunits are phosphorylated by endogenous protein kinase activity in the intact muscle cells, and that the delta-subunit displays increased phosphorylation in response to TPA. Structural analogues of TPA which do not stimulate protein kinase C have no effect on AChR surface topography or phosphorylation. Exposure of chick myotubes to the cholinergic agonist carbamylcholine was found to cause a dispersal of AChR clusters with a time course similar to that of TPA. Like TPA, carbamylcholine enhances the phosphorylation of the delta-subunit of AChR. The carbamylcholine-induced redistribution and phosphorylation of AChR is blocked by the nicotinic AChR antagonist d-tubocurarine. TPA and carbamylcholine have no effect on cell morphology during the time-course of these experiments. These findings indicate that cell surface topography of AChR may be regulated by phosphorylation of its subunits and suggest a mechanism for dispersal of AChR clusters by agonist activation.     

Probing the structure of the nicotinic acetylcholine receptor with 4-benzoylbenzoylcholine, a novel photoaffinity competitive antagonist

[(3)H]4-Benzoylbenzoylcholine (Bz(2)choline) was synthesized as a photoaffinity probe for the Torpedo nicotinic acetylcholine receptor (nAChR). [(3)H]Bz(2)choline acts as an nAChR competitive antagonist and binds at equilibrium with the same affinity (K(D) = 1.4 microm) to both agonist sites. Irradiation at 320 nm of nAChR-rich membranes equilibrated with [(3)H]Bz(2)choline results in the covalent incorporation of [(3)H]Bz(2)choline into the nAChR gamma- and delta-subunits that is inhibitable by agonist, with little specific incorporation in the alpha-subunits. To identify the sites of photoincorporation, gamma- and delta-subunits, isolated from nAChR-rich membranes photolabeled with [(3)H]Bz(2)choline, were digested enzymatically, and the labeled fragments were isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and/or reversed-phase high performance liquid chromatography. For the gamma-subunit, Staphylococcus aureus V8 protease produced a specifically labeled peptide beginning at gammaVal-102, whereas for the delta-subunit, endoproteinase Asp-N produced a labeled peptide beginning at deltaAsp-99. Amino-terminal sequence analysis identified the homologous residues gammaLeu-109 and deltaLeu-111 as the primary sites of [(3)H]Bz(2)choline photoincorporation. This is the first identification by affinity labeling of non-reactive amino acids within the acetylcholine-binding sites, and these results establish that when choline esters of benzoic acid are bound to the nAChR agonist sites, the para substituent is selectively oriented toward and in proximity to amino acids gammaLeu-109/deltaLeu-111.     

The ion channel of the nicotinic acetylcholine receptor is formed by the homologous helices M II of the receptor subunits

A binding site for the channel-blocking noncompetitive antagonist [3H]triphenylmethylphosphonium ([3H]TPMP+) was localized in the alpha-, beta- and delta-chains of the nicotinic acetylcholine receptor (AChR) from Torpedo marmorata electric tissue. The photolabel was found in homologous positions of the highly conserved sequence helix II, alpha 248, beta 254, and delta 262. The site of the photoreaction appears to not be affected by the functional state of the receptor. [3H]TPMP+ was found in position delta 262 independent of whether photolabeling was performed with the receptor in its resting, desensitized or antagonist state. A model of the AChR ion channel is proposed, according to which the channel is formed by the five helices II contributed by the five receptor subunits.     

Location of a threonine residue in the alpha-subunit M2 transmembrane segment that determines the ion flow through the acetylcholine receptor channel.

By the combination of cDNA manipulation and functional analysis of normal and mutant acetylcholine receptor (AChR) channels of Torpedo expressed in Xenopus laevis oocytes determinants of ion flow were localized in the bends bordering the putative M2 transmembrane segment (Imoto et al. 1988). We now report that in the rat muscle AChR, substitution of a threonine residue in the alpha-subunit localized in the M2 transmembrane segment increases or decreases the channel conductance, depending on the size of the amino acid side chain located at this position. This threonine residue (alpha T264) is located adjacent to the cluster of charged amino acids that form the intermediate anionic ring (Imoto et al. 1988). This effect is pronounced for the large alkali cations Cs+, Rb+, K+ whereas for Na+ the effect is much smaller. Taken together the results suggest that the threonine residues at position 264 in the two alpha-subunits together with the amino acids of the intermediate anionic ring form part of a narrow region close to the cytoplasmic mouth of the AChR channel.     

Acetylcholine receptor alpha-, beta-, gamma-, and delta-subunit mRNA levels are regulated by muscle activity

Denervation of adult skeletal muscle results in increased sensitivity to acetylcholine in extrajunctional regions of the muscle fiber. This increase in acetylcholine sensitivity is accompanied by a large increase in the level of mRNAs coding for the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. To determine whether muscle activity is sufficient to regulate expression of extrajunctional acetylcholine receptor mRNA levels, denervated muscles were stimulated with extracellular electrodes. Direct stimulation of denervated muscle suppresses both the increase in extrajunctional acetylcholine sensitivity and the expression of mRNA encoding the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. These results show that muscle activity regulates the level of extrajunctional acetylcholine receptors by regulating the expression of their mRNAs.     

Partial tertiary structure assignments for the beta-, gamma- and delta-subunits of the acetylcholine receptor on the basis of the hydrophobicity of amino acid sequences and channel location using single group rotation theory

Four transmembrane segments from each of the beta-, gamma- and delta-protein subunits of the acetylcholine receptor (AChR) [Nature (1983) 301, 251-255], [Proc. Natl. Acad. Sci. USA (1983) 80, 1111-1115] have been selected on the basis of single group rotation (SGR) theory [Symp. Structure and Dynamics of Nucleic Acids and Proteins (Sept. 1982) abst. pp. 52-53], [Biochem. Biophys. Res. Commun. (1983) 111, 1022-1029] and the hydrophobicity of amino acid sequences. One helix from each subunit is assigned to the AChR ion channel. Criteria for the selection of ion channel elements are outlined.     

A ring of uncharged polar amino acids as a component of channel constriction in the nicotinic acetylcholine receptor.

The channel pore of the nicotinic acetylcholine receptor (AChR) has been investigated by analysing single-channel conductances of systematically mutated Torpedo receptors expressed in Xenopus oocytes. The mutations mainly alter the size and polarity of uncharged polar amino acid residues of the acetylcholine receptor subunits positioned between the cytoplasmic ring and the extracellular ring. From the results obtained, we conclude that a ring of uncharged polar residues comprising threonine 244 of the alpha-subunit (alpha T244), beta S250, gamma T253 and delta S258 (referred to as the central ring) and the anionic intermediate ring, which are adjacent to each other in the assumed alpha-helical configuration of the M2-containing transmembrane segment, together form a narrow channel constriction of short length, located close to the cytoplasmic side of the membrane. Our results also suggest that individual subunits, particularly the gamma-subunit, are asymmetrically positioned at the channel constriction.     

The delta'-subunit of higher plant six-subunit mitochondrial F1-ATPase is homologous to the delta-subunit of animal mitochondrial F1-ATPase.

Mitochondrial F1-ATPases purified from several dicotyledonous plants contain six different subunits of alpha, beta, gamma, delta, delta' and epsilon. Previous N-terminal amino acid sequence analyses indicated that the gamma-, delta-, and epsilon-subunits of the sweet potato mitochondrial F1 correspond to the gamma-subunit, the oligomycin sensitivity-conferring protein and the epsilon-subunit of animal mitochondrial F1F0 complex (Kimura, T., Nakamura, K., Kajiura, H., Hattori, H., Nelson, N., and Asahi, T. (1989) J. Biol. Chem. 264, 3183-3186). However, the N-terminal amino acid sequence of the delta'-subunit did not show any obvious homologies with known protein sequences. A cDNA clone for the delta'-subunit of the sweet potato mitochondrial F1 was identified by oligonucleotide-hybridization selection of a cDNA library. The 1.0-kilobase-long cDNA contained a 600-base pair open reading frame coding for a precursor for the delta'-subunit. The precursor for the delta'-subunit contained N-terminal presequence of 21-amino acid residues. The mature delta'-subunit is composed of 179 amino acids and its sequence showed similarities of about 31-36% amino acid positional identity with the delta-subunit of animal and fungal mitochondrial F1 and about 18-25% with the epsilon-subunit of bacterial F1 and chloroplast CF1. The sweet potato delta'-subunit contains N-terminal sequence of about 45-amino acid residues that is absent in other related subunits. It is concluded that the six-subunit plant mitochondrial F1 contains the subunit that is homologous to the oligomycin sensitivity-conferring protein as one of the component in addition to five subunits that are homologous to subunits of animal mitochondrial F1.