Identification of two amino acid residues in the epsilon subunit that promote mammalian muscle acetylcholine receptor assembly in COS cells

Role of two acetylcholine receptor subunit domains in homomer formation and intersubunit recognition, as revealed by alpha 3 and alpha 7 subunit chimeras

Differential expression of subunit genes from the nicotinic acetylcholine receptor (AChR) superfamily yields distinct receptor subtypes. As each AChR subtype has a specific subunit composition and many subunit combinations appear not to be expressed, each subunit must contain some information leading to proper assembly. The neuronal AChR subunits alpha 3 and alpha 7 are expressed in bovine chromaffin cells, probably as constituents of two different AChR subtypes. These subunits have different assembly behavior when expressed in heterologous expression systems: alpha 7 subunits are able to produce homomeric AChRs, whereas alpha 3 subunits require other "structural" subunits for functional expression of AChRs. This feature allows the dissection of the requirements for subunit interactions during AChR formation. Analysis of alpha 7/alpha 3 chimeric constructs identified two regions essential to homomeric assembly and intersubunit recognition: an N-terminal extracellular region, controlling the initial association between subunits, and a second domain within a region comprising the first putative transmembrane segment, M1, and the cytoplasmic loop coupling it to the pore-forming segment, M2, involved in the subsequent interaction and stabilization of the oligomeric complex.

The amino acid residues 1-128 in the alpha subunit of the nicotinic acetylcholine receptor contain assembly signals

Expression of nicotinic acetylcholine receptor (AChR) involves complex processes including assembly of different receptor subunits into hetero-oligomers. To identify the minimal N-terminal region involved in AChR subunit association, we used a dominant negative assay. Co-expression of fragments of the alpha subunit, containing the N-terminal extracellular domain and transmembrane domain 1 (TM 1), with the parental AChR subunits in Xenopus oocytes blocked functional expression of the receptor. In contrast, co-expression of N-terminal extracellular fragments without TM1 failed to inhibit functional expression of AChRs, but altered the functional properties of co-expressed parental AChRs. Furthermore, when these alpha subunit fragments were co-expressed with the beta, gamma, and delta subunits, they were co-immunoprecipitated with a mixture of beta, gamma, and delta subunit specific antibodies. These results suggest that 'assembly signals' are confined to a local structure in the N-terminal extracellular domain. Our findings also indicate that an assembly step may be a target for genetic intervention not only to block the expression of functional receptors, but also to alter the function of the receptor.

Characterization of a chicken hepatoma cell line with a specific defect in fibrinogen secretion

This study characterizes plasma protein synthesis and its hormonal regulation in a chicken hepatoma cell line, with particular emphasis on fibrinogen. Whereas virtually all aspects of hemopexin, transferrin and albumin production in these cells corresponded to those of cultured primary hepatocytes, fibrinogen was not secreted. Analysis of fibrinogen subunit synthesis revealed a specific defect in synthesis of one subunit, gamma, correlating with a lack of its mRNA. Pulse-chase and electron microscopic studies demonstrate that, despite the inability of these cells to secrete the A alpha and B beta subunits produced, there is no long-term accumulation of unsecreted fibrinogen. The B beta fibrinogen subunits are largely degraded 2 hr after synthesis. During this time, approximately half of the A alpha subunits are degraded; the rest are converted to the glycosylated form. The implications of this type of defect with respect to the pathogenesis of fibrinogen storage disease are discussed.

Assembly of the inhibitory glycine receptor: identification of amino acid sequence motifs governing subunit stoichiometry

The inhibitory glycine receptor (GlyR) is a pentameric protein composed of two types (alpha and beta) of membrane-spanning subunits. Coexpression in Xenopus oocytes of a low affinity mutant of the alpha 2 subunit with the alpha 1 and beta subunits indicated that GlyRs assembled from alpha 1 and alpha 2 polypeptides contain variable subunit ratios, whereas alpha/beta hetero-oligomers have an invariant (3:2) stoichiometry. Analysis of different alpha/beta chimeric constructs revealed that this difference in assembly behavior is mediated by the N-terminal extracellular regions of the receptor subunits. Substitution of residues diverging between the alpha and beta subunits identified combinations of sequence motifs determining subunit stoichiometry.

Human neuronal voltage-dependent calcium channels: studies on subunit structure and role in channel assembly

Voltage-dependent calcium (Ca2+) channels, expressed in the CNS, appear to be multimeric complexes comprised of at least alpha 1, alpha 2 and beta subunits. Previously, we cloned and expressed human neuronal alpha 1, alpha 2 and beta subunits to study recombinant channel complexes that display properties of those expressed in vivo. The alpha 1B-mediated channel subtype binds omega-conotoxin (CgTx) GVIA with high affinity and exhibits properties of N-type voltage-dependent Ca2+ channels. Here we describe several alpha 2 and beta splice variants and report results on the expression of omega-CgTx GVIA binding sites, assembly of the subunit complex and biophysical function of alpha 1B-mediated channel complexes containing some of these splice variants. We optimized recombinant expression in human embryonic kidney (HEK) 293 cells of alpha 1B alpha 2b beta 1 subunit complexes by controlling the expression levels of subunit mRNAs and monitored cell surface expression by binding of omega-CgTx GVIA to the alpha 1B subunit. Co-expression of either alpha 2b or beta 1 subunits with an alpha 1B subunit increased expression of binding sites while the most efficient expression was achieved when both alpha 2b and beta 1 subunits were co-expressed with an alpha 1B subunit. The presence of alpha 2b affects the affinity of omega-CgTx GVIA binding and barium (Ba2+) current magnitudes, although it does not appear to alter kinetic properties of the Ba2+ current. This is the first evidence of an alpha 2 subunit modulating the binding affinity of a cell-surface Ca2+ channel ligand. Our results demonstrate that alpha 1, alpha 2 and beta subunits together contribute to the efficient assembly and functional expression of voltage-dependent Ca2+ channel complexes.

Interaction of the 43 kd postsynaptic protein with all subunits of the muscle nicotinic acetylcholine receptor

The 43 kd postsynaptic protein (43K) plays a key role in the aggregation of muscle nicotinic acetylcholine receptors (AChRs) in the postsynaptic membrane of the neuromuscular junction. By transiently coexpressing 43K and a single AChR subunit (alpha, beta, gamma, or delta) in the quail fibroblast cell line, QT-6, we show that 43K interacts with each subunit to form cell surface clusters in which 43K and receptor subunit are precisely colocalized. Although the level of cell surface expression of single subunits is much lower than that of fully assembled receptor, the clustering of both single subunits and fully assembled AChR occurs efficiently. In addition, 43K-induced clustering is specific for AChR subunits. From these results, we conclude that each pentameric AChR has five potential sites for interacting with 43K during cluster formation.

Specification of subunit assembly by the hydrophilic amino-terminal domain of the Shaker potassium channel

The functional heterogeneity of potassium channels in eukaryotic cells arises not only from the multiple potassium channel genes and splice variants but also from the combinatorial mixing of different potassium channel polypeptides to form heteromultimeric channels with distinct properties. One structural element that determines the compatibility of different potassium channel polypeptides in subunit assembly has now been localized to the hydrophilic amino-terminal domain. A Drosophila Shaker B (ShB) potassium channel truncated polypeptide that contains only the hydrophilic amino-terminal domain can form a homomultimer; the minimal requirement for the homophilic interaction has been localized to a fragment of 114 amino acids. Substitution of the amino-terminal domain of a distantly related mammalian potassium channel polypeptide (DRK1) with that of ShB permits the chimeric DRK1 polypeptide to coassemble with ShB.

BiP forms stable complexes with unassembled subunits of the acetylcholine receptor in transfected COS cells and in C2 muscle cells

We have investigated the role of the immunoglobulin-binding protein (BiP) in the folding and assembly of subunits of the acetylcholine receptor (AChR) in COS cells and in C2 muscle cells. Immunoprecipitation in COS cells showed that alpha, beta, and delta subunits are associated with BiP. In the case of the alpha subunit, which first folds to acquire toxin-binding activity and is then assembled with the other subunits to form the AChR, BiP was associated only with a form that is unassembled and does not bind alpha-bungarotoxin. Similar results were found in C2 cells. Although the alpha and beta subunits of the AChR are minor membrane proteins in C2 cells, they were prominent among the proteins immunoprecipitated by antibodies to BiP, suggesting that BiP could play a role in their maturation or folding. In pulse-chase experiments in C2 cells, however, labeled alpha subunit formed a stable complex with BiP that was first detected after most of the alpha subunit had acquired toxin-binding activity and whose amount continued to increase for several hours. These kinetics are not compatible with a role for the BiP complex in the folding or assembly pathway of the AChR, and suggest that BiP is associated with a misfolded form of the subunit that is slowly degraded.

Sequences on the N-terminus of ACh receptor subunits regulate their assembly

Mutant alpha subunits of Torpedo acetylcholine receptors (AChR) were constructed and expressed in Xenopus oocytes together with other normal subunits to investigate regions in the subunit that are required for subunit assembly. I have found that chimeric alpha subunits, consisting of the N-terminal extracellular domain of the AChR alpha subunit, followed either by the hydrophobic transmembrane segments of GABAA receptor or glutamate receptor subunits, were still recognized as the AChR subunit and associated with co-expressed other normal AChR subunits, suggesting that this part of the N-terminal extracellular domain contains 'assembly signals'.

The N-terminal domains of acetylcholine receptor subunits contain recognition signals for the initial steps of receptor assembly

Ligand-gated ion channels are oligomeric membrane proteins in which homologous subunits specifically recognize one another and assemble around an aqueous pore. To identify domains responsible for the specificity of subunit association, we used a dominant-negative assay in which truncated subunits of the mouse muscle acetylcholine receptor (AChR) were coexpressed with the four wild-type subunits in transfected COS cells. Fragments of the alpha, delta, and gamma subunits consisting solely of the extracellular N-terminal domain blocked surface expression of the AChR and the formation of alpha delta heterodimers, an early step in the assembly pathway of the AChR. Immunoprecipitation and sucrose gradient sedimentation experiments showed that an N-terminal fragment of the alpha subunit forms a specific complex with the intact delta subunit. Thus the extracellular N-terminal domain of the alpha, delta, and gamma subunits contains the information necessary for specific subunit association.