Genetic reconstitution of functional acetylcholine receptor channels in mouse fibroblasts

Expression of gap junction channels in communication-incompetent cells after stable transfection with cDNA encoding connexin 32

The gene family encoding gap junction proteins (connexins) consists of several known members, and multiple connexins are frequently coexpressed by coupled cells. To characterize the channel properties of the major rat liver gap junction protein (connexin 32) in isolation from other gap junction proteins, we have introduced the cDNA encoding it into a human hepatoma cell line (SKHep1) in which we have identified a gap junction deficiency. In this cell line, dye coupling was absent and junctional conductance was near zero. Connexins and connexin 32 mRNA were not detectable by immunocytochemistry and Northern blot analysis. After transfection and selection, cells were strongly coupled with regard to dye and electrical current, and connexin 32 mRNA and punctate connexin 32-immunoreactive membrane contacts were abundant. Functional gap junction channels were still expressed after 19 passages of the cells, indicating stable transfection. When junctional conductance was rendered reversibly low by exposing the cells to agents that uncouple other cell types, currents through single gap junction channels could be observed. The unitary conductance of these expressed channels was about 120-150 pS, a value that is distinctly larger than in heart cells, which express a different gap junction protein.

Gating mechanism of a cloned potassium channel expressed in frog oocytes and mammalian cells

We have cloned a cDNA coding for a delayed rectifier K+ channel from rat brain (RCK1) and rat muscle (RMK1) and expressed it in Xenopus oocytes and in a myoblast cell line (Sol-8). Stably transfected Sol-8 cells exhibited large outward K+ currents, which were indistinguishable from the K+ currents induced in Xenopus oocytes by injection of mRNA transcribed in vitro. RCK1 encodes a K+ channel with a unitary conductance of approximately 14 pS. The steep voltage dependence of channel opening resides in transitions between closed states, whereas the direct transitions into and out of the open state are very rapid and not markedly voltage-dependent. Channel inactivation is very slow, voltage-independent, and occurs from the open state only. We present a simple model that incorporates our findings and is consistent with the presumed structural symmetry of a functional K+ channel.

Gene transfer by lipofection in rabbit and human secretory epithelial cells

Lipofection, a recently-developed method for gene transfer, was tested in secretory epithelial cells. Lipofection facilitated both transient DNA transfection with plasmids containing the chloramphenicol acetyltransferase gene and stable transfection with a plasmid containing the neomycin resistance gene, which confers resistance to the antibiotic G418 (Geneticin). Gene transfer occurred efficiently in a rabbit kidney medullary thick ascending limb cell line and in primary cultures of rabbit tracheal epithelial cells. The method was also effective in Simian virus 40-transformed human airway cells isolated from a normal individual and from a patient with cystic fibrosis (CF). Cytotoxicity was minimal, particularly when the time of exposure to the lipofectin-DNA was limited to 3-5 h (less than 5% cell loss). Thus, the lipofection method is useful for gene transfer in a variety of secretory epithelial cells and should be ideal for studies of defective secretory epithelial cell function in CF.

Desensitization of the nicotinic acetylcholine receptor: molecular mechanisms and effect of modulators

1. Loss of response after prolonged or repeated application of stimulus is generally termed desensitization. A wide variety of phenomena occurring in living organisms falls under this general definition of desensitization. There are two main types of desensitization processes: specific and non-specific. 2. Desensitization of the nicotinic acetylcholine receptor is triggered by prolonged or repeated exposure to agonists and results in inactivation of its ion channel. It is a case of specific desensitization and is an intrinsic molecular property of the receptor. 3. Desensitization of the nicotinic acetylcholine receptor at the neuromuscular junction was first reported by Katz and Thesleff in 1957. Desensitization of the receptor has been demonstrated by rapid kinetic techniques and also by the characteristic "burst kinetics" obtained from single-channel recordings of receptor activity in native as well as in reconstituted membranes. In spite of a number of studies, the detailed molecular mechanism of the nicotinic acetylcholine receptor desensitization is not known with certainty. The progress of desensitization is accompanied by an increase in affinity of the receptor for its agonist. This change in affinity is attributed to a conformational change of the receptor, as detected by spectroscopic and kinetic studies. A four-state general model is consistent with the major experimental observations. 4. Desensitization of the nicotinic acetylcholine receptor can be potentially modulated by exogenous and endogenous substances and by covalent modifications of the receptor structure. Modulators include the noncompetitive blockers, calcium, the thymic hormone peptides (thymopoietin and thymopentin), substance P, the calcitonin gene-related peptide, and receptor phosphorylation. Phosphorylation is an important posttranslational covalent modification that is correlated with the regulation and desensitization of the receptor through various protein kinases. 5. Although the physiological significance of desensitization of the nicotinic receptor is not yet fully understood, desensitization of receptors probably plays a significant role in the operation of the neuronal networks associated in memory and learning processes. Desensitization of the nicotinic receptor could also possibly be related to the neuromuscular disease, myasthenia gravis.

Fibroblasts transfected with Torpedo acetylcholine receptor beta-, gamma-, and delta-subunit cDNAs express functional receptors when infected with a retroviral alpha recombinant

Torpedo californica acetylcholine receptor (AChR) alpha-, beta-, gamma-, and delta-subunit cDNAs were each stably introduced into muscle and/or fibroblast cell lines using recombinant retroviral vectors and viral infection, or using SV-40 vectors and DNA-mediated cotransfection. The expressed proteins were characterized in terms of their molecular mass, antigenicity, posttranslational processing, cell surface expression, stability in fibroblasts, stability in differentiated and undifferentiated muscle cells, and ability (of alpha) to bind alpha-bungarotoxin (BuTx). We demonstrated that the alpha, beta, gamma, and delta polypeptides acquired one, one, two, and three units of oligosaccharide, respectively. If all four subunits were expressed in the same cell, fully functional cell surface AChRs were produced which had a Kd for BuTx of 7.8 X 10(-11) M. In contrast, subunits expressed individually were not detected on the surface of fibroblasts and the Kd for BuTx binding to individual alpha polypeptides was only approximately 4 X 10(-7) M. The half-lives of the alpha, gamma, and delta subunits at 37 degrees C were all found to be quite short (approximately 43 min), while the half-life of the beta subunit was found to be even shorter (approximately 12 min). The unique half-life of the beta subunit suggests that it might perform a key regulatory role in the process of AChR subunit assembly. One stable fibroblast cell line was established by transfection that expressed beta, gamma, and delta subunits simultaneously. When this cell line was infected with a retroviral alpha recombinant, fully functional cell surface AChRs were produced. The successful expression of this pentameric protein complex combining transfection and infection techniques demonstrates one strategy for stably introducing the genes of a heterologous multisubunit protein complex into cells.

Assembly and N-glycosylation of all ACh receptor subunits are required for their efficient insertion into plasma membranes

Various combinations of synthetic acetylcholine receptor (AChR) subunit mRNAs were injected into Xenopus oocytes, and assembly of incomplete AChRs and their insertion into the plasma membrane was studied. Assembly of incomplete AChRs is not greatly affected by the absence of one or two of the other subunits. In contrast, the membrane insertion of incomplete AChRs is profoundly reduced as compared with complete AChRs. The role of N-glycosylation on the assembly of AChR subunits, and on their insertion into plasma membranes, was also studied by using the Xenopus oocyte expression system and tunicamycin. Assembly of non-N-glycosylated AChR subunits occurs in tunicamycin-treated oocytes, but these subunits remain in intracellular compartments, suggesting that N-glycosylation of AChR subunits is not a prerequisite for receptor assembly, but is required for their efficient insertion into the plasma membrane.

Pharmacology of nicotine

In recent years progress in basic neuropsychopharmacology and clinical addiction research have allowed the conclusion that tobacco smoking essentially represents an addiction to nicotine. Parallel to this work, experimental research in biochemistry, physiology and pharmacology has provided detailed descriptions of the structure and function of the nicotinic receptor, the biologic mediator of the many actions of nicotine. This article reviews current knowledge of nicotinic mechanisms in the peripheral and central nervous systems as well as some implications for the notion of smoking as an addiction to nicotine. In particular this review will focus on the effects of nicotine on brain dopamine and noradrenaline systems since these neuronal systems appear to be crucially involved in the rewarding and stimulant effects of addictive drugs.

The lipid environment of the nicotinic acetylcholine receptor in native and reconstituted membranes

Detailed knowledge of the membrane framework surrounding the nicotinic acetylcholine receptor (AChR) is key to an understanding of its structure, dynamics, and function. Recent theoretical models discuss the structural relationship between the AChR and the lipid bilayer. Independent experimental data on the composition, metabolism, and dynamics of the AChR lipid environment are analyzed in the first part of the review. The composition of the lipids in which the transmembrane AChR chains are inserted bears considerable resemblance among species, perhaps providing this evolutionarily conserved protein with an adequate milieu for its optimal functioning. The effects of lipids on the latter are discussed in the second part of the review. The third part focuses on the information gained on the dynamics of AChR and lipids in the membrane, a section that also covers the physical properties and interactions between the protein, its immediate annulus, and the bulk lipid bilayer.

Change in desensitization of cat muscle acetylcholine receptor caused by coexpression of Torpedo acetylcholine receptor subunits in Xenopus oocytes

Cat muscle acetylcholine receptors (AcChoR) expressed in Xenopus oocytes desensitized more slowly than Torpedo electric organ AcChoRs, also expressed in oocytes. To examine the bases for the different degrees of desensitization, cat-Torpedo AcChoR hybrids were formed by injecting oocytes with cat denervated muscle mRNA mixed with a large excess of cloned Torpedo AcChoR subunit mRNAs. Hybrid AcChoRs formed by coinjection of cat muscle mRNA with the Torpedo beta or delta subunit mRNAs desensitized as slowly as cat AcChoR. In contrast, the hybrid AcChoRs expressed by coinjection with the Torpedo gamma subunit mRNA desensitized much more rapidly than cat AcChoR. The AcChoRs expressed in oocytes injected with cat muscle mRNA together with the Torpedo beta, gamma, and delta subunit mRNAs desensitized as rapidly as Torpedo AcChoR, indicating that the cat alpha subunit does not play an important role in determining the slow rate of desensitization. It is concluded that the difference in the rates of desensitization of cat and Torpedo AcChoRs is determined mainly by differences in their respective gamma subunits.

Transient expression shows ligand gating and allosteric potentiation of GABAA receptor subunits

Human gamma-aminobutyric acid A (GABAA) receptor subunits were expressed transiently in cultured mammalian cells. This expression system allows the simultaneous characterization of ligand-gated ion channels by electrophysiology and by pharmacology. Thus, coexpression of the alpha and beta subunits of the GABAA receptor generated GABA-gated chloride channels and binding sites for GABAA receptor ligands. Channels consisting of only alpha or beta subunits could also be detected. These homomeric channels formed with reduced efficiencies compared to the heteromeric receptors. Both of these homomeric GABA-responsive channels were potentiated by barbiturate, indicating that sites for both ligand-gating and allosteric potentiation are present on receptors assembled from either subunit.

Heterologous expression of excitability proteins: route to more specific drugs?

Many clinically important drugs act on the intrinsic membrane proteins (ion channels, receptors, and ion pumps) that control cell excitability. A major goal of pharmacology has been to develop drugs that are more specific for a particular subtype of excitability molecule. DNA cloning has revealed that many excitability proteins are encoded by multigene families and that the diversity of previously recognized pharmacological subtypes is matched, and probably surpassed, by the diversity of messenger RNAs that encode excitability molecules. In general, the diverse subtypes retain their properties when the excitability proteins are expressed in foreign cells such as oocytes and mammalian cell lines. Such heterologous expression may therefore become a tool for testing drugs against specific subtypes. In a systematic research program to exploit this possibility, major considerations include alternative processing of messenger RNA for excitability proteins, coupling to second-messenger systems, and expression of enough protein to provide material for structural studies.