Fluorescence Characteristics of Hydrophobic Partial Agonist Probes of the Cholecystokinin Receptor

Fluorescence spectroscopic studies are powerful tools for the evaluation of receptor structure and the dynamic changes associated with receptor activation. Here, we have developed two chemically distinct fluorescent probes of the cholecystokinin (CCK) receptor by attaching acrylodan or a nitrobenzoxadiazole moiety to the amino terminus of a partial agonist CCK analogue. These two probes were able to bind to the CCK receptor specifically and with high affinity, and were able to elicit only submaximal intracellular calcium responses typical of partial agonists. The fluorescence characteristics of these probes were compared with those previously reported for structurally-related full agonist and antagonist probes. Like the previous probes, the partial agonist probes exhibited longer fluorescence lifetimes and increased anisotropy when bound to the receptor than when free in solution. The receptor-bound probes were not easily quenched by potassium iodide, suggesting that the fluorophores were protected from the extracellular aqueous milieu. The fluorescence characteristics of the partial agonist probes were quite similar to those of the analogous full agonist probes and quite distinct from the analogous antagonist probes. These data suggest that the partially activated conformational state of this receptor is more closely related to its fully active state than to its inactive state.     

Fluorescence Studies of the Nicotinic Acetylcholine Receptor in its Membrane Environment

Since the discovery of the fraction of immobilized lipid in contact with the nicotinic acetylcholine receptor (AChR), the lipid-belt region around this protein has become the focus of a variety of biophysical studies aimed at defining its properties. Here we summarize recent spectroscopic studies from our laboratory using Laurdan fluorescence to characterize distinct sites for lipids and to describe their effect on the AChR microenvironment.     

The Role of Lipids in the Function of the Acetylcholine Receptor

Abstract

The composition of membranes containing acetylcholine receptor was altered in order to examine the possible role of lipids in receptor function. Polyethylene glycol was used to fuse AcChR-rich membranes with an excess of lipid vesicles of defined composition. By this procedure, the cholesterol composition was reduced to as little as 20% of that found in native membranes. Using a TI⁺ flux assay it was possible to measure receptor function in such altered membrane environments. The apparent K_d for carbamylcholine was found to decrease as the cholesterol content was reduced. This result was confirmed by measuring the agonist-induced fluorescence change of the covalently attached probe, 4-[N-(iodoacetoxy)-ethyl-N-methyl] amino-7-nitrobenz-2-oxa-1,3-diazole. When the phospholipid composition was manipulated by membrane fusion, ion flux was found to be optimal when the lipid composition resembled that of native receptor membranes. These results indicate that membrane lipids potentially play a role in the regulation of acetylcholine receptor function.     

Local Application of Drugs to Study Nicotinic Acetylcholine Receptor Function in Mouse Brain Slices

Tobacco use leads to numerous health problems, including cancer, heart disease, emphysema, and stroke. Addiction to cigarette smoking is a prevalent neuropsychiatric disorder that stems from the biophysical and cellular actions of nicotine on nicotinic acetylcholine receptors (nAChRs) throughout the central nervous system. Understanding the various nAChR subtypes that exist in brain areas relevant to nicotine addiction is a major priority.Experiments that employ electrophysiology techniques such as whole-cell patch clamp or two-electrode voltage clamp recordings are useful for pharmacological characterization of nAChRs of interest. Cells expressing nAChRs, such as mammalian tissue culture cells or Xenopus laevis oocytes, are physically isolated and are therefore easily studied using the tools of modern pharmacology. Much progress has been made using these techniques, particularly when the target receptor was already known and ectopic expression was easily achieved. Often, however, it is necessary to study nAChRs in their native environment: in neurons within brain slices acutely harvested from laboratory mice or rats. For example, mice expressing "hypersensitive" nAChR subunits such as α4 L9′A mice ¹ and α6 L9′S mice ², allow for unambiguous identification of neurons based on their functional expression of a specific nAChR subunit. Although whole-cell patch clamp recordings from neurons in brain slices is routinely done by the skilled electrophysiologist, it is challenging to locally apply drugs such as acetylcholine or nicotine to the recorded cell within a brain slice. Dilution of drugs into the superfusate (bath application) is not rapidly reversible, and U-tube systems are not easily adapted to work with brain slices.In this paper, we describe a method for rapidly applying nAChR-activating drugs to neurons recorded in adult mouse brain slices. Standard whole-cell recordings are made from neurons in slices, and a second micropipette filled with a drug of interest is maneuvered into position near the recorded cell. An injection of pressurized air or inert nitrogen into the drug-filled pipette causes a small amount of drug solution to be ejected from the pipette onto the recorded cell. Using this method, nAChR-mediated currents are able to be resolved with millisecond accuracy. Drug application times can easily be varied, and the drug-filled pipette can be retracted and replaced with a new pipette, allowing for concentration-response curves to be created for a single neuron. Although described in the context of nAChR neurobiology, this technique should be useful for studying many types of ligand-gated ion channels or receptors in neurons from brain slices.     

Function of Interfacial Prolines at the Transmitter-binding Sites of the Neuromuscular Acetylcholine Receptor

The neuromuscular acetylcholine (ACh) receptor has two conserved prolines in loop D of the complementary subunit at each of its two transmitter-binding sites (α-ϵ and α-δ). We used single-channel electrophysiology to estimate the energy changes caused by mutations of these prolines with regard to unliganded gating (ΔG₀) and the affinity change for ACh that increases the open channel probability (ΔG_B). The effects of mutations of ProD2 (ϵPro-121/δPro-123) were greater than those of its neighbor (ϵPro-120/δPro-122) and were greater at α-ϵ versus α-δ. The main consequence of the congenital myasthenic syndrome mutation ϵProD2-L was to impair the establishment of a high affinity for ACh and thus make ΔG_B less favorable. At both binding sites, most ProD2 mutations decreased constitutive activity (increased ΔG₀). LRYHQG and RL substitutions reduced substantially the net binding energy (made ΔG_B^ACh less favorable) by ≥2 kcal/mol at α-ϵ and α-δ, respectively. Mutant cycle analyses were used to estimate energy coupling between the two ProD2 residues and between each ProD2 and glycine residues (αGly-147 and αGly-153) on the primary (α subunit) side of each binding pocket. The distant binding site prolines interact weakly. ProD2 interacts strongly with αGly-147 but only at α-ϵ and only when ACh is present. The results suggest that in the low to-high affinity change there is a concerted inter-subunit strain in the backbones at ϵProD2 and αGly-147. It is possible to engineer receptors having a single functional binding site by using a α-ϵ or α-δ ProD2-R knock-out mutation. In adult-type ACh receptors, the energy from the affinity change for ACh is approximately the same at the two binding sites (approximately −5 kcal/mol).     

Immunochemical Studies of the Muscarinic Acetylcholine Receptor

Abstract

Muscerinic receptors have been purified from calf forebrain plasma cell membranes by affinity chromatography on a dexetimide-agarose gel. SDS-PAGE analysis showed a single 70kDa band. Monoclonal antibodies have been prepared against these affinity purified 70kDa protein(s). One antibody, M-35, Immunoprecipitated up to 80% of digitonin-solubilized muscarinic receptors. M-35 had agonist-like effects on guinea-pig myometrium: it increased the intracellular cyclic GMP content, decreased prostaglandin-induced cyclic AMP accumulation and caused muscle contractions. The two first affects were inhibited by atropine. M-35 was used to visualize muscarinic receptors at the surface of human fibroblastic cells. In the particular cell line used, the receptors have a low affinty for pirenzepine, were negatively coupled to adenylate cyclase and mediated increase in the phosphatidyl-insitol breakdown.     

Effects of Substance P on Nicotinic Acetylcholine Receptor Function in PC 12 Cells

The effects of substance P on the functioning of nicotinic acetylcholine receptors in PC12 cells were examined. Carbachol-stimulated 22Na+ uptake was used to assess the functional state of the nicotinic receptor. We found that incubation of the cells with substance P alone caused a loss of receptor function. Receptors recovered from this effect with a t1/2 of 0.94 +/- 0.10 min. Since receptors recovered from carbachol-induced desensitization at a significantly slower rate (t1/2, 1.77 +/- 0.21 min), it was concluded that the two inactive states are not kinetically equivalent. The effects of substance P on carbachol-induced loss of receptor activity were also examined. Substance P had no effect on a component of carbachol-induced loss of activity that was nonrecoverable (inactivation). However, substance P had several effects on the recoverable loss of activity induced by carbachol (desensitization). Substance P caused a shift to the left in the EC50 for carbachol-induced desensitization at equilibrium. If cells were simultaneously incubated with carbachol and substance P7-11, a low-potency analog of substance P, an increase in the rate of formation of a state of the receptor that was kinetically indistinguishable from the state induced by carbachol alone was observed. However, not all inhibition of nicotinic cholinergic function could be explained by an increased rate of formation of a desensitized receptor and it is concluded that substance P causes both enhanced desensitization and block of the nicotinic receptor-linked channel.     

Specificity of Muscarinic Acetylcholine Receptor Regulation by Receptor Activity

Abstract— Regulation of muscarinic acetylcholine receptor concentration by receptor activity in neuron-like NG108-15 hybrid cells is a highly specific process. Receptor levels, monitored by binding of [³H]quinuclidinyl benzilate ([³H]QNB), decreased 50-75% following 24-h incubation of cells with muscarinic agonists, but none of the following cellular processes was altered by this chronic receptor stimulation: (1) glycolytic energy metabolism, measured by [³H]deoxy- d -glucose ([³H]DG) uptake and retention; (2) rate of cell division; (3) transport, measured by [³H]valine and [³H]uridine uptake; (4) RNA biosynthesis, measured by [³H]uridine incorporation; (5) protein biosynthesis, measured by [³H]valine and [³⁵S]methionine incorporation into total protein and into protein fractions obtained by polyacrylamide gel electrophoresis. In contrast, chronic stimulation did cause a threefold decrease in the capacity of carbachol to stimulate phosphatidylinositol (PI) turnover, a receptor-mediated response. In addition to cholinomimetics, the neuroeffector adenosine (1 m m for 24 h) also caused a decrease in [³H]QNB binding levels, but chronic stimulation of α -adrenergic, opiate, prostaglandin E₁, and prostaglandin F_2α receptors found on NG108-15 cells caused no changes. The data indicate that loss of muscarinic receptors caused by receptor stimulation is not a consequence of fundamental changes evoked in overall cellular physiology but reflects a specific regulation of cholinoceptive cell responsiveness.     

A Lipid-dependent Uncoupled Conformation of the Acetylcholine Receptor

Lipids influence the ability of Cys-loop receptors to gate open in response to neurotransmitter binding, but the underlying mechanisms are poorly understood. With the nicotinic acetylcholine receptor (nAChR) from Torpedo, current models suggest that lipids modulate the natural equilibrium between resting and desensitized conformations. We show that the lipid-inactivated nAChR is not desensitized, instead it adopts a novel conformation where the allosteric coupling between its neurotransmitter-binding sites and transmembrane pore is lost. The uncoupling is accompanied by an unmasking of previously buried residues, suggesting weakened association between structurally intact agonist-binding and transmembrane domains. These data combined with the extensive literature on Cys-loop receptor-lipid interactions suggest that the M4 transmembrane helix plays a key role as a lipid-sensor, translating bilayer properties into altered nAChR function.     

Phospholipid Asymmetry in Acetylcholine Receptor Clusters

We modified the lipids of rat myotubes in tissue culture to determine the transmembrane orientation of aminophospholipids in clusters of acetylcholine receptors (AChR). Trinitrobenzenesulfonic acid and N -hydroxysuccinimidobiotin were used to modify the amino groups of phospholipids. Reaction conditions were selected to prevent penetration of the chemical probes into the cell interior. Fluorescence microscopy was used to confirm that the probes remained impermeant. Analysis of aminophospholipids associated with clusters isolated from chemically modified cells and comparisons to results of chemically modifying isolated acetylcholine receptor clusters indicated that at least 77% of plasma membrane aminophospholipids was located in the interior leaflet of the lipid bilayer. We address the possibility that aminophospholipids on the inner lipid leaflet may contribute to the association between the cytoskeleton and the membrane at AChR clusters.     

Neural Regulation of Properties of the Nicotinic Acetylcholine Receptor

Abstract

During nerve-muscle synapse formation, acetylcholine receptors become localized and modified to allow efficient transfer of information from nerve to muscle. In this paper we summarize our studies on two aspects of receptor modulation—their concentration at synaptic sites and their ability to desensitize in response to prolonged application of agonist. We demonstrate that receptor localization is a complex event which extensively reorganizes the structure of the junctional region. This allows the subsequent influences of contraction to be exerted differently in junctional and extrajunctional regions. We indicate that increases in muscle cell Ca²⁺ appear to mediate some of the effects of muscle contraction and suggest how regulation of Ca²⁺ levels may specify junctional and extrajunctional differences. Finally, we discuss the role of receptor phosphorylation in determining the rate of desensitization.     

Glycoprotein Properties of the Solubilized Atrial Muscarinic Acetylcholine Receptor

Abstract: The muscarinic acetylcholine receptor from porcine atria exhibits sialoglycoprotein characteristics based on its sensitivity to neuraminidase digestion and its ability to interact specifically with lectin affinity resins when solubilized with a digitonin/cholate mixed detergent system. Differential lectin binding properties of the neuraminidase-treated and untreated receptor suggest that high-affinity binding to immobilized wheat germ agglutinin is accomplished through the presence of both terminal sialic acid and internal N -acetylglucosamine or its β(1→4)-linked oligomers.     

Automated Design of Probes for rRNA-Targeted Fluorescence In Situ Hybridization Reveals the Advantages of Using Dual Probes for Accurate Identification

Fluorescence in situ hybridization (FISH) is a common technique for identifying cells in their natural environment and is often used to complement next-generation sequencing approaches as an integral part of the full-cycle rRNA approach. A major challenge in FISH is the design of oligonucleotide probes with high sensitivity and specificity to their target group. The rapidly expanding number of rRNA sequences has increased awareness of the number of potential nontargets for every FISH probe, making the design of new FISH probes challenging using traditional methods. In this study, we conducted a systematic analysis of published probes that revealed that many have insufficient coverage or specificity for their intended target group. Therefore, we developed an improved thermodynamic model of FISH that can be applied at any taxonomic level, used the model to systematically design probes for all recognized genera of bacteria and archaea, and identified potential cross-hybridizations for the selected probes. This analysis resulted in high-specificity probes for 35.6% of the genera when a single probe was used in the absence of competitor probes and for 60.9% when up to two competitor probes were used. Requiring the hybridization of two independent probes for positive identification further increased specificity. In this case, we could design highly specific probe sets for up to 68.5% of the genera without the use of competitor probes and 87.7% when up to two competitor probes were used. The probes designed in this study, as well as tools for designing new probes, are available online (http://DECIPHER.cee.wisc.edu).     

Chemical Modification of the Active Site of the Acetylcholine Receptor

The receptor for acetylcholine in the subsynaptic membrane of the electroplax of Electrophorus electricus is a protein with a disulfide bond in the vicinity of the active site. This disulfide can be reduced and reoxidized with concomitant inhibition and restoration of the response to acetylcholine and other monoquaternary ammonium-depolarizing agents. Conversely, the bisquaternary hexamethonium, normally a competitive inhibitor, causes depolarization, and the activity of decamethonium is increased following reduction of the disulfide. The reduced receptor can be alkylated by various maleimide derivatives and is then no longer reoxidizable. Some quaternary ammonium maleimide derivatives act as affinity labels of the reduced receptor, alkylating it at a rate three orders of magnitude faster then do uncharged maleimide derivatives. Other types of potential affinity labels also react only with the reduced receptor and the resulting covalently attached quaternary ammonium moieties interact with the active site, strongly activating the receptor. These results suggest a model for the active site and its transitions in which an activator such as acetylcholine bridges between a negative subsite and a hydrophobic subsite in the vicinity of the disulfide, causing an altered conformation around the negative subsite and a decrasee of a few angstroms in the distance between the two subsites.     

Alteration in Ion Channel Function of Mouse Nicotinic Acetylcholine Receptor by Mutations in the M4 Transmembrane Domain

The effect of structural alterations of the M4 transmembrane segment in the Torpedo californica AChR has shown that substitution of specific residues can be critical to the channel gating (Lasalde et al., 1996). In a previous study we found that phenylalanine and tryptophan substitutions at the αC418 residue in the M4 transmembrane segment of the Torpedo californica AChR significantly altered ion channel function (Lee et al., 1994; Ortiz-Miranda et al., 1997). Cassette mutagenesis was used to mutate the Cys residue at the corresponding C418 position in the α subunit of mouse AChR. A total of nine mutations on the mouse αC418 position were tested, including the αC418A, αC418V, αC418L, αC418S, αC418M, αC418W, αC418H, αC418E and αC418G mutants. All the mutants tested were functional except the αC418G which was not expressed on the surface of the oocyte. The data obtained from macroscopic and single channel currents demonstrate that different types of amino acids can be accommodated at this presumably lipid-exposed position without loss of ion-channel function. As with the Torpedo AChR, the mutation of Cys to Trp dramatically decreased the EC₅₀ for acetylcholine and increased channel open time. The lack of expression of the mouse αC418G suggest that there are some differences in folding, oligomerization and perhaps transport to the surface membrane for this mutant between the Torpedo and the mammalian AChR. Received: 30 December 1998/Revised: 13 April 1999