Pharmacological properties and predicted binding mode of arylmethylene quinuclidine-like derivatives at the α3ß4 nicotinic acetylcholine receptor (nAChR).

We have carried out a pharmacological evaluation of arylmethylene quinuclidine derivatives interactions with human α3ß4 nAChRs subtype, using cell-based receptor binding, calcium-influx, electrophysiological patch-clamp assays and molecular modeling techniques. We have found that the compounds bind competitively to the α3ß4 receptor with micromolar affinities and some of the compounds behave as non-competitive antagonists (compounds 1, 2 and 3), displaying submicromolar IC(50) values. These evidences suggest a mixed mode of action for these compounds, having interactions at the orthosteric site and more pronounced interactions at an allosteric site to block agonist effects. One of the compounds, 1-benzyl-3-(diphenylmethylene)-1-azoniabicyclo[2.2.2]octane chloride (compound 3), exhibited poorly reversible use-dependent block of α3ß4 channels. We also found that removal of a phenyl group from compound 1 confers a partial agonism to the derived analog (compound 6). Introducing a hydrogen-bond acceptor into the 3-benzylidene quinuclidine derivative (compound 7) increases agonism potency at the α3ß4 receptor subtype. Docking into the orthosteric binding site of a α3ß4 protein structure derived by comparative modeling accurately predicted the experimentally-observed trend in binding affinity. Results supported the notion that binding requires a hydrogen bond formation between the ligand basic nitrogen and the backbone carbonyl oxygen atom of the conserved Trp-149.

Validation of a high-throughput, automated electrophysiology platform for the screening of nicotinic agonists and antagonists.

High-throughput compound screening using electrophysiology-based assays represents an important tool for biomedical research and drug discovery programs. The recent development and availability of devices capable of performing high-throughput electrophysiology-based screening have brought the need to validate these tools by producing data that are consistent with results obtained with conventional electrophysiological methods. In this study, we compared the response properties of hα3ß4 and hα4ß2 nicotinic receptors to their endogenous ligand acetylcholine (ACh) using three separate electrophysiology platforms: Dynaflow (low-throughput, manual system), PatchXpress 7000A (medium-throughput automated platform), and IonWorks Barracuda (high-throughput automated platform). We found that despite the differences in methodological approaches between these technologies, the EC(50) values from the ACh dose-response curves were consistent between all three platforms. In addition, we have validated the IonWorks Barracuda for both competitive and uncompetitive inhibition assays by using the competitive nicotinic antagonist dihydro-beta-erythroidin (DHßE) and uncompetitive nicotinic antagonist mecamylamine. Furthermore, we have demonstrated the utility of a custom-written algorithm for generating dose-response curves from multiple extrapolated current metrics that allows for discriminating between competitive and uncompetitive inhibition while maintaining high-throughput capacity. This study provides validation of the consistency of results using low-, medium-, and high-throughput electrophysiology platforms and supports their use for screening nicotinic compounds.

Structure-activity studies of 7-heteroaryl-3-azabicyclo[3.3.1]non-6-enes: a novel class of highly potent nicotinic receptor ligands.

The potential for nicotinic ligands with affinity for the α4ß2 or α7 subtypes to treat such diverse diseases as nicotine addiction, neuropathic pain, and neurodegenerative and cognitive disorders has been exhibited clinically for several compounds while preclinical activity in relevant in vivo models has been demonstrated for many more. For several therapeutic programs, we sought nicotinic ligands with various combinations of affinity and function across both subtypes, with an emphasis on dual α4ß2-α7 ligands, to explore the possibility of synergistic effects. We report here the structure-activity relationships (SAR) for a novel series of 7-heteroaryl-3-azabicyclo[3.3.1]non-6-enes and characterize many of the analogues for activity at multiple nicotinic subtypes.

Development and optimization of a high-throughput electrophysiology assay for neuronal alpha4beta2 nicotinic receptors.

Historically, the identification of alpha4beta2 nicotinic acetylcholine receptor ligands has been based on high-throughput radioligand binding, rubidium efflux assays and Ca++ flux assays using a fluorometric imaging plate reader (FLIPR). Among other approaches, low-throughput electrophysiological assays in Xenopus oocytes and two channel application "liquid filament" systems for mammalian cells have been commonly used. More recent technical innovations that have been introduced into the field of electrophysiology allow for automated simultaneous multi-channel operation. Here we report the development and optimization of a high-throughput electrophysiological assay for identifying functionally active alpha4beta2 nicotinic receptor ligands using such a system. Characterization of the test system yielded results comparable to those obtained by other investigators using conventional electrophysiological assays. For example, the concentration-response relationships obtained for alpha4beta2 receptor activation by acetylcholine and nicotine were best described by biphasic Hill equations, and the inhibition of alpha4beta2 receptor currents by the nicotinic antagonist dihydro-beta-erythroidine was consistent with previously published results. Functional up-regulation of alpha4beta2 receptors by prolonged exposure to nicotine or lower temperature was also confirmed. Using this methodology we were able to characterize the activation of alpha4beta2 receptors by multiple compounds in a mammalian cell expression system, exemplifying its utility for rapid identification of novel nicotinic ligands within a screening cascade. Our results demonstrate the utility of this electrophysiological tool for the discovery of alpha4beta2 nicotinic acetylcholine receptor ligands with potential applications in numerous clinical indications.

Variability in the measurement of hERG potassium channel inhibition: effects of temperature and stimulus pattern.

INTRODUCTION: In vitro evaluation of drug effects on hERG K(+) channels is a valuable tool for identifying potential proarrhythmic side effects in drug safety testing. Patch-clamp recording of hERG K(+) current in mammalian cells can accurately evaluate drug effects, but the methodology has not been standardized, and results vary widely. Our objective was to evaluate two potential sources of variability: the temperature at which recordings are performed and the voltage pulse protocol used to activate hERG K(+) channels expressed in HEK293 cells. METHODS: A panel of 15 drugs that spanned a broad range of potency for hERG inhibition and pharmacological class was evaluated at both room and near-physiological temperatures using several patch-clamp voltage protocols. Concentration-response analysis was performed with three stimulus protocols: 0.5- and 2-s step pulses, or a step-ramp pattern. RESULTS: Block by 2 of the 15 drugs tested, d,l-sotalol (antiarrhythmic) and erythromycin (antibiotic), was markedly temperature sensitive. hERG inhibition measured using a 2-s step-pulse protocol underestimated erythromycin potency compared with results obtained with a step-ramp protocol. Using conservative acceptance criteria and the step-ramp protocol, the IC(50) values for hERG block differed by less than twofold for 15 drugs. DISCUSSION: Data obtained at near-physiological temperatures using a step-ramp pattern are highly repeatable and provide a conservative safety evaluation of hERG inhibition.

Kurtoxin, a gating modifier of neuronal high- and low-threshold ca channels.

Studies of Ca channels expressed in oocytes have identified kurtoxin as a promising tool for functional and structural studies of low-threshold T-type Ca channels. This peptide, isolated from the venomous scorpion Parabuthus transvaalicus, inhibits low-threshold alpha1G and alpha1H Ca channels expressed in oocytes with relatively high potency and high selectivity. Here we report its effects on Ca channel currents, carried by 5 mm Ba(2+) ions, in rat central and peripheral neurons. In thalamic neurons 500 nm kurtoxin inhibited T-type Ca channel currents almost completely (90.2 +/- 2.5% at -85 mV; n = 6). Its selectivity, however, was less than expected because it also reduced the composite high-threshold Ca channel current recorded in these cells (46.1 +/- 6.9% at -30 mV; n = 6). In sympathetic and thalamic neurons, 250-500 nm kurtoxin partially inhibited N-type and L-type Ca channel currents, respectively. It similarly reduced the high-threshold Ca channel current that remains after a blockade of P-type, N-type, and L-type Ca channels in thalamic neurons. In contrast, kurtoxin facilitated steady-state P-type Ba currents in Purkinje neurons (by 34.9 +/- 3.7%; n = 10). In all cases the kurtoxin effect was voltage-dependent and entailed a modification of channel gating. Exposure to kurtoxin slowed current activation kinetics, although its effects on deactivation varied with the channel types. Kurtoxin thus appears as a unique gating-modifier that interacts with different Ca channel types with high affinity. This unusual property and the complex gating modifications it induces may facilitate future studies of gating in voltage-dependent ion channels.