In vitro synthesis of RNA for expression of ion channels in Xenopus oocytes

The use of Xenopus oocytes in drug screening

INTRODUCTION

The physiological roles of ion channels are receiving increased interest in both basic research and drug discovery, and a demand for pharmacological approaches that can characterize or screen ion channels and their ligands with higher throughput has emerged. Traditionally, screening of compound libraries at ion channel targets has been performed using assays such as binding assays, fluorescence-based assays and flux assays that allow high-throughput, but sacrifice high data quality. The use of these assays with ion channel targets can also be problematic, emphasizing the usefulness of automated Xenopus oocyte electrophysiological assays in drug screening.

AREAS COVERED

This review summarizes the use of Xenopus oocytes in drug screening, presents the advantages and disadvantages of the use of Xenopus oocytes as expression system, and addresses the options available for automated two-electrode voltage-clamp recordings from Xenopus oocytes.

EXPERT OPINION

Automated and manual Xenopus oocyte two-electrode voltage-clamp recordings are useful and important techniques in drug screening. Although they are not compatible with high-throughput experimentation, these techniques are excellent in combination or as alternatives to fluorescence-based assays for hit validation, screening of focused compound libraries and safety screening on ion channels with their high flexibility for the choice of molecular targets, quality of data and reproducibility.

Single cell electric impedance topography: mapping membrane capacitance

Single-cell electric impedance topography (sceTopo), a technique introduced here, maps the spatial distribution of capacitance (i.e. displacement current) associated with the membranes of isolated, living cells. Cells were positioned in the center of a circular recording chamber surrounded by eight electrodes. Electrodes were evenly distributed on the periphery of the recording chamber. Electric impedance measured between adjacent electrode pairs (10 kHz-5 MHz) was used to construct topographical maps of the spatial distribution of membrane capacitance. Xenopus Oocytes were used as a model cell to develop sceTopo because these cells consist of two visually distinguishable hemispheres, each with distinct membrane composition and structure. Results showed significant differences in the imaginary component of the impedance between the two oocyte hemispheres. In addition, the same circumferential array was used to map the size of the extracellular electrical shunt path around the cell, providing a means to estimate the location and shape of the cell in the recording chamber.

Xenopus oocyte electrophysiology in GPCR drug discovery

Deorphanization of the large group of G protein-coupled receptors (GPCRs) for which an endogenous activating ligand has not yet been identified (orphan GPCRs) has become increasingly difficult. A specialized technique that has been successfully applied to deorphanize some of these GPCRs involves two-electrode voltage-clamp recordings of currents through ion channels, which are activated by GPCRs heterologously expressed in Xenopus oocytes. The ion channels that couple to GPCR activation in Xenopus oocytes can be endogenous calcium-activated chloride channels (CaCCs) or heterologously expressed G protein-coupled inwardly rectifying potassium channels (GIRKs). We will describe a general approach for expression of GPCRs in Xenopus oocytes and characterization of these using electrophysiological recordings. We will focus on the detection of GPCR activation by recordings of currents through CaCCs that are activated by calcium release from the endoplasmic reticulum and thus the G(q) signaling pathway.

Counting membrane-embedded KCNE beta-subunits in functioning K+ channel complexes

Ion channels are multisubunit proteins responsible for the generation and propagation of action potentials in nerve, skeletal muscle, and heart as well as maintaining salt and water homeostasis in epithelium. The subunit composition and stoichiometry of these membrane protein complexes underlies their physiological function, as different cells pair ion-conducting alpha-subunits with specific regulatory beta-subunits to produce complexes with diverse ion-conducting and gating properties. However, determining the number of alpha- and beta-subunits in functioning ion channel complexes is challenging and often fraught with contradictory results. Here we describe the synthesis of a chemically releasable, irreversible K(+) channel inhibitor and its iterative application to tally the number of beta-subunits in a KCNQ1/KCNE1 K(+) channel complex. Using this inhibitor in electrical recordings, we definitively show that there are two KCNE subunits in a functioning tetrameric K(+) channel, breaking the apparent fourfold arrangement of the ion-conducting subunits. This digital determination rules out any measurable contribution from supra, sub, and multiple stoichiometries, providing a uniform structural picture to interpret KCNE beta-subunit modulation of voltage-gated K(+) channels and the inherited mutations that cause dysfunction. Moreover, the architectural asymmetry of the K(+) channel complex affords a unique opportunity to therapeutically target ion channels that coassemble with KCNE beta-subunits.

Nanotechnology for neuronal ion channels

Ion channels provide the basis for the regulation of electrical excitability in the central and peripheral nervous systems. This review deals with the techniques that make the study of structure and function of single channel molecules in living cells possible. These are the patch clamp technique, which was derived from the conventional voltage clamp method and is currently being developed for automated and high throughput measurements; and fluorescence and nano-techniques, which were originally applied to non-biological surfaces and are only recently being used to study cell membranes and their proteins, especially in combination with the patch clamp technique. The characterisation of the membrane channels by techniques that resolve their morphological and physical properties and dynamics in space and time in the nano range is termed nanoscopy.

Differential Expression of Voltage-Gated K + Channel Genes in Arteries From Spontaneously Hypertensive and Wistar-Kyoto Rats

Abstract —Voltage-gated K + currents play an important role in determining membrane potential, intracellular Ca 2+ , and contraction in arterial smooth muscle. In this study, the expression of genes encoding voltage-gated K + channels of the Kv1.X family was compared in arteries from spontaneously hypertensive rats (SHR) and Wistar-Kyoto rats (WKY). Expression of Kv1.X in thoracic aorta, mesenteric arteries, tail artery, and heart was determined, both qualitatively and quantitatively, by reverse transcription–polymerase chain reaction. Our results demonstrate distinct but overlapping patterns of expression in vascular tissues. In general, Kv1.2 and Kv1.5 were most highly represented, and the levels of Kv1.2 were significantly larger in all tissues from SHR. Levels of Kv1.5 in arteries did not differ significantly between strains but were greater in SHR heart. Moderate levels of Kv1.3 and Kvβ1.1 expression were also found in all tissues and were larger in SHR. Kv1.1 expression was not different between the 2 strains, and no significant expression of Kv1.4 (except in heart and aorta), Kv1.6, or Kvβ2.1 was observed in either strain. Kv1.2 and Kv1.5 transcripts represent ≈1 to 2 parts/10 5 of total mesenteric arterial RNA with ≈2- to 5-fold lower levels in aorta and tail artery. Whole-cell voltage-gated K + channel currents, recorded from mesenteric arterial myocytes, were larger in SHR than WKY (eg, at 0 mV: 7.3±0.8 versus 10.9±1.2 pA/pF). The voltage dependence of activation was more negative in SHR (V 0.5 : −20±4 mV versus −32±3 mV) but that of availability was not different. These results indicate that Kv1.X genes are differentially expressed between WKY and SHR (especially Kv1.2 and Kvβ1.1). These differences in gene expression are associated with a greater voltage-gated K + channel current density in SHR and shifted voltage-dependent activation compared with WKY. These differences may be a compensatory mechanism related to the membrane potential depolarization in SHR or some manifestation thereof.

Cloning and functional expression of two families of beta-subunits of the large conductance calcium-activated K+ channel

We report here a characterization of two families of calcium-activated K(+) channel beta-subunits, beta2 and beta3, which are encoded by distinct genes that map to 3q26.2-27. A single beta2 family member and four alternatively spliced variants of beta3 were investigated. These subunits have predicted molecular masses of 27. 1-31.6 kDa, share approximately 30-44% amino acid identity with beta1, and exhibit distinct but overlapping expression patterns. Coexpression of the beta2 or beta3a-c subunits with a BK alpha-subunit altered the functional properties of the current expressed by the alpha-subunit alone. The beta2 subunit rapidly and completely inactivated the current and shifted the voltage dependence for activation to more polarized membrane potentials. In contrast, coexpression of the beta3a-c subunits resulted in only partial inactivation of the current, and the beta3b subunit conferred an apparent inward rectification. Furthermore, unlike the beta1 and beta2 subunits, none of the beta3 subunits increased channel sensitivity to calcium or voltage. The tissue-specific expression of these beta-subunits may allow for the assembly of a large number of distinct BK channels in vivo, contributing to the functional diversity of native BK currents.

Divalent cation selectivity is a function of gating in native and recombinant cyclic nucleotide-gated ion channels from retinal photoreceptors

The selectivity of Ca2+ over Na+ is approximately 3.3-fold larger in cGMP-gated channels of cone photoreceptors than in those of rods when measured under saturating cGMP concentrations, where the probability of channel opening is 85-90%. Under physiological conditions, however, the probability of opening of the cGMP-gated channels ranges from its largest value in darkness of 1-5% to essentially zero under continuous, bright illumination. We investigated the ion selectivity of cGMP-gated channels as a function of cyclic nucleotide concentration in membrane patches detached from the outer segments of rod and cone photoreceptors and have found that ion selectivity is linked to gating. We determined ion selectivity relative to Na+ (PX/PNa) from the value of reversal potentials measured under ion concentration gradients. The selectivity for Ca2+ over Na+ increases continuously as the probability of channel opening rises. The dependence of PCa/PNa on cGMP concentration, in both rods and cones, is well described by the same Hill function that describes the cGMP dependence of current amplitude. At the cytoplasmic cGMP concentrations expected in dark-adapted intact photoreceptors, PCa/PNa in cone channels is approximately 7.4-fold greater than that in rods. The linkage between selectivity and gating is specific for divalent cations. The selectivity of Ca2+ and Sr2+ changes with cGMP concentration, but the selectivity of inorganic monovalent cations, Cs+ and NH4+, and organic cations, methylammonium+ and dimethylammonium+, is invariant with cGMP. Cyclic nucleotide-gated channels in rod photoreceptors are heteromeric assemblies of alpha and beta subunits. The maximal PCa/PNa of channels formed from alpha subunits of bovine rod channels is less than that of heteromeric channels formed from alpha and beta subunits. In addition, Ca2+ is a more effective blocker of channels formed by alpha subunits than of channels formed by alpha and beta subunits. The cGMP-dependent shift in divalent cation selectivity is a property of alphabeta channels and not of channels formed from alpha subunits alone.

The actions of muscle relaxants at nicotinic acetylcholine receptor isoforms

The pharmacological diversity of the different isoforms of the nicotinic acetylcholine receptor arises from the diversity of the subunits that assemble to form the native receptors. The aim of this study was to investigate the actions of the muscle relaxants d-tubocurarine, pancuronium and vecuronium on different isoforms of nicotinic acetylcholine receptors (mouse foetal muscle, mouse adult muscle and a rat neuronal), using the Xenopus oocyte expression system. Oocytes were injected with cRNAs for alpha, beta, gamma, delta subunits (the native foetal muscle subunit combination), or with cRNAs for alpha, beta, epsilon, delta subunits (the native adult muscle subunit combination), or with cRNAs for alpha4beta2 subunits (a putative native neuronal subunit combination). Acetylcholine had a similar potency at all three subunit combinations (EC50 11.6, 17.4 and 19.1 microM, respectively). At all three receptor types, d-tubocurarine and pancuronium blocked the responses elicited by acetylcholine in a reversible manner. Furthermore, the inhibition of the acetylcholine currents for the foetal and adult nicotinic acetylcholine receptor by pancuronium and d-tubocurarine was independent of the holding voltage over the range -100 to -40 mV. In oocytes expressing the foetal muscle nicotinic acetylcholine receptors the inhibition of the current in response to 100 microM acetylcholine by 10 nM d-tubocurarine was 29 +/- 5% (mean +/- S.E.M.; n = 7), and the inhibition by 10 nM pancuronium was 39 +/- 6% (mean +/- S.E.M.; n = 8; P > 0.05 vs. d-tubocurarine). However, in the adult form of the muscle nicotinic acetylcholine receptor, 10 nM d-tubocurarine and 10 nM pancuronium were both more effective at blocking the response to 100 microM acetylcholine compared to the foetal muscle nicotinic acetylcholine receptor, with values of 55 +/- 5% (P < 0.01; n = 12) and 60 +/- 4% (P < 0.001; n = 10), respectively. Thus the developmental switch from the gamma to the epsilon subunit alters the antagonism of the nicotinic acetylcholine receptor for both pancuronium and d-tubocurarine. Vecuronium was more potent than pancuronium. One nM vecuronium reduced the response to 100 microM acetylcholine by 71 +- 6% (n = 10) for foetal and 63 +/- 5% (n = 4) for adult nicotinic acetylcholine receptors. In the alpha4beta2 neuronal nicotinic acetylcholine receptor combination, 10 nM pancuronium was a more effective antagonist of the response to 100 microM acetylcholine (69 +/- 6%, n = 6) than 10 nM d-tubocurarine (30 +/- 5%; n = 6; P < 0.05 compared to pancuronium). This is in contrast to the adult muscle nicotinic acetylcholine receptor, where pancuronium and d-tubocurarine were equieffective. The expression of the beta2 subunit with muscle alpha, epsilon and delta subunits formed a functional receptor which was blocked by pancuronium and d-tubocurarine in a similar manner to the alphabeta1epsilondelta subunit consistent with the hypothesis that the beta subunit is not a major determinant in the action of this drug at the adult muscle nicotinic acetylcholine receptor.

K+ currents expressed from the guinea pig cardiac IsK protein are enhanced by activators of protein kinase C

We have isolated cardiac cDNA and genomic clones encoding the guinea pig IsK protein. The deduced amino acid sequence is approximately 78% identical to the rat, mouse, and human variants of this channel, and the structure of the gene encoding the protein is also similar to that in other species. For example, the gene is present only once in the haploid genome, the protein-coding sequence is present on a single uninterrupted exon, an intron exists in the 5' untranslated domain, and multiple alternative polyadenylation sites are used in processing the transcript. Expression of the guinea pig protein in Xenopus oocytes results in a slowly activating, voltage-dependent K+ current, IsK, similar to those expressed previously from the rat, mouse, and human genes. However, in sharp contrast to the rat and mouse currents, activation of protein kinase C with phorbol esters increases the amplitude of the guinea pig IsK current, analogous to its effects on the endogenous IKs current in guinea pig cardiac myocytes. Mutagenesis of the guinea pig cDNA to alter four cytoplasmic amino acid residues alters the phenotype of the current response to protein kinase C from enhancement to inhibition, mimicking that of rat and mouse IsK currents. This mutation is consistent with reports that phosphorylation of Ser-102 by protein kinase C decreases the current amplitude. These data explain previously reported differences in the regulatory properties between recombinant rat or mouse IsK channels and native guinea pig IKs channels and provide further evidence that the IsK protein forms the channels that underlie the IKs current in the heart.

Species variants of the IsK protein: differences in kinetics, voltage dependence, and La3+ block of the currents expressed in Xenopus oocytes

We have compared the slowly activating K+ currents (IsK) resulting from the expression of the human, mouse, or rat IsK proteins in Xenopus oocytes, utilizing natural, species-dependent sequence variations to initiate structure-function studies of this channel. Differences were found between the human and rodent currents in their voltage dependence, kinetics, and sensitivity to external La3+. The current/voltage relationships of the human and rat IsK currents differed significantly, with greater depolarizations required for activation of the human channel. The first 30 s of activation during depolarizations to potentials between -10 and +40 mV was best described by a triexponential function for each of the three species variants. The activation rates were, however, significantly faster for the human current than for either of the rodent forms. Similarly, deactivation kinetics were best described as a biexponential decay for each of the species variants but the human currents deactivated more rapidly than the rodent currents. The human and the rodent forms of IsK were also differentially affected by external La3+. Low concentrations (10, 50 microM) rapidly and reversibly reduced the magnitude of the mouse and rat currents during a test depolarization and increased the deactivation rates of the tail currents. In contrast, the magnitude and deactivation rates of the human IsK currents were unaffected by 50 microM La3+.