Fluorescence measurements reveal stoichiometry of K+ channels formed by modulatory and delayed rectifier alpha-subunits

Modulatory alpha-subunits, which comprise one-fourth of all voltagegated K(+) channel (Kv) alpha-subunits, do not assemble into homomeric channels, but selectively associate with delayed rectifier Kv2 subunits to form heteromeric channels of unknown stoichiometry. Their distinct expression patterns and unique functional properties have made these channels candidate molecular correlates for a broad set of native K(+) currents. Here, we combine FRET and electrophysiological measurements to determine the stoichiometry and geometry of heteromeric channels composed of the delayed rectifier Kv2.1 subunit and the modulatory Kv9.3 alpha-subunit. Kv channel alpha-subunits were fused with GFP variants, and heteromerization of different combinations of tagged and untagged alpha-subunits was studied. FRET, evaluated by acceptor photobleaching, was only observed upon formation of functional channels. Our results, obtained from two independent experimental paradigms, suggest the formation of heteromeric Kv2.1/Kv9.3 channels of fixed stoichiometry consisting of three Kv2.1 subunits and one Kv9.3 subunit. Strikingly, despite this uneven stoichiometry, we find that heteromeric Kv2.1/Kv9.3 channels maintain a pseudosymmetric arrangement of subunits around the central pore.     

Abscisic acid regulation of guard-cell K+ and anion channels in Gbeta- and RGS-deficient Arabidopsis lines

In mammals, basal currents through G protein-coupled inwardly rectifying K(+) (GIRK) channels are repressed by Galpha(i/o)GDP, and the channels are activated by direct binding of free Gbetagamma subunits released upon stimulation of Galpha(i/o)-coupled receptors. However, essentially all information on G protein regulation of GIRK electrophysiology has been gained on the basis of coexpression studies in heterologous systems. A major advantage of the model organism, Arabidopsis thaliana, is the ease with which knockout mutants can be obtained. We evaluated plants harboring mutations in the sole Arabidopsis Galpha (AtGPA1), Gbeta (AGB1), and Regulator of G protein Signaling (AtRGS1) genes for impacts on ion channel regulation. In guard cells, where K(+) fluxes are integral to cellular regulation of stomatal apertures, inhibition of inward K(+) (K(in)) currents and stomatal opening by the phytohormone abscisic acid (ABA) was equally impaired in Atgpa1 and agb1 single mutants and the Atgpa1 agb1 double mutant. AGB1 overexpressing lines maintained a wild-type phenotype. The Atrgs1 mutation did not affect K(in) current magnitude or ABA sensitivity, but K(in) voltage-activation kinetics were altered. Thus, Arabidopsis cells differ from mammalian cells in that they uniquely use the Galpha subunit or regulation of the heterotrimer to mediate K(in) channel modulation after ligand perception. In contrast, outwardly rectifying (K(out)) currents were unaltered in the mutants, and ABA activation of slow anion currents was conditionally disrupted in conjunction with cytosolic pH clamp. Our studies highlight unique aspects of ion channel regulation by heterotrimeric G proteins and relate these aspects to stomatal aperture control, a key determinant of plant biomass acquisition and drought tolerance.     

Single mutations convert an outward K+ channel into an inward K+ channel

Shaker-type K(+) channels in plants display distinct voltage-sensing properties despite sharing sequence and structural similarity. For example, an Arabidopsis K(+) channel (SKOR) and a tomato K(+) channel (LKT1) share high amino acid sequence similarity and identical domain structures; however, SKOR conducts outward K(+) current and is activated by positive membrane potentials (depolarization), whereas LKT1 conducts inward current and is activated by negative membrane potentials (hyperpolarization). The structural basis for the "opposite" voltage-sensing properties of SKOR and LKT1 remains unknown. Using a screening procedure combined with random mutagenesis, we identified in the SKOR channel single amino acid mutations that converted an outward-conducting channel into an inward-conducting channel. Further domain-swapping and random mutagenesis produced similar results, suggesting functional interactions between several regions of SKOR protein that lead to specific voltage-sensing properties. Dramatic changes in rectifying properties can be caused by single amino acid mutations, providing evidence that the inward and outward channels in the Shaker family from plants may derive from the same ancestor.     

Role of K(+) channels in frequency regulation of spontaneous action potentials in rat pituitary GH(3) cells

The frequency of spontaneous action potentials (SAP) is important in the regulation of hormone secretion. The decrease in K(+) conductance is known as a primary mechanism for increasing SAP frequency. To investigate the nature of K(+) channels that contribute to the frequency regulation of the SAP in rat clonal pituitary GH(3) cells, the effect of various K(+) channel blockers on the SAP and membrane currents were recorded using the patch-clamp technique. A classical inward rectifying K(+) channel blocker, Cs(+) (5 mM), caused an increase in firing frequency and depolarization in after-hyperpolarization (AHP) voltage. An ETHER-A-GO-GO(ERG) type K(+) channel blocker, E-4031 (5 microM), caused no significant effect on the SAP. Tetraethylammonium (TEA, 10 mM) decreased firing frequency and increased the duration of SAP. These effects were not changed by the presence of high concentration of Ca(2+) buffer (10 mM EGTA or BAPTA) in pipette solutions. In voltage-clamp experiments, Cs(+) and E-4031 did not affect outwardly rectifying K(+) currents, but significantly inhibited inwardly rectifying K(+) currents recorded in isotonic K(+) solution. However, the kinetics of Cs(+)-sensitive current and E-4031-sensitive current were distinctive: the time to peak was more immediate and the decay rate was slower in Cs(+)-sensitive current than in E-4031-sensitive current. These results imply that Cs(+) and E-4031 inhibit the distinct components of inwardly rectifying K(+) currents, and that the contribution of the Cs(+)-sensitive current can be immediate on repolarization and can last more effectively over pacemaking potential range than E-4031-sensitive current.     

Postnatal development of atrial repolarization in the mouse

OBJECTIVES AND METHODS: This study examines postnatal development of action potential duration (APD) and voltage-dependent K(+) currents in mouse atrial myocytes and compares the expression levels of corresponding K(+) channels between adult and neonatal mouse atrial tissues. APD and K(+) currents were compared between atrial myocytes isolated from postnatal Day-1, Day-7, Day-20, and adult mice. RESULTS: All K(+) currents examined underwent significant up-regulation during postnatal life in mouse atrium, resulting in a dramatic shortening of the APD. The ultrarapid delayed rectifier (I(Kur)) was absent in the developing mouse heart and only contributed to repolarization in the adult mouse atrium, whereas the density of the other K(+) currents increased earlier during the developmental period. Indeed, the major changes in the expression of the inward rectifier current (I(K1)) occurred within the first week of life, the density of the Ca(2+)-independent transient outward K(+) current (I(to)) gradually increased while the development of the steady-state outward K(+) current (I(ss)) was completed within the first 3 weeks of life. Results of RNase protection assay and Western blot analysis confirmed that the postnatal development of the mouse atrial K(+) currents correlates with an increase in expression levels of underlying K(+) channel isoforms. CONCLUSION: These findings indicate that in mouse atrium, each K(+) current exhibits a specific postnatal development, suggesting that regulatory factors taking place during development are major determinants of the functional role of K(+) channels in cardiac repolarization. The mouse atrium is, therefore, a very interesting model to gain information on the mechanisms regulating K(+) channel activity.     

Serotonin increases an anomalously rectifying K+ current in the Aplysia neuron R15.

Previous work has shown that serotonin causes an increase in K+ conductance in the identified Aplysia neuron R15. This response is mediated by cAMP-dependent protein phosphorylation. The results presented here show that the K+ channel modulated by serotonin is an anomalous or inward rectifier (designated IR) that is present in R15 together with the three other distinct K+ channels previously described for this cell. Several lines of evidence indicate that this inward rectifier is partially activated in the resting cell and is further activated by serotonin. Voltage clamp analysis of resting and serotonin-evoked membrane currents at various external K+ concentrations shows that both currents have reversal potentials close to the potassium equilibrium potential, exhibit similar dependences in magnitude on external K+ concentration, and display marked anomalous rectification. The effects of particular monovalent and divalent cations are also similar on the resting and serotonin-evoked currents. Rb+, Cs+, and Ba2+ block both currents while Tl+ can substitute for K+ as a charge carrier and channel activator in both. These properties are characteristics of anomalous rectifiers in other systems. Furthermore, measurement of the voltage dependence of inactivation for the fast transient K+ current shows that this current cannot account for the anomalously rectifying K+ conductance in R15. The inward rectifier is therefore a separate current mediated by its own channels, the activity of which can be modulated by serotonin.     

IKs, a slow and intriguing cardiac K+ channel and its associated long QT diseases

Shaping of cardiac action potentials depends on a finely tuned orchestra of ion channels. Among them, K(+) channels probably form the most diverse family. They are responsible for inwardly rectifying (I(K1), I(KAch), I(KATP)), transient (I(to)), and sustained outward rectifying (I(Kur), I(Kr), I(Ks)) K(+) currents. The properties of these cardiac K(+) channels have recently been extensively reviewed. This article focuses on recent progress made toward understanding the molecular structure of the particular channel responsible for the slow outward K(+) current I(Ks) and its implication in the delayed ventricular repolarization that characterizes the congenital long QT syndrome.     

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.     

Cardiac ion channel expression and regulation: the role of innervation

The expression and function of numerous cardiac ion channels change with development and disease. Whereas multiple regulatory processes and molecular mechanisms are certainly involved, one factor, sympathetic innervation, contributes to many of the developmental changes and is suggested to play a role in pathology. The onset of cardiac sympathetic innervation of the mammalian ventricle during early post-natal life has been associated with functional alterations in several ionic currents, including Na(+), L-type Ca(2+), pacemaker, inward rectifier and transient outward K(+) currents. The neural signaling molecule is not the same in each case, with evidence pointing to contributions from sustained activation of myocardial neuropeptide Y receptors, alpha-adrenergic receptors and beta-adrenergic receptors, as well as additional, but as yet unidentified, targets. Knowledge of the mechanisms by which innervation regulates ion channel expression and function during normal development may aid efforts to reverse remodel the diseased heart and to target pharmacologic agents to remodeled channels.     

The number of K(+) channels in the plasma membrane of guard cell protoplasts changes in parallel with the surface area

The activity of the two dominant K(+) channels in the plasma membrane of Vicia faba guard cell protoplasts was examined during pressure-driven swelling. For this purpose, the K(+) currents and the membrane capacitance (C(m)) of guard cell protoplasts were recorded in parallel. A rise in C(m), reflecting an increase of the membrane surface area, was coupled to a proportional rise in conductance of both the K(+) inward and K(+) outward rectifier. The activation kinetics of the K(+) channels were not affected during this process. The quantitative and temporal coupling of C(m) and K(+) conductance can hence be interpreted as the result of the addition of active inward and outward rectifier K(+) channels to the plasma membrane during an increase in surface area.     

Four and a half LIM protein 1: a partner for KCNA5 in human atrium

AIMS: Protein-protein interactions are critical for the normal membrane trafficking, localization, and function of voltage-gated ion channels. In human heart, the Shaker-related voltage-gated K(+) channel KCNA5 alpha-subunit forms the major basis of an atrial-specific, ultra-rapid delayed rectifier K(+) current, I(Kur). We sought to identify proteins that interact with KCNA5 in human atrium and investigate their role in the I(Kur) complex. METHODS AND RESULTS: Using a glutathione-S-transferase (GST)-KCNA5 C-terminal fusion protein and mass spectrometry-based methods, the scaffolding protein four and a half LIM (for Lin-11, Isl-1, and Mec3) protein 1 (FHL1) was identified as a potential protein partner for KCNA5. Immunoprecipitation experiments confirmed a physical interaction of FHL1 with the K(+) channel complex in human atrium, as well as in Chinese hamster ovary (CHO) cells transfected with both KCNA5 and FHL1. In cotransfected cells, confocal microscopy demonstrated areas of colocalization after immunolabelling both proteins. To investigate the functional effects of this interaction, K(+) currents were recorded in CHO cells transfected with KCNA5 in the absence and presence of FHL1 coexpression. With coexpression of FHL1, K(+) current density was markedly increased, compared with cells expressing KCNA5 alone. This effect was associated with a shift in the voltage dependence of K(+) channel activation to more positive potentials, consistent with findings of I(Kur) in atrial myocytes. FHL1 also increased the extent and speed of K(+) current slow inactivation, with additional effects on the voltage dependence and recovery of this process. CONCLUSION: These results support a role of FHL1 as a key molecular component in the I(Kur) complex in human atrium, where it likely regulates functional expression of KCNA5.     

Defining the BK channel domains required for beta1-subunit modulation

In a wide variety of cell types, including neurons and smooth muscle cells, activation of the large-conductance voltage- and Ca(2+)-activated K(+) (BK) channels causes transient membrane hyperpolarization, thereby regulating cellular excitability. Similar to other voltage-gated ion channels, BK channels, a tetramer of alpha-subunits, associate with auxiliary beta-subunits in a tissue-specific manner, modifying the channel's gating properties. The BK beta1-subunit, which is expressed in smooth muscle, increases the apparent Ca(2+) sensitivity (marked by a hyperpolarizing shift in the conductance-voltage relationship at a given Ca(2+) concentration), slows macroscopic activation and deactivation, and is required for channel activation by 17beta-estradiol. The beta1-subunit is essential for normal regulation of vascular smooth muscle contractility and blood pressure. Little is known, however, about the molecular mechanisms of beta1-subunit modulation of alpha-subunits. Here we show that the beta1-subunit's modulation of the Ca(2+) and 17beta-estradiol sensitivities can be dissociated from its effects on gating kinetics by truncation of the alpha-subunit's extracellular N-terminal residues. The BK alpha-subunit N terminus interacts uniquely with the beta1-subunit: beta2 regulation of the alpha-subunit is unaltered by truncation of the N terminus. Although the functional interaction of alpha and beta1 requires the N-terminal tail of alpha, the physical association requires the S1, S2, and S3 transmembrane helices of alpha.     

Structural determinants and biophysical properties of HERG and KCNQ1 channel gating

The delayed rectifier K(+) currents, I(Kr) and I(Ks,) play a critical role in modulating the plateau phase of the cardiac action potential. HERG encodes the alpha-subunit of channels underlying I(Kr), while I(Ks) is composed of subunits encoded by KCNQ1 and KCNE1. Mutations in any of these genes cause the long QT syndrome, a disorder of myocellular repolarization that predisposes affected individuals to life-threatening arrhythmias. Elucidation of the molecular basis of these currents has led to significant advancements in our understanding of fundamental properties of channel function. This review summarizes the current state of knowledge regarding the structural determinants and biophysical properties of HERG and KCNQ1 channels.     

Apico-basal inhomogeneity in distribution of ion channels in canine and human ventricular myocardium

OBJECTIVES: The aim of the present study was to compare the apico-basal distribution of ion currents and the underlying ion channel proteins in canine and human ventricular myocardium. METHODS: Ion currents and action potentials were recorded in canine cardiomyocytes, isolated from both apical and basal regions of the heart, using whole-cell voltage clamp techniques. Density of channel proteins in canine and human ventricular myocardium was determined by Western blotting. RESULTS: Action potential duration was shorter and the magnitude of phase-1 repolarization was significantly higher in apical than basal canine myocytes. No differences were observed in other parameters of the action potential or cell capacitance. Amplitude of the transient outward K(+) current (29.6+/-5.7 versus 16.5+/-4.4 pA/pF at +65 mV) and the slow component of the delayed rectifier K(+) current (5.61+/-0.43 versus 2.14+/-0.18 pA/pF at +50 mV) were significantly larger in apical than in basal myocytes. Densities of the inward rectifier K(+) current, rapid delayed rectifier K(+) current, and L-type Ca(2+) current were similar in myocytes of apical and basal origin. Apico-basal differences were found in the expression of only those channel proteins which are involved in mediation of the transient outward K(+) current and the slow delayed rectifier K(+) current: expression of Kv1.4, KChIP2, KvLQT1 and MinK was significantly higher in apical than in basal myocardium in both canine and human hearts. CONCLUSIONS: The results suggest that marked apico-basal electrical inhomogeneity exists in the canine-and probably in the human-ventricular myocardium, which may result in increased dispersion, and therefore, cannot be ignored when interpreting ECG recordings, pathological alterations, or drug effects.     

Novel arrhythmogenic mechanism revealed by a long-QT syndrome mutation in the cardiac Na(+) channel

Variant 3 of the congenital long-QT syndrome (LQTS-3) is caused by mutations in the gene encoding the alpha subunit of the cardiac Na(+) channel. In the present study, we report a novel LQTS-3 mutation, E1295K (EK), and describe its functional consequences when expressed in HEK293 cells. The clinical phenotype of the proband indicated QT interval prolongation in the absence of T-wave morphological abnormalities and a steep QT/R-R relationship, consistent with an LQTS-3 lesion. However, biophysical analysis of mutant channels indicates that the EK mutation changes channel activity in a manner that is distinct from previously investigated LQTS-3 mutations. The EK mutation causes significant positive shifts in the half-maximal voltage (V(1/2)) of steady-state inactivation and activation (+5.2 and +3.4 mV, respectively). These gating changes shift the window of voltages over which Na(+) channels do not completely inactivate without altering the magnitude of these currents. The change in voltage dependence of window currents suggests that this alteration in the voltage dependence of Na(+) channel gating may cause marked changes in action potential duration because of the unique voltage-dependent rectifying properties of cardiac K(+) channels that underlie the plateau and terminal repolarization phases of the action potential. Na(+) channel window current is likely to have a greater effect on net membrane current at more positive potentials (EK channels) where total K(+) channel conductance is low than at more negative potentials (wild-type channels), where total K(+) channel conductance is high. These findings suggest a fundamentally distinct mechanism of arrhythmogenesis for congenital LQTS-3.     

Structure and function of cardiac potassium channels.

Recent advances in molecular biology have had a major impact on our understanding of the biophysical and molecular properties of ion channels. This review is focused on cardiac potassium channels which, in general, serve to control and limit cardiac excitability. Approximately 60 K+ channel subunits have been cloned to date. The (evolutionary) oldest potassium channel subunits consist of two transmembrane (Tm) segments with an intervening pore-loop (P). Channels formed by four 2Tm-1P subunits generally function as inwardly rectifying K(+)-selective channels (KirX.Y): they conduct substantial current near the resting potential but carry little or no current at depolarized potentials. The inward rectifier IK1 and the ligand-gated KATP and KACh channels are composed of such subunits. The second major class of K+ channel subunits consists of six transmembrane segments (S1-S6). The S5-P-S6 section resembles the 2Tm-1P subunit, and the additional membrane-spanning segments (especially the charged S4 segment) endow these 6Tm-1P channels with voltage-dependent gating. For both major families, four subunits assemble into a homo- or heterotetrameric channel, subject to specific subunit-subunit interactions. The 6Tm-1P channels are closed at the resting potential, but activate at different rates upon depolarization to carry sustained or transient outward currents (the latter due to inactivation by different mechanisms). Cardiac cells typically display at least one transient outward current and several delayed rectifiers to control the duration of the action potential. The molecular basis for each of these currents is formed by subunits that belong to different Kvx.y subfamilies and alternative splicing can contribute further to the diversity in native cells. These subunits display distinct pharmacological properties and drug-binding sites have been identified. Additional subunits have evolved by concatenation of two 2Tm-1P subunits (4Tm-2P); dimers of such subunits yield voltage-independent leak channels. A special class of 6Tm-1P subunits encodes the 'funny' pacemaker current which activates upon hyperpolarization and carries both Na+ and K+ ions. The regional heterogeneity of K+ currents and action potential duration is explained by the heterogeneity of subunit expression, and significant changes in expression occur in cardiac disease, most frequently a reduction. This electrical remodelling may also be important for novel antiarrhythmic therapeutic strategies. The recent crystallization of a 2Tm-1P channel enhances the outlook for more refined molecular approaches.     

Evidence that neuronal G-protein-gated inwardly rectifying K+ channels are activated by G beta gamma subunits and function as heteromultimers.

Guanine nucleotide-binding proteins (G proteins) activate K+ conductances in cardiac atrial cells to slow heart rate and in neurons to decrease excitability. cDNAs encoding three isoforms of a G-protein-coupled, inwardly rectifying K+ channel (GIRK) have recently been cloned from cardiac (GIRK1/Kir 3.1) and brain cDNA libraries (GIRK2/Kir 3.2 and GIRK3/Kir 3.3). Here we report that GIRK2 but not GIRK3 can be activated by G protein subunits G beta 1 and G gamma 2 in Xenopus oocytes. Furthermore, when either GIRK3 or GIRK2 was coexpressed with GIRK1 and activated either by muscarinic receptors or by G beta gamma subunits, G-protein-mediated inward currents were increased by 5- to 40-fold. The single-channel conductance for GIRK1 plus GIRK2 coexpression was intermediate between those for GIRK1 alone and for GIRK2 alone, and voltage-jump kinetics for the coexpressed channels displayed new kinetic properties. On the other hand, coexpression of GIRK3 with GIRK2 suppressed the GIRK2 alone response. These studies suggest that formation of heteromultimers involving the several GIRKs is an important mechanism for generating diversity in expression level and function of neurotransmitter-coupled, inward rectifier K+ channels.     

Mechanism underlying bupivacaine inhibition of G protein-gated inwardly rectifying K+ channels

Local anesthetics, commonly used for treating cardiac arrhythmias, pain, and seizures, are best known for their inhibitory effects on voltage-gated Na(+) channels. Cardiovascular and central nervous system toxicity are unwanted side-effects from local anesthetics that cannot be attributed to the inhibition of only Na(+) channels. Here, we report that extracellular application of the membrane-permeant local anesthetic bupivacaine selectively inhibited G protein-gated inwardly rectifying K(+) channels (GIRK:Kir3) but not other families of inwardly rectifying K(+) channels (ROMK:Kir1 and IRK:Kir2). Bupivacaine inhibited GIRK channels within seconds of application, regardless of whether channels were activated through the muscarinic receptor or directly via coexpressed G protein G(beta)gamma subunits. Bupivacaine also inhibited alcohol-induced GIRK currents in the absence of functional pertussis toxin-sensitive G proteins. The mutated GIRK1 and GIRK2 (GIRK1/2) channels containing the high-affinity phosphatidylinositol 4,5-bisphosphate (PIP(2)) domain from IRK1, on the other hand, showed dramatically less inhibition with bupivacaine. Surprisingly, GIRK1/2 channels with high affinity for PIP(2) were inhibited by ethanol, like IRK1 channels. We propose that membrane-permeant local anesthetics inhibit GIRK channels by antagonizing the interaction of PIP(2) with the channel, which is essential for G(beta)gamma and ethanol activation of GIRK channels.