The protein kinase A inhibitor, H-89, directly inhibits KATP and Kir channels in rabbit coronary arterial smooth muscle cells

The effects of the protein kinase A (PKA) inhibitor H-89 on ATP-sensitive K+ (KATP) and inward rectifier K+ (Kir) currents were examined in rabbit coronary arterial smooth muscle cells using the patch clamp technique. The H-89, in a dose-dependent manner, inhibited KATP and Kir currents with apparent Kd values of 1.19+/-0.18 and 3.78+/-0.37 microM, respectively. H-85, which is considered as an inactive form of H-89, inhibited KATP and Kir currents, similar to the result of H-89. KATP and Kir currents were not affected by either Rp-8-CPT-cAMPs, which is a membrane-permeable selective PKA inhibitor, or KT 5720, which is also known as a PKA inhibitor. Also, these two drugs did not significantly alter the effects of H-89 on the KATP and Kir currents. These results suggest that H-89 directly inhibits the KATP and Kir currents of rabbit coronary arterial smooth muscle cells independently of PKA inhibition.     

Lysosome mediated Kir2.1 breakdown directly influences inward rectifier current density

The inward rectifier current generated by Kir2.1 ion channel proteins is primarily responsible for the stable resting membrane potential in various excitable cell types, like neurons and myocytes. Tight regulation of Kir2.1 functioning prevents premature action potential formation and ensures optimal repolarization times. While Kir2.1 forward trafficking has been addressed in a number of studies, its degradation pathways are thus far unknown. Using three different lysosomal inhibitors, NH₄Cl, chloroquine and leupeptin, we now demonstrate involvement of the lysosomal degradation pathway in Kir2.1 breakdown. Upon application of the inhibitors, increased steady state protein levels are detectable within few hours coinciding with intracellular granular Kir2.1 accumulation. Treatment for 24 h with either chloroquine or leupeptin results in increased plasmamembrane originating inward rectifier current densities, while current-voltage characteristics remain unaltered. We conclude that the lysosomal degradation pathway contributes to Kir2.1 mediated inward rectifier current regulation.     

Selective modulation of L-type calcium current by magnesium lithospermate B in guinea-pig ventricular myocytes

Magnesium lithospermate B (MLB) is the main water-soluble principle of Salviae Miltiorrhizae Radix (also called as 'Danshen' in the traditional Chinese medicine) for the treatment of cardiovascular diseases. MLB was found to possess a variety of pharmacological actions. However, it is unclear whether and how MLB affects the cardiac ion channels. In the present study, the effects of MLB on the voltage-activated ionic currents were investigated in single ventricular myocytes of adult guinea pigs. MLB reversibly inhibited L-type Ca(2+) current (I(Ca,L)). The inhibition was use-dependent and voltage-dependent (the IC(50) value of MLB was 30 microM and 393 microM, respectively, at the holding potential of -50 mV and -100 mV). In the presence of 100 microM MLB, both the activation and steady-state inactivation curves of I(Ca,L) were markedly shifted to hyperpolarizing membrane potentials, whereas the time course of recovery of I(Ca,L) from inactivation was not altered. MLB up to 300 microM had no significant effect on the fast-inactivating Na(+) current (I(Na)), delayed rectifier K(+) current (I(K)) and inward rectifier K(+) current (I(K1)). The results suggest that the voltage-dependent Ca(2+) antagonistic effect of MLB work in concert with its antioxidant action for attenuating heart ischemic injury.     

Protein kinase A-dependent activation of inward rectifier potassium channels by adenosine in rabbit coronary smooth muscle cells

We studied the effect of adenosine on the Ba(2+)-sensitive K(IR) channels in the smooth muscle cells isolated from the small-diameter (<100microm) coronary arteries of rabbit. Adenosine increased K(IR) currents in concentration-dependent manner (EC(50)=9.4+/-1.4microM, maximum increase of 153%). The adenosine-induced stimulation of K(IR) current was blocked by adenylyl cyclase inhibitor, SQ22536 and was mimicked by adenylyl cyclase activator, forskolin. The adenosine-induced increase of current was blocked by cyclic AMP-dependent protein kinase (PKA) inhibitors, KT 5720 and Rp-8-CPT-cAMPs. The adenosine-induced increase of K(IR) currents was blocked by an A(3)-selective antagonist MRS1334, while the antagonists of other subtypes (DPCPX for A(1), ZM241385 for A(2A), and alloxazine for A(2B)) were all ineffective. Furthermore, an A(3)-selective agonist, 2-Cl-IB-MECA induced increase of K(IR) currents. We also examined the effect of adenosine on coronary blood flow (CBF) rate by using the Langendorff-perfused heart. In the presence of glibenclamide to exclude the effects of ATP-sensitive K(+) (K(ATP)) channels, CBF was increased by adenosine (10microM), which was blocked by the addition of Ba(2+) (50microM). Above results suggest that adenosine increases K(IR) current via A(3) subtype through the activation of PKA in rabbit small-diameter coronary arterial smooth muscle cells.     

Inverse agonist-like action of cadmium on G-protein-gated inward-rectifier K(+) channels

The gate at the pore-forming domain of potassium channels is allosterically controlled by a stimulus-sensing domain. Using Cd²⁺ as a probe, we examined the structural elements responsible for gating in an inward-rectifier K⁺ channel (Kir3.2). One of four endogenous cysteines facing the cytoplasm contributes to a high-affinity site for inhibition by internal Cd²⁺. Crystal structure of its cytoplasmic domain in complex with Cd²⁺ reveals that octahedral coordination geometry supports the high-affinity binding. This mode of action causes the tethering of the N-terminus to CD loop in the stimulus-sensing domain, suggesting that their conformational changes participate in gating and Cd²⁺ inhibits Kir3.2 by trapping the conformation in the closed state like “inverse agonist”.     

Quaternary ammonium ion blockade of IK in nerve axons revisited. Open channel block vs. state independent block

The mechanism of blockade of the delayed rectifier potassium ion channel in squid giant axons by intracellular quaternary ammonium ions (QA) appears to be remarkably sensitive to the structure of the blocker. TEA, propyltriethyl-ammonium (C₃), and propyltetraethylammonium (TAA-C₃) all fail to alter the deactivation, or tail current time course following membrane depolarization, even with relatively large concentrations of the blockers, whereas butyltriethylammonium (C₄), butyltetraethylammonium (TAA-C₄), and pentytriethyammonium (C₅) clearly do have such an effect. The relative electrical distance of blockade for all of these ions is 0.25–0.3 from the inner surface of the membrane. The observations concerning TEA, C₃, and TAAC₃ suggest that these ions can block the channel in either its open or its closed state. The results with C₄, TAA-C₄, and C₅ are consistent with the open channel block model. Moreover, the sensitivity of block mechanism to the structure of the blocker suggests that the gate is located close to the QA ion binding site and that TEA, C₃, and TAA-C₃ do not interfere with channel gating, whereas C₄, TAA-C₄, C₅, and ions having a longer hydrophobic tail than C₅ do have such an effect. The parameters of block obtained for all QA ions investigated were unaffected by changes in the extracellular potassium ion concentration.The author gratefully acknowledges Paul Guth of Cambridge Chemical for custom synthesis of the C _n compounds used in this study, Michael Rogawski for helpful discussion of this work, and Adam Sherman of Alembic Software and Vijay Kowtha for technical assistance in data acquisition and analysis.     

Molecular and functional characterization of Anopheles gambiae inward rectifier potassium (Kir1) channels: A novel role in egg production

Inward rectifier potassium (Kir) channels play essential roles in regulating diverse physiological processes. Although Kir channels are encoded in mosquito genomes, their functions remain largely unknown. In this study, we identified the members of the Anopheles gambiae Kir gene family and began to investigate their function. Notably, we sequenced the A. gambiae Kir1 (AgKir1) gene and showed that it encodes all the canonical features of a Kir channel: an ion pore that is composed of a pore helix and a selectivity filter, two transmembrane domains that flank the ion pore, and the so-called G-loop. Heterologous expression of AgKir1 in Xenopus oocytes revealed that this gene encodes a functional, barium-sensitive Kir channel. Quantitative RT-PCR experiments then showed that relative AgKir1 mRNA levels are highest in the pupal stage, and that AgKir1 mRNA is enriched in the adult ovaries. Gene silencing of AgKir1 by RNA interference did not affect the survival of female mosquitoes following a blood meal, but decreased their egg output. These data provide evidence for a new role of Kir channels in mosquito fecundity, and further validates them as promising molecular targets for the development of a new class of mosquitocides to be used in vector control.     

Patch clamp analysis of chemically activated and modulated ionic channels in isolated mammalian cardiomyocytes

Techniques routinely utilized in this laboratory for recording currents through single ionic channels of isolated atrial and ventricular rat cardiomyocytes are described. Emphasis is placed in two main areas: first, on methods for obtaining a sufficient yield of Ca⁺⁺-tolerant myocytes suitable for patch clamp experiments, and secondly, on methods for analyzing the temporal characteristics of patched ionic channels. These methods were used on acetylcholine activated K⁺ channels in isolated atrial myocytes and on an inwardly-rectifying K⁺ channel in ventricular myocytes. The latter is an example of a hormonally modulated K⁺ channel, since its activity could be substantially increased by norepinephrine. Analysis of the closed and open time distributions suggested that one of the closed states of this channel is markedly abbreviated by norepinephrine, whereas the open state is nearly unaffected. Norepinephrine was effective when channel activity was recorded from on-cell patches and the hormone was added to the solution bathing the cell membrane outside of the patched area. This indicates that a second messenger substance is probably mediating the action of norepinephrine.     

Identification of two types of ATP-sensitive K+ channels in rat ventricular myocytes

The ATP-sensitive K(+) (K(ATP)) channels are known to provide a functional linkage between the electrical activity of the cell membrane and metabolism. Two types of inwardly rectifying K(+) channel subunits (i.e., Kir6.1 and Kir6.2) with which sulfonylurea receptors are associated were reported to constitute the K(ATP) channels. In this study, we provide evidence to show two types of K(ATP) channels with different biophysical properties functionally expressed in isolated rat ventricular myocytes. Using patch-clamp technique, we found that single-channel conductance for the different two types of K(ATP) channels in these cells was 57 and 21 pS. The kinetic properties, including mean open time and bursting kinetics, did not differ between these two types of K(ATP) channels. Diazoxide only activated the small-conductance K(ATP) channel, while pinacidil and dinitrophenol stimulated both channels. Both of these K(ATP) channels were sensitive to block by glibenclamide. Additionally, western blotting, immunochemistry, and RT-PCR revealed two types of Kir6.X channels, i.e., Kir6.1 and Kir6.2, in rat ventricular myocytes. Single-cell Ca(2+) imaging also revealed that similar to dinitrophenol, diazoxide reduced the concentration of intracellular Ca(2+). The present results suggest that these two types of K(ATP) channels may functionally be related to the activity of heart cells.     

Differential Phosphoinositide Binding to Components of the G Protein-Gated K+ Channel

The regulation of ion channels and transporters by anionic phospholipids is currently very topical. G protein-gated K⁺ channels from the Kir3.0 family are involved in slowing the heart rate, generating late inhibitory postsynaptic potentials and controlling hormone release from neuroendocrine cells. There is considerable functional precedent for the control of these channels by phosphatidylinositol 4,5-bisphosphate. In this study, we used a biochemical assay to investigate the lipid binding properties of Kir3.0 channel domains. We reveal a differential binding affinity to a range of phosphoinositides between the C termini of the Kir3.0 isoforms. Furthermore, the N terminus in addition to the C terminus of Kir3.4 is necessary to observe binding and is decreased by the mutations R72A, K195A and R196A but not K194A. Protein kinase C phosphorylation of the Kir3.1 C-terminal fusion protein decreases anionic phospholipid binding. The differential binding affinity has functional consequences as the inhibition of homomeric Kir3.1, occurring after M3 receptor activation, recovers over minutes while homomeric Kir3.2 does not.     

Angiotensin II inhibits inward rectifier K+ channels in rabbit coronary arterial smooth muscle cells through protein kinase Calpha

We investigated the effects of the vasoconstrictor angiotensin (Ang) II on the whole cell inward rectifier K(+) (Kir) current enzymatically isolated from small-diameter (<100 microm) coronary arterial smooth muscle cells (CASMCs). Ang II inhibited the Kir current in a dose-dependent manner (half inhibition value: 154 nM). Pretreatment with phospholipase C inhibitor and protein kinase C (PKC) inhibitors prevented the Ang II-induced inhibition of the Kir current. The PKC activator reduced the Kir currents. The inhibitory effect of Ang II was reduced by intracellular and extracellular Ca(2+) free condition and by G?6976, which inhibits Ca(2+)-dependent PKC isoforms alpha and beta. However, the inhibitory effect of Ang II was unaffected by a peptide that selectively inhibits the translocation of the epsilon isoform of PKC. Western blot analysis confirmed that PKCalpha, and not PKCbeta, was expressed in small-diameter CASMCs. The Ang II type 1 (AT(1))-receptor antagonist CV-11974 prevented the Ang II-induced inhibition of the Kir current. From these results, we conclude that Ang II inhibits Kir channels through AT(1) receptors by the activation of PKCalpha.     

miRNA profiling of bilateral rat hippocampal CA3 by deep sequencing

Brain capillary endothelial cells (BCECs) form blood brain barrier (BBB) to maintain brain homeostasis. Cell turnover of BCECs by the balance of cell proliferation and cell death is critical for maintaining the integrity of BBB. Here we found that stimuli with tunicamycin, endoplasmic reticulum (ER) stress inducer, up-regulated inward rectifier K⁺ channel (K_ir2.1) and facilitated cell death in t-BBEC117, a cell line derived from bovine BCECs. The activation of K_ir channels contributed to the establishment of deeply negative resting membrane potential in t-BBEC117. The deep resting membrane potential increased the resting intracellular Ca²⁺ concentration due to Ca²⁺ influx through non-selective cation channels and thereby partly but significantly regulated cell death in t-BBEC117. The present results suggest that the up-regulation of K_ir2.1 is, at least in part, responsible for cell death/cell turnover of BCECs induced by a variety of cellular stresses, particularly ER stress, under pathological conditions.     

Modulation of Kir4.2 rectification properties and pHi-sensitive run-down by association with Kir5.1

Inwardly rectifying K⁺ channels (Kir) comprise seven subfamilies that can be subdivided further on the basis of cytosolic pH (pHi) sensitivity, rectification strength and kinetics, and resistance to run-down. Although distinct residues within each channel subunit define these properties, heteromeric association with other Kir subunits can modulate them. We identified such an effect in the wild-type forms of Kir4.2 and Kir5.1 and used this to further understand how the functional properties of Kir channels relate to their structures. Kir4.2 and a Kir4.2-Kir5.1 fusion protein were expressed in HEK293 cells. Inward currents from Kir4.2 were stable over 10 min and pHi-insensitive (pH 6 to 8). Conversely, currents from Kir4.2-Kir5.1 exhibited a pHi-sensitive run-down at slightly acidic pHi. At pHi 7.2, currents in response to voltage steps positive to E_K were essentially time independent for Kir4.2 indicating rapid block by Mg²⁺. Coexpression with Kir5.1 significantly increased the blocking time constant, and increased steady-state outward current characteristic of weak rectifiers. Recovery from blockade at negative potentials was voltage dependent and 2 to 10 times slower in the homomeric channel. These results show that Kir5.1 converts Kir4.2 from a strong to a weak rectifier, rendering it sensitive to pHi, and suggesting that Kir5.1 plays a role in fine-tuning Kir4.2 activity.     

Whole-cell K+ current activation in response to voltages and carbachol in gastric parietal cells isolated from guinea pig

Summary Patch-clamp studies of whole-cell ionic currents were carried out in parietal cells obtained by collagenase digestion of the gastric fundus of the guinea pig stomach. Applications of positive command pulses induced outward currents. The conductance became progressively augmented with increasing command voltages, exhibiting an outwardly rectifying current-voltage relation. The current displayed a slow time course for activation. In contrast, inward currents were activated upon hyperpolarizing voltage applications at more negative potentials than the equilibrium potential to K⁺ (E _K). The inward currents showed time-dependent inactivation and an inwardly rectifying current-voltage relation. Tail currents elicited by voltage steps which had activated either outward or inward currents reversed at nearE _K, indicating that both time-dependent and voltagegated currents were due to K⁺ conductances. Both outward and inward K⁺ currents were suppressed by extracellular application of Ba²⁺, but little affected by quinine. Tetraethylammonium inhibited the outward current without impairing the inward current, whereas Cs⁺ blocked the inward current but not the outward current. The conductance of inward K⁺ currents, but not outward K⁺ currents, became larger with increasing extracellular K⁺ concentration. A Ca²⁺-mobilizing acid secretagogue, carbachol, and a Ca²⁺ ionophore, ionomycin, brought about activation of another type of outward K⁺ currents and voltage-independent cation currents. Both currents were abolished by cytosolic Ca²⁺ chelation. Quinine preferentially inhibited this K⁺ current. It is concluded that resting parietal cells of the guinea pig have two distinct types of voltage-dependent K⁺ channels, inward rectifier and outward rectifier, and that the cells have Ca²⁺-activated K⁺ channels which might be involved in acid secretion under stimulation by Ca²⁺-mobilizing secretagogues.     

Membrane channels as integrators of G-protein-mediated signaling

A variety of extracellular stimuli regulate cellular responses via membrane receptors. A well-known group of seven-transmembrane domain-containing proteins referred to as G protein-coupled receptors, directly couple with the intracellular GTP-binding proteins (G proteins) across cell membranes and trigger various cellular responses by regulating the activity of several enzymes as well as ion channels. Many specific populations of ion channels are directly controlled by G proteins; however, indirect modulation of some channels by G protein-dependent phosphorylation events and lipid metabolism is also observed. G protein-mediated diverse modifications affect the ion channel activities and spatio-temporally regulate membrane potentials as well as of intracellular Ca^2 + concentrations in both excitatory and non-excitatory cells. This article is part of a Special Issue entitled: Reciprocal influences between cell cytoskeleton and membrane channels, receptors and transporters. Guest Editor: Jean Claude Hervé.     

Decreased inward rectifier potassium current IK1 in dystrophin-deficient ventricular cardiomyocytes

Kir2.x channels in ventricular cardiomyocytes (most prominently Kir2.1) account for the inward rectifier potassium current I_K1, which controls the resting membrane potential and the final phase of action potential repolarization. Recently it was hypothesized that the dystrophin-associated protein complex (DAPC) is important in the regulation of Kir2.x channels. To test this hypothesis, we investigated potential I_K1 abnormalities in dystrophin-deficient ventricular cardiomyocytes derived from the hearts of Duchenne muscular dystrophy mouse models. We found that I_K1 was substantially diminished in dystrophin-deficient cardiomyocytes when compared to wild type myocytes. This finding represents the first functional evidence for a significant role of the DAPC in the regulation of Kir2.x channels.     

Veratridine blocks voltage-gated potassium current in human T lymphocytes and in mouse neuroblastoma cells

(i) Effects of veratridine on ionic conductances of human peripheral blood T lymphocytes have been investigated using the whole-cell patch-clamp technique, (ii) Veratridine reduces the net outward current evoked by membrane depolarizations. The reduction originates from block of a 4-aminopyridine-sensitive, voltage-gated K⁺ current, (iii) Human T lymphocytes do not appear to express voltage-gated Na⁺ channels, since inward currents are observed neither in control nor in veratridine- and bretylium-exposed lymphocytes. (iv) The effect of veratridine consists of an increase in the rate of decay of the voltage-gated K⁺ current and a reduction of the peak current amplitude. Both effects depend on veratridine concentration. Halfmaximum block occurs at 97 m and the time constant of decay is reduced by 50% at 54 m of veratridine. (v) Possible mechanisms of veratridine action are discussed. The increased rate of K⁺ current decay is most likely due to open channel block. The decrease of current amplitude may involve an additional mechanism. (vi) In cultured mouse neuroblastoma N1E-115 cells, veratridine blocks a component of voltage-gated K⁺ current, in addition to its effect on voltage-gated Na⁺ current. This result shows that the novel effect of veratridine is not confined to lymphocytes.We thank Jacobien Künzel of the Wilhelmina Hospital for Children, Utrecht, for providing the blood samples and Aart de Groot for technical assistance. The research was supported by a fellowship of the Royal Netherlands Academy of Arts and Sciences to M. Oortgiesen.     

Kir4.1-mediated spatial buffering of K+: Experimental challenges in determination of its temporal and quantitative contribution to K+ clearance in the brain

Neuronal activity results in release of K⁺ into the extracellular space of the central nervous system. If the excess K⁺ is allowed to accumulate, neuronal firing will be compromised by the ensuing neuronal membrane depolarization. The surrounding glial cells are involved in clearing K⁺ from the extracellular space by molecular mechanism(s), the identity of which have been a matter of controversy for over half a century. Kir4.1-mediated spatial buffering of K⁺ has been promoted as a major contributor to K⁺ removal although its quantitative and temporal contribution has remained undefined. We discuss the biophysical and experimental challenges regarding determination of the contribution of Kir4.1 to extracellular K⁺ management during neuronal activity. It is concluded that 1) the geometry of the experimental preparation is crucial for detection of Kir4.1-mediated spatial buffering and 2) Kir4.1 enacts spatial buffering of K⁺ during but not after neuronal activity.     

Kir4.1-mediated spatial buffering of K+: Experimental challenges in determination of its temporal and quantitative contribution to K+ clearance in the brain

Neuronal activity results in release of K⁺ into the extracellular space of the central nervous system. If the excess K⁺ is allowed to accumulate, neuronal firing will be compromised by the ensuing neuronal membrane depolarization. The surrounding glial cells are involved in clearing K⁺ from the extracellular space by molecular mechanism(s), the identity of which have been a matter of controversy for over half a century. Kir4.1-mediated spatial buffering of K⁺ has been promoted as a major contributor to K⁺ removal although its quantitative and temporal contribution has remained undefined. We discuss the biophysical and experimental challenges regarding determination of the contribution of Kir4.1 to extracellular K⁺ management during neuronal activity. It is concluded that 1) the geometry of the experimental preparation is crucial for detection of Kir4.1-mediated spatial buffering and 2) Kir4.1 enacts spatial buffering of K⁺ during but not after neuronal activity.