Voltage-dependent gating of veratridine-modified RIIA Na+ channel α subunit expressed heterologously in CHO cells

The voltage-dependent kinetics of veratridine-modified RIIA Na⁺ channel α subunit expressed heterologously in CHO cells were studied using the whole-cell patch-clamp technique. The activation and deactivation kinetics are well described by double exponential functions but poorly by a monoexponential function. Unlike the slow component, the fast time constant and associated amplitude factor depended steeply on the potential. The steady-state activation of veratridine-modified channels is described by a Boltzmann function with a V _1/2 of –131.9 mV and a slope of 9.41 mV. A two-state model is proposed for the fast component that explains the kinetics of veratridine’s mechanism of action. Received: 11 December 1998 / Received after revision: 23 March 1999 / Accepted: 7 April 1999     

Interaction of the antiepileptic drug lamotrigine with recombinant rat brain type IIA Na+ channels and with native Na+ channels in rat hippocampal neurones

Actions of the new antiepileptic drug lamotrigine (LTG, Lamictal) were characterised using recombinant rat brain type IIA Na⁺ channels expressed in Chinese hamster ovary (CHO) cells and native Na⁺ channels in rat hippocampal pyramidal neurones, using whole-cell recording and intracellular recording techniques. In CHO cells, LTG caused a tonic inhibition of Na⁺ currents in a concentration-dependent and voltage-dependent manner. The half-maximal inhibitory concentration (IC₅₀) of approximately 500 M was obtained at a holding potential (V _h) of –90 mV compared with an IC₅₀ of 100 M at a V _h of –60 mV. LTG (50 M) caused a 10–mV negative shift in the slow, steady-state inactivation curve and delayed considerably the recovery from inactivation, but had no significant effects on the voltage dependence of activation or fast inactivation, suggesting that LTG acts mainly on the slow inactivated state. The affinity for the inactivated channels was estimated at 12 M. The tonic inhibition was augmented by a use-dependent action in which a further inhibition by the drug developed during rapid repetitive stimulation using a train of 20-ms duration pulses (11 Hz). These results were consistent with the drug action being on firing properties of pyramidal neurones. Only in those epileptiform bursts which caused cumulative inactivation of Na⁺ spikes did LTG produce a potent inhibition. Our data suggest that the inactivated channel is a primary target for LTG action at therapeutic concentrations.     

cAMP-activation of amiloride-sensitive Na+ channels from guinea-pig colon expressed in Xenopus oocytes

Guinea-pig distal colonic mRNA injection into Xenopus laevis oocytes resulted in expression of functional active epithelial Na⁺ channels in the oocyte plasma membrane. Poly(A)⁺ RNA was extracted from distal colonic mucosa of animals fed either a high-salt (HS) or a low-salt (LS) diet. The electrophysiological properties of the expressed amiloride-sensitive Na⁺ conductances were investigated by conventional two-electrode voltage-clamp and patch-clamp measurements. Injection of poly(A)⁺ RNA from HS-fed animals [from hereon referred to as HS-poly(A)⁺ RNA] into oocytes induced the expression of amiloride-sensitive Na⁺ conductances. On the other hand, oocytes injected with poly(A)⁺ RNA from LS-fed animals [LS-poly(A)⁺ RNA] expressed a markedly larger amount of amiloride-blockable Na⁺ conductances. LS-poly(A)⁺ RNA-induced conductances were completely inhibitable by amiloride with a K _i of 77 nM, and were also blocked by benzamil with a K _i of 1.8 nM. 5-(N-Ethyl-N-isopropyl)-amiloride (EIPA), even in high doses (25 μM), had no detectable effect on the Na⁺ conductances. Expressed amiloride-sensitive Na⁺ channels could be further activated by cAMP leading to nearly doubled clamp currents. When Na⁺ was replaced by K⁺, amiloride (1 μM) showed no effect on the clamp current. Single-channel analysis revealed slow gating behaviour, open probabilities (P _o) between 0.4 and 0.9, and slope conductances of 3.8 pS for Na⁺ and 5.6 pS for Li⁺. The expressed channels showed to be highly selective for Na⁺ over K⁺ with a permeability ratio P _Na/P _K > 20. Amiloride (500 nM) reduced channel P _o to values < 0.05. All these features make the guinea-pig distal colon of LS-fed animals an interesting mRNA source for the expression of highly amiloride-sensitive Na⁺ channels in Xenopus oocytes, which could provide new insights in the regulatory mechanism of these channels. Received: 16 October 1995/Received after revision: 30 November 1995/Accepted: 12 December 1995     

KCNQ-encoded channels regulate Na+ transport across H441 lung epithelial cells

H441 cells are a model of absorptive airway epithelia that are characterised by a pronounced apical Na⁺ flux through amiloride-sensitive Na⁺ channels. The flux of Na⁺ is intimately linked to Na⁺ handling by the cell as well as the membrane potential across the apical membrane. As KCNQ-encoded K⁺ channels influence chloride secretion in gastrointestinal epithelia, the goal of the present study was to ascertain the expression of KCNQ genes in H441 cells and determine the functional role of the expression products. Message for KCNQ3 and KCNQ5 was detected by RT-polymerase chain reaction and the translated proteins were observed by immunocytochemistry. Ussing experiments showed that the pan-KCNQ channel blocker XE991, but not KCNQ1 selective blockers, reduced the short circuit current and the amiloride-sensitive component. These data show for the first time that potassium channels encoded by KCNQ3 or KCNQ5 are crucial determinants of epithelial Na⁺ flux.     

Functional coupling between heterologously expressed dopamine D(2) receptors and KCNQ channels

Activation of KCNQ potassium channels by stimulation of co-expressed dopamine D₂ receptors was studied electrophysiologically in Xenopus laevis oocytes and in mammalian cells. To address the specificity of the interaction between D₂-like receptors and KCNQ channels, combinations of KCNQ1–5 channels and D₂-like receptors (D_2L, D₃, and D₄) were investigated in Xenopus oocytes. Activation of either receptor with the selective D₂-like receptor agonist quinpirole (100 nM) stimulated all the KCNQ currents, independently of the subunit combination, indicating a common pathway of receptor-channel interaction. The KCNQ4 current was investigated in further detail and was increased by 19.9±1.6% (n=20) by D_2L receptor stimulation. The effect could be mimicked by injection of GTPS and prevented by injection of Bordetella pertussis toxin, indicating that channel stimulation was mediated via a G protein of the G_i/o subtype. Cells of the human neuroblastoma line SH-SY5Y were co-transfected transiently with KCNQ4 and D_2L receptors. Stimulation of D_2L receptors increased the KCNQ4 current (n=6) as determined in whole-cell patch-clamp recordings. The specificity of the dopaminergic activation of the KCNQ channels was confirmed by co-expression of other neuronal K⁺ channels (BK, K_V1.1, and K_V4.3) with the D_2L receptor in Xenopus oocytes. None of these K⁺ channels responded to stimulation of the D_2L receptor. In the mammalian brain, dopamine D₂ receptors and KCNQ channels co-localise postsynaptically in several brain regions, so modulation of neuronal excitability by dopamine release could in part be mediated via an effect on KCNQ channels.     

Expression and regulation of epithelial Na+ channels by nucleotides in pleural mesothelial cells

Pleural effusions are commonly clinical disorders, resulting from the imbalance between pleural fluid turnover and reabsorption. The mechanisms underlying pleural fluid clearance across the mesothelium remain to be elucidated. We hypothesized that epithelial Na(+) channel (ENaC) is expressed and forms the molecular basis of the amiloride-sensitive resistance in human mesothelial cells. Our RT-PCR results showed that three ENaC subunits, namely, alpha, beta, gamma, and two delta ENaC subunits, are expressed in human primary pleural mesothelial cells, a human mesothelioma cell line (M9K), and mouse pleural tissue. In addition, Western blotting and immunofluorescence microscopy studies revealed that alpha, beta, gamma, and delta ENaC subunits are expressed in primary human mesothelial cells and M9K cells at the protein level. An amiloride-inhibitable short-circuit current was detected in M9K monolayers and mouse pleural tissues when mounted in Ussing chambers. Whole-cell patch clamp recordings showed an ENaC-like channel with an amiloride concentration producing 50% inhibition of 12 microM in M9K cells. This cation channel has a high affinity for extracellular Na+ ions (K(m): 53 mM). The ion selectivity of this channel to cations follows the same order as ENaC: Li+ > Na+ > K+. The unitary Li(+) conductance was 15 pS in on-cell patches. Four ENaC subunits form a functional Na+ channel when coinjected into Xenopus oocytes. Furthermore, we found that both forskolin and cGMP increased the short-circuit currents in mouse pleural tissues. Taken together, our data demonstrate that the ENaC channels are biochemically and functionally expressed in human pleural mesothelial cells, and can be up-regulated by cyclic AMP and cyclic GMP.     

Overproduction of voltage-dependent Na+ channels in the developing brain of genetically seizure-susceptible E1 mice.

We used E1 mice, a ddY mouse-derived, autosomal mutant strain and a model of hereditary sensory-precipitated epilepsy, to test the hypothesis that epileptic susceptibility may be associated with the activity of voltage-dependent ion channels. We examined the saxitoxin binding capacity of the receptor site 1 of the Na+ channel alpha-subunit, the expression activity of the Na+ channel mRNA, the veratridine-induced 22Na+ influx in the brain synaptosomes, and the regional distribution of Na+ channels in the brain. Compared with control ddY mice, in E1 mice which have not experienced seizures, the number of Na+ channels in the brain synaptosomes increased by approximately 20% starting at the fourth postnatal week through the adult stage as determined by [3H]saxitoxin binding assay. Northern blot hybridization analysis showed excess expression of Na+ channel mRNA (by 30-40%) coincidentally with Na+ channel increases. Regional analysis using the saxitoxin binding assay demonstrated approximately 1.3-fold denser distribution of Na+ channels in the cortex and cerebellum but not the hippocampus and midbrain including thalamus of E1 mice compared to ddY mice. Scatchard plot analysis for saxitoxin binding in the cortex of E1 mouse brains revealed higher maximum binding capacity (Bmax) values (ddY, 4.43 +/- 0.28 pmol/mg protein; E1, 5.43 +/- 0.25 pmol/mg protein) without a change in Kd (ddY, 1.05 +/- 0.03 nM; E1, 1.03 +/- 0.01 nM). Lastly, veratridine-evoked 22Na+ influx, sensitive to tetrodotoxin, was increased approximately 45% in the cortical synaptosomes in six-week-old E1 mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

O2 sensing by recombinant TWIK-related halothane-inhibitable K+ channel-1 background K+ channels heterologously expressed in human embryonic kidney cells

Hypoxic inhibition of K+ channels provides a link between low O2 and cell function, and in glossopharyngeal neurons hypoxic inhibition of a TWIK-related halothane-inhibitable K+ channel-1 (THIK-1)-like background K+ channel regulates neuronal function. In the present study, we examined directly the O2 sensitivity of recombinant THIK-1 channels, expressed in human embryonic kidney (HE293) cells. THIK-1 expression conferred a moderately outwardly rectifying halothane-inhibited and arachidonic acid-potentiated K+ current and invoked a strongly hyperpolarized resting membrane potential. Endogenous K+ currents in untransfected cells were unaffected by either agent. Hypoxia (P(O2), 20 mmHg) reversibly inhibited THIK-1 currents and caused membrane depolarization, effects that were occluded by halothane. Neither the mitochondrial complex I inhibitors rotenone, myxothiazol and sodium cyanide, nor the NADPH oxidase inhibitors diphenylene iodonium and phenylarsine oxide, were effective in inhibiting the O2-sensitivity of THIK-1. Thus, hypoxic inhibition of THIK-1 occurs by a mechanism dissimilar to that which regulates the activity of other members of the background K+ channel family. Given the O2 sensitivity of THIK-1 channels and their abundant expression in the CNS, we raise for the first time the possibility of a physiological and/or pathological role for these channels during brain ischemia.     

Blockade of epithelial Na+ channels by triamterenes — Underlying mechanisms and molecular basis

The three subunits (α, β, γ) encoding for the rat epithelial Na⁺ channel (rENaC) were expressed in Xenopus oocytes, and the induced Na⁺ conductance was tested for its sensitivity to various triamterene derivatives. Triamterene blocked rENaC in a voltage-dependent manner, and was 100-fold less potent than amiloride at pH 7.5. At −90 mV and −40 mV, the IC₅₀ values were 5 μM and 10 μM, respectively. The blockage by triamterene, which is a weak base with a pK _a of 6.2, was dependent on the extracellular pH. The IC₅₀ was 1 μM at pH 6.5 and only 17 μM at pH 8.5, suggesting that the protonated compound is more potent than the unprotonated one. According to a simple kinetic analysis, the apparent inhibition constants at −90 mV were 0.74 μM for the charged and 100.6 μM for the uncharged triamterene. The main metabolite of triamterene, p-hydroxytriamterene sulfuric acid ester, inhibited rENaC with an approximately twofold lower affinity. Derivatives of triamterene, in which the p-position of the phenylmoiety was substituted by acidic or basic residues, inhibited rENaC with IC₅₀ values in the range of 0.1–20 μM. Acidic and basic triamterenes produced a rENaC blockade with a similar voltage and pH dependence as the parent compound, suggesting that the pteridinemoiety of triamterene is responsible for that characteristic. Expression of the rENaC α-subunit-deletion mutant, Δ278–283, which lacks a putative amiloride-binding site, induced a Na⁺ channel with a greatly reduced affinity for both triamterene and amiloride. In summary, rENaC is a molecular target for triamterene that binds to its binding site within the electrical field, preferably as a positively charged molecule in a voltage- and pH-dependent fashion. We propose that amiloride and triamterene bind to rENaC using very similar mechanisms. Received: 2 January 1996/Accepted: 17 May 1996     

Influence of voltage and extracellular Na+ on amiloride block and transport kinetics of rat epithelial Na+ channel expressed in Xenopus oocytes

We expressed the three subunits of the epithelial amiloride-sensitive Na(+) channel (ENaC) from rat distal colon heterologously in oocytes of Xenopus laevis and analysed blocker-induced fluctuations in current using conventional dual-microelectrode voltage-clamp. To minimize Na(+) accumulation we performed all experiments in low-Na(+) solutions (15 mM). Noise analysis revealed that control or ENaC-injected oocytes did not exhibit spontaneous relaxation noise. However, in ENaC-expressing oocytes, amiloride induced a distinct Lorentzian component in the power density spectra. With three amiloride concentrations and a linear analysis of the respective changes in the corner frequency f(c) (2 pi f(c) plot) we determined the rate constants k(on) and k(off) for the amiloride-ENaC interaction. At a clamp potential (V(m)) of -60 mV k(on) was 80.8 +/- 5.1 microM(-1) s(-1) and k(off) 15.4 +/- 4.2 s(-1). The half-maximal blocker concentration (K(mic,ami)) was 0.19 microM (V(m)=-60 mV). While k(on) was voltage-independent in the range -50 to -100 mV, k(off) and K(mic,ami) decreased significantly with increasing membrane hyperpolarization, resulting in an increased affinity of amiloride for its binding site on ENaC. Increasing extracellular [Na(+)] ([Na(+)](o)) led to saturation of ENaC. Subsequent noise analysis revealed that single-channel current increased non-linearly with [Na(+)](o) and that saturation was not due to a reduction in the number of open channels. The apparent affinity of Na(+) for its binding site on the channel was voltage dependent and increased with hyperpolarization. Noise analysis revealed that k(on) and k(off) for amiloride decreased with increasing [Na(+)](o), while the affinity of the amiloride-binding site did not change. These findings show that the affinity of rat intestinal ENaC for amiloride is voltage dependent and is influenced non-competitively by [Na(+)](o), indicating that Na(+) and amiloride do not compete for the same binding site at the channel.     

AMPK controls epithelial Na+ channels through Nedd4-2 and causes an epithelial phenotype when mutated

The metabolic sensor adenosine-monophosphate-activated kinase (AMPK) detects the cellular energy status and adjusts metabolic activity according to the cytosolic AMP to ATP ratio. Na⁺ absorption by epithelial Na⁺ channels (ENaC) is a highly energy-consuming process that is inhibited by AMPK. We show that the catalytic subunit α1 of AMPK inhibits ENaC in epithelial tissues from airways, kidney, and colon and that AMPK regulation of ENaC is absent in AMPKα1−/− mice. These mice demonstrate enhanced electrogenic Na⁺ absorption that leads to subtle changes in intestinal and renal function and may also affect Na⁺ absorption and mucociliary clearance in the airways. We demonstrate that AMPK uses the ubiquitin ligase Nedd4-2 to inhibit ENaC by increasing ubiquitination and endocytosis of ENaC. Thus, enhanced expression of epithelial Na⁺ channels was detected in colon, airways, and kidney of AMPKα1−/− mice. Therefore, AMPKα1 is a physiologically important regulator of electrogenic Na⁺ absorption and may provide a novel pharmacological target for controlling epithelial Na⁺ transport. Categories: Membranes and Transport; bioenergetics, anabolic/catabolic processes studied at the molecular level.     

Regulation of alveolar epithelial Na+ channels by ERK1/2 in chlorine-breathing mice

The mechanisms by which the exposure of mice to Cl(2) decreases vectorial Na(+) transport and fluid clearance across their distal lung spaces have not been elucidated. We examined the biophysical, biochemical, and physiological changes of rodent lung epithelial Na(+) channels (ENaCs) after exposure to Cl(2), and identified the mechanisms involved. We measured amiloride-sensitive short-circuit currents (I(amil)) across isolated alveolar Type II (ATII) cell monolayers and ENaC single-channel properties by patching ATII and ATI cells in situ. α-ENaC, γ-ENaC, total and phosphorylated extracellular signal-related kinase (ERK)1/2, and advanced products of lipid peroxidation in ATII cells were measured by Western blot analysis. Concentrations of reactive intermediates were assessed by electron spin resonance (ESR). Amiloride-sensitive Na(+) channels with conductances of 4.5 and 18 pS were evident in ATI and ATII cells in situ of air-breathing mice. At 1 hour and 24 hours after exposure to Cl(2), the open probabilities of these two channels decreased. This effect was prevented by incubating lung slices with inhibitors of ERK1/2 or of proteasomes and lysosomes. The exposure of ATII cell monolayers to Cl(2) increased concentrations of reactive intermediates, leading to ERK1/2 phosphorylation and decreased I(amil) and α-ENaC concentrations at 1 hour and 24 hours after exposure. The administration of antioxidants to ATII cells before and after exposure to Cl(2) decreased concentrations of reactive intermediates and ERK1/2 activation, which mitigated the decrease in I(amil) and ENaC concentrations. The reactive intermediates formed during and after exposure to Cl(2) activated ERK1/2 in ATII cells in vitro and in vivo, leading to decreased ENaC concentrations and activity.     

Inhibition of voltage-dependent Na+ and K+ currents by forskolin in nodes of Ranvier

The effect of forskolin on voltage-activated Na⁺ and K⁺ currents in nodes of Ranvier from the toad, Bufo marinus, has been examined using the vaseline-gap voltageclamp technique. Peak Na⁺ currents (I _Na) were reduced by 35% and the rate of decline of Na⁺ current during continuous depolarization was accelerated following treatment with 450 M forskolin. However, the voltage-dependence of steady-state inactivation as well as the rate of recovery from fast inactivation remained unchanged. Upon repetitive depolarization at 1–10 Hz, a further inhibition of I _Na (60%) was observed. This use-dependent or phasic inhibition recovers slowly at -80 mV ( 13 s) and had a voltage-dependence like that of activation of the Na conductance. Near maximal steady-state phasic inhibition occurred with depolarizing pulse durations of only 4 ms, consistent with a direct involvement of the open Na⁺ channel in the blocking process. Inhibition of the delayed K⁺ current (I _K) was characterized by a concentration-dependent reduction in steady-state current amplitude (IC₅₀ 80 M) and a concentration-independent acceleration of current inactivation. A similar inhibition of I _K was obtained with 1,9-dideoxyforskolin, a homolog which does not activate adenylate cyclase (AC). The results suggest that the inhibition of I _K and perhaps I _Na follows directly from drug binding and is not a consequence of AC activation.     

Calcium-activated potassium channels in the luminal membrane of Amphiuma diluting segment: voltage-dependent block by intracellular Na+ upon depolarisation

Calcium-activated potassium channels in the luminal membrane of Amphiuma diluting segment were studied using the patch-clamp technique in both the cellattached and inside-out configurations. The open probability (P _o) of the channel is sensitive to both membrane potential and cytoplasmic calcium activity; depolarizing potenials and high calcium concentrations leading to an increased P _o. In the cell-attached condition, channel openings were observed between pipette potentials of –100 and –240 mV. As the driving force for potassium exit from the cell into the pipette is increased the single channel currents show a biphasic response. First, the currents increase as expected; however, the single channel currents diminish in magnitude at pipette potentials more negative than –120 mV. We propose that this reduction is due to rapid blockade of the potassium channel by intracellular sodium.This proposal is supported by two facts: (a) using inside-out patches it was possible to reduce the single channel currents in a concentration- and voltage-dependent manner, similar to that observed in the cell-attached condition, by raising the sodium concentration of the fluid bathing the cytoplasmic face of the patch; (b) pretreatment of tubules with the loop-acting diuretic furosemide (10^–5M), an agent known to decrease the intracellular sodium activity, caused an attenuation of the reduction in single channel current seen under control conditions. Given the very low P _o of the channels at the resting membrane potential and the sensitivity of the channels to intracellular sodium, it is unlikely that blockade of these channels by intracellular sodium would lead to a physiological regulation of the apical K conductance.     

Modulation of Ca2+ channels by heterologously expressed wild-type and mutant human micro-opioid receptors (hMORs) containing the A118G single-nucleotide polymorphism

The most common single-nucleotide polymorphism (SNP) of the human mu-opioid receptor (hMOR) gene occurs at position 118 (A118G) and results in substitution of asparagine to aspartate at the N-terminus. The purpose of the present study was to compare the pharmacological profile of several opioid agonists to heterologously expressed hMOR and N-type Ca(2+) channels in sympathetic neurons. cDNA constructs coding for wild-type and mutant hMOR were microinjected in rat superior cervical ganglion neurons and N-type Ca(2+) channel modulation was investigated using the whole cell variant of the patch-clamp technique. Concentration-response relationships were generated with the following selective MOR agonists: DAMGO, morphine, morphine-6-glucuronide (M-6-G), and endomorphin I. The estimated maximal inhibition for the agonists ranged from 52 to 64% for neurons expressing either hMOR subtype. The rank order of potencies for estimated EC(50) values (nM) in cells expressing wild-type hMOR was: DAMGO (31) > morphine (76) congruent with M-6-G (77) congruent with endomorphin I (86). On the other hand, the rank order in mutant-expressing neurons was: DAMGO (14) > morphine (39) > endomorphin I (74) congruent with M-6-G (82), with a twofold leftward shift for both DAMGO and morphine. The DAMGO-mediated Ca(2+) current inhibition was abolished by the selective MOR blocker, CTAP, and by pertussis toxin pretreatment of neurons expressing either hMOR subtype. These results suggest that the A118G variant MOR exhibits an altered signal transduction pathway and may help explain the variability of responses to opiates observed with carriers of the mutant allele.     

Multiple levels of native cardiac Na+ channels at elevated temperature measured with high-bandwidth/low-noise patch clamp

Currents through single Na⁺ channels were studied in cell-attached patches of enzymatically dispersed heart cells of the mouse with a low-noise patch-clamp technique that allows evaluation of current levels at temperatures of up to 35°C with bandwidths of up to 13 kHz. Noise arising from the pipette and the holder was reduced by the use of short (total length 8 mm) patch pipettes, which were sealed at their end with oil and inserted for only 1.5 mm into an appropriately tipped holder. At 9°C (filter 5 kHz), channel openings were regularly dominated by one open level, and amplitude histograms could be fitted with high accuracy with a sum of Gaussian curves. Above 24°C (filter 10 or 13 kHz), however, channel-open levels were heterogeneous with maximum levels of up to 4.5 pA at –50 mV. Amplitude histograms with improved resolution, based on variance calculation with window widths of 75 s or 195 s, confirmed the observed heterogeneity of open levels. Regular level patterns were not found. The frequency of the largest levels strongly varied from patch to patch and intermediate levels were always the most frequent. A corresponding dissociation of amplitudes was also observed at 35°C. Averaged currents, formed from trace ensembles including only levels below arbitrarily set borders, obeyed equal kinetics. It is concluded that at low temperature the conductance of single Na⁺ channel currents is much more homogeneous than at 24°C and above, where the same channels have multiple open states with different conductance.Heisenberg Fellow of the Deutsche Forschungsgemeinschaft