Characterization of whole-cell currents elicited by mechanical stimulation of Xenopus oocytes

Whole-cell mechanosensitive current (I(ms)) in Xenopus oocytes was studied using the two-electrode voltage-clamp technique. I(ms) was evoked by mechanically pressing the oocyte surface with a glass micropipette. The current was found to depend on the amplitude of the stimulus, showed a time-dependent decay, and turned off immediately after the stimulus was removed. The current-voltage relationship for the peak current exhibited inward and outward rectification at negative and positive potentials, respectively, while that for the sustained current exhibited only inward rectification. I(ms) was significantly suppressed by 30 microM Gd3+. One millimolar amiloride also significantly suppressed the inward I(ms) at negative potentials, but not the outward one at positive potentials. Replacing extracellular Na+ with K+ did not change the current-voltage relationship, whereas replacing extracellular Na+ with choline+ or tetraethylammonium+ significantly decreased the inward I(ms). The outward rectifier at positive potentials was abolished by replacing extracellular Cl- with gluconate-, by intracellular injection of 1,2-bis (2-aminophenoxy) ethane-N,N,N',N'-tetraacetic acid (BAPTA), by extracellular application of anthracene-9-carboxylic acid, and by replacing extracellular Ca2+ with Mg2+. These results suggest that mechanical stimulation activates stretch-activated cation channels and Ca2+-activated Cl- channels, the latter being secondarily activated by an increase in intracellular Ca2+ concentration by Ca2+ influx through stretch-activated cation channels.     

Selective inhibition of transient K+ current by La3+ in crab peptide-secretory neurons

Although divalent cations and lanthides are well-known inhibitors of voltage-dependent Ca2+ currents (ICa), their ability to selectively inhibit a voltage-gated K+ current is less widely documented. We report that La3+ inhibits the transient K+ current (IA) of crab (Cardisoma carnifex) neurosecretory cells at ED50 approximately 5 microM, similar to that blocking ICa, without effecting the delayed rectifier K+ current (IK). Neurons were dissociated from the major crustacean neuroendocrine system, the X-organ-sinus gland, plated in defined medium, and recorded by whole cell patch clamp after 1-2 days in culture. The bath saline included 0.5 microM TTX and 0.5 mM CdCl2 to eliminate inward currents. Responses to depolarizing steps from a holding potential of -40 mV represented primarily IK. They were unchanged by La3+ up to 500 microM. Currents from -80 mV in the presence of 20 mM TEA were shown to represent primarily IA. La3+ (with TEA) reduced IA and maximum conductance (GA) by approximately 10% for 1 microM and another 10% each in 10 and 100 microM La3+. Normalized GA-V curves were well fit with a single Boltzmann function, with V1/2 +4 mV and slope 15 mV in control; V1/2 was successively approximately 15 mV depolarized and slope increased approximately 2 mV for each of these La3+ concentrations. Cd2+ (1 mM), Zn2+ (200 microM), and Pb2+ (100 microM) or removal of saline Mg2+ (26 mM) had little or no effect on IA. Steady-state inactivation showed similar right shifts (from V1/2 -39 mV) and slope increases (from 2.5 mV) in 10 and 100 microM La3+. Time to peak IA was slowed in 10 and 100 microM La3+, whereas curves of normalized time constants of initial decay from peak IA versus Vc were right-shifted successively approximately 15 mV for the three La3+ concentrations. The observations were fitted by a Woodhull-type model postulating a La3+-selective site that lies 0.26-0.34 of the distance across the membrane electric field, and both block of K+ movement and interaction with voltage-gating mechanisms; block can be relieved by depolarization and/or outward current. The observation of selective inhibition of IA by micromolar La3+ raises concerns about its use in studies of ICa to evaluate contamination by outward current.     

Single channel analysis of the inward rectifier K current in the rabbit ventricular cells

The inward rectifier K channel in rabbit ventricular cells was studied by the patch-clamp method. Single channel currents were recorded in giga-sealed cell-attached patches with 150 mM K+ in the pipette. The slope conductance in the membrane potential range from -140 to -40 mV was 46.6 +/- 6.7 pS (mean +/- S.D., n = 16), and was reduced by decreasing [K+] in the pipette (20 or 50 mM). The channel was blocked by an application of Cs+ or Ba2+ (0.04-1 mM) in the pipette. Outwardly directed current, recorded with 50 mM K+ in the pipette, revealed the inward rectification of the single channel current. The probability of the channel being open was 0.33 +/- 0.05 (n = 10) at the resting potential (RP=-81.7 +/- 1.7 mV, n = 16) with 150 mM K+ in the pipette, and it decreased with hyperpolarization. The mean open time of the channel was 178 +/- 25 msec (n = 6) at RP. The closed time of the channel seemed to have two exponential components, with time constants of 11.0 +/- 2.0 msec and 1.92 +/- 0.52 sec (n = 6) at RP. The slower time constant was increased with hyperpolarization. The averaged patch current recorded upon hyperpolarizing pulses demonstrated a time-dependent current decay as expected from the single channel kinetics. The results indicated that the inward rectifier K+ current has time- and voltage-dependent kinetics.     

Characterisation of the ionic currents in freshly isolated rat ureter smooth muscle cells: evidence for species-dependent currents

To better understand excitability, and hence contraction, the ionic currents underlying the action potential were identified and characterised in enzymatically isolated smooth muscle cells of the rat ureter. Using the whole-cell patch-clamp, under voltage-clamp conditions with K(+) in the pipette, three types of responses occurred to depolarisation: (1) sustained outward current and spontaneous transient outward currents (STOCs); (2) inward current; and (3) fast outward current. Investigation using different voltage protocols and pharmacological blockers and agonists revealed the presence of three outward and two inward currents. The outward currents were: (1) a sustained BK current, sensitive to low concentrations of tetraethylammonium (TEA) and featuring bursts of STOCs superimposed on it; (2) a fast, transient, A-type K current sensitive to 4-aminopyridine; and (3) a TEA and Ca(2+)-insensitive, late K(+) rectifier current. The inward currents were: (1) a fast L-type Ca(2+) channel current sensitive to nifedipine, Cd(2+) and potentiated by Ba(2+); and (2) a Ca(2+)-sensitive Cl(-) channel, which was inhibited by niflumic acid and Ba(2+), and produced a large tail current upon repolarisation at the end of the voltage step. The I- V relationships and peak amplitudes of all the currents are described. The finding of a K(+) rectifier and Ca(2+)-activated Cl(-) channel distinguish the rat ureteric cells from those of the guinea-pig. Thus, as well as the previously established difference in sarcoplasmic reticulum Ca(2+)-release mechanisms, there is also a species difference in ion channel expression in this tissue. We relate these currents to their possible contribution to the characteristically extremely long lasting action potential in the rat ureter.     

Characterization of outward currents induced by 5-HT in neurons of rat dorsolateral septal nucleus

Properties of the 5-hydroxytryptamine (5-HT)-induced current (I(5-HT)) were examined in neurons of rat dorsolateral septal nucleus (DLSN) by using whole cell patch-clamp techniques. I(5-HT) was associated with an increase in the membrane conductance of DLSN neurons. The reversal potential of I(5-HT) was -93 +/- 6 (SE) mV (n = 7) in the artificial cerebrospinal fluid (ACSF) and was changed by 54 mV per decade change in the external K(+) concentration, indicating that I(5-HT) is carried exclusively by K(+). Voltage dependency of the K(+) conductance underlying I(5-HT) was investigated by using current-voltage relationship. I(5-HT) showed a linear I-V relation in 63%, inward rectification in 21%, and outward rectification in 16% of DLSN neurons. (+/-)-8-Hydroxy-dipropylaminotetralin hydrobromide (30 microM), a selective 5-HT(1A) receptor agonist, also produced outward currents with three types of voltage dependency. Ba(2+) (100 microM) blocked the inward rectifier I(5-HT) but not the outward rectifier I(5-HT). In I(5-HT) with linear I-V relation, blockade of the inward rectifier K(+) current by Ba(2+) (100 microM) unmasked the outward rectifier current in DLSN neurons. These results suggest that I(5-HT) with linear I-V relation is the sum of inward rectifier and outward rectifier K(+) currents in DLSN neurons. Intracellular application of guanosine-5'-O-(3-thiotriphosphate) (300 microM) and guanosine-5'-O-(2-thiodiphosphate) (5 mM), blockers of G protein, irreversibly depressed I(5-HT). Protein kinase C (PKC) 19-36 (20 microM), a specific PKC inhibitor, depressed the outward rectifier I(5-HT) but not the inward rectifier I(5-HT). I(5-HT) was depressed by N-ethylmaleimide, which uncouples the G-protein-coupled receptor from pertussis-toxin-sensitive G proteins. H-89 (10 microM) and adenosine 3',5'-cyclic monophosphothioate Rp-isomer (300 microM), protein kinase A inhibitors, did not depress I(5-HT). Phorbol 12-myristate 13-acetate (10 microM), an activator of PKC, produced an outward rectifying K(+) current. These results suggest that both 5-HT-induced inward and outward rectifying currents are mediated by a G protein and that PKC is probably involved in the transduction pathway of the outward rectifying I(5-HT) in DLSN neurons.     

Muscarine affects calcium-currents in rat hippocampal pyramidal cells in vitro

Ca2+-currents were recorded from single CA3 pyramidal cells in hippocampal slice cultures, voltage-clamped through a single Cs+ - or K+-filled microelectrode and perfused with Hanks' balanced salt solution containing 1 microM tetrodotoxin and 10 mM tetraethylammonium. The Ca2+-current was reversibly reduced by bath-perfused muscarine (10-100 microM). This effect was inhibited by pirenzepine (10 microM) or atropine (1 microM). In K+-filled cells, inhibition was preceded by a phase of inward current enhancement; this was considered to be secondary to rapid outward current inhibition induced it by muscarine since it was reduced when outward currents were previously inhibited with Ba2+. In partially clamped or unclamped cells inhibition of Ca2+-current leads to a shortening of the Ca2+-spike plateau.     

Block by the neuropeptide TRH of an apparently novel K+ conductance of rat motoneurones

Using a single electrode voltage clamp technique the actions of rapidly superfused thyrotropin-releasing hormone (TRH, 1 microM) on lumbar motoneurones of the isolated neonatal rat spinal cord were investigated. TRH induced a slowly developing inward current (associated with an input conductance fall) with slow recovery on washout. In the presence of TRH the normally linear current-voltage relations displayed strong inward rectification up to about -40 mV. The TRH-induced current peaked at -50 mV, reversed at -120 mV and was not blocked by Cs+, tetraethylammonium, 4-aminopyridine, Cd2+, or low Na+. Its reversal potential was sensitive to changes in extracellular K+. Ba2+ (0.2-1.5 mM) depressed the effects of TRH. It is suggested that in rat motoneurones TRH blocked an apparently novel K+ conductance (IK(T)) active at resting membrane potential.     

An investigation of the role played by the E-4031-sensitive (rapid delayed rectifier) potassium current in isolated rabbit atrioventricular nodal and ventricular myocytes

The aim of this study was to measure and compare the profile of rapid delayed rectifier potassium current (IKr) elicited by action potential (AP) waveforms applied to isolated rabbit atrioventricular nodal (AVN) and ventricular myocytes. All measurements were made using whole-cell patch-clamp recordings at 37 degrees C. In AVN myocytes, IKr during voltage steps and slow ramp depolarisations showed "inward rectification" (characteristic for this channel) at positive potentials. The E-4031-sensitive current showed half-maximal activation at -10.8 +/- 0.86 mV, with a slope factor for the activation relation of 6.5 +/- 0.77 mV (n = 7). During AVN APs, IKr rapidly reached a peak after the AP upstroke and remained at similar amplitude until late in AP repolarisation. At the maximum diastolic potential following the AVN AP, a component of IKr remained which decayed during the pacemaker depolarisation, consistent with a role for the current in generating AVN pacemaker activity. In ventricular myocytes IKr was small at the beginning of the AP, and increased slowly during the AP plateau. Measurement of Ba-sensitive-inward rectifier K current (IK1) in ventricular myocytes revealed that IK1 rapidly increased during the final AP repolarisation phase, whilst IKr declined. It is concluded that IKr may participate in both AP repolarisation and the pacemaker depolarisation in AVN cells, whilst in ventricular myocytes, IKr and IK1 participate in controlling early and final AP repolarisation respectively.     

Intracellular Ca modulates K-inward rectification in cardiac myocytes

Summary In cardiac myocytes, instantaneous inward rectification of the K-rectifying channel is abolished by removal of divalent cations from the intracellular environment and can be restored by addition of Mg ions at submillimolar concentrations, which has led to the proposal that Mg ions regulate inward rectification in these cells (Matsuda et al., 1987; Vandenberg, 1987; Matsuda, 1988). Here we report that Ca, too, reduces outward current flow through single inward rectifier channels in cell-free inside-out patches at much lower (submicromolar) concentrations. Intracellular Ca induces rectification by decreasing the probability of the main open channel state and by favouring the opening of channel substates. Ca concentrations generating rectification are in the range of the Ca transient during activity, suggesting that Ca ions can contribute to K-rectification during cardiac muscle contraction.     

Initial uncoordinated expression of three types of voltage-gated currents in cultured Xenopus myocytes.

The expression of three types of voltage-gated ionic currents, namely the Na+ inward current, K+ outward rectifier current and K+ inward rectifier current, was examined in cultured developing Xenopus myocytes. In the population of myocytes, the Na+ inward current and K+ outward rectifier current appeared at around 32 h after fertilization (stage 27) and gradually increased during the period of observation, up to more than 44 h after fertilization (stage 33/34). The developmental time course of these two types of currents was similar. However, during the transition period individual myocytes did not necessarily express these two types of currents in a coordinated fashion. Some myocytes had a large Na+ inward current and small K+ outward rectifier current or vice versa. The K+ inward rectifier current was observed in some cells earlier than stage 27 and also gradually increased during the observation period. The initial expression of this current was not correlated with the K+ outward rectifier current or with the Na+ inward current.     

Ca2+-channel current and its modification by the dihydropyridine agonist BAY k 8644 in isolated smooth muscle cells

The electrophysiological properties of single smooth muscle cells isolated from the longitudinal layer of the guinea-pig ileum were studied with the whole-cell patch-clamp technique. The finding of resting potentials between -45 and -50 mV and the occurrence of spontaneous electrical activity when K+ was the predominant intracellular cation indicated that the cells were not leaky or hyperpermeable. The existence of an inward Ca2+ current overlapping in time with an outward rectifying K+ current was demonstrated. The latter could be selectively blocked by replacing internal K+ with Cs+ and external Ca2+ with Ba2+. Depolarizations to potentials between -40 and +50 mV evoked time-dependent inward currents, with a maximum peak value between -20 and 0 mV. For depolarizations beyond +50 mV time-dependent outward currents appeared. These currents were inhibited by 0.1 mM CdCl2. The activation of the inward current showed a sigmoidal time course, and the rate of onset of the current increased at more positive potentials. Inactivation could be described by two exponentials. The threshold for activation was about -40 mV, and full activation was reached at 0 mV. Inactivation was complete near 0 mV, whereas the channels were fully available at -80 mV. The fully-activated Ca2+-channel current was strongly voltage dependent. The conductance decreased for potentials close to the reversal potential, and showed rectification for hyperpolarizing potentials. The Ca2+ agonist BAY k 8644 enhanced the Ca2+-channel current without a significant effect on its kinetics. The fully-activated current and the steady-state activation were enhanced in a rather voltage-independent way.     

The intrinsic gating of inward rectifier K+ channels expressed from the murine IRK1 gene depends on voltage, K+ and Mg2+.

1. We describe the cloning of the inward rectifier K+ channel IRK1 from genomic DNA of mouse; the gene is intronless. 2. The IRK1 gene can be stably expressed in murine erythroleukaemia (MEL) cells. Such transfected cells show inward rectification under whole-cell recording. 3. Channels encoded by the IRK1 gene have an intrinsic gating that depends on voltage and [K+]o. Rate constants are reduced e-fold as the driving force on K+(V-EK) is reduced by 24.1 mV. 4. Removal of intracellular Mg2+ permits brief outward currents under depolarization. The instantaneous current-voltage relation may be fitted by an appropriate constant field expression. 5. Removal of intracellular Mg2+ speeds channel closure at positive voltages. In nominally zero [Mg2+]i, rate constants for the opening and closing of channels, processes which are first order, are similar to those of native channels.     

Barium decreases endothelium-dependent smooth muscle responses to transient but not to more prolonged acetylcholine applications

The influence of inhibiting the inward rectifier and Na/K pump on endothelium-dependent hyperpolarizations in smooth muscle cells of the mesenteric artery was investigated. Membrane potential was measured with microelectrodes, and the influence of low concentrations of Ba2+ (30 microM) and of high concentrations of ouabain (0.5 mM) on smooth muscle hyperpolarization elicited by prolonged or by transient exposure to acetylcholine (ACh, 3x10(-7) M) was assessed in the continuous presence of NG-nitro-L-arginine (100 microM) and indomethacin (50 microM). Pre-exposure to Ba2+ did not inhibit the magnitude of smooth muscle cell hyperpolarization induced by ACh superfusion, but significantly slowed its onset and time course. The membrane potential response to transient ACh applications, however, was impaired. After combined Ba2+ and ouabain pre-exposure, peak hyperpolarizations to ACh superfusion were somewhat decreased but not abolished. In addition, 4-5 mM increases of the extracellular K+ concentration consistently depolarized smooth muscle cells. These findings argue against the idea that smooth muscle inward rectifier K+ channels and Na/K pumping play a role in the ACh-induced endothelium-dependent hyperpolarization of this preparation. Moreover, the slowing of smooth muscle membrane hyperpolarization by Ba2+ is discussed in terms of the influence of this ion on the release of hyperpolarizing factor.     

Action potentials and membrane currents of isolated single smooth muscle cells of cat and rabbit colon

Membrane potentials, action potentials and macroscopic currents in enzymatically dispersed, single smooth muscle cells of the circular layer of cat and rabbit colon were investigated. The cells did not exhibit spontaneous depolarizations and repolarizations (slow waves) or spontaneous action potentials. Single action potentials of smooth muscle cells were evoked by depolarizing current pulses of 5 ms to 3 s duration. A repetitive action potential discharge and an increase in the duration of the action potential was observed in cells during long depolarizing current pulses by superfusion with tetraethylammonium (TEA) or 4-aminopyridine (4-AP). Tetrodotoxin (TTX) did not alter the configuration of the action potential. Voltage-clamp experiments revealed two major outward macroscopic currents: a quasi-instantaneous (time-independent) and a time-dependent outward current. Both currents were identified as potassium (K) currents due to their pharmacological sensitivity to K antagonists [TEA, 4-AP and cesium (Cs)] and due to the reversal potential of outward tail currents. Barium selectively blocked the time-independent current. A time-dependent outward K current in colon cells was observed which appeared to be dependent upon entry of calcium ions (Ca²⁺) through voltage-dependent Ca-channels, since it was blocked by cadmium and low concentrations of nifedipine. The majority of cells did not exhibit transient outward currents. Inward currents were exposed in some of the cells when the K currents were blocked by external TEA and by replacement of K by Cs and TEA in the recording pipette. Inward currents were presumably carried by Ca²⁺, since they were not altered by TTX, were sensitive to external Ca concentrations and were abolished by the Ca channel antagonist, nifedipine. Carbachol augmented the amplitude of the inward Ca current.     

Rat hippocampal neurons in culture: potassium conductances

Two-electrode voltage-clamp methodology was used to analyze voltage-dependent ionic conductances in 81 rat hippocampal neurons grown in culture for 4-6 wk. Pyramidal and multipolar cells with 15- to 20-micron-diameter cell bodies were impaled with two independent KCl electrodes. The cells had resting potentials of -30 to -60 mV and an average input resistance of about 30 M omega. A depolarizing command applied to a cell maintained in normal medium invariably evoked a fast (2-10 ms) inward current that saturated the current-passing capacity of the system. This was blocked in a reversible manner by application of tetrodotoxin (TTX) (0.1-1.0 microM) near the recorded cell. In the presence of TTX, a depolarizing command evoked a rapidly rising (3-5 ms), rapidly decaying (25 ms) transient outward current reminiscent of "IA" reported in molluscan neurons. This was followed by a more slowly activating (approximately 100 ms) outward current response of greater amplitude that decayed with a time constant of about 2-3 s. These properties resemble those associated with the K+ conductance, IK, underlying delayed rectification described in many excitable membranes. IK was blocked by extracellular application of tetraethylammonium (TEA) but was insensitive to 4-aminopyridine (4-AP) at concentrations that effectively eliminated IA. IA, in turn, was only marginally depressed by TEA. Unlike IK, IA was completely inactivated when the membrane was held at potentials positive to -50 mV. Inactivation was completely removed by conditioning hyperpolarization at -90 mV. A brief hyperpolarizing pulse (10 ms) was sufficient to remove 95% of the inactivation. IA activated on commands to potentials more positive than -50 mV. The inversion potential of the ionic conductance underlying IA and IK was in the range of the K+ equilibrium potential, EK, as measured by the inversion of tail currents; and this potential was shifted in a depolarizing direction by elevated [K+]0. Thus, both current species reflect activation of membrane conductance to K+ ions. Hyperpolarizing commands from resting potentials revealed a time- and voltage-dependent slowly developing inward current in the majority of cells studied. This membrane current was observed in cells exhibiting "anomalous rectification" and was therefore labeled IAR. It was activated at potentials negative to -70 mV with a time constant of 100-200 ms and was not inactivated. A return to resting potential revealed a tail current that disappeared at about EK. IAR was blocked by extracellular CS+ and was enhanced by elevating [K+]0. It thus appears to be carried by inward movement of K+ ions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Muscarine modulation by a G-protein alpha-subunit of delayed rectifier K+ current in rat ventromedial hypothalamic neurones.

1. Rat cultured ventromedial hypothalamic (VMH) neurones obtained from embryonic hypothalamus were used to study the muscarinic (carbachol) modulation of voltage-gated K+ currents with the whole-cell patch-clamp technique. 2. Carbachol produced a potent and concentration-dependent (100 fM to 100 microM) decrease of the outward delayed rectifier K+ current (IK) with an IC50 of 44 pM and a Hill coefficient of 0.4. The carbachol-induced depression of IK was reduced by pirenzepine (1-10 microM) and atropine (1 microM). Carbachol had no effect on the transient outward K+ current (IA). 3. Intracellular dialysis with guanosine 5'-O-(2-thiodiophosphate) (GDP-beta-S, 500 microM) significantly diminished the carbachol-induced depression of IK, suggesting GTP-binding protein (G-protein) involvement. Pre-incubation of VMH neurones with pertussis toxin (200-400 ng ml-1) or cholera toxin (1 microgram ml-1) for 24-48 h had no effect on the carbachol-induced depression of IK. This suggested that the G alpha o, G alpha i, and G alpha s G-protein alpha-subunits were not involved in mediating the carbachol-induced depression of IK in VMH neurones. 4. Treatment (24-48 h) of VMH neurones with antisense phosphothio-oligodeoxynucleotides to the G alpha 11 G-protein subunit (10 microM) significantly diminished the carbachol-induced depression of IK. Treatment with 10 microM of either G alpha 11 sense or antisense to G alpha q had no effect. 5. These results demonstrate a novel and potent muscarinic depression of IK in VMN neurones, and that this depression is specifically mediated by the G alpha 11 G-protein subunit.(ABSTRACT TRUNCATED AT 250 WORDS)     

Features of 4-aminopyridine sensitive outward current observed in single smooth muscle cells from the rabbit pulmonary artery

The 4-aminopyridine (4AP) sensitive outward current of enzymatically dispersed single smooth muscle cells of the rabbit main pulmonary artery were investigated using the voltage clamp method. When the cell was exposed to physiological salt solution (PSS) in the bath and high K⁺ in the pipette no inward current was generated by depolarization of the membrane, but when 4AP was present in the bath or when Cs⁺ with tetraethylammonium⁺ (Cs⁺-TEA⁺) in the pipette, an inward current was generated. This current was enhanced by Ba²⁺ or high Ca²⁺ and was blocked by inorganic or organic Ca²⁺ channel blockers.The outward current was partly inhibited by the Ca²⁺ channel blockers, Ca²⁺-free or Mn²⁺ containing solution. The residual outward current was blocked by external application of 10 mM 4AP, whereas it was inhibited by half with 100 mM TEA⁺. To investigate further natures of 4AP sensitive outward current, the following experiments were done in the bath solution containing 2.5 mM Mn²⁺. The reversal potential of this outward current, estimated from the tail current, remained the same in Na⁺-deficient solution, but shifted to near the K⁺-equilibrium potential in Cl^– deficient solution. Thus, the main current carrier for the outward current seems to be K⁺, but Cl^– may participate to some extent. The amplitude of the outward current decreased slowly. However, the reversal potential was not changed, suggesting the reduction in amplitude of the outward current was not due to the accumulation of K⁺ on the outer surface of the membrane. As 4AP inhibited the outward current to a greater extent at lower than higher membrane potential levels, 4AP bound to the channel may be dislodged at higher levels. When pH of the bath solution was modified from 7.3 to 8.0, inhibitory actions of 4AP were enhanced (pKa value of 4AP=9.17). Thus, a non-ionized form of 4AP may act as a channel blocker. We conclude that in smooth muscle cells of the pulmonary artery, lack of an action potential in physiological solution may partly be due to a small inward current as well as a large contribution of the 4AP sensitive outward current.     

Glutamate release from microglia via glutamate transporter is enhanced by amyloid-beta peptide.

In the present study, we found that amyloid-beta peptide enhanced glutamate release from primary cultured rat microglia via the Na+-dependent glutamate transporter, which was activated by extracellular K+. Glutamate transport current was measured by a conventional whole-cell patch recording mode under voltage-clamp conditions. With the pipette solution containing 10 mM glutamate and 100 mM Na+, an increase of the external K+ concentration from 0 to 10 mM evoked an outward current, resulting from co-extrusion of glutamate and Na+. The inward current, reflecting forward glutamate transport, was also activated by external glutamate. Both these reverse and forward glutamate transport currents were three-fold greater in microglia incubated with a relatively low concentration of amyloid-beta peptide (25-35) (5 microM) for four days. The glutamate-activated inward current was blocked by D,L-threo-beta-hydroxyaspartate in a dose-dependent manner (ranging from 0.001 to 1 mM), but not by a high concentration of kainate (1 mM). The glutamate concentration released from microglia upon high-K+ stimulation was also significantly increased (up to 170 microM) after treatment with amyloid-beta peptide (25-35). These results suggest that, at the pathological sites where extracellular K+ concentration may increase, the activation of microglia by amyloid-beta peptide causes an increase in extracellular glutamate concentration via reverse glutamate transporter, and therefore this mechanism may contribute to the pathogenesis of neuronal dysfunction and death in Alzheimer's disease.