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Query: UMLS:C0432222 (SEM)
 47,337 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The murine macrophage-like cell line J774.1 was used as a source of mRNA for the expression of inwardly rectifying potassium channels in Xenopus oocytes. RNA was isolated, poly(A)(+)-selected, and size-fractionated by sucrose density gradient centrifugation. Oocytes injected with J774.1 RNA expressed large-amplitude current (0.9 +/- 0.07 microA; mean +/- SEM, n = 31) at -100 mV in 96 mM extracellular K+ showing prominent inward rectification. The inwardly rectifying currents were most strongly expressed by an mRNA size class of 4-5 kb. The expressed current displayed selectivity, conductance, and rectification properties of inwardly rectifying potassium channels in their native membranes. The current was potassium selective and was specifically blocked by Ba2+. The conductance and the voltage dependence of the current rectification depended on the extracellular potassium concentration, with the midpoint in peak conductance following the potassium equilibrium potential. This high level of expression of inward rectifier current and the absence of other expressed currents suggest that J774.1 mRNA represents an excellent starting material for expression cloning of the inward rectifier potassium channel cDNA.
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PMID:Expression of an inwardly rectifying potassium channel in Xenopus oocytes. 138 29

Background outward K+ currents in guinea pig ventricular myocytes were characterized over a broad range of membrane potentials, including those corresponding to the plateau of the action potential. The background current that is blocked by 1 mM Ba2+ (IK,p) activates within 5 msec at positive potentials, does not inactivate, and deactivates very rapidly on repolarization. IK,p is insensitive to Cl- channel blockers, internal or external [Cl-], dihydropyridines, and sulfonylureas. In contrast, the delayed rectifier K+ current (IK) was not completely blocked even by 30 mM Ba2+. Ba(2+)-sensitive current density increased progressively from 0.16 +/- 0.04 pA/pF at 0 mV to 0.52 +/- 0.21 pA/pF at +80 mV (n = 13, mean +/- SEM). The background current remains present when [K+]o is reduced to 0 mM, which suppresses the inward rectifier K+ current (IK1). These and other features suggest that IK,p is generated by K+ channels that are distinct from IK1 or IK. The kinetics and voltage dependence of IK,p render it capable of modulating both the height and duration of the cardiac action potential.
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PMID:Background potassium current active during the plateau of the action potential in guinea pig ventricular myocytes. 844 75

Whole cell patch-clamp recordings of K+ currents from oligodendrocyte precursors in 10-day-old rats (P10) and, following myelination, in mature oligodendrocytes from 20-day-old rats (P20) were correlated with extracellular space (ECS) diffusion parameters measured by the local diffusion of iontophoretically injected tetramethylammonium ions (TMA+). The aim of this study was to find an explanation for the changes in glial currents that occur with myelination. Oligodendrocyte precursors (P10) in slices from corpus callosum were characterized by the presence of A-type K+ currents, delayed and inward rectifier currents, and lack of tail currents after the offset of a voltage jump. Mature oligodendrocytes in corpus callosum slices from P20 rats were characterized by passive, decaying currents and large tail currents after the offset of a voltage jump. Measurements of the reversal potential for the tail currents indicate that they result from increases in [K+]e by an average of 32 mM during a 20 msec 100 mV voltage step. Concomitant with the change in oligodendrocyte electrophysiological behavior after myelination there is a decrease in the ECS of the corpus callosum. ECS volume decreases from 36% (P9-10) to 25% (P20-21) of total tissue volume. ECS tortuosity lambda = (D/ADC)0.5, where D is the free diffusion coefficient and ADC is the apparent diffusion coefficient of TMA+ in the brain, increases as measured perpendicular to the axons from 1.53 +/- 0.02 (n = 6, mean +/- SEM) to 1.70 +/- 0.02 (n = 6). TMA+ non-specific uptake (k') was significantly larger at P20 (5.2 +/- 0.6 x 10(-3) s(-1), n = 6) than at P10 (3.5 +/- 0.4 x 10(-3) s(-1), n = 6). It can be concluded that membrane potential changes in mature oligodendrocytes are accompanied by rapid changes in the K+ gradient resulting from K+ fluxes across the glial membrane. As a result of the reduced extracellular volume and increased tortuosity, the membrane fluxes produce larger changes in [K+]e in the more mature myelinated corpus callosum than before myelination. These conclusions also account for differences between membrane currents in cells in slices compared to those in tissue culture where the ECS is essentially infinite. The size and geometry of the ECS influence the membrane current patterns of glial cells and may have consequences for the role of glial cells in spatial buffering.
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PMID:Changes in glial K+ currents with decreased extracellular volume in developing rat white matter. 921 94

Voltage recordings from neostriatal projection neurons were obtained using in vitro intracellular techniques before and during K+-conductance blockade. Neurons were stained with the biocytin technique. Somatic surface area (AS) was determined by both whole-cell recordings in isolated somata and by measuring stained somata recorded in slices. Dendritic measurements were done in reconstructed neurons. Average determinations of dendritic (AD) and neuronal (AN) surface areas coincided with previously reported anatomical data. Thus: As approximately 6.5 x 10(-6) cm2; AD approximately 1.9 x 10(-4) cm2; AN approximately AD + AS approximately 2 x 10(-4) cm2; AD/AS approximately 30. Measurements were done before and after superfusion with K+-conductance blockers (K+-blockers). Cells whose neuronal morphology was not obviously distorted by K+-blockade were chosen for the present study. Electrotonic transients were matched to a somatic shunt equivalent cylinder model adjusted with the generalized correction factor (Fdga) that constrains the parameters for neuronal anatomy. Neuronal input resistance (RN; mean +/- SEM) increased when it was corrected for somatic shunt, from 49 +/- 2 Momega (n = 80) to 179 +/- 7 Momega (n = 32). A difference was also obtained between the slowest time constant, tau0 = 16 +/- 0.9 ms (n = 49), and the dendritic membrane time constant, taumD = 33 +/- 1.6 ms (n = 36). When these electrophysiological measurements were used to calculate AN, the value obtained was similar to the anatomical measurements. Combining anatomical and electrophysiological data, somatic and dendritic input resistances were determined: RD = 182 +/- 7 Momega; Rs (with shunt) = 74 +/- 4 Momega (n = 32). The generalized correction factor, Fdga = 0.91 +/- 0.007 (n = 10), implied a short effective electrotonic length for dendrites: LD = 0.46 +/- 0.014 (n = 32). Saturating concentrations of the K+-blockers tetraethylammonium, Cs+, and Ba2+ increased RN and induced charging curves well fitted by single exponential functions in 56% of neostriatal neurons. Ba2+ greatly decreased the somatic shunt (n = 5): (RN = 216 +/- 21 Momega, tau0 = 46 +/- 2 ms, RD = 239 +/- 25 Momega, and RS = 3.2 +/- 0.5 Gomega), rendering values similar to those obtained with whole-cell recordings (e.g., RN approximately 198 Momega, RS approximately 2.62 Gomega) (n = 52). Cs+ (n = 5) had less effect on the somatic shunt (RN = 115 +/- 19 Momega, tau0 = 49 +/- 13 ms, RS = 161 +/- 8 Momega), although dendritic conductance was equally blocked (RD = 261 +/- 16 Momega). The Cs+-sensitive conductance exhibited inward rectifying properties not displayed by the Ba2+-sensitive conductance, suggesting that Cs+ preferentially acted upon inward rectifier conductances. In contrast, Ba2+ significantly acted upon linear conductances making up the somatic shunt. This suggests a differential action of different K+-blockers on the somato-dendritic membrane, implying a differential distribution of membrane conductances. Another action of K+-blockers, in about 40% of the cells, was to induce dye and probably electrical coupling between neighboring neurons.
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PMID:Passive properties of neostriatal neurons during potassium conductance blockade. 962 5

Atrial action potential heterogeneity is a major determinant of atrial reentrant arrhythmias, but the underlying ionic mechanisms are poorly understood. To evaluate the basis of spatial heterogeneity in canine right atrial repolarization, we isolated cells from 4 regions: the crista terminalis (CT), appendage (APG), atrioventricular ring (AVR) area, and pectinate muscles. Systematic action potential (AP) differences were noted: CT cells had a "spike-and-dome" morphology and the longest AP duration (APD; value to 95% repolarization at 1 Hz, 270+/-10 ms [mean+/-SEM]); APG and pectinate muscle cells had intermediate APDs (180+/-3 and 190+/-3 ms, respectively; P<0.001 versus CT for each), with APG cells having a small phase 1; and AVR cells had the shortest APD (160+/-4 ms, P<0.001 versus other regions). The inward rectifier and the slow and ultrarapid delayed rectifier currents were similar in all regions. The transient outward K+ current was significantly smaller in APG cells, explaining their small phase 1 and high plateau. L-type Ca2+ current was greatest in CT cells and least in AVR cells, contributing to their longer and shorter APD, respectively. The E-4031-sensitive rapid delayed rectifier K+ current was larger in AVR cells compared with other regions. Voltage- and time-dependent current properties were constant across regions. We conclude that myocytes from different right atrial regions of the dog show systematic variations in AP properties and ionic currents and that the spatial variation in ionic current density may explain AP differences. Regional variation in atrial ionic currents may play an important role in atrial arrhythmia generation and may present opportunities for improving antiarrhythmic drug therapy.
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PMID:Ionic mechanisms of regional action potential heterogeneity in the canine right atrium. 973 77

Although the cationic inward rectifiers (Kir and hyperpolarization-activated I(f) channels) have been well characterized in cardiac myocytes, the expression and physiological role of anionic inward rectifiers in heart are unknown. In the present study, we report the functional and molecular identification of a novel chloride (Cl(-)) inward rectifier (Cl.ir) in mammalian heart. Under conditions in which cationic inward rectifier channels were blocked, membrane hyperpolarization (-40 to -140 mV) activated an inwardly rectifying whole-cell current in mouse atrial and ventricular myocytes. Under isotonic conditions, the current activated slowly with a biexponential time course (time constants averaging 179.7+/-23.4 [mean+/-SEM] and 2073.6+/-287.6 ms at -120 mV). Hypotonic cell swelling accelerated the activation and increased the current amplitude whereas hypertonic cell shrinkage inhibited the current. The inwardly rectifying current was carried by Cl(-) (I(Cl.ir)) and had an anion permeability sequence of Cl(-)>I(-)>>aspartate. I(Cl.ir) was blocked by 9-anthracene-carboxylic acid and cadmium but not by stilbene disulfonates and tamoxifen. A similar I(Cl.ir) was also observed in guinea pig cardiac myocytes. The properties of I(Cl.ir) are consistent with currents generated by expression of ClC-2 Cl(-) channels. Reverse transcription polymerase chain reaction and Northern blot analysis confirmed transcriptional expression of ClC-2 in both atrial and ventricular tissues and isolated myocytes of mouse and guinea pig hearts. These results indicate that a novel I(Cl.ir) is present in mammalian heart and support a potentially important role of ClC-2 channels in the regulation of cardiac electrical activity and cell volume under physiological and pathological conditions.
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PMID:A novel anionic inward rectifier in native cardiac myocytes. 1070 Apr 56