Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. We have investigated the effect of 2',5'-di (tert-butyl)-1,4-benzohydroquinone (BHQ) and thapsigargin, inhibitors of the intracellular Ca(2+)-ATPase, on ionic currents in rat basophilic leukaemia (RBL-2H3) cells under whole cell voltage clamp. 2. The whole cell current was inwardly rectifying and reversed at -35 +/- 6 mV (n = 16). The conductance of the inward current increased as the concentration of extracellular K+ was raised from 2.7 to 5.4, 10.8 and 21.6 mM. BaCl2 (100 microM) reduced the current to a small linear component and shifted the reversal potential to -4 +/- 3 mV (n = 6). A concentration of 50 microM BaCl2 produced 45 +/- 10% (n = 4) blockade of the inward current. 3. BHQ and thapsigargin were examined for their effects on the inwardly rectifying current. A maximal blockade of inward current was obtained within 6 min after perfusion with 10 microM BHQ. The small current remaining after blockade with BHQ had a linear voltage-dependence and reversed direction at -6 +/- 9 mV (n = 6). Thapsigargin (up to 3 microM) was without effect on the inward rectifier. 4. In contrast to the blockade of the inward rectifier produced by BaCl2 which was predominantly on the steady state current, particularly at the very hyperpolarized holding potentials (-120 mV), blockade by BHQ was equally strong on the instantaneous as well as the steady state current. 5. Blockade of the inward rectifier by BHQ may cause depolarization of the cell which will affect Ca2+ influx during investigations with BHQ. Thapsigargin does not block the inward rectifier and will not inhibit Ca2+ influx in this way.
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PMID:Blockade of the inward rectifier potassium current by the Ca(2+)-ATPase inhibitor 2',5'-di(tert-butyl)-1,4-benzohydroquinone (BHQ). 795 72

Second messenger regulation of IRK1 (Kir2.1) inward rectifier K+ channels was investigated in giant inside-out patches from Xenopus oocytes. Kir2.1-mediated currents that run down completely within minutes upon excision of the patches could be partly restored by application of Mg-ATP together with > 10 microM free Mg2+ to the cytoplasmic side of the patch. As restoration could not be induced by the ATP analogs AMP-PNP or ATP gamma S, this suggests an ATPase-like mechanism. In addition to ATP, the catalytic subunit of cAMP-dependent protein kinase (PKA) induced an increase in current amplitude, which could, however, only be observed if channels were previously or subsequently stimulated by Mg-ATP and free Mg2+. This indicates that functional activity of Kir2.1 channels requires both phosphorylation by PKA and ATP hydrolysis. Moreover, currents could be down-regulated by N-heptyl-5-chloro-1-naphthalenesulfonamide, a specific stimulator of protein kinase C (PKC), suggesting that PKA and PKC mediate inverse effects on Kir2.1 channels. Regulation of Kir2.1 channels described here may be an important mechanism for regulation of excitability.
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PMID:Kir2.1 inward rectifier K+ channels are regulated independently by protein kinases and ATP hydrolysis. 799 32

1. The hyperpolarization that follows tetanic stimulation was recorded intra-axonally from the internodal region of intramuscular myelinated motor axons. 2. The peak amplitude of the posttetanic hyperpolarization (PTH) that followed stimulation at 20-100 Hz for < or = 35 s increased with increasing train duration, reaching a maximum of 22 mV. PTH decayed over a time course that increased from tens to hundreds of seconds with increasing train duration. For a given frequency of stimulation the time integral of PTH was proportional to the number of stimuli in the train, averaging 3-4 mV.s per action potential. 3. Ouabain (0.1-1 mM) and cyanide (1 mM) depolarized the resting potential and abolished PTH. Tetanic stimulation in ouabain was followed by a slowly decaying depolarization (probably due to extra-axonal K+ accumulation) whose magnitude and duration increased as the duration of the train increased. 4. Axonal input resistance showed no consistent change during PTH in normal solution but increased during PTH in the presence of 3 mM Cs+ (which blocks axonal inward rectifier currents). 5. PTH was abolished when bath Na+ was replaced by Li+ or choline. PTH persisted after removal of bath Ca2+ and addition of 2 mM Mn2+. 6. Removal of bath K+ abolished the PTH recorded after brief stimulus trains and greatly reduced the duration of PTH recorded after longer stimulus trains. 7. A brief application of 10 mM K+, which normally depolarizes axons, produced a ouabain-sensitive hyperpolarization in axons bathed in K(+)-free solution. 8. These observations suggest that in these myelinated axons PTH is produced mainly by activation of an electrogenic Na(+)-K(+)-ATPase, rather than by changes in K+ permeability or transmembrane [K+] gradients. This conclusion is supported by calculations showing agreement between estimates of Na+ efflux/impulse based on PTH measurements and estimates of Na+ influx/impulse based on nodal voltage-clamp measurements. Pump activity also appears to contribute to the resting potential. 9. The stimulus intensity required to initiate a propagating action potential increased during PTH but decreased during the posttetanic depolarization recorded in ouabain. Thus changes in axonal excitability after tetanic stimulation correlate with changes in the posttetanic membrane potential. 10. Action potentials that propagated during PTH had a larger peak amplitude and were followed by a larger and longer depolarizing afterpotential than action potentials elicited at the resting potential. This enhancement of the depolarizing afterpotential is consistent with previous reports of an increased superexcitable period after action potentials evoked during PTH.
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PMID:Posttetanic hyperpolarization produced by electrogenic Na(+)-K+ pump in lizard axons impaled near their motor terminals. 829 60

We have investigated the electrophysiological basis of potassium inward rectification of the KAT1 gene product from Arabidopsis thaliana expressed in Xenopus oocytes and of functionally related K+ channels in the plasma membrane of guard and root cells from Vicia faba and Zea mays. The whole-cell currents passed by these channels activate, following steps to membrane potentials more negative than -100 mV, with half activation times of tens of milliseconds. This voltage dependence was unaffected by the removal of cytoplasmic magnesium. Consequently, unlike inward rectifier channels of animals, inward rectification of plant potassium channels is an intrinsic property of the channel protein itself. We also found that the activation kinetics of KAT1 were modulated by external pH. Decreasing the pH in the range 8.5 to 4.5 hastened activation and shifted the steady state activation curve by 19 mV per pH unit. This indicates that the activity of these K+ channels and the activity of the plasma membrane H(+)-ATPase may not only be coordinated by membrane potential but also by pH. The instantaneous current-voltage relationship, on the other hand, did not depend on pH, indicating that H+ do not block the channel. In addition to sensitivity towards protons, the channels showed a high affinity voltage dependent block in the presence of cesium, but were less sensitive to barium. Recordings from membrane patches of KAT1 injected oocytes in symmetric, Mg(2+)-free, 100 mM-K+, solutions allowed measurements of the current-voltage relation of single open KAT1 channels with a unitary conductance of 5 pS. We conclude that the inward rectification of the currents mediated by the KAT1 gene product, or the related endogenous channels of plant cells, results from voltage-modulated structural changes within the channel proteins. The voltage-sensing or the gating-structures appear to interact with a titratable acidic residue exposed to the extracellular medium.
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PMID:Inward rectifier potassium channels in plants differ from their animal counterparts in response to voltage and channel modulators. 858 18

1. The hypothesis that inward rectifier K(+) channels are involved in the vasodilatation of small coronary and cerebral arteries (100-200 microm diameter) in response to elevated [K+]o was tested. The diameters and membrane potentials of pressurized arteries from rat were measured using a video-imaging system and conventional microelectrodes, respectively. 2. Elevation of [K+]o from 6 to 16 mM caused the membrane potential of pressurized (60 mmHg) arteries to hyperpolarize by 12-14 mV. Extracellular Ba(2+) (Ba2+(o)) blocked K(+)-induced membrane potential hyperpolarizations at concentrations (IC(50), 6 microM) that block inward rectifier K(+) currents in smooth muscle cells isolated from these arteries. 3. Elevation of [K+]o from 6 to 16 mM caused sustained dilatations of pressurized coronary and cerebral arteries with diameters increasing from 125 to 192 microm and 110 to 180 microm in coronary and cerebral arteries, respectively. Ba2+(o) blocked K(+)-induced dilatations of pressurized coronary and cerebral arteries (IC50, 3-8 microM). 4. Elevated [K+]o-induced vasodilatation was not prevented by blockers of other types of K(+) channels (1 mM 4-aminopyridine, 1 mM TEA+, and 10 mu M glibenclamide), and blockers of Na(+)-K(+)-ATPase. Elevated [K+]o-induced vasodilatation was unaffected by removal of the endothelium. 5. These findings suggest that K+(o) dilates small rat coronary and cerebral arteries through activation of inward rectifier K(+) channels. Furthermore, these results support the hypothesis that inward rectifier K(+) channels may be involved in metabolic regulation of coronary and cerebral blood flow in response to changes in [K+]o.
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PMID:Extracellular K(+)-induced hyperpolarizations and dilatations of rat coronary and cerebral arteries involve inward rectifier K(+) channels. 901 39

The mechanisms underlying direct muscarinic depolarizing responses in the stellate cells (SCs) and non-SCs of medial entorhinal cortex layer II were investigated in tissue slices by intracellular recording and pressure-pulse applications of carbachol (CCh). Subthreshold CCh depolarizations were largely potentiated in amplitude and duration when paired with a short DC depolarization that triggered cell firing. During Na+ conductance block, CCh depolarizations were also potentiated by a brief DC depolarization that allowed Ca2+ influx and the potentiation was more robust in non-SCs than in SCs. Also, in non-SCs, CCh depolarizations could be accompanied by spikelike voltage oscillations at a slow frequency. In both SCs and non-SCs, the voltage-current (V-I) relations were similarly affected by CCh, which caused a shift to the left of the steady-state V-I relations over the entire voltage range and an increase in apparent slope input resistance at potentials positive to about -70 mV. CCh responses potentiated by Ca2+ influx demonstrated a selective increase in slope input resistance at potentials positive to about -75 mV in relation to the nonpotentiated responses. K+ conductance block with intracellular injection of Cs+ (3 M) and extracellular Ba2+ (1 mM) neither abolished CCh depolarizations nor resulted in any qualitatively distinct effect of CCh on the V-I relations. CCh depolarizations were also undiminished by block of the time-dependent inward rectifier Ih, with extracellular Cs . However, CCh depolarizations were abolished during Ca2+ conductance block with low-Ca2+ (0.5 mM) solutions containing Cd2+, Co2+, or Mn2+, as well as by intracellular Ca2+ chelation with bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid. Inhibition of the Na+-K+ ATPase with strophanthidin resulted in larger CCh depolarizations. On the other hand, when NaCl was replaced by N-methyl-D-glucamine, CCh depolarizations were largely diminished. CCh responses were blocked by 0.8 microM pirenzepine, whereas hexahydro-sila-difenidolhydrochloride,p-fluoroanalog (p-F-HHSiD) and himbacine were only effective antagonists at 5- to 10-fold larger concentrations. Our data are consistent with CCh depolarizations being mediated in both SCs and non-SCs by m1 receptor activation of a Ca2+-dependent cationic conductance largely permeable to Na+. Activation of this conductance is potentiated in a voltage-dependent manner by activity triggering Ca2+ influx. This property implements a Hebbian-like mechanism whereby muscarinic receptor activation may only be translated into substantial membrane depolarization if coupled to postsynaptic cell activity. Such a mechanism could be highly significant in light of the role of the entorhinal cortex in learning and memory as well as in pathologies such as temporal lobe epilepsy.
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PMID:Ionic mechanisms of muscarinic depolarization in entorhinal cortex layer II neurons. 911 39

The potassium conductance of the basolateral membrane (BLM) of proximal tubule cells is a critical regulator of transport since it is the major determinant of the negative cell membrane potential and is necessary for pump-leak coupling to the Na+,K+-ATPase pump. Despite this pivotal physiological role, the properties of this conductance have been incompletely characterized, in part due to difficulty gaining access to the BLM. We have investigated the properties of this BLM K+ conductance in dissociated, polarized Ambystoma proximal tubule cells. Nearly all seals made on Ambystoma cells contained inward rectifier K+ channels (gammaslope, in = 24.5 +/- 0.6 pS, gammachord, out = 3.7 +/- 0.4 pS). The rectification is mediated in part by internal Mg2+. The open probability of the channel increases modestly with hyperpolarization. The inward conducting properties are described by a saturating binding-unbinding model. The channel conducts Tl+ and K+, but there is no significant conductance for Na+, Rb+, Cs+, Li+, NH4+, or Cl-. The channel is inhibited by barium and the sulfonylurea agent glibenclamide, but not by tetraethylammonium. Channel rundown typically occurs in the absence of ATP, but cytosolic addition of 0. 2 mM ATP (or any hydrolyzable nucleoside triphosphate) sustains channel activity indefinitely. Phosphorylation processes alone fail to sustain channel activity. Higher doses of ATP (or other nucleoside triphosphates) reversibly inhibit the channel. The K+ channel opener diazoxide opens the channel in the presence of 0.2 mM ATP, but does not alleviate the inhibition of millimolar doses of ATP. We conclude that this K+ channel is the major ATP-sensitive basolateral K+ conductance in the proximal tubule.
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PMID:Properties of an inwardly rectifying ATP-sensitive K+ channel in the basolateral membrane of renal proximal tubule. 941 41

The differential responsiveness of (SUR1/K(IR)6.2)(4) pancreatic beta-cell versus (SUR2A/K(IR)6.2)(4) sarcolemmal or (SUR2B/K(IR)6. 0)(4) smooth muscle cell K(ATP) channels to K(+) channel openers (KCOs) is the basis for the selective prevention of hyperinsulinemia, myocardial infarction, and acute hypertension. KCO-stimulation of K(ATP) channels is a unique example of functional coupling between a transport ATPase and a K(+) inward rectifier. KCO binding to SUR is Mg-ATP-dependent and antagonizes the inhibition of (K(IR)6.0)(4) pore opening by nucleotides. Patch-clamping of matched chimeric human SUR1-SUR2A/K(IR)6.2 channels was used to identify the SUR regions that specify the selective response of sarcolemmal versus beta-cell channels to cromakalim or pinacidil versus diazoxide. The SUR2 segment containing the 12th through 17th predicted transmembrane domains, TMD12-17, confers sensitivity to the benzopyran, cromakalim, and the pyridine, pinacidil, whereas an SUR1 segment which includes TMD6-11 and the first nucleotide-binding fold, NBF1, controls responsiveness to the benzothiadiazine, diazoxide. These data are incorporated into a functional topology model for the regulatory SUR subunits of K(ATP) channels.
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PMID:Pharmaco-topology of sulfonylurea receptors. Separate domains of the regulatory subunits of K(ATP) channel isoforms are required for selective interaction with K(+) channel openers. 1062 98

Phosphorylation-dependent events have been shown to modulate the activity of several members of the mammalian CLC Cl- channel gene family, including the inward rectifier ClC-2. In the present study we investigated the regulation of rat ClC-2 expressed in the TSA-201 cell line (a transformed HEK293 cell line that stably expresses the SV40 T-antigen) by protein kinases. Protein kinase A activation phosphorylated ClC-2 in vivo, whereas stimulation of protein kinase C with phorbol 12-myristate 13-acetate did not. In vitro labeling studies confirmed that protein kinase A could directly phosphorylate ClC-2, and that protein kinase C and Ca2+/calmodulin-dependent protein kinase II did not. Nevertheless, protein kinase A-dependent phosphorylation of CLC-2 failed to regulate either the magnitude or the kinetics of the hyperpolarization-activated Cl- currents. Considered together, we demonstrate that protein kinase A activation results in the phosphorylation of rat ClC-2 in vivo, but this event is independent of Cl- channel activity.
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PMID:Protein kinase A activation phosphorylates the rat ClC-2 Cl- channel but does not change activity. 1142 97

Systolic heart failure (HF) is characterized by reduced systolic function and often by arrhythmias. We studied a rabbit model of HF (induced by combined aortic insufficiency and stenosis) which shows both contractile dysfunction and arrhythmogenesis. In this model we find an approximately 100% increase in Na/Ca exchange (NaCaX) expression at the level of mRNA, protein and function, but only a modest decrease in SR Ca-ATPase (approximately 24%, only detectable in cellular function). This combination results in a 40% reduction in SR Ca content in HF, which is sufficient to explain the 40% reduction in twitch Ca transients and 30-38% decrease in contractile function in this HF model. When stimulated by isoproterenol the SR Ca load readily reaches the threshold for spontaneous SR Ca release (this threshold Ca load is unchanged in HF). This SR Ca release activates a transient inward current (I(ti)) carried exclusively by NaCaX. For a given SR Ca release there is greater I(ti) in HF (due to higher NaCaX). We also find a 49% decrease in the inward rectifier potassium current (I(K1)), which allows greater depolarization for a given I(ti). Thus, higher NaCaX and lower I(K1) greatly increase the likelihood that an SR Ca release-induced delayed afterdepolarization (DAD) will trigger an arrhythmogenic action potential. We conclude that NaCaX contributes in major ways to both contractile dysfunction (by reducing SR Ca) and increased propensity for triggered arrhythmias (by increasing I(ti) and DADs).
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PMID:Upregulated Na/Ca exchange is involved in both contractile dysfunction and arrhythmogenesis in heart failure. 1247 32


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