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Query: EC:2.7.11.13 (
protein kinase C
)
49,245
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Expression of
IsK
in Xenopus oocytes has been obtained in 2 ways: (i) by injection of cardiac polyA+ RNA from neonatal mouse heart; (ii) by injection of a cRNA synthesized in vitro. It was observed that polyA+ RNA not only directs the expression of the
IsK
channel but also contains purinergic P2 and endothelin receptors. Stimulation of these receptors, that produce intracellular Ca2+ increase together with diacylglycerol production activating
protein kinase C
, increases
IsK
activity. The same type of results and the same conclusions were obtained by co-injecting cRNA's corresponding to the 5-HT2 receptor and the
IsK
channel into oocytes. This stimulatory effect was shown to be due to Ca2+ via a calmodulin-dependent kinase process. Conversely, activation of
protein kinase C
pathway alone by phorbol esters leads to inhibition of
IsK
activity.
...
PMID:Receptor-mediated regulation of IsK, a very slowly activating, voltage-dependent K+ channel in Xenopus oocytes. 137 54
We have isolated cardiac cDNA and genomic clones encoding the guinea pig
IsK
protein. The deduced amino acid sequence is approximately 78% identical to the rat, mouse, and human variants of this channel, and the structure of the gene encoding the protein is also similar to that in other species. For example, the gene is present only once in the haploid genome, the protein-coding sequence is present on a single uninterrupted exon, an intron exists in the 5' untranslated domain, and multiple alternative polyadenylation sites are used in processing the transcript. Expression of the guinea pig protein in Xenopus oocytes results in a slowly activating, voltage-dependent K+ current,
IsK
, similar to those expressed previously from the rat, mouse, and human genes. However, in sharp contrast to the rat and mouse currents, activation of
protein kinase C
with phorbol esters increases the amplitude of the guinea pig
IsK
current, analogous to its effects on the endogenous IKs current in guinea pig cardiac myocytes. Mutagenesis of the guinea pig cDNA to alter four cytoplasmic amino acid residues alters the phenotype of the current response to
protein kinase C
from enhancement to inhibition, mimicking that of rat and mouse
IsK
currents. This mutation is consistent with reports that phosphorylation of Ser-102 by
protein kinase C
decreases the current amplitude. These data explain previously reported differences in the regulatory properties between recombinant rat or mouse
IsK
channels and native guinea pig IKs channels and provide further evidence that the
IsK
protein forms the channels that underlie the IKs current in the heart.
...
PMID:K+ currents expressed from the guinea pig cardiac IsK protein are enhanced by activators of protein kinase C. 751 Apr 7
Expression of
minK
protein in Xenopus oocytes induces a slowly activating, voltage-dependent, potassium-selective current. Point mutations in
minK
that alter current gating kinetics, ion selectivity, pharmacology, and response to
protein kinase C
all support the notion that
minK
is a structural protein for a channel-type transporter. Yet,
minK
has just 130 amino acids and a single transmembrane domain. Though larger cloned potassium channels form functional channels through tetrameric subunit association, the subunit composition of
minK
is unknown. Subunit stoichiometry was determined by coexpression of wild-type
minK
and a dominant lethal point mutant of
minK
, which reaches the plasma membrane but passes no current. The results support a model for complete
minK
potassium channels in which just two
minK
monomers are present, with other, as yet unidentified, non-
minK
subunits.
...
PMID:Subunit composition of minK potassium channels. 760 39
A clone encoding the guinea pig (gp) min K potassium channel was isolated and expressed in Xenopus oocytes. The currents, gpIsK, exhibit many of the electrophysiological and pharmacological properties characteristic of gpIKs, the slow component of the delayed rectifier potassium conductance in guinea pig cardiac myocytes. Depolarizing commands evoke outward potassium currents that activate slowly, with time constants on the order of seconds. The currents are blocked by the class III antiarrhythmic compound clofilium but not by the sotalol derivative E4031 or low concentrations of lanthanum. Like IKs in guinea pig myocytes, gpIsK is modulated by stimulation of protein kinase A and
protein kinase C
(
PKC
). In contrast to rat and mouse
IsK
, which are decreased upon stimulation of
PKC
, myocyte IK and gpIsK in oocytes are increased after
PKC
stimulation. Substitution of an asparagine residue at position 102 by serine (N102S), the residue found in the analogous position of the mouse and rat min K proteins, results in decreased gpIsK in response to
PKC
stimulation. These results support the hypothesis that the min K protein underlies the slow component of the delayed rectifier potassium current in ventricular myocytes and account for the species-specific responses to stimulation of
PKC
.
...
PMID:The min K channel underlies the cardiac potassium current IKs and mediates species-specific responses to protein kinase C. 826 83
Expression of the
IsK
protein in Xenopus oocytes induced the characteristically slow, voltage-dependent outward currents. Superfusion with the parathyroid hormone (PTH) peptide 1-34 had no effect on
IsK
when expressed alone, but increased
IsK
when
IsK
was coexpressed with the PTH-receptor. PTH receptor stimulation caused a shift of
IsK
conductance-voltage relationship to more negative potentials, and a decrease of both the rate of
IsK
activation and deactivation.
IsK
regulation by PTH was independent of extracellular Ca2+, and was also present
IsK
protein mutants lacking the
protein kinase C
consensus site. However, regulation of
IsK
by PTH was mimicked by activators of protein kinase A (PKA) and greatly reduced in the presence of the kinase inhibitors staurosporine and H89. These results suggest that PTH regulates
IsK
by a mechanism involving phosphorylation independent of
protein kinase C
(
PKC
). Such regulation may play a role in proximal tubule cells of the kidney, where both PTH receptor and the
IsK
protein are expressed.
...
PMID:Coexpression and stimulation of parathyroid hormone receptor positively regulates slowly activating IsK channels expressed in Xenopus oocytes. 877 Sep 56
Vestibular dark cells (VDC) are known to electrogenically secrete K+ via slowly activating K+ (
IsK
) channels, consisting of
IsK
regulatory and KvLQT1 channel subunits, and the associated short-circuit current (Isc) is inhibited by agonists of the apical P2U (P2Y2) receptor (J. Liu, K. Kozakura, and D. C. Marcus. Audit. Neurosci. 2: 331-340, 1995). Measurements of relative K+ flux (JK) with a self-referencing K(+)-selective probe demonstrated a decrease in JK after apical perfusion of 100 microM ATP. On-cell macropatch recordings from gerbil VDC showed a decrease of the
IsK
channel current (IIsK) by 83 +/- 7% during pipette perfusion of 10 microM ATP. The magnitude of the decrease of Isc by ATP was diminished in the presence of inhibitors of phospholipase C (PLC) and
protein kinase C
(
PKC
), U-73122 and GF109203X. Activation of
PKC
by phorbol 12-myristate 13-acetate (PMA, 20 nM) decreased IIsK by 79 +/- 3% in perforated-patch whole cell recordings, whereas the inactive analog, 4 alpha-PMA, had no effect. In contrast, elevation of cytosolic Ca2+ concentration by A-23187 increased the whole cell IIsK. The expression of the isk gene transcript was confirmed, and the serine responsible for the species-specific response to
PKC
was found to be present in the gerbil
IsK
sequence. These data provide evidence consistent with a direct effect of the
PKC
branch of the PLC pathway on the
IsK
channel of VDC in response to activation of the apical P2U receptor and predict that the secretion of endolymph in the human vestibular system may be controlled by
PKC
in the same way as in our animal model.
...
PMID:P2U purinergic receptor inhibits apical IsK/KvLQT1 channel via protein kinase C in vestibular dark cells. 943 9
Strial marginal cells (SMC) electrogenically secrete K+ via slowly activating K+ (I[sK]) channels, consisting of I(sK) regulatory and KvLQT1 channel subunits, and the associated short circuit current (I[sc]) is inhibited by agonists of the apical P2U receptor [Liu et al., Audit. Neurosci. 2 (1995) 331-340]. Measurements of relative K+ flux (JK) with a self-referencing K+-selective probe demonstrated a decrease in JK after apical perfusion of 100 microM ATP. On-cell macro patch recordings from the apical membrane of gerbil SMC showed a decrease of the I(sK) channel current (I[
IsK
]) by 88 +/- 8% during pipette perfusion of 100 microM ATP. The magnitude of the decrease of L(sc) by ATP was diminished in the presence of inhibitors of phospholipase C (PLC) and
protein kinase C
(
PKC
), U-73122 and GF109203X. Activation of
PKC
by phorbol 12-myristate 13-acetate (20 nM) decreased I(
IsK
) (gerbil: by 62 +/- 10%; rat: by 72 +/- 6%) in perforated-patch whole-cell recordings while the inactive analog, 4alphaPMA, had no effect. By contrast, elevation of cytosolic [Ca2+] by A23187 increased the whole-cell I(
IsK
). The expression of the isk gene transcript was confirmed and the serine responsible for the species-specific response to
PKC
was found to be present in the gerbil I(sK) sequence. These data provide evidence consistent with a direct effect of the
PKC
branch of the PLC pathway on the I(sK) channel of SMC in response to activation of the apical P2U receptor and predict that the secretion of endolymph in the human cochlea may be controlled by
PKC
in the same way as in our animal model.
...
PMID:Protein kinase C mediates P2U purinergic receptor inhibition of K+ channel in apical membrane of strial marginal cells. 947 37
Expression of
minK
in Xenopus oocytes results in a current similar to the cardiac slow delayed rectifying K+ (IKs) current. Modulation of the IKs current in cardiac myocytes has been studied extensively because of its role in shaping the cardiac action potential. The human and cat
minK
cDNA have been cloned, but their regulation by protein kinases has not been characterized. We report here on the complex modulation of human and cat IKs currents by
protein kinase C
(
PKC
) and protein kinase A (PKA). Activation of
PKC
by phorbol ester (100 nmol/L phorbol 12,13-didecanoate [PDD]) produces an increase in IKs current that peaks after 20 minutes and then subsequently decreases to approximately 50% of the control level after 1 hour. PKA activation only produces a sustained increase in IKs current. Interestingly, premodulation by
PKC
prevents IKs current modulation by PKA, and
PKC
has no effect on IKs current after potentiation by PKA. This shows that the IKs current is modulated by
PKC
and PKA in a mutually exclusive manner and suggests that multiple interacting phosphorylation sites are involved. Activation of
PKC
by diacylglycerol analogues only produces a slow decrease in IKs current. The biphasic effects of
PKC
on IKs current activated by PDD can also be separated by dose and duration. Low doses of PDD (5 nmol/L) or brief applications (5 minutes) of 100 nmol/L PDD only produces IKs current activation. These data suggest that there are at least 2 independent
PKC
phosphorylation sites in the
minK
-KvLQT1 channel. Additionally, long-term activation of
PKC
strongly attenuates the IKs current expression even when the corresponding changes in capacitance are taken into account.
...
PMID:Independent and exclusive modulation of cardiac delayed rectifying K+ current by protein kinase C and protein kinase A. 981 47
The effect of
protein kinase C
(
PKC
) signaling pathway on the activity of voltage-dependent
delayed rectifier potassium channel
(K(V)) and the expression of K(V) isoform K(V)1.5 in rat bronchial smooth cells (BSMCs) were investigated with whole-cell patch clamp, Western-blot and RT-PCR techniques. The results showed: (1) phorbol 12-myristate 13-acetate (PMA), a
PKC
activator, caused a significant inhibition of K(V) channel currents in rat BSMCs. The inhibition was partly abolished by Ro31-8220, a
PKC
inhibitor. (2) PMA caused a significant suppression of the expression of K(V)1.5 mRNA and protein in rat BSMCs. These effects were attenuated by Ro31-8220. The results suggest that in rat BSMCs
PKC
activation inhibits K(V) currents and down-regulates the expression of K(V)1.5.
...
PMID:[Effect of protein kinase C on K(V) channel in rat bronchial smooth muscle]. 1271
Delayed rectifier K(+) currents (I(K)) play a critical role in determining cardiac action potential duration (APD). Modulation of I(K) affects cardiac excitability critically. There are three components of cardiac delayed rectifier, and the slowly activating component (I(Ks)) is influenced strongly by a variety of stimuli. Plasma levels of noradrenaline and endothelin are elevated in heart failure, and arrhythmias are promoted by such humoral abnormalities through modulation of ion channels. It has been reported that protein kinase A (PKA) and
protein kinase C
(
PKC
) modulate I(Ks) from human
minK
in a complex manner. In the present study, we coexpressed human
minK
with the human beta(1)-adrenoceptor (hbeta(1)AR) and the endothelin receptor subtype A (hET(A)R) in Xenopus oocytes and investigated the effects of receptor activation on the currents (I(Ks)) flowing through the oocytes. ET-1 modulated I(Ks) biphasically: a transient increase followed by a decrease. The
PKC
inhibitor chelerythrine completely inhibited the effects of ET-1. Intracellular EGTA abolished the transient increase by ET-1 and partially inhibited the subsequent decrease in the currents. When I(Ks) was increased by 10(-6) M isoproterenol (ISO), ET-1 did not increase but rather decreased the current to an even greater extent than under control conditions. In addition, the effects of ISO on I(Ks) were suppressed by ET(A)R stimulation. These data indicate that I(Ks) can be regulated by cross-talk between the ET(A)R and beta(1)AR systems in addition to direct regulation by each receptor system.
...
PMID:Cross-talk between beta(1)-adrenoceptors and ET(A) receptors in modulation of the slow component of delayed rectifier K(+) currents. 1570 50
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