K+ Channels Channels Research Articles

Identification and characterization of Ca2+-activated K+ channels in granulosa cells of the human ovary

BackgroundGranulosa cells (GCs) represent a major endocrine compartment of the ovary producing sex steroid hormones. Recently, we identified in human GCs a Ca2+-activated K+ channel (KCa) of big conductance (BKCa), which is involved in steroidogenesis. This channel is activated by intraovarian signalling molecules (e.g. acetylcholine) via raised intracellular Ca2+ levels. In this study, we aimed at characterizing 1. expression and functions of KCa channels (including BKCa beta-subunits), and 2. biophysical properties of BKCa channels.MethodsGCs were obtained from in vitro-fertilization patients and cultured. Expression of mRNA was determined by standard RT-PCR and protein expression in human ovarian slices was detected by immunohistochemistry. Progesterone production was measured in cell culture supernatants using ELISAs. Single channels were recorded in the inside-out configuration of the patch-clamp technique.ResultsWe identified two KCa types in human GCs, the intermediate- (IK) and the small-conductance KCa (SK). Their functionality was concluded from attenuation of human chorionic gonadotropin-stimulated progesterone production by KCa blockers (TRAM-34, apamin). Functional IK channels were also demonstrated by electrophysiological recording of single KCa channels with distinctive features. Both, IK and BKCa channels were found to be simultaneously active in individual GCs. In agreement with functional data, we identified mRNAs encoding IK, SK1, SK2 and SK3 in human GCs and proteins of IK and SK2 in corresponding human ovarian cells. Molecular characterization of the BKCa channel revealed the presence of mRNAs encoding several BKCa beta-subunits (beta2, beta3, beta4) in human GCs. The multitude of beta-subunits detected might contribute to variations in Ca2+ dependence of individual BKCa channels which we observed in electrophysiological recordings.ConclusionFunctional and molecular studies indicate the presence of active IK and SK channels in human GCs. Considering the already described BKCa, they express all three KCa types known. We suggest that the plurality and co-expression of different KCa channels and BKCa beta-subunits might allow differentiated responses to Ca2+ signals over a wide range caused by various intraovarian signalling molecules (e.g. acetylcholine, ATP, dopamine). The knowledge of ovarian KCa channel properties and functions should help to understand the link between endocrine and paracrine/autocrine control in the human ovary.

Endothelial modulation of swine coronary artery tone through coupling of basal IP3R‐dependent Ca2+ signals to endothelial SK and IK channels

Basal Ca2+ events originate from IP3 receptors (IP3R) at distinct sites in endothelial cells leading to stimulation of membrane Ca2+‐activated K+ channels (KCa). Persistent activation of small (SK) and intermediate (IK) conductance KCa channels may provide the foundation of endothelium derived hyperpolarization (EDH) in many vascular beds. Here we investigate the role of IP3‐mediated Ca2+ signaling through SK or IK channels in endothelial modulation of sustained coronary artery tone. In arteries pre‐contracted with U46619, the SK channel blocker apamin and the IK channel blocker charybdotoxin increased tone by 28.2% and 40.0%, respectively. These effects were endothelium dependent and were completely blocked by pretreatment with IP3R inhibitors xestospongin C or 2APB but not by ryanodine. Confocal imaging revealed dynamic endothelial Ca2+ events emanating from distinct spots along the basolateral membrane. Immunostaining in the same vessels showed endothelial expression of all three IP3R isoforms with discrete distribution profiles. Our findings indicate basal endothelial IP3R Ca2+ signals continuously modify coronary artery tone through constitutive SK and IK dependent hyperpolarization and relaxation. A working deterministic model was generated relating the density and distribution of specific endothelial IP3Rs to the origination and dynamics of Ca2+ events in coronary artery endothelium.

Vascular insulin resistance in cerebral arteries of Zucker obese rats is mediated by uncoupled eNOS and NADPH oxidase

Insulin resistance (IR) is a risk factor for cerebrovascular disease. We evaluated the responses to insulin in isolated cerebral arteries from Zucker obese rats (ZO) with IR and lean rats (ZL). Insulin responses were determined in the presence and absence of endothelium, inhibitors of calcium‐activated K+ channels (KCa), NOS and NADPH oxidase (iberiotoxin, L‐NAME and apocynin, respectively). Insulin induced only vasodilation in ZL while a biphasic response with an initial constriction followed by a diminished dilation was observed in ZO (‰ maximal relaxation: 52±10 in ZL vs. 13±8 in ZO, p<0.05). Iberiotoxin abolished vasodilation to insulin in both groups. In ZL, L‐NAME promoted vasoconstriction to insulin while apocynin had no effect. In ZO, insulin induced vasoconstriction was reduced by L‐NAME and apocynin. Endothelial denudation diminished vasodilation to insulin in ZL while ZO were unaffected, suggesting an endothelium independent vasodilation in ZL. Thus, insulin induced vasodilation in cerebral arteries was mediated by endothelium, NO and KCa channels. Insulin caused abnormal vasoconstriction and diminished vasodilation in ZO that may be due to oxidative stress from uncoupled eNOS and NADPH oxidase. Support: NIH grants HL‐030260, HL‐065380, HL‐077731.

Perinatal hypoxia triggers alterations in K+channels of adult pulmonary artery smooth muscle cells

Adverse events during the perinatal period, like hypoxia, have been associated with adult diseases. In pulmonary vessels, K(+) channels play an important role in the regulation of vascular tone. In the fetus, Ca(2+)-activated K(+) channels (K(Ca)) are predominant, whereas from birth voltage-gated K(+) channels (K(V)) prevail in the adult. We postulated that perinatal hypoxia could alter this maturational shift and influence regulation of pulmonary vascular tone in relation to K(+) channels in adulthood. We evaluated the effects of perinatal hypoxia on K(V) and K(Ca) channels in the adult main pulmonary artery (PA) using a murine model. Electrophysiological measurements showed a greater outward current in PA smooth muscle cells of mice born in hypoxia than in controls. In controls, only K(V) channels contributed to this current, whereas in mice born in hypoxia both K(V) and K(Ca) channels were implicated. K(V) channel activity was even higher in mice born in hypoxia than in controls. Therefore, perinatal hypoxia results in increased K(Ca) and K(V) channel activity in adult PA. Moreover, PA of adults born in hypoxia displayed higher large-conductance K(Ca) alpha-subunit and K(V)1.5 alpha-subunit protein expression than controls. Interestingly, relaxation induced by nitric oxide (NO) donors [S-nitroso-N-acetyl-D,l-penicillamine, 2-(N,N-diethylamino)-diazenolate-2-oxide] in isolated PA of control mice was not mediated by K(Ca) channels and only slightly by K(V) channels, whereas following perinatal hypoxia both K(Ca) and K(V) channels contributed to this relaxation. Thus perinatal hypoxia results in altered expression and activity of different K(+) channels in the adult main PA, which could contribute to modifications of pulmonary vasoreactivity.

Reduced expression of SKCa and IKCa channel proteins in rat small mesenteric arteries during angiotensin II-induced hypertension

Ca(2+)-activated K(+) channels (K(Ca)), in particular, the small and intermediate K(Ca) (SK(Ca) and IK(Ca), respectively) channels, are key players in endothelium-derived hyperpolarizing factor (EDHF)-mediated relaxation in small arteries. Hypertension is characterized by an endothelial dysfunction, possibly via reduced EDHF release and/or function. We hypothesize that during angiotensin II (14 days)-induced hypertension (ANG II-14d), the contribution of SK(Ca) and IK(Ca) channels in ACh-induced relaxations is reduced due to decreased expression of SK(Ca) and IK(Ca) channel proteins in rat small mesenteric arteries (MAs). Nitric oxide- and prostacyclin-independent vasorelaxation to ACh was similar in small MAs of sham-operated and ANG II-14d rats. Catalase had no inhibitory effects on these relaxations. The highly selective SK(Ca) channel blocker UCL-1684 almost completely blocked these responses in MAs of sham-operated rats but partially in MAs of ANG II-14d rats. These changes were pressure dependent since UCL-1684 caused a greater inhibition in MAs of 1-day ANG II-treated normotensive rats compared with ANG II-14d rats. Expression levels of both mRNA and protein SK3 were significantly reduced in MAs of ANG II-14d rats. The IK(Ca) channel blocker 1-[(2-chlorophenyl)diphenylmethyl]-1H-pyrazole (TRAM-34) resulted in comparable reductions in the relaxation responses to ACh in MAs of sham-operated and ANG II-14d rats. Relative mRNA expression levels of IK1 were significantly reduced in MAs of ANG II-14d rats, whereas protein levels of IK1 were not but tended to be lower in MAs of ANG II-14d rats. The findings demonstrate that EDHF-like responses are not compromised in a situation of reduced functional activity and expression of SK3 channels in small MAs of ANG II-induced hypertensive rats. The role of IK1 channels is less clear but might compensate for reduced SK3 activity.

Endothelium-Independent Relaxation by Adrenomedullin in Pregnant Rat Mesenteric Artery: Role of cAMP-Dependent Protein Kinase A and Calcium-Activated Potassium Channels

The mechanisms of relaxation of adrenomedullin were investigated in isolated mesenteric artery from pregnant rats. Adrenomedullin (1 nM-0.3 microM) produced concentration-dependent relaxation of endothelium-denuded mesenteric artery rings precontracted with norepinephrine at a concentration required to produce 70% of maximal response (ED70). The concentration-response curve of adrenomedullin was shifted to the right by adrenomedullin receptor antagonist adrenomedullin(22-52) (10 microM) or calcitonin gene-related peptide(8-37) (1 microM). Inhibition of adenylate cyclase by 9-(tetrahydro-2-furanyl)-9H-purin-6-amine (SQ22536) (10 microM) or protein kinase A [Rp-cyclic adenosine monophosphorothioate (Rp-cAMP); 10 microM] reduced the adrenomedullin-induced relaxation to the same magnitude. Adrenomedullin increased the intracellular cAMP level from 0.38 +/- 0.07 to 2.00 +/- 0.47 pmol/mg tissues, which was completely inhibited by adrenomedullin(22-52) (100 microM). Extracellular high potassium (80 mM), which inactivates the potassium channels, reduced the adrenomedullin-induced relaxation. Blockade of ATP-sensitive, voltage-gated, or inward rectifier potassium channels did not affect the adrenomedullin-induced relaxation. Blockade of calcium-activated K+ channels (KCa) by tetraethylammonium (1 mM) or iberiotoxin (100 nM) inhibited the adrenomedullin-induced relaxation, whereas there was no additional inhibition by SQ22536 or Rp-cAMP when KCa channels were already inhibited. In conclusion, this study provides evidence that cAMP-dependent protein kinase A and KCa channels seem to mediate as the cellular pathways in the adrenomedullin-induced endothelium-independent relaxation of mesenteric artery from pregnant rats.

Regional heterogeneity in EDHF‐mediated relaxation in the rat mesenteric vascular bed: role of small‐ and intermediate conductance calcium‐activated K+ channels

Background Calcium-activated K+-channels (KCa) are important regulators of vasomotor tone. Activation of these endothelial KCa channels result in smooth muscle hyperpolarization and relaxation. The relative contribution of the EDHF-mediated relaxation differs depending on the vessel type and size. It is unknown whether these KCa channels are differentially distributed along the same vascular bed and hence have different roles in mediating the EDHF response. We therefore assessed the role of small- (SKCa) and intermediate- (IKCa) conductance KCa channels in mediating EDHF-induced relaxations in both 4th and 1st-order side branches of the rat superior mesenteric artery (MrA). Methods and Results 2-mm segments of each MrA were mounted in the wire-myograph, incubated with L-NAME (100 μM) and indomethacin (INDO, 10 μM) and pre-contracted with phenylephrine (10 μM). Cumulative concentration-response curves to ACh (10−9–10−5 M) were performed in the absence or presence of the selective SKCa channel antagonist apamin (0.5 μM) or the selective IKCa channel antagonist TRAM-34 (10 μM). Maximal ACh-induced relaxations in the presence of both L-NAME and INDO were similar in both artery types (Emax 76±4% in 4th-order versus 75±7% in 1st-order MrA). Apamin almost completely abolished these relaxations in 4th-order MrA (Emax 2±2 %), but only partially blocked relaxations in 1st-order MrA (Emax 36±8%). TRAM-34 caused a significantly greater inhibition of the ACh-induced EDHF-mediated relaxation in 4th-order MrA compared to 1st-order MrA (Emax 26±7% versus 57±8%, respectively). Conclusion Our data demonstrate regional heterogeneity in SKCa and IKCa function, and stress the importance of KCa channels in smaller resistance-sized arteries, where the role of EDHF is more pronounced.

Regional heterogeneity in acetylcholine-induced relaxation in rat vascular bed: role of calcium-activated K+ channels

Ca+ -activated K+ -channels (KCa) regulate vasomotor tone via smooth muscle hyperpolarization and relaxation. The relative contribution of the endothelium-derived hyperpolarizing factor (EDHF)-mediated relaxation differs depending on vessel type and size. It is unknown whether these KCa channels are differentially distributed along the same vascular bed and hence have different roles in mediating the EDHF response. We therefore assessed the role of small- (SKCa), intermediate- (IKCa), and large-conductance (BKCa) channels in mediating acetylcholine-induced relaxations in both first- and fourth-order side branches of the rat superior mesenteric artery (MA1 and MA4, respectively). Two-millimeter segments of each MA were mounted in the wire myograph, incubated with Nomega-nitro-L-arginine methyl ester (L-NAME, 100 micromol/l) and indomethacin (10 micromol/l), and precontracted with phenylephrine (10 micromol/l). Cumulative concentration-response curves to ACh (0.001-10 micromol/l) were performed in the absence or presence of selective KCa channel antagonists. Apamin almost completely abolished these relaxations in MA4 but only partially blocked relaxations in MA1. The selective IKCa channel blocker 1-[(2-chlorophenyl) diphenylmethyl]-1H-pyrazole (TRAM-34) caused a significantly greater inhibition of the ACh-induced relaxation in MA4 compared with MA1. Iberiotoxin had no inhibitory effect in MA4 but blunted relaxation in MA1. Relative mRNA expression levels of SKCa (rSK1, rSK3, and rSK4 = rIK1) were significantly higher in MA4 compared with MA1. BKCa (rBKalpha1 and rBKbeta1) genes were similar in both MA1 and MA4. Our data demonstrate regional heterogeneity in SKCa and IKCa function and gene expression and stress the importance of these channels in smaller resistance-sized arteries, where the role of EDHF is more pronounced.

L-S-nitrosothiols: endothelium-derived hyperpolarizing factors in porcine coronary arteries?

Bradykinin-induced, endothelium-derived hyperpolarizing factor (EDHF)-mediated responses depend on Ca-dependent K-channels (KCa) of small (SKCa) and intermediate (IKCa) conductance, inwardly rectifying K (KIR) channels and/or Na-K-ATPase. Here we investigated in porcine coronary arteries (PCAs) whether S-nitrosothiols can act as EDHF. Preconstricted PCAs were exposed to bradykinin, the NO donor S-nitroso-N-penicillamine (SNAP), or the S-nitrosothiols L-S-nitrosocysteine (L-SNC), D-SNC and L-S-nitrosoglutathione (L-SNG), with or without KCl, the NO scavenger hydroxocobalamin, the S-nitrosothiol-depleting agent p-hydroxymercurobenzoic acid (PHMBA) and/or inhibitors of NO synthase (L-NAME), guanylyl cyclase (ODQ), SKCa channels (apamin), KCa channels of large conductance (BKCa) (iberiotoxin), IKCa + BKCa channels (charybdotoxin), KIR channels (BaCl2) or Na-K-ATPase (ouabain). All agonists concentration-dependently relaxed PCAs. L-NAME, charybdotoxin + apamin, KCl, and ouabain shifted the bradykinin concentration-response curve (CRC) approximately 10-fold to the right. BaCl2 did not exert additional effects on top of ouabain. Full blockade of bradykinin was obtained when combining L-NAME with charybdotoxin + apamin, KCl or ouabain + BaCl2. PHMBA reduced the maximum effect of bradykinin. Iberiotoxin + apamin, alone or on top of L-NAME, did not affect bradykinin, SNAP or L-SNC. ODQ and hydroxocobalamin shifted the SNAP, L-SNC, D-SNC, and L-SNG CRCs approximately 10-fold to the right, and, in combination, fully blocked SNAP-induced effects. Charybdotoxin + apamin shifted the L-SNC and L-SNG CRCs, but not the D-SNC or SNAP CRCs, approximately 5-fold to the right. KCl and ouabain (but not BaCl2) shifted the SNAP, L-SNC and L-SNG CRCs 5-10 fold to the right. L-S-nitrosothiols activate SKCa + IKCa channels in a stereoselective manner, whereas NO activates Na-K-ATPase. Since S-nitrosothiols decompose to NO, stored L-S-nitrosothiols may mediate bradykinin-induced, EDHF-dependent relaxation.

Blockade of the intermediate-conductance calcium-activated potassium channel as a new therapeutic strategy for restenosis.

Angioplasty stimulates proliferation and migration of vascular smooth muscle cells (VSMC), leading to neointimal thickening and vascular restenosis. In a rat model of balloon catheter injury (BCI), we investigated whether alterations in expression of Ca2+-activated K+ channels (KCa) contribute to intimal hyperplasia and vascular restenosis. Function and expression of KCa in mature medial and neointimal VSMC were characterized in situ by combined single-cell RT-PCR and patch-clamp analysis. Mature medial VSMC exclusively expressed large-conductance KCa (BKCa) channels. Two weeks after BCI, expression of BKCa was significantly reduced in neointimal VSMC, whereas expression of intermediate-conductance KCa (IKCa1) channels was upregulated. In the aortic VSMC cell line, A7r5 epidermal growth factor (EGF) induced IKCa1 upregulation and EGF-stimulated proliferation was suppressed by the selective IKCa1 blocker TRAM-34. Daily in vivo administration of TRAM-34 to rats significantly reduced intimal hyperplasia by approximately 40% at 1, 2, and 6 weeks after BCI. Two weeks of treatment with the related compound clotrimazole was equally effective. Reduction of intimal hyperplasia was accompanied by decreased neointimal cell content, with no change in the rate of apoptosis or collagen content. The switch toward IKCa1 expression may promote excessive neointimal VSMC proliferation. Blockade of IKCa1 could therefore represent a new therapeutic strategy to prevent restenosis after angioplasty.

Role of Ca2+-dependent K+ channels in erythrocyte lysate-induced contraction of rabbit cerebral artery

K+ channel openers may be useful in the treatment of cerebral vasospasm following subarachnoid hemorrhage. However, the role of Ca2+ -dependent K+ channel (KCa) openers in cerebral vasospasm remain unclear. This study was undertaken to examine the role ofKCa in hemolysate-induced contraction of rabbit cerebral and peripheral arteries: 7. Iberiotoxin (IBX), a selective KCa channel blocker, produced more pronounced contraction in basilar than in those of carotid or femoral arteries, indicating KCa channels are important regulating factors in cerebral arteries; 2. NS1619, a selective KCa channel opener, abolished the contraction of basilar artery to erythrocyte lysate, a causative agent for cerebral vasospasm; 3. In rabbit basilar artery, NS1619 relaxed the contractions to IBX, erythrocyte lysate and KCI (20 and 60 mM), indicating that NS1619, besides opening KCa channels, possesses other vasodilating actions. We conclude that KCa channels are important factors in the regulation of cerebral vascular tension and KCa channel opener NS1619 may have dual relaxant actions in cerebral arteries. [Neurol Res 1999; 21: 705–711 ]

TGFbeta1 regulates the gating properties of intermediate-conductance KCa channels in developing parasympathetic neurons.

The developmental expression of Ca2+-activated K+ channels (KCa) in chick ciliary ganglion (CG) neurons is regulated by a target-derived avian isoform of TGFbeta1, which evokes a robust increase in the number of functional large-conductance (BK) KCa channels but which produces no change in their kinetics. However, CG neurons express multiple KCa channel subtypes. Here we show that TGFbeta1 regulates the gating properties of intermediate-conductance (IK) KCa channels in developing CG neurons. IK channels in inside-out patches excised from control E9 CG neurons became active on exposure to 1-5 microM free Ca2+ but then remained active on return to Ca2+-free salines. In contrast, IK channels in TGFbeta1-treated cells became active on exposure to 1-5 microM Ca2+, but became quiescent immediately on return to Ca2+-free salines. In contrast to its effects on BK channels, TGFbeta1 had no effect on the mean number of IK channels detected in excised patches. IK channels were not activated in cell-attached patches on E9 neurons depolarized by bath application of 145 mM KCl in the presence of 5 mM external Ca2+. However, BK channels were activated immediately by this procedure and were detected at a higher density in TGFbeta1-treated cells. In addition, analyses of macroscopic KCa fluctuations, and the voltage-dependence of KCa tail currents, suggest that IK channels do not contribute to voltage-evoked whole cell KCa. IK channels therefore may have some other function. These results indicate that the effects of TGFbeta1 on CG neurons entail distinct actions on multiple KCa channel subtypes.

Calcium influx through N- and P/Q-type channels activate apamin-sensitive calcium-dependent potassium channels generating the late afterhyperpolarization in lamprey spinal neurons.

Lamprey spinal neurons exhibit a fast afterhyperpolarization and a late afterhyperpolarization (AHP) which is due to the activation of apamin-sensitive SK Ca2+-dependent K+ channels (KCa) activated by calcium influx through voltage-dependent channels during the action potential (Hill et al. 1992, Neuroreport, 3, 943-945). In this study we have investigated which calcium channel subtypes are responsible for the activation of the KCa channels underlying the AHP. The effects of applying specific calcium channel blockers and agonists were analysed with regard to their effects on the AHP. Blockade of N-type calcium channels by omega-conotoxin GVIA resulted in a significant decrease in the amplitude of the AHP by 76.2+/-14.9% (mean +/- SD). Application of the P/Q-type calcium channel blocker omega-agatoxin IVA reduced the amplitude of the AHP by 20.3+/-10.4%. The amplitude of the AHP was unchanged during application of the L-type calcium channel antagonist nimodipine or the agonist (+/-)-BAY K 8644, as was the compound afterhyperpolarization after a train of 10 spikes at 100 Hz. The effects of calcium channel blockers were also tested on the spike frequency adaptation during a train of action potentials induced by a 100-200 ms depolarizing pulse. The N- and P/Q-type calcium channel antagonists decreased the spike frequency adaptation, whereas blockade of L-type channels had no effect. Thus in lamprey spinal cord motor- and interneurons, apamin-sensitive KCa channels underlying the AHP are activated primarily by calcium entering through N-type channels, and to a lesser extent through P/Q-type channels.

Stochastic nature and red cell population distribution of the sickling-induced Ca2+ permeability.

To explore basic properties of the sickling-induced cation permeability pathway, the Ca2+ component (Psickle-Ca) was studied in density-fractionated sickle cell anemia (SS) discocytes through its effects on the activity of the cells' Ca2+sensitive K+-channels (KCa). The instant state of KCa channel activation was monitored during continuous or cyclic deoxygenation of the cells using a novel thiocyanate-densecell formation method. Each deoxy pulse caused a reversible, sustained Psickle-Ca, which activated KCa channels in only 10-45% of cells at physiological [Ca2+]o ("activated cells"). After removal of cells activated by each previous deoxy pulse, subsequent pulses generated similar activated cell fractions, indicating a random determination rather than the response of a specific vulnerable subpopulation. The fraction of activated cells rose monotonically with [Ca2+]o along a curve reflecting the cells' distribution of Psickle-Ca, with values high enough in a small cell fraction to trigger near-maximal KCa channels. Consistent with the stochastic nature of Psickle-Ca, repeated deoxygenated-oxygenated pulsing led to progressive dense cell formation, whereas single long pulses caused one early density shift. Thus deoxygenation-induced Ca2+-permeabilization in SS cells is a probabilistic event with large cumulative dehydrating potential. The possible molecular nature of Psickle-Ca is discussed.

Role of Tyrosine Phosphorylation in Potassium Channel Activation: FUNCTIONAL ASSOCIATION WITH PROLACTIN RECEPTOR AND JAK2 TYROSINE KINASE

Chinese hamster ovary (CHO) cells, stably transfected with the long form of the prolactin (PRL) receptor (PRL-R) cDNA, were used for PRL-R signal transduction studies. Patch-clamp technique in whole cell and cell-free configurations were employed. Exposure of transfected CHO cells to 5 nM PRL led to the increase of Ca(2+)- and voltage-dependent K+ channel (KCa) activity. The effect was direct as it was observed also in excised patch experiments. A series of tyrosine kinase inhibitors was studied to investigate the possible involvement of protein tyrosine kinases in KCa functioning and its stimulation by PRL. Genistein, lavendustin A, and herbimycin A decreased in a concentration and time-dependent manner the amplitude of the KCa current in whole cell and the open probability of KCa channels in cell-free experiments. The subsequent application of PRL was ineffective. The protein tyrosine phosphatase inhibitor orthovanadate (1 mM) stimulated KCa channel activity in excised patches, indicating that channels can be modulated in opposite directions by protein tyrosine kinase and protein tyrosine phosphatase. Moreover, in whole cell experiments as well as in excised patch recordings, anti-JAK2 tyrosine kinase antibody decreased the KCa conductance and the open probability of the KCa channels. Subsequent application of PRL was no longer able to stimulate KCa conductance. Immunoblotting studies using the same anti-JAK2 antibody, revealed the constitutive association of JAK2 kinase with PRL-R. Preincubation of anti-JAK2 antibody with the JAK2 Immunizing Peptide abolished the effects observed using anti-JAK2 antibody alone in both electrophysiological and immunoblotting studies. We conclude from these findings that these KCa channels are regulated through tyrosine phosphorylation/dephosphorylation; JAK2 tyrosine kinase, constitutively associated with PRL-R, is implicated in PRL stimulation of KCa channels.

Relaxin stimulates myometrial calcium-activated potassium channel activity via protein kinase A.

Relaxin, a hormone that is elevated during pregnancy, can suppress myometrial contractile activity. Ca(2+)-activated K+ channels (KCa) play a role in the modulation of uterine contractions and myometrial Ca2+ homeostasis and have been implicated in the control of smooth muscle excitability. We now show that relaxin stimulates KCa channels in cell-attached patches in a cell line derived from term pregnant human myometrium. This effect was prevented by the protein kinase A (PKA) antagonist, the Rp diastereomer of adenosine 3',5'-cyclic monophosphothioate (Rp-cAMPS). After patch excision, the channel was activated by PKA and inhibited by alkaline phosphatase. These data suggest that relaxin may promote myometrial quiescence in part by stimulation of KCa channels via a PKA-mediated mechanism.

Control of lamprey locomotor neurons by colocalized monoamine transmitters.

Neurons in the central nervous system (CNS) often store more than one neurotransmitter, but as yet the functional significance of this type of coexistence is poorly understood. 5-Hydroxytryptamine (5-HT) modulates calcium-dependent K+ channels (KCa) responsible for the postspike afterhyperpolarization in different regions of the CNS. In lamprey, 5-HT neurons control apamine-sensitive KCa channels in spinal locomotor network interneurons, thereby in addition regulating the duration of locomotor bursts. We report here that these spinal 5-HT neurons also contain dopamine. Like 5-HT, dopamine causes a reduction of the afterhyperpolarization, but in this case it is due to a reduction of calcium entry during the action potential, which results in a reduced activation of KCa. 5-HT and dopamine are both released from these midline neurons, and both reduce the afterhyperpolarization through two distinctly different, but complementary cellular mechanisms. The net effect of dopamine (10-100 microM) on the locomotor network is similar to that of 5-HT, and the effects of dopamine and 5-HT are additive at the network level.

KCa channel antagonists reduce NO donor-mediated relaxation of vascular and tracheal smooth muscle

Electrophysiological studies suggest that activation of large-conductance Ca-activated K channels (KCa) with nitric oxide (NO) causes hyperpolarization and relaxation of smooth muscle. We determined whether KCa blockers decreased relaxation to the NO donors S-nitroso-N-acetylpenicillamine (SNAP) and 3-morpholinosydonimine-hydrochloride (SIN-1) in isolated segments from main pulmonary artery (MPA), its left branch (LPA), aorta (Ao), carotid artery (CA), and trachea (Tr). NO donors caused concentration-dependent relaxation of tissues precontracted with histamine whereas the inactive carrier molecule C88-3934 was without effect. The rank order profiles of SNAP and SIN-1 sensitivity were CA = Ao = MPA > LPA = Tr. Compared with histamine, 80 mM KCl precontraction caused variable reductions in tissue sensitivity and maximum relaxation to SNAP. The KCa antagonists charybdotoxin, iberiotoxin, and tetraethylammonium decreased sensitivity to SNAP and SIN-1 2- to 11-fold in MPA, LPA, and Tr, with variable shifts in Ao and CA. The effect of iberiotoxin was not altered by removing the endothelium or epithelium. Furthermore, charybdotoxin or iberiotoxin did not alter basal or SNAP-stimulated guanosine 3',5'-cyclic monophosphate content. Glibenclamide, noxiustoxin, and leiurotoxin I, antagonists of ATP-dependent, delayed rectifier, and small-conductance KCa channels, respectively, had no effect. In conclusion, antagonists of KCa decrease NO donor-mediated relaxation of pulmonary arterial and tracheal smooth muscle.

Kaliotoxin, a novel peptidyl inhibitor of neuronal BK-type Ca(2+)-activated K+ channels characterized from Androctonus mauretanicus mauretanicus venom.

A peptidyl inhibitor of the high conductance Ca(2+)-activated K+ channels (KCa) has been purified to homogeneity from the venom of the scorpion Androctonus mauretanicus mauretanicus. The peptide has been named kaliotoxin (KTX). It is a single 4-kDa polypeptide chain. Its complete amino acid sequence has been determined. KTX displays sequence homology with other scorpion-derived inhibitors of Ca(2+)-activated or voltage-gated K+ channels: 44% homology with charybdotoxin (CTX), 52% with noxiustoxin (NTX), and 44% with iberiotoxin (IbTX). Electrophysiological experiments performed in identified nerve cells from the mollusc Helix pomatia showed that KTX specifically suppressed the whole cell Ca(2+)-activated K+ current. KTX had no detectable effects on voltage-gated K+ current (delayed rectifier and fast transient A current) or on L-type Ca2+ currents. KTX interacts in a one-to-one way with KCa channels with a Kd of 20 nM. Single channel experiments were performed on high conductance KCa channels excised from the above Helix neurons and from rabbit coeliac ganglia sympathetic neurons. KTX acted exclusively at the outer face of the channel. KTX applied on excised outside-out KCa channels induced a transient period of fast-flicker block followed by a persistent channel blockade. The KTX-induced block was not voltage-dependent which suggests differences in the blockade of KCa channels by KTX and by CTX. Comparison of KTX and CTX sequences leads to the identification of a short amino acid sequence (26-33) which may be implicated in the toxin-channel interaction. KTX therefore appears to be a useful tool for elucidating the molecular pharmacology of the high conductance Ca(2+)-activated K+ channel.