Effects of neuropeptide Y on contraction, relaxation, and membrane potential of rabbit cerebral arteries

The effects of porcine neuropeptide Y (NPY) on agonist-induced contraction, relaxation, and intracellular membrane potential were studied in isolated ring segments of rabbit cerebral arteries. NPY caused contraction of cerebral arteries with a mean EC50 of 2.7 +/- 0.07 nM. After exposure of cerebral arteries to 1.5 nM NPY, the potencies of norepinephrine (NE) and histamine in causing contraction were increased by approximately twofold, with no change in maximal contraction. In cerebral arteries contracted with histamine, adenosine, and acetylcholine-induced relaxation was inhibited by 7-14-fold in the presence of 1.5 nM NPY, with no change in maximal relaxation. These effects of NPY were not altered by sympathetic denervation of cerebral arteries. Intracellular membrane potential in smooth muscle cells of cerebral arteries was measured using glass microelectrodes and averaged -66 +/- 1 mV. NPY 3 nM, ouabain 3 microM, and K+ Krebs solution 1 mM depolarized cerebral arteries by 15, 22, and 14 mV, respectively. In arteries depolarized by ouabain or 1 mM K+ Krebs solution, 3 nM NPY caused no additional depolarization. The potency of NE in causing contraction of cerebral arteries was increased by 3 microM ouabain (3.8-fold) and 1 mM K+ Krebs solution (1.9-fold); however, 3 nM NPY in the presence of ouabain or 1 mM K+ Krebs solution caused no greater increase in agonist potency. Ouabain 3 microM inhibited adenosine-induced relaxation by 5.1-fold whereas addition of 3 nM NPY to ouabain exposed arteries caused an additional 4.6-fold inhibition of relaxation. Ouabain and ouabain plus NPY also decreased the maximal relaxant effect of adenosine. These results suggest that the ability of NPY to potentiate contraction and inhibit relaxation of cerebral arteries is caused, at least in part, by NPY-induced membrane depolarization.     

Effects of noradrenaline and neuropeptide Y on rat mesenteric microvessel contraction

We have studied the contractile effects of the sympathetic transmitter noradrenaline and its cotransmitter neuropeptide Y (NPY) given alone and in combination on isolated rat mesenteric resistance vessels (200–300 m diameter). Noradrenaline and NPY each concentration-dependently contracted rat mesenteric microvessels (EC₅₀ 800 nM and 10 nM, respectively), but noradrenaline caused considerably greater maximal effects than NPY (14.3 mN vs. 3.5mN). A low antagonistic potency of yohimbine indicated that the response to noradrenaline did not involve ₂-adrenoceptors, and the subtype-selective antagonists 5-methylurapidil, tamsulosin and chloroethylclonidine indicated mediation via an _1A-adrenoceptor. Shallow Schild regressions for prazosin and 5-methylurapidil indicated that an ₁-adrenoceptor subtype with relatively low prazosin affinity might additionally be involved. Studies with the NPY analogues PYY, [Leu³¹, Pro³⁴]NPY and NPY_18–36 demonstrated that NPY acted via a Y₁ NPY receptor. In addition to its direct vasoconstricting effects NPY also lowered the noradrenaline EC₅₀ but did not appreciably affect maximal noradrenaline responses indicating possible potentiation. The potentiating NPY response occured with similar agonist potency as the direct contractile NPY effects and also via a Y₁ NPY receptor. The Ca²⁺ entry blocker nitrendipine (300 nM) reduced direct contractile responses to noradrenaline and NPY but did not affect the potentiation response to NPY.     

Endothelium removal does not affect potentiation by neuropeptide Y in rabbit ear artery

Influence of endothelial cells on the effect of neuropeptide Y (NPY) was investigated. NPY (30 nM) doubled the vasoconstriction elicited by transmural nerve stimulation (8 pulses at 8 Hz) in the perfused rabbit ear artery with or without endothelium. Conditions that increase the biophase concentration of norepinephrine, longer stimulation trains or application of yohimbine, decreased the potentiation by NPY, although in the presence of cocaine potentiation by NPY was unchanged. However, no significant differences between control and endothelium-removed arteries were revealed. Thus modulation of adrenergic neurotransmission by NPY does not depend on endothelium-derived vasoactive substances.     

Endothelin-1-induced contraction of mesenteric small arteries is mediated by ryanodine receptor Ca2+ channels and cyclic ADP-ribose

Contraction of vascular smooth muscle by endothelin-1 is dependent on extracellular and intracellular Ca2+. However, the role of ryanodine-sensitive Ca2+ stores in endothelin-1-induced contraction is unknown. Vascular contraction was measured in mesenteric small arteries (200-300 microm intraluminal diameter) isolated from Sprague-Dawley rats and maintained at a constant intraluminal pressure of 40 mm Hg. The presence of functional ryanodine receptor Ca2+ release channels (RyRC) was demonstrated by the finding that ryanodine (10 microM), which locks the RyRC in a subconductance state, produced significant contraction of small arteries in the presence of 15 mM KCl. This effect was inhibited by dantrolene (10 microM), a RyRC inhibitor. Dantrolene significantly reduced the ET(A) receptor-mediated contraction to endothelin-1 (10(-11)-10(-9) M). The ability of dantrolene to reverse contraction induced by endothelin-1 was also determined. Dantrolene (1-10 microM) produced concentration-dependent relaxation of vessels precontracted to 38+/-3% of resting diameter with endothelin-1 but had no effect in vessels precontracted to a similar degree with phenylephrine or KCl. Because activation of RyRC may be dependent on production of cyclic ADP-ribose, the effect of nicotinamide (2 mM), an inhibitor of ADP-ribosyl cyclase, on contraction to endothelin-1 was determined. Nicotinamide had an inhibitory effect similar to that produced by dantrolene. A combination of nicotinamide and dantrolene had no greater effect than either agent alone, suggesting a common pathway for cyclic ADP-ribose and RyRC. In summary, endothelin-1 induces contraction of small mesenteric arteries through ET(A) receptor-mediated production of cyclic ADP-ribose and activation of RyRC.     

The effect of neuropeptide Y on voltage-sensitive Ca2+ channels

Neuropeptide Y (NPY) (50-1000 nM) failed to modify basal or K(+)-stimulated Ca2+ influx in cortical or hippocampal synaptosomes from rat brain, whereas the voltage-sensitive Ca2+ channel (VSCC) blocker Cd2+ (50 microM) caused major inhibition. In cortical synaptosomes from chicken brain NPY (1.0 microM) failed to modify, whereas omega-conotoxin GV1A (0.1 microM) markedly inhibited Ca2+ influx. NPY does not appear to modify synaptosomal Ca2+ influx, however it may still affect VSCCs spatially distinct or 'upstream' from the nerve terminals.     

Inhibition of Ca2+-dependent contraction in swine carotid artery by myosin kinase inhibitors.

Experiments were designed to examine the efficacy of the MLCK inhibitors wortmannin and ML-9 in intact smooth muscle to determine whether contractile agonists can induce a Ca(2+) and myosin light chain phosphorylation-independent contraction. Both wortmannin and ML-9 reduced active stress in a dose-dependent manner. Both inhibitors interfered with Ca2+ mobilization in either the K(+)-depolarized or agonist activated swine carotid media at concentrations greater than 10 microM. Wortmannin reduced MRLC phosphorylation and stress to resting levels in stimulated tissues while Ca2+ remained above resting levels. There was no evidence for Ca2+ and MRLC phosphorylation-independent stress generation in swine arterial smooth muscle.     

Augmented sphingosylphosphorylcholine-induced Ca2+-sensitization of mesenteric artery contraction in spontaneously hypertensive rat

Sphingosylphosphorylcholine (SPC) is a vasoconstricting lysosphingolipid, and the RhoA/Rho-kinase pathway plays an important role in SPC-induced contraction. Since RhoA/Rho-kinase-mediated signaling is involved in the generation and/or maintenance of hypertension, we compared the effect of SPC on the contractility of endothelium-denuded small mesenteric arteries in spontaneously hypertensive rats (SHR) and Wistar Kyoto rats (WKY). Fura-2 Ca²⁺ signals, contractile responses, and phosphorylation of 20-kDa myosin light chains (MLC₂₀) were measured. Ten μM SPC induced a gradual and sustained vasoconstriction, which was greater in arteries of the SHR (82.5±4.3%, n=9) than in those of the WKY (26.7±4.5%, n=10). In Ca²⁺-free media, SPC gradually increased vascular tone in the SHR, but caused little vasoconstriction in the WKY. In the SHR and WKY, SPC evoked a greater vasoconstriction than did high K⁺depolarization at a given Ca²⁺ ratio, and the Ca²⁺ ratio–tension curve induced by SPC was significantly shifted to the left compared with that induced by high K⁺ depolarization. However, the magnitude of shift to the left was greater in the SHR than in the WKY. The Rho-kinase inhibitor Y-27632 significantly inhibited SPC-induced contractions, but neither the protein kinase C inhibitor calphostin-C nor PD98059, which inhibits activation of some mitogen-activated protein kinases, had any effect on the SHR or the WKY. SPC significantly increased the phosphorylation of MLC₂₀ in both the SHR and the WKY, and Y-27632 inhibited the SPC-induced increase in MLC₂₀ phosphorylation in the SHR. Our results suggest that SPC induces greater vascular tone in the SHR than in the WKY. Furthermore, our results indicate that activation of the Rho-kinase pathway plays an important role in the SPC-induced Ca²⁺ sensitization in the SHR.     

Neuropeptide Y potentiates contraction and inhibits relaxation of rabbit coronary arteries

The effects of neuropeptide Y (NPY) on contraction and relaxation of isolated rabbit coronary arteries were studied. NPY alone caused a weak contraction of coronary arteries with a mean EC50 value of 29 +/- 2.0 nM. Following exposure of coronary arteries to 30 nM NPY, the potencies of norepinephrine (in the presence of 3 microM timolol) and histamine in causing contraction were increased twofold, with no change in maximal contraction. After half-maximal contraction of coronary arteries with histamine and addition of 30 nM NPY, relaxation produced by norepinephrine (in the presence of 3 microM phentolamine), adenosine, and acetylcholine was inhibited. Concentration-response curves for all vasodilators were shifted to the right 10-22-fold by 30 nM NPY. Maximal relaxation caused by adenosine and norepinephrine was not changed by NPY, whereas the maximal response to acetylcholine was 37% less in the presence of NPY. Correlation of the tension produced by NPY with the shift in agonist contraction or relaxation concentration-response curves indicated that NPY-induced increases in baseline tone had no effect on the degree of shift in agonist concentration-response curves. These results show that NPY causes a modest potentiation of agonist-induced contraction and a dramatic blockade of vasodilator-induced relaxation of rabbit coronary arteries.     

Molecular determinants of Ca2+ potentiation of diltiazem block and Ca2+-dependent inactivation in the pore region of cav1.2

Diltiazem block of Cav1.2 is frequency-dependent and potentiated by Ca2+. We examined the molecular determinants of these characteristics using mutations that affect Ca2+ interactions with Cav1.2. Mutant and wild-type (WT) Cav1.2 channels were transiently expressed in tsA 201 cells with beta1b and alpha2delta subunits. The four conserved glutamates that compose the Ca2+ selectivity filter in Cav1.2 were mutated to Gln (E363Q, E709Q, E1118Q, E1419Q), and each single mutant was assayed for block by diltiazem using whole-cell voltage-clamp recordings in either 10 mM Ba2+ or 10 mM Ca2+. In Ba2+, none of the mutations affected the potency of diltiazem block of closed channels (0.05 Hz stimulation). However, frequency-dependent block (1Hz stimulation) was eliminated in the mutant E1419Q (domain IV), which recovered more rapidly than WT channels from inactivated channel block. Potentiation of diltiazem block of closed Cav1.2 channels in Ca2+ was abolished in the E1118Q, F1117G (domain III), and E1419Q mutants. Frequency-dependent block in Ca2+ was reduced compared with WT Cav1.2 in the F1117G, E1118Q, and E1419Q mutants. The C-terminal tail IQ domain mutation I1627A, which disrupts Ca2+ dependent inactivation, enhanced diltiazem block of closed channels in Ba2+. We conclude that, in Ba2+, E1419 slows recovery from diltiazem block of depolarized Cav1.2 channels, but in Ca2+, E1118, E1419, and F1117 form a Ca2+ binding site that mediates the potentiation of diltiazem block of both closed and inactivated Cav1.2 channels. Furthermore, Ca2+-dependent inactivation, which is impaired in E709Q, E1118Q, E1419Q, and I1627A, is not required for Ca2+ potentiation of diltiazem block.     

Ketamine attenuates the Na+-dependent Ca2+ overload in rabbit ventricular myocytes in vitro by inhibiting late Na+ and L-type Ca2+ currents

Aim:

Intracellular Ca²⁺ ([Ca²⁺]_i) overload occurs in myocardial ischemia. An increase in the late sodium current (I_NaL) causes intracellular Na⁺ overload and subsequently [Ca²⁺]_i overload via the reverse-mode sodium-calcium exchanger (NCX). Thus, inhibition of INaL is a potential therapeutic target for cardiac diseases associated with [Ca²⁺]_i overload. The aim of this study was to investigate the effects of ketamine on Na⁺-dependent Ca²⁺ overload in ventricular myocytes in vitro.

Methods:

Ventricular myocytes were enzymatically isolated from hearts of rabbits. I_NaL, NCX current (I_NCX) and L-type Ca²⁺ current (I_CaL) were recorded using whole-cell patch-clamp technique. Myocyte shortening and [Ca²⁺]_i transients were measured simultaneously using a video-based edge detection and dual excitation fluorescence photomultiplier system.

Results:

Ketamine (20, 40, 80 μmol/L) inhibited I_NaL in a concentration-dependent manner. In the presence of sea anemone toxin II (ATX, 30 nmol/L), I_NaL was augmented by more than 3-fold, while ketamine concentration-dependently suppressed the ATX-augmented I_NaL. Ketamine (40 μmol/L) also significantly suppressed hypoxia or H₂O₂-induced enhancement of I_NaL. Furthermore, ketamine concentration-dependently attenuated ATX-induced enhancement of reverse-mode I_NCX. In addition, ketamine (40 μmol/L) inhibited I_CaL by 33.4%. In the presence of ATX (3 nmol/L), the rate and amplitude of cell shortening and relaxation, the diastolic [Ca²⁺]_i, and the rate and amplitude of [Ca²⁺]_i rise and decay were significantly increased, which were reverted to control levels by tetrodotoxin (TTX, 2 μmol/L) or by ketamine (40 μmol/L).

Conclusion:

Ketamine protects isolated rabbit ventricular myocytes against [Ca²⁺]_i overload by inhibiting I_NaL and I_CaL.     

Inhibitory effect of 8-bromo cyclic GMP on an extracellular Ca2+-dependent arachidonic acid liberation in collagen-stimulated rabbit platelets

The inhibitory effect of cyclic GMP on collagen-induced platelet activation was studied using 8-bromo cyclic GMP (8brcGMP) in washed rabbit platelets. Addition of collagen (1 micrograms/ml) to platelet suspension caused shape change and aggregation associated with thromboxane (TX) A2 formation. 8brcGMP (10-1000 microM) inhibited collagen-induced platelet aggregation and TXA2 formation in a concentration-dependent manner. 8brcGMP did not affect platelet cyclooxygenase pathways, but markedly inhibited collagen-induced arachidonic acid (AA) liberation from membrane phospholipids in [3H]AA-prelabeled platelets, indicating that the inhibitory effect of 8brcGMP on collagen-induced aggregation is due to an inhibition of AA liberation. In [32P]orthophosphate-labeled platelets, collagen stimulated phosphorylation of a 20,000 dalton (20-kD) and 40-kD proteins. 8BrcGMP stimulated phosphorylation of a specific protein having molecular weight of 46-kD and inhibited collagen-induced both 20- and 40-kD protein phosphorylation. Collagen could stimulate the AA liberation without activation of phospholipase C or Na+-H+ exchange, but could not in the absence of extracellular Ca2+. These findings suggest that cyclic GMP inhibits collagen-induced AA liberation which is mediated by an extracellular Ca2+-dependent phospholipase A2. However, cyclic GMP seems to inhibit the Ca2+-activated phospholipase A2 indirectly, since 8brcGMP had no effect on Ca2+ ionophore A23187-induced platelet aggregation or AA liberation. It is therefore suggested that cyclic GMP may regulate collagen-induced increase in an availability of extracellular Ca2+ which is responsible for phospholipase A2 activation in rabbit platelets.     

Dynamics of Ca2+-dependent Cl- channel modulation by niflumic acid in rabbit coronary arterial myocytes

Calcium-activated chloride channels (Cl(Ca)) are crucial regulators of vascular tone by promoting a depolarizing influence on the resting membrane potential of vascular smooth muscle cells. Niflumic acid (NFA), a potent blocker of Cl(Ca) in vascular myocytes, was shown recently to cause inhibition and paradoxical stimulation of sustained calcium-activated chloride currents [I(Cl(Ca))] in rabbit pulmonary artery myocytes. The aims of the present study were to investigate whether NFA produced a similar dual effect in coronary artery smooth muscle cells and to determine the concentration-dependence and dynamics of such a phenomenon. Sustained I(Cl(Ca)) evoked by intracellular Ca(2+) clamped at 500 nM were dose-dependently inhibited by NFA (IC(50) = 159 microM) and transiently augmented in a concentration-independent manner (10 microM to 1 mM) approximately 2-fold after NFA removal. However, the time to peak and duration of NFA-enhanced I(Cl(Ca)) increased in a concentration-dependent fashion. Moreover, the rate of recovery was reduced by membrane depolarization, suggesting the involvement of a voltage-dependent step in the interaction of NFA, leading to stimulation of I(Cl(Ca)). Computer simulations derived from a kinetic model involving low (K(i) = 1.25 mM) and high (K(i) < 30 microM) affinity sites could reproduce the properties of the NFA-modulated I(Cl(Ca)) fairly well.     

Enhanced neuropeptide Y immunoreactivity and vasoconstriction in mesenteric small arteries from the early non-obese diabetic mouse

The present study investigated whether sympathetic neurotransmission is altered at an early stage of diabetes in mesenteric small arteries isolated from female non-obese diabetic (NOD) and control animals without diabetes from the same mouse strain. The NOD diabetic mice had increased plasma glucose and hypertension. Confocal microscopy showed distribution of nerve terminals was similar, but immunoreaction intensity for neuropeptide Y (NPY) and tyrosine hydroxylase was higher in small arteries from NOD diabetic compared with NOD control mice. In the presence of prazosin and activated with vasopressin, electrical field stimulation evoked contractions which were more pronounced in mesenteric arteries from NOD diabetic versus NOD control mice and inhibited by the NPY Y(1) receptor antagonist, BIBP 3226. NPY concentration-response curves were leftward shifted in arteries from NOD diabetic versus NOD control both in arteries with and without endothelium, but not in the presence of the BIBP 3226. The present findings suggest that enhanced NPY content and vasoconstriction to NPY by activation of NPY Y(1) receptors in arteries from diabetic mice may contribute to the enhanced sympathetic nerve activity and vascular resistance in female non-obese early diabetic animals.     

The Y1 antagonist BIBP 3226 inhibits potentiation of methoxamine-induced vasoconstriction by neuropeptide Y

We investigated the interaction of neuropeptide Y (NPY) with the α₁-adrenoceptor agonist, methoxamine, in control of mean arterial pressure, renovascular resistance and mesenteric vascular resistance in anaesthetized rats. Infusion of 3.0 but not 0.3μg/kg/min NPY enhanced the elevations of all three haemodynamic parameters caused by bolus injections of methoxamine (10–100μg/kg). These enhancements largely involved a prolongation of the methoxamine effects. While infusion of the Y₁ NPY receptor-selective antagonist, BIBP 3226 (10μg/kg/min), alone did not alter methoxamine-induced vasoconstriction, it inhibited the potentiation by NPY. We conclude that NPY can potentiate methoxamine-induced vasoconstriction in vivo. This is mediated predominantly, if not exclusively, via the Y₁ receptor. Endogenously released NPY does not appear to reach sufficient concentrations to cause tonic systemic vasoconstriction or potentiation thereof in the anaesthetized rat. Received: 30 May 1997 / Accepted: 25 July 1997     

Potentiation by neuropeptide Y of vasoconstriction in rat resistance arteries.

1. The effects of neuropeptide Y (NPY) on resistance arteries were investigated on 3rd generation mesenteric arterioles of the rat. 2. Contractions were elicited by noradrenaline (NA), 5-hydroxytryptamine (5-HT), prostaglandin F2 alpha (PGF2 alpha), depolarization (KCl substituted for NaCl) and by the calcium agonist Bay K 8644, in the absence and in the presence of NPY (100 nM), a concentration which by itself did not induce vasoconstriction. 3. NPY produced a leftward shift of the concentration-response curves to the agonists and to KCl, without any alteration of maximal contractions. 4. NPY also potentiated contractions elicited by addition of CaCl2 to KCl-depolarized vessels, but its effect on calcium-induced contractions decreased with increasing KCl concentrations (from 20 to 100 mM). 5. Calcium-induced contractions were inhibited by the calcium channel blocker nitrendipine, both in the presence and absence of NPY (100 nM). NPY increased slightly (but significantly) the sensitivity to nitrendipine (the apparent KB increased from 2.9 x 10(-10) M to 1.6 x 10(-10) M). 6. The KCl concentration necessary for the maximal effect of Bay K 8644 was decreased in the presence of NPY, and the sensitivity to the calcium channel agonist was increased. 7. Elevating the KCl concentration in the bath from 5 to 20 mM (which gives the same displacement to the left of the KCl concentration-effect curve seen in the presence of NPY) induced a parallel leftward shift of NA and 5-HT concentration-response curves. This shift was identical to the one induced by NPY on 5-HT-evoked contractions, but it was significantly smaller (P less than 0.001) than the shift of the NA concentration-response curve observed in the presence of NPY. In the latter case, NPY enhanced more markedly the contractions induced by low NA concentrations (between 10(-9) and 3 x 10(-8 M) than those induced by high concentrations (up to 3 x 10(-7) M), thus giving a shallow concentration-response curve. 8. The results strongly suggest that NPY partially depolarizes the arterioles and induces an increase in calcium entry through voltage-dependent channels, thus enhancing contractions elicited by agonists or by KCl-depolarization. In addition, they support the view that another mechanism also plays a part in the potentiation by NPY of the effects of low concentrations of NA.     

Differential potentiation by depolarization of the effects of calcium antagonists on contraction and Ca2+ current in guinea-pig heart.

1. The effects of elevation of extracellular K+ concentration ([K+]o) on the negative inotropic potencies of three representative calcium antagonists, diltiazem, verapamil and nifedipine, were investigated in guinea-pig papillary muscle preparations. 2. The negative inotropic effect of diltiazem was potentiated 110 fold when [K+]o was raised from 2.7 mM to 12.7 mM. The effect of verapamil was also potentiated to a lesser extent, but that of nifedipine was not affected. 3. Resting membrane potentials in ventricular muscles were about -80 mV and -60 mV in 2.7 mM K+ and 12.7 mM K+, respectively. 4. To clarify the mechanism responsible for the differential potentiation of the negative inotropic effects, the blocking actions of the three calcium antagonists on the L-type Ca2+ channel current (ICa(L)) were compared at the holding potentials of -80 mV and -60 mV by the whole-cell patch-clamp technique. 5. The use-dependent blocking effect of diltiazem on ICa(L) was enhanced markedly by the change in the holding potential from -80 mV to -60 mV. The effect of verapamil was also enhanced to a lesser extent but that of nifedipine was not affected in this range of depolarization. 6. The differential effects of the [K+]o elevation on the negative inotropic potencies of the three calcium antagonists are explained by the differences in voltage-dependency of their use-dependent blocking effects on ICa(L). 7. The properties of diltiazem and verapamil observed in this study may contribute to their protective effects on the ischaemic myocardium, without affecting the normal myocardium.     

The relationship between noradrenaline-induced contraction and 45Ca efflux stimulation in rabbit mesenteric artery.

Cellular Ca2+ recycling in a branch of the rabbit mesenteric artery was investigated by measuring the time- and concentration-dependent effects of noradrenaline (NA) on contraction and 45Ca efflux in Ca2+-free solution. When NA was present continuously (15 min), both force development and 45Ca efflux stimulation consisted of a fast and a slow (often oscillatory) component. These components were sensitive to caffeine and are probably both related to Ca2+ release from the intracellular Ca2+ store, presumably sarcoplasmic reticulum (s.r.). When NA was applied for shorter time periods, both tension and stimulated 45Ca efflux decreased similarly. Repetitive short (30 s) NA applications resulted in repeated contractions and stimulations of 45Ca efflux. The NA-stimulated 45Ca efflux was not inhibited when external Ca2+ was present or in Na+-free medium. Loading the cell with Ca2+ (with physiological salt solution for 3 h or with a high K+ depolarizing solution) increases the number of subsequent NA-induced repeated contractions in Ca2+-free solution. The Ca2+ content of the sarcoplasmic reticulum (s.r.) in the smooth muscle cells of this small artery was estimated to be at least 50 mumol kg-1 wet weight, corresponding to an s.r. Ca2+ concentration of about 3.1 mM. These results indicate that the NA-induced increase in cytosolic free Ca2+ (as measured by force development) is accompanied by an increase in Ca2+ extrusion (as measured by stimulation of 45Ca efflux). This suggests that at least part of the activator Ca2+ cycles through the extracellular space during hormone-induced activation of vascular smooth muscle.     

Characterization of Ca2+ channels involved in endothelin-1-induced contraction of rabbit basilar artery

This study attempted to characterize Ca2+ channels involved in endothelin-1-induced contraction of rabbit basilar artery using whole-cell patch-clamp and measurement of intracellular free Ca2+ concentration. Endothelin-1 activates two types of Ca2+-permeable nonselective cation channels (NSCC-1 and NSCC-2) and a store-operated Ca2+ channel (SOCC) in addition to the voltage-operated Ca2+ channel (VOCC). These channels can be discriminated using Ca2+ channel blockers, SK&F 96365 and LOE 908. Tension study was conducted to clarify the Ca2+ channels involved in endothelin-1-induced contraction of basilar artery. Endothelin-1-induced basilar artery contraction is fully dependent on extracellular Ca2+ influx. Based on sensitivity to nifedipine, an L-type VOCC blocker, VOCCs have a minor role in endothelin-1-induced contraction. Both LOE 908 and SK&F 96365 inhibit endothelin-1-induced contraction in a concentration-dependent manner, and their combination abolished it. The median inhibitory concentrations of these blockers for endothelin-1-induced contraction correlated well with those of the endothelin-1-induced [Ca2+]i responses. Thus, the inhibitory action of these blockers on endothelin-1-induced contraction may be mediated by blockade of NSCC-1, NSCC-2, and the SOCC. Extracellular Ca2+ influx through NSCC-1, NSCC-2, and SOCC may be essential for endothelin-1-induced basilar artery contraction.     

Multiple P2Y receptors mediate contraction in guinea pig mesenteric vein

Vasoconstrictor responses to exogenous adenine and pyrimidine nucleotides were measured in endothelium-denuded segments of guinea pig mesenteric vein and compared with responses in mesenteric artery. The rank order of potency for nucleotides in veins was: 2-MeSADP = 2-MeSATP > UTP > ATPgammaS = alpha,betaMeATP > UDP = ATP > ADP > beta,gamma-D-MeATP = beta,gamma-L-MeATP. In contrast 2-MeSADP, UTP, and UDP were inactive in arteries, and the rank order of potency of other nucleotides differed; that is, alpha,betaMeATP > beta, gamma-D-MeATP > beta,gamma-L-MeATP = ATPgammaS = 2-MeSATP > ATP > ADP. In veins, UTP, ATP, and 2-MeSATP were more efficacious contractile agents than alpha,beta MeATP. In addition, the ability to desensitize responses to these nucleotides and inhibit them with various blockers differed. The response to alpha,betaMeATP in veins exhibited rapid desensitization and was inhibited by pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid tetrasodium (PPADS) and suramin. The response to 2-MeSATP in veins did not desensitize; nor was it inhibited by prior alpha,betaMeATP desensitization, but it was inhibited by PPADS, suramin, and the selective P2Y(1) receptor antagonist adenosine 3',5'-bisphosphate (ABP, 10-100 microM). Responses to ATP and UTP in veins did not desensitize and were not inhibited by PPADS, suramin, ABP, or alpha, betaMeATP desensitization. In conclusion, our results suggest that venous contraction to a variety of nucleotides is mediated in large part by P2Y receptors including P2Y(1) receptors and an UTP-preferring P2Y receptor. A small component of contraction also appears to be mediated by P2X(1) receptors. This receptor profile differs markedly from that of mesenteric arteries in which P2X(1) receptors predominate.     

Potentiation of P2Y receptors by physiological elevations of extracellular K+ via a mechanism independent of Ca2+ influx

Many physiological and pathophysiological situations generate a significant increase in extracellular K+ concentration. This is known to influence a number of membrane conductances and exchangers, whereas direct effects of K+ on the activation of G protein-coupled receptors have not been reported. We now show that Ca2+ release evoked by P2Y1 receptors expressed in 1321-N1 astrocytoma cells is markedly potentiated by small increases in external K+ concentration. This effect was blocked by the phospholipase-C inhibitor U-73122 (1-[6-[[17 beta]-methoxyestra-1,3,5(10)-trien-17-yl]amino]hexyl]-1H-pyrrole-2,5-dione), but not by its analog U-73343 (1-[6-[[17 beta]-3-methoxyestra-1,3,5(10)-trien-17-yl]amino]hexyl]-2,5-pyrrolidinedione), and not by nifedipine, Ni2+, Cd2+, or Gd3+. Thus, K+ enhances d-myo-inositol 1,4,5-trisphosphate-dependent Ca2+ release without a requirement for Ca2+ influx. The cation dependence of this effect displayed the order K+ > Rb+ > N-methyl-D-glucamine+, and Cs+ and choline+ were ineffective. The potentiation by K+ is half-maximal at an increase of 2.6 mM (total K+ of 7.6 mM). K+ caused a reduction in EC50 (2.7-fold for a 29 mM increase) without a change of slope; thus, the greatest effect was observed at near-threshold agonist levels. The response to K+ can be explained in part by depolarization-dependent potentiation of P2Y1 receptors [J Physiol (Lond) 555:61-70, 2004]. However, electrophysiological recordings of 1321-N1 cells and megakaryocytes demonstrated that K+ also amplifies ADP-evoked Ca2+ responses independently of changes in membrane potential. Elevated K+ also amplified endogenous UTP-dependent Ca2+ responses in human embryonic kidney 293 cells, suggesting that other P2Y receptors are K(+)-dependent. P2Y receptors display a widespread tissue distribution; therefore, their modulation by small changes in extracellular K+ may represent a novel means of autocrine and paracrine regulation of cellular activity.