Augmented EDHF signaling in rat uteroplacental vasculature during late pregnancy.

A successful pregnancy outcome relies on extensive maternal cardiovascular adaptation, including enhanced uteroplacental vasodilator mechanisms. The objective of the present study was to determine the contribution of the endothelium-derived hyperpolarizing factor (EDHF) signaling in pregnancy-enhanced uterine vasodilation, to define the role of Ca(2+)-activated K(+) channels in mediating EDHF effects, and to explore the impact of endothelial Ca(2+) signaling in pregnancy-specific upregulation of EDHF. Fura 2-based measurements of smooth muscle cell (SMC) and endothelial cell cytosolic Ca(2+) concentration ([Ca(2+)](i)) were performed simultaneously with measurements of the diameter of uterine radial arteries from nonpregnant (NP) and late pregnant (LP) rats. Changes in SMC membrane potential of pressurized arteries from LP rats were assessed using glass microelectrodes. After blockade of nitric oxide and prostacyclin production, a cumulative application of ACh induced rapid and effective dilatation of uterine vessels from both NP and LP rats. This vasodilation was associated with SMC hyperpolarization and SMC [Ca(2+)](i) reduction and was abolished by a high-K(+) solution, demonstrating that N(G)-nitro-L-arginine (L-NNA)- and indomethacin-resistant responses are attributable to EDHF. Pregnancy significantly potentiates EDHF-mediated vasodilation in part due to enhanced endothelial Ca(2+) signaling. L-NNA- and indomethacin-resistant responses were insensitive to iberiotoxin but abolished by a combined treatment with apamin and charybdotoxin, supporting the key role of small- and intermediate-conductance K(+) channels in mediating EDHF signaling in the maternal uterine resistance vasculature.

Histamine-induced depolarization: ionic mechanisms and role in sustained contraction of rabbit cerebral arteries.

The role of membrane depolarization in the histamine-induced contraction of the rabbit middle cerebral artery was examined by simultaneous measurements of membrane potential and isometric force. Histamine (1-100 microM) induced a concentration-dependent sustained contraction associated with sustained depolarization. Action potentials were observed during depolarization caused by histamine but not by high-K(+) solution. K(+)-induced contraction was much smaller than sustained contraction associated with the same depolarization caused by histamine. Nifedipine attenuates histamine-induced sustained contraction by 80%, with no effect on depolarization. Inhibition of nonselective cation channels with Co(2+) (100-200 microM) reversed the histamine-induced depolarization and relaxed the arteries but induced only a minor change in K(+)-induced contraction. In the presence of Co(2+) and in low-Na(+) solution, histamine-evoked depolarization and contraction were transient. We conclude that nonselective cation channels contribute to histamine-induced sustained depolarization, which stimulates Ca(2+) influx through voltage-dependent Ca(2+) channels participating in contraction. The histamine-induced depolarization, although an important and necessary mechanism, cannot fully account for sustained contraction, which may be due in part to augmentation of currents through voltage-dependent Ca(2+) channels and Ca(2+) sensitization of the contractile process.

Role of intracellular Ca(2+) release in histamine-induced depolarization in rabbit middle cerebral artery.

The role of Ca(2+) mobilization from intracellular stores and Ca(2+)-activated Cl(-) channels in caffeine- and histamine-induced depolarization and contraction of the rabbit middle cerebral artery has been studied by recording membrane potential and isometric force. Caffeine induced a transient contraction and a transient followed by sustained depolarization. The transient depolarization was abolished by ryanodine, DIDS, and niflumic acid, suggesting involvement of Ca(2+)-activated Cl(-) channels. Histamine-evoked transient contraction in Ca(2+)-free solution was abolished by ryanodine or by caffeine-induced depletion of Ca(2+) stores. Ryanodine slowed the development of depolarization induced by histamine in Ca(2+)-containing solution but did not affect its magnitude. In arteries treated with 1 mM Co(2+), histamine elicited a transient depolarization and contraction, which was abolished by ryanodine. DIDS and niflumic acid reduced histamine-evoked depolarization and contraction. Histamine caused a sustained depolarization and contraction in low-Cl(-) solution. These results suggest that Ca(2+) mobilization from ryanodine-sensitive stores is involved in histamine-induced initial, but not sustained, depolarization and contraction. Ca(2+)-activated Cl(-) channels contribute mainly to histamine-induced initial depolarization and less importantly to sustained depolarization, which is most likely dependent on activation of nonselective cation channels.

Increased Ca2+ sensitivity as a key mechanism of PKC-induced constriction in pressurized cerebral arteries.

The effects of activating protein kinase C (PKC) with indolactam V (Indo-V) and 1,2-dioctanoyl-sn-glycerol (DOG) on smooth muscle intracellular Ca2+ concentrations ([Ca2+]i) and arterial diameter were determined using ratiometric Ca2+ imaging and video edge detection of pressurized rat posterior cerebral arteries. Elevation of intraluminal pressure from 10 to 60 mmHg resulted in an increase in [Ca2+]i from 74 +/- 5 to 219 +/- 8 nM and myogenic constriction. Application of Indo-V (0.01-3 microM) or DOG (0.1-30 microM) induced constriction and decreased [Ca2+]i to 140 +/- 11 and 127 +/- 12 nM, respectively, at the highest concentrations used. In the presence of Indo-V, the dihydropyridine Ca2+-channel-blocker nisoldipine produced nearly maximum dilation and decreased [Ca2+]i to 97 +/- 7 nM. In alpha-toxin-permeabilized arteries, the constrictor effects of Indo-V and DOG were not observed in the absence of Ca2+. Both PKC activators significantly increased the degree of constriction of permeabilized arteries at different [Ca2+]i. We conclude that 1) Indo-V- or DOG-induced constriction of pressurized arteries requires Ca2+ influx through voltage-dependent Ca2+ channels, and 2) PKC-induced constriction of pressurized rat cerebral arteries is associated with a decrease in [Ca2+]i, suggesting an increase in the Ca2+ sensitivity of the contractile process.

Temperature and protein kinase C modulate myofilament Ca2+ sensitivity in pressurized rat cerebral arteries.

The effects of pharmacological activation and inhibition of protein kinase C (PKC) and temperature on the relationship between cytoplasmic Ca2+ and lumen diameter were studied in pressurized (50 mmHg) rat posterior cerebral arteries permeabilized with alpha-toxin. Increasing Ca2+ concentrations (30 nM-10 microM, 22 degrees C) induced stable, concentration-dependent constrictions with a half-maximal effective concentration (EC50) of 112 nM. The maximal constriction was 80% of baseline diameter and 157% of that during depolarization of nonpermeabilized vessels with 124 mM KCl. Elevation of temperature to 37 degrees C increased the EC50 to 246 nM and enhanced the steepness of concentration-response curves. Exposure of permeabilized arteries to indolactam V, an activator of PKC, resulted in a significant myofilament Ca2+ sensitization (e.g., EC50 at 5 microM = 126 nM) without changing efficacy. The effects of calphostin C, a PKC inhibitor, on Ca2+ sensitivity were minimal; however, the amplitude of Ca2+-induced constrictions in both control and indolactam-treated arteries was suppressed in a concentration-dependent manner. Thus 1) temperature is an important variable in studies of arterial Ca2+ sensitivity, and 2) changes in PKC activity can significantly alter both myofilament sensitivity to and constrictor efficacy of cytosolic Ca2+.

Role of Ca(2+)-activated K+ channels in the regulation of membrane potential and tone of smooth muscle in human pial arteries.

Smooth muscle cells (SMCs) in 58% of human pial arteries obtained during surgery showed no spontaneous contractions and displayed a stable resting membrane potential (MP) of -54.7 +/- 1.5 mV. Those that exhibited periodic spontaneous contractions associated with periodic depolarization and generation of spontaneous action potentials (APs) had a less negative MP of -43.1 +/- 0.5 mV (42%). Inhibition of calcium-activated potassium (KCa) channels in the silent arteries by charybdotoxin (CTX) and tetraethylammonium ions (TEA) induced dose-dependent depolarization, AP generation, and contraction. TEA and CTX enhanced the spontaneous depolarization and force in arteries that exhibited spontaneous activity. They also prolonged the spontaneous APs up to several times and increased their upstroke amplitude. Both TEA and CTX failed to produce significant depolarization in arteries treated with nifedipine. It is concluded that KCa channels are important regulators of human pial artery SMC resting MP and tone. They are also involved in the control of AP amplitude and duration and the associated contractions. These data suggest that alterations in the activity of SMC KCa channels could be responsible for the appearance of spontaneous activity in human pial arteries in vitro and that impaired function of these channels might be related to vasospastic phenomena in human cerebral circulation.

Electrical activity underlying rhythmic contraction in human pial arteries.

Human pial arteries obtained during surgery frequently exhibit spontaneous periodic contractions. Simultaneous measurements of membrane potential and vessel wall force were used to examine whether these contractions are associated with electrical activity of smooth muscle cells (SMCs). A total of 53 segments from 38 patients were studied, and of these, 26 showed spontaneous contractions related to periodic depolarization and generation of action potentials (APs). The resting membrane potential during the silent periods was -44.0 +/- 0.5 mV. APs without "overshoot'' were observed when spontaneous depolarization reached levels of -40 to -35 mV. Just over half of the arterial segments failed to exhibit spontaneous activity; however, APs could be generated during K+-induced depolarization. The mean SMC resting membrane potential of these vessels was -53.5 +/- 1.5 mV, and this value differed significantly from that of SMCs in spontaneously active arteries. Application of tetrodotoxin did not change the amplitude and duration of APs. Removal of Ca2+ from the bathing solution and addition of nifedipine completely inhibited the spontaneous APs and associated contractions. K+ depolarization failed to induce APs and contraction in the presence of nifedipine. We conclude that periodic spontaneous depolarization and AP generation underlie the periodic spontaneous contractions of human pial arteries. Both the APs and associated contractions are related to the activation of dihydropyridine-sensitive voltage-dependent Ca2+ channels. It is suggested that AP generation can be responsible for vasomotion of human pial arteries in vivo.

[Effects of the membrane potential level on serotonin-induced contraction of the pulmonary artery smooth muscle in rabbits]. / Vliianie urovnia membrannogo potentsiala na vyzyvaemye serotoninom sokrashcheniia gladkikh myshts legochnoi arterii krolika.

The effects of changes in membrane potential level on the electrical and contractile responses induced by serotonin (10(-6) mol/l) were investigated in muscle strips from rabbit main pulmonary artery using sucrose-gap technique. In spite of the fact that serotonin-induced depolarization did not exceed the threshold level for development of contraction, it was followed by a strong tonic contraction. Nearly a half of this contraction could be relaxed by an electrotonic hyperpolarization of the membrane. A week preliminary depolarization of the muscle cells resulted in an increase while a strong depolarization--in dramatic decrease of serotonin-induced contraction. Nifedipine effectively blocked potassium-induced, but not serotonin induced contraction. We suggest that in addition to voltage-operated and receptor operated Ca channels in vascular smooth muscle cell membrane there is a separate class of nifedipine-insensitive Ca channels operated by both serotonin receptor and membrane potential.

[Mechanism of the effect of dibasol on the contractile and electric activities of the smooth muscle of the portal vein]. / Issledovanie mekhanizma deistviia dibazola na sokratite'lnuiu i élektricheskuiu aktivnos't gladkoi myshtsy vorotnoi veny.

The effects of dibasol on spontaneous electrical and contractile activities as well as on the reactions evoked by hyperkalemic solution and noradrenaline were studied in smooth muscle of rabbit portal vein. It was shown that dibasol blocked the potential-operated influx Ca2+ into smooth muscle cells. The noninactivating calcium channels were found to be more sensitive to dibasol than inactivating ones. Significant part of the tonic contraction induced by noradrenaline was resistant to dibasol suggesting its weak effect on Ca2+ influx through calcium channels operated by alpha 1-adrenoceptors. It is supposed that vasodilative effect of dibasol is associated with blocking the influx Ca2+ through potential-operated noninactivating calcium channels into smooth muscle cells.

[Excitation-contraction coupling in the smooth muscle of the femoral artery under the effects of noradrenaline]. / Sopriazhenie vozbuzhdeniia-sokrashcheniia v gladkoi myshtse bedrennoi arterii pri deistvii noradrenalina.

Noradrenaline (5 x 10(-8) - 10(-5) M) induced a dose-dependent contraction of muscle strips from rabbit femoral artery. At concentrations higher than 10(-7) M noradrenaline evoked also a depolarization of smooth muscle cells due to an increase in sodium and/or chloride permeability of the membrane. Repolarization of the membrane to original level by inwardly applied current resulted in restoration of membrane resistance and partial relaxation of noradrenaline-evoked contraction. The same part of contraction was also blocked by verapamil. In calcium-free EGTA-containing solution noradrenaline induced only a small transient contraction. These findings indicate that noradrenaline-activated sodium (or chloride) permeability is voltage dependent. Noradrenaline evoked contraction is activated by calcium ions entered the cell through receptor-operated and partly through voltage-operated calcium channels.

[The role of calcium and potassium conductance in electrogenesis of smooth-muscle cells of the basilar artery]. / Rol' kal'tsievoi i kalievoi provodimostei v elektrogeneze gladkomyshechnykh kletok osnovnoi arterii.

The role of calcium and potassium conductances in electrogenesis of smooth muscle cells of the bovine basilar artery has been investigated using blocking agents of calcium and potassium channels both in the normal Krebs solution and in hyperpotassium solution under anelectrotonic repolarization of the cell membrane. It is shown that both voltage-operated calcium and potassium conductances participate in generation of gradual action potentials evoked by electrical stimulation. A higher contribution of potassium conductance into the total membrane conductance during depolarization is found to be the main factor interfered with development of full-size action potential.

[Mechanism of action of voltaren on the smooth muscles of the blood vessels]. / Mekhanizm deistviia vol'tarena na gladkie myshtsy krovenosnykh sosudov.

The effect of voltaren on the electrical and contractile activity of smooth muscle cells of the rabbit portal vein and the bovine cerebral arteries was studied by sucrose gap method. Voltaren was found to rarefy (10(-6)-10-10(-3)mol/l) or to suppress (10(-4)-10(-3)mol/l) spontaneous electrical and contractile activity and to relax the portal vein muscle strips. At concentrations of 5.10(-6)-5.10(-3) mol/l voltaren caused a dose-dependent relaxation of the cerebral arterial muscle strips. The relaxation of the smooth muscles of the blood vessels induced by voltaren is suggested to be due to inhibition of calcium ions influx into muscle cells through different types of calcium channels.

[The role of intra- and extracellular Ca in the activation of contraction of pulmonary artery smooth muscles induced by serotonin]. / Rol' vnutri- i vnekletochnogo Ca v aktivatsii sokrashcheniia gladkikh myshts legochnoi arterii, vyzyvaemogo serotoninom.

In Ca-free EGTA-containing solution serotonin induced a transient contraction of rabbit pulmonary artery smooth muscle which decayed to nearly steady-state level accounted for 17.7 +/- 1.6% of original contraction in Krebs solution. Both phasic and tonic components of this contraction were effectively inhibited by verapamil and Cd2+. Caffeine induced no contraction of muscle strips if it was applied after withdrawal of serotonin. But when the sequence of these drugs application was reversed, serotonin still evoked contraction with reduced phasic component. The results obtained in these experiments suggest, that serotonin-induced contraction of pulmonary artery smooth muscle is partly (less than 20%) due to mobilization of bound calcium from at least two stores located on the opposite sides of the cell membrane. Calcium released from external store site enters the cell via receptor-operated calcium channels.

[Membrane mechanisms of the excitatory action of serotonin on the smooth muscles of the rabbit pulmonary artery]. / Issledovanie membrannykh mekhanizmov vozbuzhdaiushchego deistviia serotonina na gladkie myshtsy legochnoi arterii krolika.

Serotonin induced dose-dependent tonic contractions of the rabbit pulmonary artery smooth muscles with KED50, of 2.7 X 10(-7) mol/l. More than 80% of these contractions were found to be dependent on extracellular calcium. Hyperpolarization of cell membrane by inwardly applied electrical current caused nearly 50% reduction in serotonin-induced contractions. The same portion of contractions was inhibited by verapamil and Ca2+. Serotonin-, but not potassium-induced contractions were completely inhibited by sodium nitroprusside which is thought to be selective inhibitor of receptor-operated calcium channels. These findings could indicate that Ca2+ ions, responsible for serotonin-induced contractions enter the cell from the outer surface of the cellular membrane via receptor-operated calcium channels. Nearly half of serotonin-operated Ca2+ channels appear to be also potential-operated.

[Electrophysiological analysis of the action of kavinton on the smooth muscles]. / Elektrofiziologicheskii analiz deistviia kavintona na gladkie myshtsy.

Cavinton at a concentration of 10(-7)-10(-5) M was found to have a dose-dependent relaxing effect on bovine cerebral artery smooth muscles, without changing the resting potential and membrane resistance. Smooth muscles of the rabbit portal vein and guinea-pig taenia coli were insensitive to low cavinton concentrations. The results are consistent with the hypothesis that relaxing action of cavinton is due to the blocking of Ca2+ ions influx into the cells of cerebral artery through receptor-operated calcium channels. At higher concentrations (exceeding 10(-5) M) cavinton exerts nonspecific influence on the smooth muscles under study, inhibiting their excitability and decreasing membrane resistance resulting in the attenuation of tetanic contractions in the smooth muscles of the portal vein and taenia coli.