Membrane Potential Of Endothelial Cells Research Articles

Endothelial Membrane Potential Changes are Required for Propagated Vasodilation

Introduction: The coordination of blood flow in response to localized increases in metabolic activity is vital for tissue function. This adaptive response typically involves the release of vasoactive factors leading to local vasodilation. This local vasodilation must propagate upstream to proximal feed arterioles and arteries to ensure a coordinated increase in blood flow and adequate tissue perfusion. But the mechanisms underlying such propagated vasodilation remain to be fully understood. This study aims to identify the conduction pathway(s) that facilitate this response. The hypothesis is that endothelial membrane potential changes are required for propagated vasodilation to occur. Methods: To dissect the pathways involved in propagated vasodilation, we employed micropuffng techniques to locally apply vasoactive agents to precontracted rat 2nd order mesenteric arteries. Using a 50um tip micropipette activators were applied against a flowing perfusate, to limit the action of the drug, and the precise site of activators determined by co-application of the fluorophore sulforhodamine. Vasodilator responses were recorded at the site of application and at intervals upstream from the application site. Results: Local application of the muscarinic receptor agonist, acetylcholine (ACh), evoked robust vasodilator responses that propagated upstream from the site of application. The propagation of vasodilation terminated at the site of removal of a 100uM wide strip of endothelial cells. A high-potassium solution, which induces depolarization and ‘clamps’ the membrane potential, also inhibited propagated vasodilation. In contrast, the nitric oxide donor, sodium nitroprusside did not initiate propagated vasodilation in arteries with an intact endothelium. Conclusion: Collectively, these results show that the endothelium serves as the primary signalling pathways for propagated vasodilation. Furthermore, our results highlight the necessity of endothelial cell membrane potential change in the initiation of this vasodilator signal. These insights reinforce the endothelium’s pivotal role in coordinating vascular function. British Heart Foundation. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

SUV39H1 Inhibits Angiogenesis in Limb Ischemia of Mice

Peripheral arterial disease (PAD), characterized by atherosclerosis of the peripheral arteries or even amputation, has threatened public life and health. However, the underlying mechanism remains largely obscure. SUV39H1, a histone methyltransferase, could specifically methylate lysine 9 of histone H3 and act as a repressor in transcriptional activity. The study aimed to investigate the role of SUV39H1 in limb ischemia. C57BL/6 male mice were randomly divided into Sham or Model groups to investigate the expression of SUV39H1 in the ischemic limbs. Then, pharmaceutical inhibition or genetic deletion of SUV39H1 in the limb ischemia mice model was performed to confirm its effect on limb ischemia. The blood perfusion was quantified by laser speckle contrast imaging (LSCI). Capillary density and muscle edema were measured by CD31 immunohistochemical staining and HE staining. The expressions of SUV39H1 and Catalase were confirmed by western blot. Transcriptome sequencing of siSUV39H1 in human umbilical vein endothelial cells (HUVECs) was used to explore the regulation mechanism of SUV39H1 on angiogenesis. The results showed that SUV39H1 was highly expressed in the ischemic muscle tissue of the mice. Pharmaceutical inhibition or genetic deletion of SUV39H1 significantly improved blood perfusion, capillary density, and angiogenesis in ischemic muscle tissue. Cell experiments showed that SUV39H1 knockdown promoted cell migration, tube formation, and mitochondrial membrane potential in endothelial cells under oxidative stress. The transcriptome sequencing results unmasked mechanisms of the regulation of angiogenesis induced by SUV39H1. Finally, Salvianolic acid B and Astragaloside IV were identified as potential drug candidates for the improvement of endothelial function by repressing SUV39H1. Our study reveals a new mechanism in limb ischemia. Targeting SUV39H1 could improve endothelial dysfunction and thus prevent limb ischemia.

Changes in the mitochondrial membrane potential in endothelial cells can be detected by Raman microscopy

The role of mitochondria goes beyond their capacity to create molecular fuel and includes e.g. the production of reactive oxygen species and the regulation of cell death. In endothelial cells, mitochondria have a significant impact on cellular function under both healthy and pathological conditions. Endothelial dysfunction contributes to the development of various lifestyle diseases and the key players in their pathogenesis are among others vascular inflammation and oxidative stress. The latter is very closely related to mitochondrial dysfunction; however, it is not straightforward. First, because mitochondria are small cellular structures, and second, it requires a sensitive method to follow the subtle biochemical changes. For this purpose, Raman microscopy (RM) was used here, which is considered a high-resolution method and can be applied in situ, usually as a non-labeled technique. In this work, we show that RM can not only locate mitochondria in the cell but also track their functional changes. Moreover, we test if labeling cells with Raman probes (Rp) can improve the specificity and sensitivity of RM (compared to conventional labeled techniques such as fluorescence, and the non-labeled Raman technique). MitoBADY Rp was used to detect changes in mitochondrial membrane potential as an indicator of mitochondrial activity, e.g. hyperpolarization or distortion of the proton gradient in the intermembrane space (depolarization). Thus, we show and compare RM, in the form of a label and non-labeled, to such a subtle cellular analysis.

A theoretical model for flow regulation in the cerebral cortex: role of penetrating arterioles

Activation of a region of the brain results in a local increase in blood flow, a process known as neurovascular coupling (NVC). Here, a theoretical model of blood flow regulation in the cerebral cortex is utilized to investigate the potential role of penetrating arterioles as the primary mechanism for local control of blood flow. Penetrating arterioles connect pial arterioles with the capillary meshwork deeper in the cortex and have a typical length of approximately 600 μm. This is about one‐sixth of the length of corresponding small arterioles in skeletal muscle. The question arises whether these relatively short arterioles can achieve the range of flow modulation observed in the cerebral cortex. A previously developed compartmental model for flow regulation in skeletal muscle was modified to represent the structure of cerebral microvasculature. A compartment consisting of penetrating arterioles with a reference diameter of 14.8 μm and a length of 600 μm is assumed to provide active control of blood flow. Smooth muscle tone in these arterioles is assumed to depend on a combination of signals representing myogenic, shear‐dependent, and metabolic responses. The metabolic response is represented by a change in endothelial cell membrane potential, propagated upstream along arterioles by conducted responses. Sensitivity of diameter to membrane potential was determined based on experimental data. According to the model, a hyperpolarization of 40 mV can result in an increase in local blood flow by approximately 70%. Since increases in local blood flow of 50% with activation have been observed, these results imply that vasoconstriction and vasodilation by penetrating arterioles can provide typical levels of blood flow control seen in neurovascular coupling.

Mitophagy alleviates ischemia/reperfusion-induced microvascular damage through improving mitochondrial quality control

ABSTRACT The coronary arteries mainly function to perfuse the myocardium. When coronary artery resistance increases, myocardial perfusion decreases and myocardial remodeling occurs. Mitochondrial damage has been regarded as the primary cause of microvascular dysfunction. In the present study, we explored the effects of mitophagy activation on microvascular damage. Hypoxia/reoxygenation injury induced mitochondrial oxidative stress, thereby promoting mitochondrial dysfunction in endothelial cells. Mitochondrial impairment induced apoptosis, reducing the viability and proliferation of endothelial cells. However, supplementation with the mitophagy inducer urolithin A (UA) preserved mitochondrial function by reducing mitochondrial oxidative stress and stabilizing the mitochondrial membrane potential in endothelial cells. UA also sustained the viability and improved the proliferative capacity of endothelial cells by suppressing apoptotic factors and upregulating cyclins D and E. In addition, UA inhibited mitochondrial fission and restored mitochondrial fusion, which reduced the proportion of fragmented mitochondria within endothelial cells. UA enhanced mitochondrial biogenesis in endothelial cells by upregulating sirtuin 3 and peroxisome proliferator-activated receptor gamma coactivator 1-alpha. These results suggested that activation of mitophagy may reduce hypoxia/reoxygenation-induced cardiac microvascular damage by improving mitochondrial quality control and increasing cell viability and proliferation.

TRPV4 Channels Regulate Endothelial Ca Signaling in Rat Maternal Uteroplacental Vasculature

An increase in cytosolic Ca2+ ([Ca2+]i) is a key mechanism translating the effects of agonist stimulation of endothelial cells (ECs) into cellular responses. In this study we explored the role of TRPV4 channels in regulating EC Ca2+ signaling in uteroplacental arteries of pregnant rats. The diameters, SMC membrane potential (MP) and [Ca2+]i responses to activation of TRPV4 channels with GSK 1016790A (GSK) were studied using pressurized arteries. ACh- and GSK-induced EC [Ca2+]i responses were characterized in sheets of ECs. The effects of GSK on MP of ECs were tested using perforated patch clamp. RT PCR was performed to quantify mRNA levels of TRPV4 in uterine vasculature. GSK induced an endothelium-mediated vasodilation (78 ± 7 % at 10 nM, n = 8) that was associated with SMC hyperpolarization (by 22 ± 3 mV) or SMC [Ca2+]i reduction. GSK induced EC [Ca2+]i rise of 418 ± 45 nM (n = 4). HC067047 (HC) and TRAM-34, inhibitors of TRPV4 and IK channels, abolished GSK responses. EC hyperpolarization (by 25 ± 6 mV, n = 5) to GSK was reversed by charybdotoxin. ACh-induced vasodilation or elevation of EC [Ca2+]i was reduced by HC by 76 % (n = 4). TRPV4 expression in radial arteries was two-fold higher than in main uterine artery. TRPV4 channels are essential Ca2+ entry pathways in ECs of uteroplacental arteries. They induce IK-dependent hyperpolarization of ECs resulting in EC and SMC hyperpolarization, SMC [Ca2+]i reduction and vasodilation. Downregulation of these channels may contribute to an impaired EC Ca2+ signaling and uterine endothelial dysfunction in complicated pregnancies. Supported by NIH HL088245 (NIG), P01 HL095488 (ADB)

Shear stress-related mechanosignaling with lung ischemia: lessons from basic research can inform lung transplantation.

Cessation of blood flow represents a physical event that is sensed by the pulmonary endothelium leading to a signaling cascade that has been termed "mechanotransduction." This paradigm has clinical relevance for conditions such as pulmonary embolism, lung bypass surgery, and organ procurement and storage during lung transplantation. On the basis of our findings with stop of flow, we postulate that normal blood flow is "sensed" by the endothelium by virtue of its location at the interface of the blood and vessel wall and that this signal is necessary to maintain the endothelial cell membrane potential. Stop of flow is sensed by a "mechanosome" consisting of PECAM-VEGF receptor-VE cadherin that is located in the endothelial cell caveolae. Activation of the mechanosome results in endothelial cell membrane depolarization that in turn leads to activation of NADPH oxidase (NOX2) to generate reactive oxygen species (ROS). Endothelial depolarization additionally results in opening of T-type voltage-gated Ca(2+) channels, increased intracellular Ca(2+), and activation of nitric oxide (NO) synthase with resultant generation of NO. Increased NO causes vasodilatation whereas ROS provide a signal for neovascularization; however, with lung transplantation overproduction of ROS and NO can cause oxidative injury and/or activation of proteins that drive inflammation and cell death. Understanding the key events in the mechanosignaling cascade has important lessons for the design of strategies or interventions that may reduce injury during storage of donor lungs with the goal to increase the availability of lungs suitable for donation and thus improving access to lung transplantation.

Endothelial caveolar modulation of SK3 channel activity

Small‐ and intermediate‐conductance Ca2+‐activated K+ channels (SK3/Kcnn3 and IK1/Kcnn4) are expressed in vascular endothelium. Their activities play important roles in regulating vascular tone through their modulation of [Ca2+]i required for the production of endothelium‐derived vasoactive agents. Activation of endothelial IK1 or SK3 channels hyperpolarizes endothelial cell membrane potential, increases Ca2+ influx, and leads to the release of vasoactive factors, thereby impacting blood pressure. To examine the distinct roles of IK1 and SK3 channels, we used electrophysiological recordings to investigate IK1 and SK3 channel trafficking in acutely dissociated endothelial cells from mouse aorta. The results show that SK3 channels undergo Ca2+‐dependent cycling between the plasma membrane and intracellular organelles; disrupting Ca2+‐dependent endothelial caveolae cycling abolishes SK3 channel trafficking. Moreover, transmitter induced changes in SK3 channel activity and surface expression modulate endothelial membrane potential. In contrast, IK1 channels do not undergo rapid trafficking and their activity remains unchanged when either exo‐ or endocytosis is block. Thus, modulation of SK3 surface expression may play an important role in regulating endothelial membrane potential in a Ca2+‐dependent manner.

Endothelial Feedback and the Myoendothelial Projection

The endothelium plays a critical role in controlling resistance artery diameter, and thus blood flow and blood pressure. Circulating chemical mediators and physical forces act directly on the endothelium to release diffusible relaxing factors, such as NO, and elicit hyperpolarization of the endothelial cell membrane potential, which spreads to the underlying smooth muscle cells via gap junctions (EDH). It has long been known that arterial vasoconstriction in response to agonists is limited by the endothelium, but the question of how contraction of smooth muscle cells leads to activation of the endothelium (myoendothelial feedback) has, until recently, received little attention. Initial studies proposed the permissive movement of Ca(2+) ions from smooth muscle to endothelial cells to elicit release of NO. However, more recent evidence supports the notion that flux of IP(3) leading to localized Ca(2+) events within spatially restricted myoendothelial projections and activation of EDH may underlie myoendothelial feedback. In this perspective, we review recent data which supports the functional role of myoendothelial projections in smooth muscle to endothelial communication. We also discuss the functional evidence supporting the notion that EDH, as opposed to NO, is the primary mediator of myoendothelial feedback in resistance arteries.

Endothelial calcium-activated potassium channels as therapeutic targets to enhance availability of nitric oxide

The vascular endothelium plays a critical role in vascular health by controlling arterial diameter, regulating local cell growth, and protecting blood vessels from the deleterious consequences of platelet aggregation and activation of inflammatory responses. Circulating chemical mediators and physical forces act directly on the endothelium to release diffusible relaxing factors, such as nitric oxide (NO), and to elicit hyperpolarization of the endothelial cell membrane potential, which can spread to the surrounding smooth muscle cells via gap junctions. Endothelial hyperpolarization, mediated by activation of calcium-activated potassium (K(Ca)) channels, has generally been regarded as a distinct pathway for smooth muscle relaxation. However, recent evidence supports a role for endothelial K(Ca) channels in production of endothelium-derived NO, and indicates that pharmacological activation of these channels can enhance NO-mediated responses. In this review we summarize the current data on the functional role of endothelial K(Ca) channels in regulating NO-mediated changes in arterial diameter and NO production, and explore the tempting possibility that these channels may represent a novel avenue for therapeutic intervention in conditions associated with reduced NO availability such as hypertension, hypercholesterolemia, smoking, and diabetes mellitus.

Modulation of endothelial SK3 channel activity by Ca2+-dependent caveolar trafficking

Small- and intermediate-conductance Ca(2+)-activated K(+) channels (SK3/Kcnn3 and IK1/Kcnn4) are expressed in vascular endothelium. Their activities play important roles in regulating vascular tone through their modulation of intracellular concentration ([Ca(2+)](i)) required for the production of endothelium-derived vasoactive agents. Activation of endothelial IK1 or SK3 channels hyperpolarizes endothelial cell membrane potential, increases Ca(2+) influx, and leads to the release of vasoactive factors, thereby impacting blood pressure. To examine the distinct roles of IK1 and SK3 channels, we used electrophysiological recordings to investigate IK1 and SK3 channel trafficking in acutely dissociated endothelial cells from mouse aorta. The results show that SK3 channels undergo Ca(2+)-dependent cycling between the plasma membrane and intracellular organelles; disrupting Ca(2+)-dependent endothelial caveolae cycling abolishes SK3 channel trafficking. Moreover, transmitter-induced changes in SK3 channel activity and surface expression modulate endothelial membrane potential. In contrast, IK1 channels do not undergo rapid trafficking and their activity remains unchanged when either exo- or endocytosis is block. Thus modulation of SK3 surface expression may play an important role in regulating endothelial membrane potential in a Ca(2+)-dependent manner.

Potassium channel openers elicit endothelium‐dependent enhancement of nerve‐mediated vasoconstriction

The vascular endothelium modulates arterial diameter via the release of diffusible relaxing and contracting factors and by direct electrical coupling with smooth muscle cells (endothelium‐dependent hyperpolarization; EDH). Hyperpolarization of the endothelial cell membrane potential facilitates Ca2+ influx through non‐selective cation channels and spreads electrotonically to the smooth muscle cells via gap junctions. We hypothesized that pharmacological activators of Ca2+‐activated potassium (KCa) would cause endothelium‐dependent attenuation of nerve‐mediated vasoconstriction in the rat perfused mesenteric bed. The presence of CYPPA, an activator of small conductance KCa channels, nerve‐mediated vasoconstriction was significantly attenuated in the endothelium‐intact perfused mesenteric bed. However, on washout, a rebound effect was observed with nerve‐mediated constriction significantly enhanced. Addition of indomethacin enhanced CYPPA‐induced depression of nerve‐evoked constriction but prevented the rebound increase in vasoconstriction. In endothelium‐denuded preparations, CYPPA caused a smaller depression of vasoconstriction also with no rebound. These data indicate that activators of KCa channels may activate both endothelium‐dependent dilator and contractile pathways. Supported by HSFC.

Role of caveolin-1 in endothelial BKCa channel regulation of vasoreactivity

A novel vasodilatory influence of endothelial cell (EC) large-conductance Ca(2+)-activated K(+) (BK(Ca)) channels is present following in vivo exposure to chronic hypoxia (CH) and may exist in other pathological states. However, the mechanism of channel activation that results in altered vasoreactivity is unknown. We tested the hypothesis that CH removes an inhibitory effect of the scaffolding domain of caveolin-1 (Cav-1) on EC BK(Ca) channels to permit activation, thereby affecting vasoreactivity. Experiments were performed on gracilis resistance arteries and ECs from control and CH-exposed (380 mmHg barometric pressure for 48 h) rats. EC membrane potential was hyperpolarized in arteries from CH-exposed rats and arteries treated with the cholesterol-depleting agent methyl-β-cyclodextrin (MBCD) compared with controls. Hyperpolarization was reversed by the BK(Ca) channel antagonist iberiotoxin (IBTX) or by a scaffolding domain peptide of Cav-1 (AP-CAV). Patch-clamp experiments documented an IBTX-sensitive current in ECs from CH-exposed rats and in MBCD-treated cells that was not present in controls. This current was enhanced by the BK(Ca) channel activator NS-1619 and blocked by AP-CAV or cholesterol supplementation. EC BK(Ca) channels displayed similar unitary conductance but greater Ca(2+) sensitivity than BK(Ca) channels from vascular smooth muscle. Immunofluorescence imaging demonstrated greater association of BK(Ca) α-subunits with Cav-1 in control arteries than in arteries from CH-exposed rats, although fluorescence intensity for each protein did not differ between groups. Finally, AP-CAV restored myogenic and phenylephrine-induced constriction in arteries from CH-exposed rats without affecting controls. AP-CAV similarly restored diminished reactivity to phenylephrine in control arteries pretreated with MBCD. We conclude that CH unmasks EC BK(Ca) channel activity by removing an inhibitory action of the Cav-1 scaffolding domain that may depend on cellular cholesterol levels.

Magnesium lithospermate B decreases [Ca 2+]i in endothelial cells by inhibiting K + currents

Magnesium lithospermate B (MLB) is a hydrophilic active component of Salviae miltiorrhizae Radix. Studies have shown that MLB affected intracellular calcium ([Ca 2+]i), but the underlying mechanism was unclear yet. The present work was aimed to investigate the underlying mechanism of MLB affecting [Ca 2+]i in endothelial cells (ECs). Isolated mesentery arteries were employed to test the involvement of L-Ca 2+ channel. [Ca 2+]i was measured in ECs loaded with Fluo-3. Membrane potential and membrane currents were recorded in ECs using patch-clamp techniques. Results showed that MLB did not inhibit Ca 2+ influx via L-Ca 2+ channel in isolated mesenteric arteries. However, MLB decreased [Ca 2+]i in a concentration-dependent manner in ECs. MLB depolarized the membrane potential of ECs and inhibited K + currents. These results demonstrated that MLB decreased [Ca 2+]i by inhibiting K + currents and depolarizing membrane potential in ECs.

Електричні реакції інтактних і культивованих ендотеліальних клітин при дії активаторів аденозинтрифосфатчутливих калієвих каналів

The influence of pinacidil, an activator of ATP-sensitive K+ channels, on the membrane potential of endothelial cells from intact rat aorta and cultured endothelial cells was investigated. Pinacidil evoked a slowly developing sustained hyperpolariza-tion of endothelial cells from isolated artery with the amplitude of 15±4 mV from the resting membrane potential of –4Ш мВ. In contrast, in cultured endothelial cells pinacidil was without response. Diazoxide, another activator of ATP-sensitive K+ channels, in half of the cultured cells tested, evoked a slowly developing sustained hyperpolarization with the amplitude of 3 mV. The rest of the cells studied did not respond by membrane potential changes to diazoxide. It was suggested that high sen­sitivity of the membrane potential of in situ endothelial cells to potassium channels openers may represent a potent signaling mechanism influencing endothelial cell function upon stimula­tion of vascular KATP channels.

Rac and PI3 Kinase Mediate Endothelial Cell–Reactive Oxygen Species Generation During Normoxic Lung Ischemia

Abrupt reduction of flow (ischemia) leads to endothelial cell membrane depolarization, NADPH oxidase activation, and reactive oxygen species (ROS) generation in isolated rat and mouse lungs and in flow-adapted endothelial cells in vitro. Here we evaluated the role of PI-3-kinase and rac in activation of endothelial NADPH oxidase. Endothelium of isolated perfused mouse lungs labeled with 2',7'-dichlorodihydrofluorescein (H(2)DCF) or hydroethidine (HE) showed increased ROS generation with ischemia; these results were supported by TBARS measurement in whole-lung homogenate and by in vitro studies using flow-adapted mouse pulmonary microvascular endothelial cells. Ischemia-induced ROS generation in intact lung or isolated cells was blocked by pretreatment with Clostridium difficile toxin B, a rac inhibitor, and by wortmannin or LY294002, PI3 kinase inhibitors. In cells, immunofluorescence and immunoblot after subcellular fractionation showed ischemia-induced translocation of rac, p47(phox), and p67(phox) to the plasma membrane. Increased extracellular K(+) also resulted in rac translocation, providing evidence that this pathway is sensitive to alterations of endothelial cell membrane potential. These results indicate that PI-3-kinase and the small G protein rac are involved in the activation of endothelial cell NADPH oxidase that is associated with the acute loss of shear stress.

Reduced store-operated Ca2+entry in pulmonary endothelial cells from chronically hypoxic rats

Chronic hypoxia (CH)-induced pulmonary hypertension may influence basal endothelial cell (EC) intracellular Ca(2+) concentration ([Ca(2+)](i)). We hypothesized that CH decreases EC [Ca(2+)](i) associated with membrane depolarization and reduced Ca(2+) entry. To test this hypothesis, we assessed 1) basal endothelial Ca(2+) in pressurized pulmonary arteries and freshly isolated ECs, 2) EC membrane potential (E(m)), 3) store-operated Ca(2+) current (I(SOC)), and 4) store-operated Ca(2+) (SOC) entry in arteries from control and CH rats. We found that basal EC Ca(2+) was significantly lower in pressurized pulmonary arteries and freshly isolated ECs from CH rats compared with controls. Similarly, ECs in intact arteries from CH rats were depolarized compared with controls, although no differences were observed between groups in isolated cells. I(SOC) activation by 1 muM thapsigargin displayed diminished inward current and a reversal potential closer to 0 mV in cells from CH rats compared with controls. In addition, SOC entry determined by fura 2 fluorescence and Mn(2+) quenching revealed a parallel reduction in Ca(2+) entry following CH. We conclude that differences in the magnitude of SOC entry exist between freshly dispersed ECs from CH and control rats and correlates with the decrease in basal EC [Ca(2+)](i). In contrast, basal EC Ca(2+) influx is unaffected and membrane depolarization is limited to intact arteries, suggesting that E(m) may not play a major role in determining basal EC [Ca(2+)](i) following CH.

Antiphase oscillations of endothelium and smooth muscle [Ca 2+] i in vasomotion of rat mesenteric small arteries

The mechanisms leading to vasomotion in the presence of noradrenaline and inhibitors of the sarcoplasmic/endoplasmic reticulum calcium ATPase were investigated in isolated rat mesenteric small arteries. Isobaric diameter and isometric force were measured together with membrane potential in endothelial cells and smooth muscle cells (SMC). Calcium in the endothelial cells and SMC was imaged with confocal microscopy. In the presence of noradrenaline and cyclopiazonic acid, ryanodine-insensitive oscillations in tone were produced. The frequency was about 1 min −1 and amplitude about 70% of the maximal tone. The amplitude was reduced by indomethacin and increased with L-NAME. Vasomotion was inhibited by nifedipine and by 40 mM potassium. The frequency was increased and amplitude decreased by removal of the endothelium and by application of charybdotoxin and apamin. The vasomotion was associated with in-phase oscillations of membrane potential in endothelial cells and SMC and oscillations of [Ca 2+] i that were in near anti-phase. We suggest a working model for the generation of oscillation based on a membrane oscillator where ion channels in both endothelial cells and SMC interact via a current running between the two cell types through myoendothelial gap junctions, which sets up a near anti-phase oscillation of [Ca 2+] i in the two cell types.

Combination of Ca2+‐activated K+ channel blockers inhibits acetylcholine‐evoked nitric oxide release in rat superior mesenteric artery

The present study investigated whether calcium-activated K+ channels are involved in acetylcholine-evoked nitric oxide (NO) release and relaxation. Simultaneous measurements of NO concentration and relaxation were performed in rat superior mesenteric artery and endothelial cell membrane potential and intracellular calcium ([Ca2+]i) were measured. A combination of apamin plus charybotoxin, which are, respectively, blockers of small-conductance and of intermediate- and large-conductance Ca2+ -activated K channels abolished acetylcholine (10 microM)-evoked hyperpolarization of endothelial cell membrane potential. Acetylcholine-evoked NO release was reduced by 68% in high K+ (80 mM) and by 85% in the presence of apamin plus charybdotoxin. In noradrenaline-contracted arteries, asymmetric dimethylarginine (ADMA), an inhibitor of NO synthase inhibited acetylcholine-evoked NO release and relaxation. However, only further addition of oxyhaemoglobin or apamin plus charybdotoxin eliminated the residual acetylcholine-evoked NO release and relaxation. Removal of extracellular calcium or an inhibitor of calcium influx channels, SKF96365, abolished acetylcholine-evoked increase in NO concentration and [Ca2+]i. Cyclopiazonic acid (CPA, 30 microM), an inhibitor of sarcoplasmic Ca2+ -ATPase, caused a sustained NO release in the presence, but only a transient increase in the absence, of extracellular calcium. Incubation with apamin and charybdotoxin did not change acetylcholine or CPA-induced increases in [Ca2+]i, but inhibited the sustained NO release induced by CPA. Acetylcholine increases endothelial cell [Ca2+]i by release of stored calcium and calcium influx resulting in activation of apamin and charybdotoxin-sensitive K channels, hyperpolarization and release of NO in the rat superior mesenteric artery.

Role of Membrane Potential in Endothelium-Dependent Relaxation of Isolated Mouse Main Pulmonary Artery

The physiology of smooth muscle and endothelial cells of a particular vascular bed and from different species differs from each other. Acetylcholine causes an endothelium-dependent relaxation of preconstricted pulmonary arteries from the rat. This relaxation is mediated by nitric oxide (NO) plus a yet-unidentified endothelium-derived hyperpolarizing factor, which relaxes the smooth muscles by hyperpolarizing them. Our aim is to test whether these observations could be generalized to the smooth muscle cells from the mouse pulmonary artery. Smooth muscle or endothelial cell membrane potential of strips of murine pulmonary artery were measured simultaneously with the force developed by the strip. Acetylcholine hyperpolarized the endothelial cells. However, acetylcholine did not induce an endothelium-dependent hyperpolarization of the smooth muscle, while it relaxed the strip in an endothelium-dependent manner. This relaxation was abolished by an inhibitor of NO synthesis, nitro-L-arginine. Moreover, nitroglycerin relaxed the strips without changing the membrane potential of the smooth muscle cells. Injection of Lucifer yellow into the endothelial cells and the smooth muscle cells did not show heterocellular dye coupling. Furthermore, electron microscopy did not show gap junction plate at the myoendothelial junctions. We conclude that in the mouse main pulmonary artery, NO alone is responsible for the acetylcholine-induced endothelium-dependent vasodilatation, whereas the phenomenon called endothelium-derived hyperpolizing factor is not present. Therefore, caution should be taken when comparing different animal models to study pulmonary circulation and its reactivity.