Depolarization Of Smooth Muscle Cells Research Articles

Stronger vasoconstriction and weaker vasodilation in mesenteric arteries of Ossabaw than Göttingen minipigs before manifestation of metabolic syndrome

The metabolic syndrome predisposes and contributes to the development and progression of atherosclerosis. The minipig strain “Ossabaw” is characterized by a polygenic predisposition to develop metabolic syndrome and diffuse atherosclerosis in response to a hypercaloric atherogenic diet. The aim of this study was to investigate whether Ossabaw minipigs exhibit an altered vasomotor function even before they develop their diseased phenotype. Mesenteric arteries of adult Ossabaw (n=30) and Göttingen minipigs (n=40), a pig strain without genetic predisposition to a metabolic syndrome, were harvested postmortem, dissected, and mounted on a myograph for isometric force measurements. Maximal vasoconstriction to smooth muscle cell depolarization with potassium chloride (KClmax) was repeatedly induced (twice 0.6×10−1 mol/L and twice 1.2×10−1 mol/L). Cumulative concentration-response curves were determined in response to 1×10−9 -1×10−4 mol/L norepinephrine. Endothelium-dependent and -independent vasodilation were analyzed in response to carbachol and nitroprusside, respectively (1×10−9 - 1×10−4 mol/L, each) after pre-constriction by norepinephrine. The baseline diameter of mesenteric arteries from Ossabaw minipigs was smaller than that from Göttingen minipigs (329±20 vs. 435±11 μm), and mesenteric arteries of Ossabaw minipigs developed a higher baseline force of contraction than mesenteric arteries of Göttingen minipigs (6.2±0.7 vs. 3.6±0.3 mN). The maximal vasoconstrictor response to KCl was comparable between the minipig strains. Vasoconstriction in response to norepinephrine was more pronounced in Ossabaw than in Göttingen minipigs (143±9 vs. 108±6% KClmax). Endothelium-dependent vasodilation (46.4±5.5 vs. 16.0±3.0% of norepinephrine-induced preconstriction) and -independent vasodilation (36.7±4.9 vs. 2.3±0.6% of norepinephrine-induced preconstriction) were less pronounced in Ossabaw than in Göttingen minipigs. Neither the differences in baseline diameter nor in baseline developed force of contraction had any effect on the above data, as analyzed in retrospectively matched subsets of mesenteric arteries with a comparable baseline diameter or a comparable baseline developed force of contraction, respectively. Even before the development of metabolic syndrome, vasomotor function is shifted to more vasoconstriction and less vasodilation in Ossabaw minipigs, suggesting a genetic predisposition for the early development of vascular dysfunction. Thus, Ossabaw minipigs may be a suitable model to reflect the human situation of a heterogeneous, genetically determined primordial risk constellation for vascular dysfunction. This work was supported by the German Research Foundation [SFB 1116 B08 to G.H. and P.K.] and the European COST ACTION in CARDIOPROTECTION [CA16225 to G.H. and IG16225 to G.H. and P.K.]. 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.

5-Lipoxygenase Mediates Vascular Smooth Muscle Cell Depolarization Induced by 4-hydroxynonenal

5-Lipoxygenase Mediates Vascular Smooth Muscle Cell Depolarization Induced by 4-hydroxynonenal

Acid-sensing ion channel 1 contributes to pulmonary arterial smooth muscle cell depolarization following hypoxic pulmonary hypertension.

Pulmonary hypertension is characterized by sustained vasoconstriction and remodelling of the small pulmonary arteries, which is associated with persistent depolarization of the resting membrane potential (Em ) of pulmonary arterial smooth muscle cells (PASMCs). It is well-known that the underlying mechanism of this depolarization includes inhibition of K+ channels; however, whether other ion channels contribute to this depolarization is unknown. We previously reported that acid-sensing ion channel 1 (ASIC1), a non-selective cation channel (NSCC) that conducts both Na+ and Ca2+ , is present in PASMCs and contributes to the development of chronic hypoxia (CH)-induced pulmonary hypertension. Therefore, we tested the hypothesis that ASIC1-mediated Na+ influx contributes to PASMC Em regulation following CH-induced pulmonary hypertension. Using sharp electrode intracellular recordings in isolated, pressurized small pulmonary arteries from rats and mice, we show that exposure to CH leads to PASMC membrane depolarization compared with control animals, and this is independent of intraluminal pressure-induced depolarization. In addition to a decrease in PASMC whole-cell K+ currents following CH, we demonstrate that whole-cell NSCC currents are increased and essential to the persistent CH-induced Em depolarization in PASMCs. Both the specific inhibitor of ASIC1, psalmotoxin 1, and global knockout of ASIC1 (Asic1-/- ) prevents CH-induced Em depolarization and largely inhibits whole-cell NSCC currents, without affecting whole-cell K+ currents. Our results show a combination of factors, including inhibition of K+ efflux and augmented Na+ influx, mediate CH-induced PASMC depolarization. Furthermore, this study demonstrates a novel role for ASIC1 in the regulation of Em in PASMCs during CH-induced pulmonary hypertension. KEY POINTS: In pulmonary hypertensive patients and animal models of pulmonary hypertension, the resting membrane potential (Em ) of pulmonary arterial smooth muscle cells (PASMCs) is persistently depolarized. In addition to the well-established reduction of K+ conductance, we show that non-selective cation channel currents are increased and essential to the persistent Em depolarization in PASMCs following chronic hypoxia (CH)-induced pulmonary hypertension. The current study provides novel evidence that acid-sensing ion channel 1 (ASIC1)-mediated Na+ influx induces membrane depolarization and regulates Em in PASMCs following CH exposure. Although fairly quiescent under control conditions, our findings demonstrate a pathological function of ASIC1 in the development of chronic hypoxia-induced pulmonary hypertension.

Nimodipine inhibits intestinal and aortic smooth muscle contraction by regulating Ca2+-activated Cl− channels

Nimodipine is a clinically used dihydropyridine L-type calcium channel antagonist that effectively inhibits transmembrane Ca2+ influx following the depolarization of smooth muscle cells, but the detailed effect on smooth muscle contraction is not fully understood. Ca2+-activated Cl− channels (CaCCs) in vascular smooth muscle cells (VSMCs) may regulate vascular contractility. We found that nimodipine can inhibit transmembrane protein 16A (TMEM16A) activity in a concentration-dependent manner by cell-based fluorescence-quenching assay and short-circuit current analysis, with an IC50 value of ~5 μM. Short-circuit current analysis also showed that nimodipine prevented Ca2+-activated Cl− current in both HT-29 cells and mouse colonic epithelia accompanied by significantly decreased cytoplasmic Ca2+ concentrations. In the absence of extracellular Ca2+, nimodipine still exhibited an inhibitory effect on TMEM16A/CaCCs. Additionally, the application of nimodipine to CFTR-expressing FRT cells and mouse colonic mucosa resulted in mild activation of CFTR-mediated Cl− currents. Nimodipine inhibited basolateral CCh-activated K+ channel activity with no effect on Na+/K+-ATPase activity. Evaluation of intestinal smooth muscle contraction showed that nimodipine inhibits intestinal smooth muscle contractility and frequency, with an activity pattern that was similar to that of non-specific inhibitors of CaCCs. In aortic smooth muscle, the expression of TMEM16A in thoracic aorta is higher than that in abdominal aorta, corresponding to stronger maximum contractility in thoracic aorta smooth muscle stimulated by phenylephrine (PE) and Eact. Nimodipine completely inhibited the contraction of aortic smooth muscle stimulated by Eact, and partially inhibited the contraction stimulated by PE. In summary, the results indicate that nimodipine effectively inhibits TMEM16A/CaCCs by reduction transmembrane Ca2+ influx and directly interacting with TMEM16A, explaining the mechanisms of nimodipine relaxation of intestinal and aortic smooth muscle contraction and providing new targets for pharmacological applications.

Low-voltage-activated inward current in murine antral smooth muscle cells is an artifact

Two types of voltage-dependent inward currents were evoked by depolarization in murine antral smooth muscle cells (SMCs) bathed in Ca2+-containing physiological solution: high-voltage-activated (HVA) and low-voltage-activated (LVA) inward currents. We examined whether the LVA current was due to: 1) T-type Ca2+ channels, 2) Ca2+-activated Cl−channels, 3) nonselective cation channels (NSCC), or 4) voltage-dependent K+ channels. Replacement of external Ca2+ (2 mM) with equimolar Ba2+ increased the amplitude of the HVA current but blocked the LVA current. Nicardipine blocked the HVA current, and in the presence of nicardipine, T-type Ca2+ blockers failed to block LVA current. A Cl− channel antagonist had little effect on LVA current. Cation-free external solution completely abolished both HVA and LVA currents. Addition of Ca2+ to the solution restored only HVA currents. Addition of K+ (5 mM) to otherwise cation-free solution induced LVA current that reversed at −20 mV. These data suggest that LVA current is not due to T-type Ca2+ channels, Ca2+-activated Cl− channels, or NSCC. A-type K+ (KA) currents and delayed rectifying K+ (KDR) currents can be resolved in antral SMCs dialyzed with a solution containing 140 mM K+. When cells were exposed to high K+ external solution and dialyzed with Cs+-rich solution in the presence of nicardipine, LVA current was evoked and reversed at positive potentials. LVA currents were blocked by K+ channel blockers, 4-aminopyridine, and tetraethylammonium. In conclusion, LVA inward currents can be generated by K+ influx via KA channels in murine antral SMCs when cells were dialyzed with Cs+-rich solution.

Trophic sympathetic influence weakens pro-contractile role of Cl\u2212 channels in rat arteries during postnatal maturation

Membrane transporters and their functional contribution in vasculature change during early postnatal development. Here we tested the hypothesis that the contribution of Cl− channels to arterial contraction declines during early postnatal development and this decline is associated with the trophic sympathetic influence. Endothelium‐denuded saphenous arteries from 1- to 2-week-old and 2- to 3-month-old male rats were used. Arterial contraction was assessed in the isometric myograph, in some experiments combined with measurements of membrane potential. mRNA and protein levels were determined by qPCR and Western blot. Sympathectomy was performed by treatment with guanethidine from the first postnatal day until 8–9-week age. Cl− substitution in the solution as well as Cl−-channel blockers (MONNA, DIDS) had larger suppressive effect on the methoxamine-induced arterial contraction and methoxamine-induced depolarization of smooth muscle cells in 1- to 2-week-old compared to 2- to 3-month-old rats. Vasculature of younger group demonstrated elevated expression levels of TMEM16A and bestrophin 3. Chronic sympathectomy increased Cl− contribution to arterial contraction in 2-month-old rats that was associated with an increased TMEM16A expression level. Our study demonstrates that contribution of Cl− channels to agonist-induced arterial contraction and depolarization decreases during postnatal development. This postnatal decline is associated with sympathetic nerves development.

HB-EGF depolarizes hippocampal arterioles to restore myogenic tone in a genetic model of small vessel disease

Vascular cognitive impairment, the second most common cause of dementia, profoundly affects hippocampal-dependent functions. However, while the growing literature covers complex neuronal interactions, little is known about the sustaining hippocampal microcirculation. Here we examined vasoconstriction to physiological pressures of hippocampal arterioles, a fundamental feature of small arteries, in a genetic mouse model of CADASIL, an archetypal cerebral small vessel disease. Using diameter and membrane potential recordings on isolated arterioles, we observed both blunted pressure-induced vasoconstriction and smooth muscle cell depolarization in CADASIL. This impairment was abolished in the presence of voltage-gated potassium (KV1) channel blocker 4-aminopyridine, or by application of heparin-binding EGF-like growth factor (HB-EGF), which promotes KV1 channel down-regulations. Interestingly, we observed that HB-EGF induced a depolarization of the myocyte plasma membrane within the arteriolar wall in CADASIL, but not wild-type, arterioles. Collectively, our results indicate that hippocampal arterioles in CADASIL mice display a blunted contractile response to luminal pressure, similar to the defect we previously reported in cortical arterioles and pial arteries, that is rescued by HB-EGF. Hippocampal vascular dysfunction in CADASIL could then contribute to the decreased vascular reserve associated with decreased cognitive performance, and its correction may provide a therapeutic option for treating vascular cognitive impairment.

Cytochrome P450 epoxygenase-derived 5,6-epoxyeicosatrienoic acid relaxes pulmonary arteries in normoxia but promotes sustained pulmonary vasoconstriction in hypoxia.

The aim of the study was to investigate the role of cytochrome P450 (CYP) epoxygenase-derived epoxyeicosatrienoic acids (EETs) in sustained hypoxic pulmonary vasoconstriction (HPV). Vasomotor responses of isolated mouse intrapulmonary arteries (IPAs) were assessed using wire myography. Key findings were verified by haemodynamic measurements in isolated perfused and ventilated mouse lungs. Pharmacological inhibition of EET synthesis with MS-PPOH, application of the EET antagonist 14,15-EEZE or deficiency of CYP2J isoforms suppressed sustained HPV. In contrast, knockdown of EET-degrading soluble epoxide hydrolase or its inhibition with TPPU augmented sustained HPV almost twofold. All EET regioisomers elicited relaxation in IPAs pre-contracted with thromboxane mimetic U46619. However, in the presence of KCl-induced depolarization, 5,6-EET caused biphasic contraction in IPAs and elevation of pulmonary vascular tone in isolated lungs, whereas other regioisomers had no effect. In patch-clamp experiments, hypoxia elicited depolarization in pulmonary artery smooth muscle cells (PASMCs), and 5,6-EET evoked inward whole cell currents in PASMCs depolarized to the hypoxic level, but not at their resting membrane potential. The EET pathway substantially contributes to sustained HPV in mouse pulmonary arteries. 5,6-EET specifically appears to be involved in HPV, as it is the only EET regioisomer able to elicit not only relaxation, but also sustained contraction in these vessels. 5,6-EET-induced pulmonary vasoconstriction is enabled by PASMC depolarization, which occurs in hypoxia. The discovery of the dual role of 5,6-EET in the regulation of pulmonary vascular tone may provide a basis for the development of novel therapeutic strategies for treatment of HPV-related diseases.

Hypoxia‐induced depolarization of pulmonary arterial smooth muscle cells relies on simultaneous inhibition of K+‐currents and redox state alterations

Hypoxic pulmonary vasoconstriction (HPV) is a physiological response to localized alveolar hypoxia that is intrinsic to the pulmonary circulation. By hypoxia‐induced contraction of pulmonary arterial smooth muscle cells (PASMCs), pulmonary capillary blood flow is redirected to alveolar areas of high oxygen partial pressure (pO2), thus maintaining the ventilation‐perfusion ratio. Although the principle of HPV was recognized decades ago the underlying pathway still remains elusive.Voltage gated K+‐channels (Kv‐channels) are known to be redox‐sensitive and crucial for mediating membrane potential in PASMCs ‐ thereby controlling Ca2+‐entry and subsequently vascular tone. Here, we investigated whether acute hypoxia alters the redox state of isolated PASMCs from mice and if this impacts Kv‐channel activity, membrane potential and intracellular Ca2+‐ level.Kv‐currents and membrane potential in response to hypoxia or the oxidizing agent H2O2 were investigated by whole cell patch clamp experiments (voltage and current clamp, resp.) on freshly isolated murine PASMCs. Simultaneously, pO2 was recorded using an optical oxygen sensor and intracellular Ca2+ was measured by ratiometric FURA‐2 imaging. The redox state was monitored by Raman spectroscopy using an excitation wavelength that was in resonance with the hemeproteins (532 nm).Raman‐spectra values for reduced myoglobin (1607 cm−1) and cytochrome c (1622 cm−1) both increased upon exposure of PASMCs to hypoxia (4 % O2) and returned to the initial value upon reverting to normoxia (21 % O2), thus indicating a shift in the cells' redox state. In accordance, Kv‐currents were dose‐dependently inhibited by hypoxia and H2O2, resulting in a depolarization from −37,5 ± 2 mV (before) to −28.09 ± 2 mV after exposure to hypoxia (Mean ± SEM; n = 23; p = < 0,001; paired t‐test). The oxidizing agent H2O2 (124 nM) mimicked this effect under normoxic conditions by elevating the membrane potential of the PASMCs from −37.4 ± 3 mV (before) to −25,2 ± 4 mV upon application of 124 nM H2O2 (Mean ± SEM; n = 5, p = 0,005, paired t‐test) ‐ thereby triggering a rise in intracellular Ca2+.In conclusion, hypoxia induced a shift in redox state in PASMCs, thereby mediating the inhibition of KV‐channels. The resulting depolarization and Ca2+‐entry may account for the contraction of PASMCs – thus initiating HPV.Support or Funding InformationThis study was funded by the German Research Foundation (DFG, CRC 1213) and the Swedish Research Council (Grant 2016‐04220).This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Oxytocin can regulate myometrial smooth muscle excitability by inhibiting the Na+ -activated K+ channel, Slo2.1.

At the end of pregnancy, the uterus transitions from a quiescent state to a highly contractile state. This transition requires that the uterine (myometrial) smooth muscle cells increase their excitability, although how this occurs is not fully understood. We identified SLO2.1, a potassium channel previously unknown in uterine smooth muscle, as a potential significant contributor to the electrical excitability of myometrial smooth muscle cells. We found that activity of the SLO2.1 channel is negatively regulated by oxytocin via Gαq-protein-coupled receptor activation of protein kinase C. This results in depolarization of the uterine smooth muscle cells and calcium entry, which may contribute to uterine contraction. These findings provide novel insights into a previously unknown mechanism by which oxytocin may act to modulate myometrial smooth muscle cell excitability. Our findings also reveal a new potential pharmacological target for modulating uterine excitability. During pregnancy, the uterus transitions from a quiescent state to a more excitable contractile state. This is considered to be at least partly a result of changes in the myometrial smooth muscle cell (MSMC) resting membrane potential. However, the ion channels controlling the myometrial resting membrane potential and the mechanism of transition to a more excitable state have not been fully clarified. In the present study, we show that the sodium-activated, high-conductance, potassium leak channel, SLO2.1, is expressed and active at the resting membrane potential in MSMCs. Additionally, we report that SLO2.1 is inhibited by oxytocin binding to the oxytocin receptor. Inhibition of SLO2.1 leads to membrane depolarization and activation of voltage-dependent calcium channels, resulting in calcium influx. The results of the present study reveal that oxytocin may modulate MSMC electrical activity by inhibiting SLO2.1 potassium channels.

Manometric recordings bring out post-stimulus refractory states in the anal canal in neonates.

Anorectal manometry is a diagnostic technique used to investigate the correct mechanical performance of the internal anal sphincter (IAS). By distending the rectal ampulla while recording changes in the luminal pressure, this method allows for characterizing the anorectal reflex. It can also provide, indirectly, information about the electrical activity of the IAS. In this study, seventeen neonates having 24-hour delayed passage of meconium or presenting distal intestinal obstruction symptoms underwent anorectal manometry to discard Hirschsprung's disease. All patients had normal anorectal reflex. The time delay between stimulation of the rectal ampulla and the relaxation of the anal canal was studied. The average period of the pressure fluctuations was 5.44 ± 0.13s. The overall duration of the relaxation time was 9.71 ± 0.21s. The maximum lag between the onset of the stimulus and the relaxation of the IAS was 2.90 s, and was achieved when the stimulus was applied following a local maximum of the pressure wave. The existence of a refractory period during the suprathreshold depolarization of smooth muscle cells can explain the evidence of a temporal delay between the stimulus and the mechanical response. In occasions, relaxation appeared first distally. This phenomenon can be explained by the arrangement and morphology of bipolar cells, which may evidence the anisotropic propagation of the mechanical activity. These data may contribute to depict the alterations in excitability underlying the relaxation reflex by means of manometric recording of the anal canal.

Voltage-gated Ca2+ channel activity modulates smooth muscle cell calcium waves in hamster cremaster arterioles.

Cremaster muscle arteriolar smooth muscle cells (SMCs) display inositol 1,4,5-trisphosphate receptor-dependent Ca2+ waves that contribute to global myoplasmic Ca2+ concentration and myogenic tone. However, the contribution made by voltage-gated Ca2+ channels (VGCCs) to arteriolar SMC Ca2+ waves is unknown. We tested the hypothesis that VGCC activity modulates SMC Ca2+ waves in pressurized (80 cmH2O/59 mmHg, 34°C) hamster cremaster muscle arterioles loaded with Fluo-4 and imaged by confocal microscopy. Removal of extracellular Ca2+ dilated arterioles (32 ± 3 to 45 ± 3 μm, n = 15, P < 0.05) and inhibited the occurrence, amplitude, and frequency of Ca2+ waves ( n = 15, P < 0.05), indicating dependence of Ca2+ waves on Ca2+ influx. Blockade of VGCCs with nifedipine (1 μM) or diltiazem (10 μM) or deactivation of VGCCs by hyperpolarization of smooth muscle with the K+ channel agonist cromakalim (10 μM) produced similar inhibition of Ca2+ waves ( P < 0.05). Conversely, depolarization of SMCs with the K+ channel blocker tetraethylammonium (1 mM) constricted arterioles from 26 ± 3 to 14 ± 2 μm ( n = 11, P < 0.05) and increased wave occurrence (9 ± 3 to 16 ± 3 waves/SMC), amplitude (1.6 ± 0.07 to 1.9 ± 0.1), and frequency (0.5 ± 0.1 to 0.9 ± 0.2 Hz, n = 10, P < 0.05), effects that were blocked by nifedipine (1 μM, P < 0.05). Similarly, the VGCC agonist Bay K8644 (5 nM) constricted arterioles from 14 ± 1 to 8 ± 1 μm and increased wave occurrence (3 ± 1 to 10 ± 1 waves/SMC) and frequency (0.2 ± 0.1 to 0.6 ± 0.1 Hz, n = 6, P < 0.05), effects that were unaltered by ryanodine (50 μM, n = 6, P > 0.05). These data support the hypothesis that Ca2+ waves in arteriolar SMCs depend, in part, on the activity of VGCCs. NEW & NOTEWORTHY Arterioles that control blood flow to and within skeletal muscle depend on Ca2+ influx through voltage-gated Ca2+ channels and release of Ca2+ from internal stores through inositol 1,4,5-trisphosphate receptors in the form of Ca2+ waves to maintain pressure-induced smooth muscle tone.

Voltage-dependent inward currents in smooth muscle cells of skeletal muscle arterioles.

Voltage-dependent inward currents responsible for the depolarizing phase of action potentials were characterized in smooth muscle cells of 4th order arterioles in mouse skeletal muscle. Currents through L-type Ca2+ channels were expected to be dominant; however, action potentials were not eliminated in nominally Ca2+-free bathing solution or by addition of L-type Ca2+ channel blocker nifedipine (10 μM). Instead, Na+ channel blocker tetrodotoxin (TTX, 1 μM) reduced the maximal velocity of the upstroke at low, but not at normal (2 mM), Ca2+ in the bath. The magnitude of TTX-sensitive currents recorded with 140 mM Na+ was about 20 pA/pF. TTX-sensitive currents decreased five-fold when Ca2+ increased from 2 to 10 mM. The currents reduced three-fold in the presence of 10 mM caffeine, but remained unaltered by 1 mM of isobutylmethylxanthine (IBMX). In addition to L-type Ca2+ currents (15 pA/pF in 20 mM Ca2+), we also found Ca2+ currents that are resistant to 10 μM nifedipine (5 pA/pF in 20 mM Ca2+). Based on their biophysical properties, these Ca2+ currents are likely to be through voltage-gated T-type Ca2+ channels. Our results suggest that Na+ and at least two types (T- and L-) of Ca2+ voltage-gated channels contribute to depolarization of smooth muscle cells in skeletal muscle arterioles. Voltage-gated Na+ channels appear to be under a tight control by Ca2+ signaling.

MicroRNA‑138 promotes proliferation and suppresses mitochondrial depolarization in human pulmonary artery smooth muscle cells through targeting TASK‑1.

MicroRNA (miR)-138 serves an important role in the proliferation, differentiation and apoptosis of human pulmonary artery smooth muscle cells (HPASMCs), indicating the involvement of miR-138 in the development and progression of pulmonary artery hypertension (PAH). Potassium channel subfamily K member 3 (TASK-1), a two-pore domain K+ channel, is expressed in HPASMCs and is associated with hypoxic PAH. However, whether miR-138 mediates PAH through targeting TASK-1 is not known. In the present study, HPASMCs were transfected with miR-138 mimic to establish a PAH model in vitro, and the effects of a miR-138 inhibitor and a TASK-1 inhibitor (A293) were examined. Cell proliferation and mitochondrial membrane potential (MMP) were measured by CCK-8 assay and flow cytometry, respectively. Reverse transcription-quantitative polymerase chain reaction and western blotting were performed to examine the expression of miR-138, TASK-1, Bcl-2, caspase-3 and activation of extracellular signal-regulated kinase 1/2 (ERK1/2). A dual-luciferase reporter assay was also used to analyse the expression level of TASK-1 in HPASMCs. The results of the present study demonstrated that the miR-138 mimic promoted proliferation and MMP level, which was similar to the effect of A293 treatment on HPASMCs. However, the miR-138 inhibitor inhibited the effects induced by miR-138 mimic or A293 treatment, as demonstrated by a decrease in proliferation and MMP level in HPASMCs, accompanied by a decrease of Bcl-2 and an increase of caspase-3 expression levels, as well as ERK1/2 activation. The dual-luciferase reporter assay indicated that TASK-1 expression was negatively regulated by miR-138. The results of the present study suggested that miR-138 promoted proliferation and suppressed mitochondrial depolarization of HPASMCs by targeting TASK-1.

Local Ca2+ coupling between mitochondria and sarcoplasmic reticulum following depolarization in guinea pig urinary bladder smooth muscle cells.

Spatiotemporal changes in cytosolic Ca2+ concentration ([Ca2+]c) trigger a number of physiological functions in smooth muscle cells (SMCs). We previously imaged Ca2+-induced Ca2+ release following membrane depolarization as local Ca2+ transients, Ca2+ hotspots, in subplasmalemmal regions. In this study, the physiological significance of mitochondria on local Ca2+ signaling was examined. Cytosolic and mitochondrial Ca2+ images following depolarization or action potentials were recorded in single SMCs from the guinea pig urinary bladder using a fast-scanning confocal fluorescent microscope. Depolarization- and action potential-induced [Ca2+]c transients occurred at several discrete sites in subplasmalemmal regions, peaked within 30 ms, and then spread throughout the whole-cell. In contrast, Ca2+ concentration in the mitochondria matrix ([Ca2+]m) increased after a delay of ~50 ms from the start of depolarization, and then peaked within 500 ms. Following repolarization, [Ca2+]c returned to the resting level with a half-decay time of ~500 ms, while [Ca2+]m recovered more slowly (∼1.5 s). Carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone, a mitochondrial uncoupler, abolished depolarization-induced [Ca2+]m elevations and slowed [Ca2+]c changes. Importantly, short depolarization-induced changes in [Ca2+]m and transmembrane potential in mitochondria coupled to Ca2+ hotspots were significantly larger than those in other mitochondria. Total internal reflection fluorescence imaging revealed that a subset of mitochondria closely localized with ryanodine receptors and voltage-dependent Ca2+ channels. These results indicate that particular mitochondria are functionally coupled to ion channels and sarcoplasmic reticulum fragments within the local Ca2+ microdomain, and thus, strongly contribute to [Ca2+]c regulation in SMCs.

Membrane depolarization activates BK channels through ROCK-mediated β1 subunit surface trafficking to limit vasoconstriction.

Membrane depolarization of smooth muscle cells (myocytes) in the small arteries that regulate regional organ blood flow leads to vasoconstriction. Membrane depolarization also activates large-conductance calcium (Ca2+)-activated potassium (BK) channels, which limits Ca2+ channel activity that promotes vasoconstriction, thus leading to vasodilation. We showed that in human and rat arterial myocytes, membrane depolarization rapidly increased the cell surface abundance of auxiliary BK β1 subunits but not that of the pore-forming BKα channels. Membrane depolarization stimulated voltage-dependent Ca2+ channels, leading to Ca2+ influx and the activation of Rho kinase (ROCK) 1 and 2. ROCK1/2-mediated activation of Rab11A promoted the delivery of β1 subunits to the plasma membrane by Rab11A-positive recycling endosomes. These additional β1 subunits associated with BKα channels already at the plasma membrane, leading to an increase in apparent Ca2+ sensitivity and activation of the channels in pressurized arterial myocytes and vasodilation. Thus, membrane depolarization activates BK channels through stimulation of ROCK- and Rab11A-dependent trafficking of β1 subunits to the surface of arterial myocytes.

Intravascular Pressure Self‐Regulates the Myogenic Response by Controlling Surface PKD2 (TRPP1) Channel Abundance in Smooth Muscle Cells of Skeletal Muscle Arteries

Intravascular pressure stimulates arterial smooth muscle cell depolarization, leading to voltage‐dependent Ca2+ channel (Cav1.2) activation and vasoconstriction; a reaction termed the ‘myogenic response’. PKD2 (also termed TRPP1), is a non‐selective cation channel, expression of which has been demonstrated in myocytes of cerebral and mesenteric arteries. Mechanisms that regulate PKD2 activity are unclear. Here, we investigated the regulation of PKD2 surface abundance by intravascular pressure in murine hindlimb arteries using a combination of Western blotting, arterial biotinylation, and pressurized artery myography techniques. We found that PKD2 is primarily plasma membrane‐localized in myocytes of hindlimb arteries. Loss of intravascular pressure due to depressurization lead to PKD2 internalization and lysosomal degradation. In contrast, arterial depressurization did not alter TRPM4, TRPC6, CaV1.2, ANO1, or KV2.1 proteins. Intravascular pressure (80 mmHg) or a bath solution containing 30 mM K+, which depolarizes arteries to physiological membrane potential, prevented PKD2 internalization and degradation. Nimodipine, a voltage‐dependent Ca2+ channel (Cav1.2) blocker, inhibited depolarization‐induced stabilization of PKD2 protein. PKD2 surface protein and myogenic tone were measured in arteries pressurized to either 10 or 80 mmHg. Pressurizing arteries to 80 mmHg prevented the loss of both surface PKD2 and myogenic tone that occurred in arteries pressurized to 10 mmHg. Consistent with a central function of PKD2, myogenic tone was strongly attenuated in hindlimb arteries from conditional, smooth muscle‐specific PKD2 knockout mice. In summary, we show that intravascular pressure promotes PKD2 surface expression in arterial smooth muscle cells through a mechanism involving membrane depolarization and Cav1.2 channel activation, to cause vasoconstriction. Thus, intravascular pressure self‐regulates the myogenic response by controlling PKD2 surface abundance in arterial smooth muscle cells.Support or Funding InformationThis study was supported by NIH/NHLBI grants to J.H.J. and American Heart Association grants to R.H. and S.B.

Muscarinic Receptor Induced Contractions of the Detrusor are Mediated by Activation of TRPC4 Channels

Muscarinic receptor mediated contractions of the detrusor rely on Ca2+ influx through voltage-gated Ca2+ channels but to our knowledge the mechanism linking stimulation of M3Rs to the activation of voltage dependent Ca2+ channels has not been established. TRPC4 channels are receptor operated cation channels that couple muscarinic receptor activation to depolarization of intestinal smooth muscle cells, voltage-activated Ca2+ influx and contraction. We investigated whether TRPC4 channels are involved in cholinergic mediated contractions of the detrusor. Isometric tension recordings were made on strips of murine detrusor and intracellular Ca2+ measurements were made on isolated detrusor myocytes using confocal microscopy. Transcriptional expression of TRPC and IP3R subtypes in intact detrusor strips and isolated detrusor myocytes was assessed using reverse transcriptase-polymerase chain reaction. Cholinergic stimulation of the detrusor induced by electrical field stimulation or exogenous application of carbachol or neostigmine evoked contractions consisting of a transient plus a tonic response, which was blocked by ML204, an inhibitor of TRPC4 channels. A phasic oscillatory component was blocked by the IP3R inhibitor 2-APB. Carbachol evoked reproducible Ca2+ responses in isolated detrusor myocytes, consisting of an initial Ca2+ transient followed by Ca2+ oscillations. ML204 inhibited the initial Ca2+ transient whereas 2-APB inhibited the Ca2+ oscillations. Reverse transcriptase-polymerase chain reaction experiments showed that TRPC4β, TRPC6 and IP3R1 were selectively expressed in isolated detrusor myocytes. Control experiments demonstrated that ML204 did not affect L-type Ca2+ or BK current amplitude, caffeine induced Ca2+ transients or KCl induced contractions of the detrusor. Muscarinic receptor mediated contractions of the detrusor involve the activation of TRPC4β channels.

The Prostacyclin Analog Treprostinil Inhibits Ano1-Encoded Ca2+-Activated Cl− Channels and Mouse Pulmonary Arterial Tone Through Stimulation of cAMP-Dependent Signaling Pathway

Ca2+-activated Cl- channels (CaCCs) encoded by the gene Tmem16a or Anoctamin1 (ANO1) produce membrane depolarization and contraction of vascular smooth muscle cells (VSMCs) when stimulated by endogenous vasoconstrictors acting on Gq-protein coupled receptors. Treprostinil (TPL) is one of several prostacyclin analogs clinically used to treat patients diagnosed with pulmonary arterial hypertension (PAH). TPL reduces pulmonary arterial tone in PAH patients by binding to the IP prostanoid receptor. Activation of this Gs-coupled receptor leads to elevation in cAMP levels causing vasorelaxation by reducing intracellular [Ca2+]i. In this study, we examined whether TPL could exert vasorelaxation of mouse pulmonary arteries (mPA) by inhibiting, at least in part, ANO1-encoded CaCCs. TPL dose-dependently inhibited the contraction of mPA elicited by 10 μM 5-HT (IC50 ≈ 500 nM). The specific ANO1 inhibitor T16Ainh-A01 also dose-dependently inhibited the 5-HT-induced contraction of mPA but had no effect on the KCl-induced contraction (85.4 mM) at concentrations ≤ 10 μM. 200 nM TPL produced a rightward shift of the dose-response curve to T16AInh-A01, suggesting that TPL may inhibit CaCCs. Consistent with this hypothesis, Ca2+-activated Cl- currents (elicited by 1 μM free Ca2+ in the pipette solution) recorded in HEK-293 cells transfected with mouse ANO1 were significantly reduced by TPL (1 μM), or the adenylate cyclase activator Forskolin (10 μM). These preliminary results suggest that elevation of cAMP levels (perhaps through a phosphorylation step involving Protein Kinase A) may down-regulate ANO1-encoded CaCCs and attenuate the depolarization and vasoconstriction triggered by 5-HT. Our findings also suggest that part of the beneficial effects of TPL in PAH patients might be attributable to an interaction with ANO1 channels.

Vascular potassium channels in NVC.

It has long been proposed that the external potassium ion ([K(+)]0) works as a potent vasodilator in the dynamic regulation of local cerebral blood flow. Astrocytes may play a central role for producing K(+) outflow possibly through calcium-activated potassium channels on the end feet, responding to a rise in the intracellular Ca(2+) concentration, which might well reflect local neuronal activity. A mild elevation of [K(+)]0 in the end feet/vascular smooth muscle space could activate Na(+)/K(+)-ATPase concomitant with inwardly rectifying potassium (Kir) channels in vascular smooth muscle cells, leading to a hyperpolarization of vascular smooth muscle and relaxation of smooth muscle actin-positive vessels. Also proposed notion is endothelial calcium-activated potassium channels and/or inwardly rectifying potassium channel-mediated hyperpolarization of vascular smooth muscle. A larger elevation of [K(+)]0, which may occur pathophysiologically in such as spreading depression or stroke, can trigger a depolarization of vascular smooth muscle cells and vasoconstriction instead.