Epithelial Na(+) channel proteins are mechanotransducers of myogenic constriction in rat posterior cerebral arteries

It has been suggested that mechanosensitive ion channels initiate myogenic responses in vessels; however, the molecular identity of the mechanosensitive ion channel complex is unknown. Although previous reports have suggested that epithelial Na(+) channel (ENaC) proteins are mechanotransducers in arteries, experimental evidence demonstrating that ENaC proteins are mechanotransducers are not fully elucidated. The goal of the present study was to determine whether the ENaC is a mechanotransducer for the myogenic response by providing supporting evidence in the rat posterior cerebral artery (PCA). We measured the effect of ENaC inhibition on the pressure-induced myogenic response, Ca(2+) concentration and 20 kDa myosin light chain (MLC(20)) phosphorylation. We detected expression of βENaC and γENaC subunits in rat PCA by Western blots and immunofluorescence. Inhibition of ENaCs with amiloride, ethyl isopropyl amiloride or benzamil blocked the myogenic response. Moreover, the myogenic response was inhibited in rat PCA transfected with βENaC and γENaC small interfering RNA. The myogenic response was inhibited by elimination of external Na(+), which was replaced with N-methyl-d-glucamine. Amiloride and nifedipine inhibited the pressure-induced increase in Ca(2+) concentration. Finally, MLC(20) increased when the intraluminal pressure was raised, and the pressure-induced increase in MLC(20) phosphorylation was inhibited by pretreatment with amiloride, and in arteries transfected with βENaC or γENaC small interfering RNA. Our results suggest that ENaCs may play an important role as mechanosensitive ion channels initiating pressure-induced myogenic responses in rat PCA.     

Potassium channel blockers inhibit anion secretion in cultured rat epididymal epithelium

The effect of putative K channel blockers on anion secretion has been studied in primary monolayer cultures of rat epididymal cells using the short circuit current technique. Under basal conditions, monolayers had a transepithelial potential difference of about 2-3 mV, apical side negative and a short circuit current (SCC) of about 2 microA.cm-2. The transepithelial resistance was about 500 omega.cm2. Addition of adrenaline (0.23 microM, basolaterally) caused the SCC to rise to a peak value of about 10.5 microA.cm-2 and then stabilized at about 4 microA.cm-2 after 15 min. This rise in the short circuit current has previously been shown to be due to an increase in net anion secretion from the basolateral to the apical medium. In tissues stimulated with adrenaline, addition of barium (Ba) to the apical side did not affect the adrenaline-induced SCC, but addition to the basolateral side caused a dose-dependent inhibition of the current with an IC50 value (concentration required to inhibit 50% of the current) of 0.92 mM. At Ba concentration of 5 mM, the adrenaline-induced SCC was completely abolished. There was no effect on transepithelial resistance. Addition of tetraethylamonium (TEA) (16 mM) to the apical or basolateral side had no significant effect on the adrenaline-stimulated SCC. Lidocaine and quinidine inhibited the adrenaline-stimulated SCC when added either to the apical or basolateral bathing solution. The IC50 values for lidocaine were 0.42 mM and 0.35 mM for basolateral and apical application, respectively. The IC50 values for quinidine were 0.062 mM and 0.050 mM for basolateral and apical application, respectively. In all cases there was no change in tissue resistance. It is proposed that in the basolateral membrane of the epididymal cells, there is a component which is sensitive to putative K channel blockers. It is likely that it is a K channel. As in other secretory cells, this channel plays an important role in secretion.     

Influence of transmural pressure on myogenic responses of isolated cerebral arteries of the rat

We examined the diameter responses of isolated and pressurized posterior cerebral artery branches to various static and dynamic pressure alterations. These vessels, dissected from an anatomically identifiable location in the rat brain, developed tone when placed in a normal calcium physiological salt solution (1.6 mM Ca-PSS). Following a series of transmural pressure steps (Δp) of 25 or 50 mm Hg completed in 1–2 s and made every 5 min, they attained additional tone resulting in a mean luminal diameter of 139 μm at 100 mm Hg which was 35% less than their relaxed size measured in 1 mM EGTA-PSS. Continuous measurements of wall thickness and lumen diameter were obtained using a video electronic system in 1–2 mm long arterial segments, and autoregulatory gain factors calculated. Myogenic responses were obtained from each of 6 vessels taken from 6 WKY rats. Diameters following the step pressure changes were usually stable within 2–4 min. The data defined a myogenic regulatory pressure range from 49–145 mm Hg. Gain values averaged about 17% of that necessary for these arteries to maintain perfect flow autoregulation. Our results for myogenicity are comparable with the pressure range for blood flow autoregulation reported by others for the rat. We conclude that myogenic mechanisms, at least in this size artery, are partly responsible for flow autoregulation, and that they are supplemented by metabolic mechanisms operative in the intact rat brain. Research supported by grant HL 17335 from the NHLBI.     

Contribution of Na+/Ca2+ exchanger to the regulation of myogenic tone in isolated rat small arteries

The contribution of the Na⁺/Ca²⁺ exchanger to the myogenic vascular tone was examined in rat isolated skeletal muscle small arteries (A_SK) with pronounced myogenic tone and mesenteric small arteries (A_MS) with little myogenic tone. Myogenic tone was assessed by the vascular inner diameter at transmural pressures of 40 and 100 mmHg. To depress the Na⁺/Ca²⁺ exchanger, the extracellular Na⁺ concentration ([Na⁺]o) was lowered from 143 to 1.2 mM by substituting choline‐Cl for NaCl. The A_SK developed significant myogenic tone and constricted further in low [Na⁺]o. Nifedipine (1 μM ) reduced both myogenic tone and low [Na⁺]o‐induced contraction. Because the membrane potential of A_SK was not changed by low [Na⁺]o (–35 ± 2 mV at 143 mM [Na⁺]o, ?37 ± 3 mV at 1.2 mM [Na⁺]o), depolarization‐induced Ca²⁺ influx was not a cause of the low [Na⁺]o‐induced contraction. The A_MS did not develop significant myogenic tone. Although low [Na⁺]o also constricted A_MS, the magnitude of constriction was significantly weaker than that in A_SK (17 ± 4 vs. 47 ± 6%, P < 0.01, at 58 mM Na⁺). With Bay K 8644, A_MS developed myogenic tone, and low [Na⁺]o‐induced constriction was significantly increased. In conclusion, Na⁺/Ca²⁺ exchanger may play an important role in regulating myogenic tone, likely via mediating Ca²⁺‐extrusion.     

Contribution of Na+/Ca2+ exchanger to the regulation of myogenic tone in isolated rat small arteries.

The contribution of the Na+/Ca2+ exchanger to the myogenic vascular tone was examined in rat isolated skeletal muscle small arteries (ASK) with pronounced myogenic tone and mesenteric small arteries (AMS) with little myogenic tone. Myogenic tone was assessed by the vascular inner diameter at transmural pressures of 40 and 100 mmHg. To depress the Na+/Ca2+ exchanger, the extracellular Na+ concentration ([Na+]o) was lowered from 143 to 1.2 mM by substituting choline-Cl for NaCl. The ASK developed significant myogenic tone and constricted further in low [Na+]o. Nifedipine (1 microM) reduced both myogenic tone and low [Na+]o-induced contraction. Because the membrane potential of ASK was not changed by low [Na+]o (-35 +/- 2 mV at 143 mM [Na+]o, -37 +/- 3 mV at 1.2 mM [Na+]o), depolarization-induced Ca2+ influx was not a cause of the low [Na+]o-induced contraction. The AMS did not develop significant myogenic tone. Although low [Na+]o also constricted AMS, the magnitude of constriction was significantly weaker than that in ASK (17 +/- 4 vs. 47 +/- 6%, P < 0.01, at 58 mM Na+). With Bay K 8644, AMS developed myogenic tone, and low [Na+]o-induced constriction was significantly increased. In conclusion, Na+/Ca2+ exchanger may play an important role in regulating myogenic tone, likely via mediating Ca2+-extrusion.     

钠离子通道阻断剂抑制骨髓间充质干细胞向心肌样细胞的分化

背景：研究发现人和动物的多种间充质干细胞均存在河豚毒素敏感性钠离子通道,但钠离子通道是否会影响间充质干细胞向心肌细胞分化尚无共识。 目的：观察钠离子通道特异性阻断剂河豚毒素对骨髓间充质干细胞向心肌样细胞分化的影响。 方法：利用Percoll’s密度梯度离心法结合差速贴壁法分离大鼠骨髓间充质干细胞,用主动脉逆行生物酶灌流法分离大鼠成体心肌细胞。将DAPI标记的大鼠骨髓间充质干细胞与成体心肌细胞混合培养,应用0,10,100 μmol/L的河豚毒素进行干预,1周后观察骨髓间充质干细胞向心肌样细胞的分化情况。 结果与结论：免疫荧光细胞化学染色显示,大鼠骨髓间充质干细胞和成体心肌细胞混合培养1周后,骨髓间充质干细胞显著表达心肌特异性蛋白结蛋白和肌球蛋白,而10,100 μmol/L的河豚毒素均可完全抑制结蛋白和肌球蛋白在骨髓间充质干细胞中的表达。提示钠离子通道是骨髓间充质干细胞向心肌样细胞分化的必要条件。     

A cellular mechanism for myogenic regulation of cat cerebral arteries

Autoregulation of cerebral blood flow is accomplished through integration of metabolic, neurogenic and myogenic mechanisms. Myogenic mechanisms involve activation of cerebral arterial muscle cells as transmural pressure increases, providing a means through which vessel caliber can be regulated to maintain blood flow constant. The cellular mechanisms involved in this myogenic response may involve changes in the electrical potential across the plasma membrane. When isolated cat middle cerebral arteries are cannulated and prepared in a manner allowing manipulation of transmural pressure, the muscle cell membrane depolarizes as pressure increases. The degree of membrane depolarization in response to an elevated pressure is dependent upon extracellular Ca²⁺ ([Ca]₀), increasing as [Ca]₀ is elevated and markedly decreasing as [Ca]₀ is reduced to low levels. When these arterial preparations are maintained at a physiological pressure of around 100 mm Hg, spontaneous action potentials can be recorded which increase in frequency upon further elevation in pressure. Vessels exhibiting such electrical activity can be observed to decrease in diameter as pressure is increased. Such finding suggest a membrane electrical mechanism for myogenic autoregulation of cerebral arteries.     

The myogenic response in isolated rat cerebrovascular arteries: vessel model

We develop an integrated model of isolated rat arterial resistance vessel (RV), which can simulate its major property of myogenic response. The vascular smooth muscle cell is an important component of the wall of this vessel, and serves as a vasomotor organ providing the active tension generation that underlies the myogenic response of the wall to stretch. In the previous study, we focused on the development of a smooth muscle cell model that can mimic the strain-sensing and force-generating features of the myogenic mechanism. In the current model, we embed this cell model in a larger vessel wall configuration, and couple the time course of cellular contractile activation to macroscopic changes in vessel diameter. The integrated model is used to mimic published pressure-vessel diameter data obtained from isolated RVs that are mounted in a hydraulic test apparatus. The model provides biophysically based insights into the myogenic mechanism as it responds to changes in transmural pressure, in the presence and absence of Ca2+ blockers applied to the bathing fluid.It mimics measured data very well and provides a model that is able to link events at subcellular level to macroscopic changes in vessel diameter. The model initiates a mechanistic approach to investigate myogenic response, which has not been taken previously by any other models.     

Chloride channel blockers attenuate the inhibition of renin secretion by angiotensin II

The aim of this study was to assess the relevance of chloride channels to the inhibitory effect of angiotensin II (ANGII) on renin secretion. We thus examined the effects of the chloride channels blockers IAA-94 and niflumic acid, the Na-K-Cl cotransport blocker bumetanide and substitution of isethionate for extracellular chloride on the action of ANGII on renin secretion from isolated perfused rat kidneys. Renin secretion prestimulated by isoproterenol (10 nmol/l) was almost completely blocked by ANGII with a concentration yielding a half-maximal response (EC50) of around 150 nmol/l. In the presence of IAA-94 and niflumic acid the EC50 for ANGII was shifted to about 400 nmol/l. In the presence of bumetanide and isethionate renin secretion responded more sensitively to ANGII and the EC50 for ANGII was below 100 nmol/l. On the assumption that the chloride equilibrium potential in renin-secreting cells is more positive than the membrane potential, our findings would suggest that the inhibitory effect of ANGII is enhanced when chloride entry is blocked and attenuated when chloride efflux is impaired. Activation of chloride channels therefore probably contributes to the inhibitory action of ANGII on renin secretion.     

The myogenic response in isolated rat cerebrovascular arteries: smooth muscle cell model

Previous models of the cerebrovascular smooth muscle cell have not addressed the interaction between the electrical, chemical, and mechanical components of cell function during the development of active tension. These models are primarily electrical, biochemical or mechanical in their orientation, and do not permit a full exploration of how the smooth muscle responds to electrical or mechanical forcing. To address this issue, we have developed a new model that consists of two major components: electrochemical and chemomechanical subsystem models of the smooth muscle cell. Included in the electrochemical model are models of the electrophysiological behavior of the cell membrane, fluid compartments, Ca2+ release and uptake by the sarcoplasmic reticulum (SR), and cytosolic Ca2+ buffering, particularly by calmodulin (CM). With this subsystem model, we can study the mechanics of the production of intracellular Ca2+ transient in response to membrane voltage clamp pulses. The chemomechanical model includes models of: (a) the chemical kinetics of myosin phosphorylation, and the formation of phosphorylated (cycling) myosin cross-bridges with actin, as well as attached (non-cycling) latch-type cross-bridges; and (b) a model of force generation and mechanical coupling to the contractile filaments and their attachments to protein structures and the skeletal framework of the cell. The two subsystem models are tested independently and compared with data. Likewise, the complete (combined) cell model responses to voltage pulse stimulation under isometric and isotonic conditions are calculated and compared with measured single cell length-force and force-velocity data obtained from literature. This integrated cell model provides biophysically based explanations of electrical, chemical, and mechanical phenomena in cerebrovascular smooth muscle, and has considerable utility as an adjunct to laboratory research and experimental design.     

Effect of Cl- channel blockers on aconitine-induced arrhythmias in rat heart

The effects of Cl- channel blockers 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) and niflumic acid (NFA) on aconitine-induced arrhythmias were investigated. Left ventricular pressure and electrocardiogram were monitored in Langendorff-perfused rat hearts. Whole-cell patch-clamp and current-clamp techniques were used to measure sodium current (I(Na)) and action potential (AP), respectively, in single rat cardiac ventricular myocytes. Addition of the Na+ channel agonist aconitine (0.1 microM) to the perfusion solution produced polymorphic ventricular arrhythmias with a latent period of 25.5 +/- 6.3 s. NPPB could reverse aconitine-induced arrhythmias. A similar effect was observed by using NFA. NPPB and NFA reversibly depressed the upstroke of the AP in a dose-dependent manner with IC50 values of approximately 12.3 and approximately 73.1 microM, respectively, without significantly affecting the resting potential of rat ventricular myocytes. Both Cl- channel blockers inhibited I(Na) and induced a leftward shift of the steady-state inactivation of I(Na). In conclusion, the results of this study demonstrate that NPPB as well as NFA can suppress aconitine-induced arrhythmias in rat hearts mainly by inhibiting cardiac I(Na).     

Effect of calcium channel blockers on cerebral ischemia-induced hyperactivity in Mongolian gerbils.

When both common carotid arteries of Mongolian gerbils were occluded for 5 min to produce ischemic insult, locomotor activity was increased the following day. The effect of calcium channel blockers on this ischemia-induced hyperactivity was investigated. Nimodipine, at doses of 5, 10, and 20 mg/kg, dose dependently and significantly decreased ischemia-induced hyperactivity. Nicardipine significantly decreased ischemia-induced hyperactivity and doses of 10 and 20 mg/kg. Nifedipine and flunaridine also significantly decreased ischemia-induced hyperactivity at doses of 20 mg/kg. Verapamil had no effect on ischemia-induced hyperactivity at a dose of 20 mg/kg. These findings suggest that ischemia-induced hyperactivity is related to calcium channels. These relationship between calcium channels and dopaminergic function is discussed.     

Withdrawal of magnesium causes vasospasm while elevated magnesium produces relaxation of tone in cerebral arteries

Excised middle cerebral and basilar arteries from dogs were incubated in Krebs-Ringer bicarbonate solution and exposed to normal, high and low concentrations of magnesium [Mg] in the medium. Sudden withdrawal of extracellular Mg²⁺ ([Mg²⁺]_o) from the medium produced contraction of arterial smooth muscle, whereas elevated concentrations of [Mg²⁺]_o decreased the basal tensions in a concentration-dependent manner.     

Active,passive and myogenic characteristics of isolated rat intramural coronary resistance arteries

We have investigated the active, passive and myogenic tension-internal circumference relations of rat intramural coronary and, as controls, mesenteric small arteries (internal diameter ca. 200 m) using an isometric myograph. The active tensions of the vessels (when fully activated with 30 M serotonin in K-saline) reached a maximum (2.54 N/m, coronary; 3.39 N/m, mesenteric) at an internal circumference, L₀, where the passive tensions (measured in Ca-free solution) were 0.80 N/m (coronary) and 0.74 N/m (mesenteric). Below 0.8 L₀ and above 1.2 L₀ the active tensions fell linearly, the zero tension intercepts being 0.37 L₀ and 1.74 L₀ (coronary) and 0.40 L₀ and 1.72 L₀ (mesenteric). The passive wall tensions of the vessels rose exponentially as a function of internal circumference, the wall tension at 1.5 L₀ being 10.0 N/m (coronary) and 8.5 N/m (mesenteric). In normal physiological salt solution, the coronary vessels had a Ca²⁺ dependent myogenic tone which was also dependent on the internal circumference. Maximum myogenic tone (0.54 N/m) was obtained at 1.18 L₀. The mesenteric vessels had no such myogenic tone. Histological examination showed that the media/lumen ratios of both vessel types were the same, and that the smooth muscle content of the media was greater in the coronary (81%) than in the mesenteric (72%) vessels. The smaller active tension of the coronary vessels could not therefore be ascribed to a reduced smooth muscle content, but possibly in part to an observed heterogeneous arrangement of the smooth muscle cells in the coronary vessels.     

Dual effect of initial [K] on vascular tone in rat mesenteric arteries

A slight increase in extracellular concentration of potassium () can act as a vasodilator in rat mesenteric vascular bed. However, in recent years, several groups have failed to consistently observe relaxation of rat mesenteric arteries in these conditions. The aim of the present study was to provide a mechanistic understanding of this discrepancy. In rat small mesenteric arteries, 37 of 40 arteries mounted for measurement of isometric force and pre-contracted with phenylephrine (PE) did not relax when was raised from 5.9 mM (control ) to 11.2 or 21.2 mM. However, when was briefly lowered to 1.2 mM, increasing to between 5.9 and 41.2 mM evoked relaxation. This relaxation was not reduced by barium or by removal of the endothelium, but was abolished by 0.1 mM ouabain. Raising from concentrations between 0 and 5.9 mM to 13.8 mM elicited a relaxation of PE-induced tone that was inversely proportional to initial . Relaxation was associated with a ouabain-sensitive hyperpolarization of smooth muscle cells. In arteries exposed to dihydroouabain (DHO), raising from 5.9 to 13.8 mM and simultaneously washing out DHO resulted in relaxation of PE-induced force. These results suggest that only when the initial is less than ∼5 mM do small elevations in evoke smooth muscle hyperpolarization and relaxation via activation of Na,K-ATPase, and not inwardly rectifying K⁺ channels. Therefore, small differences in the initial (4.6 vs 5.9 mM) can strongly influence the variations of vascular tone to increases in .