Abstract-Vasomotion is the regular variation in tone of arteries. In our study, we suggest a model for the initiation of vasomotion. We suggest that intermittent release of Ca 2ϩ from the sarcoplasmic reticulum (SR, cytosolic oscillator), which is initially unsynchronized between the vascular smooth muscle cells, becomes synchronized to initiate vasomotion. The synchronization is achieved by an ion current over the cell membrane, which is activated by the oscillating Ca 2ϩ release. This current results in an oscillating membrane potential, which synchronizes the SR in the vessel wall and starts vasomotion. Therefore, the pacemaker of the vascular wall can be envisaged as a diffuse array of individual cytosolic oscillators that become entrained by a reciprocal interaction with the cell membrane. The model is supported by experimental data. Confocal [Ca 2ϩ ] i imaging and isometric force development in isolated rat resistance arteries showed that low norepinephrine concentrations induced SR-dependent unsynchronized waves of Ca 2ϩ in the vascular smooth muscle. In the presence of the endothelium, the waves converted to global synchronized oscillations of [Ca 2ϩ ] i after some time, and vasomotion appeared. Synchronization was also seen in the absence of endothelium if 8-bromo-cGMP was added to the bath. Using the patch-clamp technique and microelectrodes, we showed that Ca 2ϩ release can activate an inward current in isolated smooth muscle cells from the arteries and cause depolarization. These electrophysiological effects of Ca 2ϩ release were cGMP dependent, which is consistent with the possibility that they are important for the cGMP-dependent synchronization. Further support for the model is the observation that a short-lasting current pulse can initiate vasomotion in an unsynchronized artery as expected from the model.
Disruption of Na + ,HCO 3 − Cotransporter NBCn1 (slc4a7) Inhibits NO-Mediated Vasorelaxation, Smooth Muscle Ca 2+ Sensitivity, and Hypertension Development in Mice
Background-Disturbances in pH affect artery function, but the mechanistic background remains controversial. We investigated whether Na ϩ ,HCO 3 Ϫ cotransporter NBCn1, by regulating intracellular pH (pH i ), influences artery function and blood pressure regulation. Methods and Results-Knockout of NBCn1 in mice eliminated Na ϩ ,HCO 3 Ϫ cotransport and caused a lower steady-state pH i in mesenteric artery smooth muscle and endothelial cells in situ evaluated by fluorescence microscopy. Using myography, arteries from NBCn1 knockout mice showed reduced acetylcholine-induced NO-mediated relaxations and lower rho-kinase-dependent norepinephrine-stimulated smooth muscle Ca 2ϩ sensitivity. Acetylcholine-stimulated NO levels (electrode measurements) and N-nitro-L-arginine methyl ester-sensitive L-arginine conversion (radioisotope measurements) were reduced in arteries from NBCn1 knockout mice, whereas relaxation to NO-donor S-nitroso-Nacetylpenicillamine, acetylcholine-induced endothelial Ca 2ϩ responses (fluorescence microscopy), and total and Ser-1177 phosphorylated endothelial NO-synthase expression (Western blot analyses) were unaffected. Reduced NO-mediated relaxations in arteries from NBCn1 knockout mice were not rescued by superoxide scavenging. Phosphorylation of myosin phosphatase targeting subunit at Thr-850 was reduced in arteries from NBCn1 knockout mice. Evaluated by an in vitro assay, rho-kinase activity was reduced at low pH. Without CO 2 /HCO 3 Ϫ , no differences in pH i , contraction or relaxation were observed between arteries from NBCn1 knockout and wild-type mice. Based on radiotelemetry and tail-cuff measurements, NBCn1 knockout mice were mildly hypertensive at rest, displayed attenuated blood pressure responses to NO-synthase and rho-kinase inhibition and were resistant to developing hypertension during angiotensin-II infusion. Conclusions-Intracellular acidification of smooth muscle and endothelial cells after knockout of NBCn1 inhibits NO-mediated and rho-kinase-dependent signaling in isolated arteries and perturbs blood pressure regulation. (Circulation. 2011;124:1819-1829.)Key Words: pH Ⅲ hypertension Ⅲ blood pressure Ⅲ nitric oxide Ⅲ rho-kinase B lood pressure dysregulation is a major cause of human disease. Hypertension is a risk factor for development of coronary heart disease, stroke, and peripheral vascular disease 1-3 whereas hypotension is related to syncope and falls. 4,5 Both hyper-and hypotension increase overall mortality. 6 -8 Editorial see p 1806 Clinical Perspective on p 1829Arterial tone regulation is important for blood pressure control and is modulated by local and systemic factors. Sustained changes in intracellular pH (pH i ) of vascular smooth muscle cells (VSMCs) and endothelial cells (ECs) occur physiologically and pathologically, but have been difficult to investigate experimentally, and little is known about their vascular effects. 9 It has, however, been proposed that endothelial enzymes (eg, endothelial nitric oxide synthase [eNOS] 10 and endothelin converting...
This minireview discusses vasomotion, which is the oscillation in tone of blood vessels leading to flowmotion. We will briefly discuss the prevalence of vasomotion and its potential physiological and pathophysiological relevance. We will also discuss the models that have been suggested to explain how a coordinated oscillatory activity of the smooth muscle tone can occur and emphasize the role of the endothelium, the handling of intracellular Ca(2+) and the role of smooth muscle cell ion conductances. It is concluded that vasomotion is likely to enhance tissue dialysis, although this concept still requires more experimental verification, and that an understanding at the molecular level for the pathways leading to vasomotion is beginning to emerge.
We have previously demonstrated the presence of a cyclic GMP (cGMP)-dependent calcium-activated inward current in vascular smooth-muscle cells, and suggested this to be of importance in synchronizing smooth-muscle contraction. Here we demonstrate the characteristics of this current. Using conventional patch-clamp technique, whole-cell currents were evoked in freshly isolated smooth-muscle cells from rat mesenteric resistance arteries by elevation of intracellular calcium with either 10 mM caffeine, 1 μM BAY K8644, 0.4 μM ionomycin, or by high calcium concentration (900 nM) in the pipette solution. The current was found to be a calcium-activated chloride current with an absolute requirement for cyclic GMP (EC50 6.4 μM). The current could be activated by the constitutively active subunit of PKG. Current activation was blocked by the protein kinase G antagonist Rp-8-Br-PET-cGMP or with a peptide inhibitor of PKG, or with the nonhydrolysable ATP analogue AMP-PNP. Under biionic conditions, the anion permeability sequence of the channel was SCN− > Br− > I− > Cl− > acetate > F− >> aspartate, but the conductance sequence was I− > Br− > Cl− > acetate > F− > aspartate = SCN−. The current had no voltage or time dependence. It was inhibited by nickel and zinc ions in the micromolar range, but was unaffected by cobalt and had a low sensitivity to inhibition by the chloride channel blockers niflumic acid, DIDS, and IAA-94. The properties of this current in mesenteric artery smooth-muscle cells differed from those of the calcium-activated chloride current in pulmonary myocytes, which was cGMP-independent, exhibited a high sensitivity to inhibition by niflumic acid, was unaffected by zinc ions, and showed outward current rectification as has previously been reported for this current. Under conditions of high calcium in the patch-pipette solution, a current similar to the latter could be identified also in the mesenteric artery smooth-muscle cells. We conclude that smooth-muscle cells from rat mesenteric resistance arteries have a novel cGMP-dependent calcium-activated chloride current, which is activated by intracellular calcium release and which has characteristics distinct from other calcium-activated chloride currents.
Abstract-Although the biophysical fingerprints (ion selectivity, voltage-dependence, kinetics, etc) of Ca 2ϩ -activated Cl Ϫ currents are well established, their molecular identity is still controversial. Several molecular candidates have been suggested; however, none of them has been fully accepted. We have recently characterized a cGMP-dependent Ca 2ϩ -activated Cl Ϫ current with unique characteristics in smooth muscle cells. This novel current has been shown to coexist with a "classic" (cGMP-independent) Ca 2ϩ -activated Cl Ϫ current and to have characteristics distinct from those previously known for Ca 2ϩ -activated Cl Ϫ currents. Here, we suggest that a bestrophin, a product of the Best gene family, is responsible for the cGMP-dependent Ca 2ϩ -activated Cl Ϫ current based on similarities between the membrane currents produced by heterologous expressions of bestrophins and the cGMP-dependent Ca 2ϩ -activated Cl Ϫ current. This is supported by similarities in the distribution pattern of the cGMP-dependent Ca 2ϩ -activated Cl Ϫ current and bestrophin-3 (the product of Best-3 gene) expression in different smooth muscle. Furthermore, downregulation of Best-3 gene expression with small interfering RNA both in cultured cells and in vascular smooth muscle cells in vivo was associated with a significant reduction of the cGMP-dependent Ca 2ϩ -activated Cl Ϫ current, whereas the magnitude of the classic Ca 2ϩ -activated Cl Ϫ current was not affected. Ϫ channel, which results in depolarization in vascular smooth muscle. Furthermore, the current is of similar magnitude as "classic" Ca 2ϩ -activated Cl Ϫ currents in most vascular beds and even larger in some vascular smooth muscles. 3 It is, therefore, highly desirable to know the molecular structure of the channel responsible for this current because it is likely to play an important role in smooth muscle function.Although their biophysical fingerprints (ion selectivity, voltage-dependence, kinetics, etc) are well established, 4 -6 the molecular identity of Ca 2ϩ -sensitive Cl Ϫ channels is still controversial. 7 Recently, the gene responsible for vitelliform macular dystrophy 8 and its homologs that code for bestrophin proteins have been suggested as candidates. 9,10 Four bestrophin family members in the mammalian genome and many homologues in genomes of invertebrates and even prokaryotes have been identified. 11-13 Two different nomenclatures for mammalian bestrophins were previously devel- The majority of suggestions that bestrophins function as Cl Ϫ channels are based on the findings that expression of the gene in different cell types leads to the appearance of a Cl Ϫ conductance 9,10 and that mutations or chemical modifications of the predicted channel pore change this conductance. [15][16][17][18] Although downregulation by small interfering (si)RNA in recent studies demonstrated a direct association between the endogenous Cl Ϫ current in epithelial cell culture and Best-1 expression, 19 -21 the exact role of the bestrophins in native tissues remains questionable...
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