The AMP-Related Kinase (AMPK) Induces Ca2+-Independent Dilation of Resistance Arteries by Interfering With Actin Filament Formation.

RATIONALE: Decreasing Ca2+ sensitivity of vascular smooth muscle (VSM) allows for vasodilation without lowering of cytosolic Ca2+. This may be particularly important in states requiring maintained dilation, such as hypoxia. AMP-related kinase (AMPK) is an important cellular energy sensor in VSM. Regulation of Ca2+ sensitivity usually is attributed to myosin light chain phosphatase activity, but findings in non-VSM identified changes in the actin cytoskeleton. The potential role of AMPK in this setting is widely unknown. OBJECTIVE: To assess the influence of AMPK on the actin cytoskeleton in VSM of resistance arteries with regard to potential Ca2+ desensitization of VSM contractile apparatus. METHODS AND RESULTS: AMPK induced a slowly developing dilation at unchanged cytosolic Ca2+ levels in potassium chloride-constricted intact arteries isolated from mouse mesenteric tissue. This dilation was not associated with changes in phosphorylation of myosin light chain or of myosin light chain phosphatase regulatory subunit. Using ultracentrifugation and confocal microscopy, we found that AMPK induced depolymerization of F-actin (filamentous actin). Imaging of arteries from LifeAct mice showed F-actin rarefaction in the midcellular portion of VSM. Immunoblotting revealed that this was associated with activation of the actin severing factor cofilin. Coimmunoprecipitation experiments indicated that AMPK leads to the liberation of cofilin from 14-3-3 protein. CONCLUSIONS: AMPK induces actin depolymerization, which reduces vascular tone and the response to vasoconstrictors. Our findings demonstrate a new role of AMPK in the control of actin cytoskeletal dynamics, potentially allowing for long-term dilation of microvessels without substantial changes in cytosolic Ca2+.

NO Augments Endothelial Reactivity by Reducing Myoendothelial Calcium Signal Spreading: A Novel Role for Cx37 (Connexin 37) and the Protein Tyrosine Phosphatase SHP-2.

OBJECTIVE: Because of its strategic position between endothelial and smooth muscle cells in microvessels, Cx37 (Connexin 37) plays an important role in myoendothelial gap junctional intercellular communication. We have shown before that NO inhibits gap junctional intercellular communication through gap junctions containing Cx37. However, the underlying mechanism is not yet identified. APPROACH AND RESULTS: Using channel-forming Cx37 mutants exhibiting partial deletions or amino acid exchanges in their C-terminal loops, we now show that the phosphorylation state of a tyrosine residue at position 332 (Y332) in the C-terminus of Cx37 controls the gap junction-dependent spread of calcium signals. Mass spectra revealed that NO protects Cx37 from dephosphorylation at Y332 by inhibition of the protein tyrosine phosphatase SHP-2. Functionally, the inhibition of gap junctional intercellular communication by NO decreased the spread of the calcium signal (induced by mechanical stimulation of individual endothelial cells) from endothelial to smooth muscle cells in intact vessels, while, at the same time, augmenting the calcium signal spreading within the endothelium. Consequently, preincubation of small resistance arteries with exogenous NO enhanced the endothelium-dependent dilator response to acetylcholine in spite of a pharmacological blockade of NO-dependent cGMP formation by the soluable guanylyl cyclase inhibitor ODQ (1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one). CONCLUSIONS: Our results identify a novel mechanism by which NO can increase the efficacy of calcium, rising vasoactive agonists in the microvascular endothelium.

Cysteinyl leukotriene 1 receptors as novel mechanosensors mediating myogenic tone together with angiotensin II type 1 receptors-brief report.

OBJECTIVE: Myogenic vasoconstriction is mediated by vascular smooth muscle cells of resistance arteries sensing mechanical stretch. Angiotensin II AT1 receptors and in particular AT1BRs in murine vascular smooth muscle cells have been characterized as mechanosensors that cannot fully account for myogenic vasoconstriction observed. Therefore, we aimed at uncovering novel vascular mechanosensors by expression profiling and functional characterization of candidate proteins. APPROACH AND RESULTS: Analyzing myogenic tone of isolated murine mesenteric arteries of AT1A and AT1B receptor double gene-deficient (AT1A/1B (-/-)) mice ex vivo, we observed a decreased myogenic tone at high intraluminal pressures and an unexpected hyper-reactivity at low intraluminal pressures because of upregulation of cysteinyl leukotriene 1 receptors (CysLT1Rs). Pharmacological blockade of CysLT1Rs with pranlukast significantly reduced myogenic tone not only in AT1A/1B (-/-) but also in wild-type arteries. In wild-type arteries, additional blockade of angiotensin II AT1 receptors with candesartan resulted in an additive reduction of myogenic tone. Furthermore, calcium imaging experiments were performed with fura-2-loaded human embryonic kidney 293 cells overexpressing CysLT1Rs and with isolated mesenteric vascular smooth muscle cells. Hypo-osmotically induced membrane stretch provoked calcium transients that were significantly reduced by pranlukast. Incubations of isolated mesenteric vascular smooth muscle cells with the 5-lipoxygenase inhibitor zileuton had no effect. Furthermore, the Gq/11-protein inhibitor YM 254890 profoundly reduced myogenic tone to the same extent as induced by the application of pranlukast plus candesartan. CONCLUSIONS: Here, we identify a novel, hitherto unappreciated role of CysLT1Rs in vascular regulation. We identified CysLT1Rs as novel mechanosensors in the vasculature involved in myogenic vasoconstriction. Moreover, our findings suggest that myogenic tone is determined by AT1 and CysLT1 receptors acting together as mechanosensors via Gq/11-protein activation.

Novel role of mechanosensitive AT1B receptors in myogenic vasoconstriction.

Myogenic vasoconstriction is an inherent property of vascular smooth muscle cells (VSMCs) of resistance arteries harboring ill-defined mechanosensing and mechanotransducing elements. G protein-coupled receptors (GPCRs) are discussed as mechanosensors in VSMCs. In this study, we sought to identify and characterize the role and impact of GPCRs on myogenic vasoconstriction. Thus, we analyzed mRNA expression levels of GPCRs in resistance versus preceding conduit arteries revealing a significant enrichment of several GPCRs in resistance vessels. Selective pharmacological blockade of the highly expressed GPCRs in isolated murine mesenteric arteries ex vivo decreased myogenic vasoconstriction. In particular, candesartan and losartan most prominently suppressed myogenic tone, suggesting that AT1 receptors play a central role in myogenic vasoconstriction. Analyzing angiotensinogen(-/-) mice, a relevant contribution of locally produced angiotensin II to myogenic tone could be excluded. Investigation of AT1A (-/-) and AT1B (-/-) murine mesenteric arteries revealed that AT1B, but not AT1A, receptors are key components of myogenic regulation. This notion was supported by examining fura-2-loaded isolated AT1A (-/-) and AT1B (-/-) VSMCs. Our results indicate that in VSMCs, AT1B receptors are more mechanosensitive than AT1A receptors even at comparable receptor expression levels. Furthermore, we demonstrate that the mechanosensitivity of GPCRs is agonist-independent and positively correlates with receptor expression levels.

AMPK Dilates Resistance Arteries via Activation of SERCA and BKCa Channels in Smooth Muscle.

The protective effects of 5'-AMP-activated protein kinase (AMPK) on the metabolic syndrome may include direct effects on resistance artery vasomotor function. However, the precise actions of AMPK on microvessels and their potential interaction are largely unknown. Thus, we set to determine the effects of AMPK activation on vascular smooth muscle tone and the underlying mechanisms. Resistance arteries isolated from hamster and mouse exhibited a pronounced endothelium-independent dilation on direct pharmacological AMPK activation by 2 structurally unrelated compounds (PT1 and A769662). The dilation was associated with a decrease of intracellular-free calcium [Ca(2+)]i in vascular smooth muscle cell. AMPK stimulation induced activation of BKCa channels as assessed by patch clamp studies in freshly isolated hamster vascular smooth muscle cell and confirmed by direct proof of membrane hyperpolarization in intact arteries. The BKCa channel blocker iberiotoxin abolished the hyperpolarization but only partially reduced the dilation and did not affect the decrease of [Ca(2+)]i. By contrast, the sarcoplasmic/endoplasmic Ca(2+)-ATPase (SERCA) inhibitor thapsigargin largely reduced these effects, whereas combined inhibition of SERCA and BKCa channels virtually abolished them. AMPK stimulation significantly increased the phosphorylation of the SERCA modulator phospholamban at the regulatory T17 site. Stimulation of smooth muscle AMPK represents a new, potent vasodilator mechanism in resistance vessels. AMPK directly relaxes vascular smooth muscle cell by a decrease of [Ca(2+)]i. This is achieved by calcium sequestration via SERCA activation, as well as activation of BKCa channels. There is in part a mutual compensation of both calcium-lowering mechanisms. However, SERCA activation which involves an AMPK-dependent phosphorylation of phospholamban is the predominant mechanism in resistance vessels.