Extracellular nucleotides, particularly ATP, are involved in the modulation of arterial vasomotricity via P2 purinoceptors present on smooth muscle and endothelial cells. These nucleotides could also be implicated in the smooth muscle cell hyperplasia observed in intimal lesions. In this study, we tried to define the potential role of the P2Y2 (P2u) purinoceptor by studying its expression in normal and balloon-injured rat aortas. The cloning of a rat P2Y2 cDNA from a rat smooth muscle cell cDNA library made it possible to study P2Y2 expression both by Northern blot and in situ hybridization. Northern blot experiments indicated that P2Y2 mRNA was present in rat medial aortic smooth muscle and in cultured rat aortic smooth muscle cells. In situ hybridization indicated that P2Y2 mRNA was present in endothelial cells of the intima and in some smooth muscle cells scattered throughout the media of adult rat aortas, while almost all medial smooth muscle cells of rat embryo aorta expressed this receptor. In contrast with adult aortic media, the majority of neointimal smooth muscle cells found in aortic intimal lesions either 8 or 20 days after balloon injury were positive for P2Y2 mRNA. Moreover, a subpopulation of neointimal cells localized at the luminal surface could be identified by a higher P2Y2 expression than the underlying neointimal smooth muscle cells. These data showing a strong expression of the P2Y2 purinoceptor in the neointima of injured arteries suggest that extracellular nucleotides may be involved, via this receptor, in the intimal hyperplasia and/or chronic constriction observed at the lesion site, and consequently in the restenotic process.
Abstract-Many factors have been shown to be involved in the development of hyperplasic lesions of vessels, but the role of extracellular nucleotides remains largely unknown. The presence of P2Y and P2X nucleotide receptors on arterial endothelial and smooth muscle cells suggests a potential role for nucleotides in the vessel pathophysiology. Although the role of P2X in physiology of vessels is well documented, that of P2Y is not completely understood. We recently demonstrated that extracellular nucleotides, and particularly UTP, induced migration of cultured arterial smooth muscle cells (ASMCs). This migration is dependent on osteopontin expression and involves the Rho and mitogen-activated protein (MAP) kinase pathways. An important question is to determine the specific role of the different P2Y receptors of rat ASMCs in the UTP-induced migration process. Therefore, we first quantified mRNA levels of P2Y 2 , P2Y 4 , and P2Y 6 nucleotide receptors in cultured rat ASMCs by a competitive RT-PCR approach and demonstrated that P2Y 2 is the most highly expressed among these receptors potentially involved in the UTP-mediated response. In addition to UTP, UDP also induced ASMC migration even when UTP regeneration was inhibited, suggesting the involvement of UDP receptor P2Y 6 . Moreover, suramin, a specific antagonist of rat P2Y 2 receptor, acted as an inhibitor of UTP-induced migration. Taken together, these results suggest a prominent role for the UTP receptor, P2Y 2 , and for the UDP receptor, Key Words: purinergic receptors Ⅲ migration Ⅲ UTP Ⅲ smooth muscle cells T he important role of arterial smooth muscle cell (ASMC) migration and proliferation in arterial hyperplasia is well documented in experimental models for atherosclerosis and restenosis. 1 Although proliferation can be easily demonstrated in arterial injury models, evidence for in vivo ASMC migration is suggested only by the presence of these cells in the intima.Many factors have been shown to be involved in the development of hyperplasic lesions of vessels. 2 Among these, the role of extracellular nucleotides remains largely unknown. Two families of receptors have been identified for these compounds: inotropic P2X receptors and metabotropic P2Y receptors. The presence of P2Y and P2X receptors on endothelial and ASMCs suggests a potential role for nucleotides in the arterial pathophysiology. Although the role of P2X receptors in vasomotoricity of vessels is well documented, that of P2Y receptors in the vessel wall is still under investigation.Several studies have shown that ATP and UTP binding to P2Y G protein-coupled receptors mediates ASMC activation, 3 cell-cycle progression, 4 and cell proliferation. 5,6 Moreover, we recently demonstrated that UTP induces ASMC migration and that this migration is dependent on osteopontin expression and involves the Rho and mitogen-activated protein (MAP) kinase pathways. 7 The overexpression of the ATP/UTP P2Y 2 receptor in ASMCs of rat aortic intimal lesion 8 and in ASMCs of human coronary atherosclerotic/restenotic ...
beta1- and beta2-AR, but not beta3-AR, mediate relaxation of mice pulmonary arteries. The beta2-AR component is dependent on eNOS activity and is preserved following chronic hypoxia. These data highlight the role of the beta2-AR as a pharmacological target to induce/restore endothelial NO-dependent protective effects in pulmonary circulation.
Rationale A better understanding of the mechanism underlying skeletal muscle repair is required to develop therapies that promote tissue regeneration in adults. Hedgehog signaling has been shown previously to be involved in myogenesis and angiogenesis: 2 crucial processes for muscle development and regeneration. Objective The objective of this study was to identify the role of the hedgehog transcription factor Gli3 in the crosstalk between angiogenesis and myogenesis in adults. Methods and Results Using conditional knockout mice, we found that Gli3 deficiency in endothelial cells did not affect ischemic muscle repair, whereas in myocytes, Gli3 deficiency resulted in severely delayed ischemia-induced myogenesis. Moreover, angiogenesis was also significantly impaired in HSA-CreERT2; Gli3Flox/Flox mice, demonstrating that impaired myogenesis indirectly affects ischemia-induced angiogenesis. The role of Gli3 in myocytes was then further investigated. We found that Gli3 promotes myoblast differentiation through myogenic factor 5 regulation. In addition, we found that Gli3 regulates several proangiogenic factors, including thymidine phosphorylase and angiopoietin-1 both in vitro and in vivo, which indirectly promote endothelial cell proliferation and arteriole formation. In addition, we found that Gli3 is upregulated in proliferating myoblasts by the cell cycle–associated transcription factor E2F1. Conclusions This study shows for the first time that Gli3-regulated postnatal myogenesis is necessary for muscle repair–associated angiogenesis. Most importantly, it implies that myogenesis drives angiogenesis in the setting of skeletal muscle repair and identifies Gli3 as a potential target for regenerative medicine.
Key features of asthma include bronchial hyperresponsiveness (BHR), eosinophilic airway inflammation, and bronchial remodeling, characterized by subepithelial collagen deposition, airway fibrosis, and increased bronchial smooth muscle (BSM) mass. The calcium-activated K(+) channel K(Ca)3.1 is expressed by many cells implicated in the pathogenesis of asthma, and is involved in both inflammatory and remodeling responses in a number of tissues. The specific K(Ca)3.1 blocker 5-[(2-chlorophenyl)(diphenyl)methyl]-1H-pyrazole (TRAM-34) attenuates BSM cell proliferation, and both mast cell and fibrocyte recruitment in vitro. We aimed to examine the effects of K(Ca)3.1 blockade on BSM remodeling, airway inflammation, and BHR in a murine model of chronic asthma. BALB/c mice were sensitized with intraperitoneal ovalbumin (OVA) on Days 0 and 14, and then challenged with intranasal OVA during Days 14-75. OVA-sensitized/challenged mice received TRAM-34 (120 mg/kg/day, subcutaneous) from Days -7 to 75 (combined treatment), Days -7 to 20 (preventive treatment), or Days 21 to 75 (curative treatment). Untreated mice received daily injections of vehicle (n = 8 per group). Bronchial remodeling was assessed by histological and immunohistochemical analyses. Inflammation was evaluated using bronchoalveolar lavage and flow cytometry. We also determined BHR in both conscious and anesthetized mice via plethysmography. We demonstrated that curative treatment with TRAM-34 abolishes BSM remodeling and subbasement collagen deposition, and attenuates airway eosinophilia. Although curative treatment alone did not significantly reduce BHR, the combined treatment attenuated nonspecific BHR to methacholine. This study indicates that K(Ca)3.1 blockade could provide a new therapeutic strategy in asthma.
mRNA of the P2u purinoceptor (or nucleotide receptor) is detected both by polymerase chain reaction or Northern blot analyses in cultured aortic smooth muscle cells. When added to the culture medium of these cells, UTP, a specific ligand of the P2u receptor, induces an increased expression of both immediate-early and delayed-early cell cycle-dependent genes. This induction demonstrates similar features (kinetics, concentration dependence) to those obtained after stimulation of aortic smooth cells by exogenous ATP, a common ligand for most P2 purinoceptors. In contrast, 2-methylthioATP, a preferential ligand for P2y purinoceptors, induces only a significant increase of immediate-early genes but not of delayed-early genes. Moreover, the 2-methylthioATP-induced responses (c-fos mRNA increase, free intracellular calcium transient) are lower than those induced by ATP or UTP and are complementary to those of UTP. These results demonstrate that functional P2u receptors are present on cultured aortic smooth muscle cells and suggest that the bulk of responses induced by extracellular ATP on cell cycle progression are mediated via P2u purinoceptors, a hypothesis confirmed by cytofluorometric studies. Since some ATP- or UTP-induced genes code for chemotactic proteins (monocyte chemoattractant protein-1 and osteopontin), this study suggests that these nucleotides may contribute to vascular or blood cell migration and proliferation and consequently to the genesis of arterial diseases.
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