Nebivolol induces calcium-independent signaling in endothelial cells by a possible beta-adrenergic pathway.

Nebivolol is a highly selective beta1-adrenoreceptor-blocking agent with a peculiar pharmacodynamic profile. It has peripheral acute vasodilating properties that are mediated by modulation of the endogenous production of nitric oxide. In this study we analyzed the different signaling pathways implicated in the response of human umbilical vein endothelial cells to nebivolol. Its effect on endothelial transduction pathways was determined by assaying phospholipase C and A2 activities and cyclic adenosine monophosphate (AMP) production. Variations in intracellular calcium concentration were also measured. Our results showed that nebivolol activates a calcium-independent transduction pathway that implicates an increase in adenylate cyclase and phospholipase A2 activity. Beta1- or beta2-Adrenoreceptor antagonists do not inhibit the action of nebivolol. However, its action on cyclic AMP production is inhibited by bupranolol, a beta1-3-adrenoreceptor antagonist, and S-(-)-cyanopindolol, a selective beta3-adrenoreceptor antagonist. Nebivolol also dose-dependently increased nitrite production. This effect was inhibited by bupranolol, suggesting that the possible action of nebivolol on beta3-adrenoreceptor is involved in its vasodilating properties. This study suggests that nebivolol could behave as a beta3-adrenoreceptor agonist and induce some calcium-independent pathways implicating phospholipase A2 and adenylate cyclase. This agonistic activity of nebivolol seems to be responsible for its endothelium-dependent vasodilating activity.

Increasing endothelial cell permeability improves the efficiency of myocyte adenoviral vector infection.

BACKGROUND: Gene delivery to the myocardium using blood-borne adenoviral vectors is hindered by the endothelium, which represents a barrier limiting the infection rate of underlying myocytes. However, endothelial permeability may be modulated by pharmacological agents. METHODS: In the present study, we modeled the endothelial barrier in vitro using a human umbilical vein endothelial cell (HUVEC) monolayer seeded on a Transwell membrane as a support and diffusion of fluorescent dextrans as a permeability index. We used alpha-thrombin (100 nM) as a pharmacological agent known to increase endothelial permeability and tested the barrier function of the endothelial cell monolayer on adenovector-mediated luciferase gene transfer to underlying isolated cardiac myocytes. RESULTS: A confluent HUVEC monolayer represented a considerable physical barrier to dextran diffusion; it reduced the permeability of the micropore membrane alone to fluorescein isothiocyanate (FITC)-labeled dextrans of molecular weights 4, 70, 150 and 2000 kDa by approximately 54, 78, 88 and 98%, respectively. Alpha-thrombin (100 nM) increased the permeability coefficients (P(EC)) by 276, 264, 562 and 4166% for the same dextrans, respectively. A confluent HUVEC monolayer represented a major impediment to adenovector-mediated luciferase gene transfer to cardiac myocytes, largely reducing gene transfer efficiency. However thrombin induced a nine-fold increase in myocyte infection. CONCLUSION: In our model, the endothelial cell monolayer represents a major impediment to myocyte adenovector-mediated gene transfer which can be partially improved by pharmacologically increasing endothelial permeability. The Transwell model is therefore particularly useful for testing the efficiency of pharmacological agents in modulating adenovector passage through the endothelial barrier.

Shear stress induces iNOS expression in cultured smooth muscle cells: role of oxidative stress.

After deendothelialization, the most luminal smooth muscle cells of the neointima are in contact with blood flow and express inducible nitric oxide synthase (iNOS) in vivo. We hypothesized that shear stress may be a stimulus for this iNOS overexpression. We have thus submitted smooth muscle cells to laminar shear and measured the iNOS expression. Shear stress (20 dyn/cm(2)) induced iNOS mRNA and protein expression, whereas brain NOS mRNA expression was decreased. Conversely, nitrite production was increased. This production was blocked by a selective iNOS inhibitor. Pyrrolidine dithiocarbamate, an antioxidant molecule, and BXT-51072, a gluthation peroxidase mimic, both inhibited the shear-induced iNOS expression. Shear stress also increased the expression of both membrane subunits of NADPH oxidase p22(phox) and Mox-1. Shear stress activated the redox-sensitive nuclear translocation of the transcription nuclear factor-kappaB (NF-kappaB) and stimulated the degradation of both cytosolic inhibitors kappaB alpha and beta. These results show that shear stress can induce iNOS expression and nitrite production in smooth muscle cells and suggest that this regulation is probably mediated by oxidative stress-induced NF-kappaB activation.

Shear stress induces angiotensin converting enzyme expression in cultured smooth muscle cells: possible involvement of bFGF.

OBJECTIVE: Hemodynamic stresses are considered to be important regulators of gene expression in vascular cells. In this study, we have investigated the role of shear stress on ACE expression in cultured rat vascular cells, and focused on the regulation of ACE expression in smooth muscle cells. METHODS: Rat aortic endothelial cells, smooth muscle cells and fibroblasts isolated from Wistar rats were submitted to shear stress using a laminar shear flow parallel chamber. RESULTS: A 10 dynes/cm2 shear rate for 24 h increased ACE activity in the three vascular cell types (x 2.14 in endothelial cells, x 2.9 in smooth muscle cells, x 3.33 in fibroblasts). This induction was blocked by a 24 h pre-incubation with a translation blocker (10(-4)M cycloheximide) showing the role of protein neosynthesis. Therefore the study was focused on smooth muscle cells and we demonstrated that the increase in ACE activity was due to an elevation in ACE mRNA level in response to a 10 dynes/cm2 shear stress for 24 h. This induction was dependent on the shear intensity (P < 0.0001). Six hours of a 15 dynes/cm2 shear stress showed no effect on ACE activity or mRNA expression. In contrast, the same duration of shear significantly increased bFGF mRNA level (x 3.7). Conversely, bFGF dose dependently increased ACE mRNA expression and activity in smooth muscle cells. This result suggests that bFGF could be one of the potential inductors of ACE expression in the stressed smooth muscle cells. CONCLUSIONS: Mechanical stress increases ACE expression in vascular cells. bFGF could be one of the potential factors involved in this activation. This phenomenon could participate in the role of ACE activity in vascular wall remodeling.