[Effects of angiotensin II and pressure on cellular fibronectin in the vascular wall in organotypic culture]. / Effets de l'angiotensine II et de la pression sur l'expression de la fibronectine cellulaire dans la paroi vasculaire en culture organotypique.

Fibronectin is a dimeric glycoprotein found in the extracellular matrix of most tissues, which can influence processes, including cell growth, adhesion and migration. Fibronectin synthesis has been shown to be overexpressed in hypertension. However, the respective effects of humoral factors, including angiotensin II, versus mechanical factors in vascular remodeling have not yet been clarified. To study fibronectin de novo synthesis in the arterial wall, we have developed a new model for organ culture of rabbit thoracic aorta. Arteries held at their in vivo length were incubated and perfused (40 ml/min) in DME medium containing antibiotics, supplemented with 20% fetal calf serum or with 5% bovine serum albumin. In a series of experiments, angiotensin II (10(-6) M) and indomethacin (10(-5) M) were added to culture media. Vessels were pressurized at 0, 80 or 150 mmHg, and kept for 3 days in incubator at 37 degrees C under 5% CO2. De novo synthesis of fibronectin was detected by immunofluorescence using anti-cellular fibronectin antibodies (1/200). In the absence of angiotensin II and serum, fibronectin was expressed in the sub-endothelium at 80 mmHg, and in the inner media at 150 mmHg. In the presence of serum, fibronectin expression was increased by the high pressure. When angiotensin II was added, a gradient of fibronectin became apparent in the inner media at 80 mmHg with a marked expression at the luminal side. Angiotensin II markedly enhanced fibronectin expression at 150 mmHg, the protein being detected in almost the whole media. Our results indicate that both angiotensin II and transmural pressure can induce fibronectin expression in the arterial wall, and both act synergically.

Intraluminal pressure is essential for the maintenance of smooth muscle caldesmon and filamin content in aortic organ culture.

Different forms of mechanical stimulation are among the physiological factors constantly acting on the vessel wall. We previously demonstrated that subjecting vascular smooth muscle cells (VSMCs) in culture to cyclic stretch increased the expression of high-molecular-weight caldesmon, a marker protein of a differentiated, contractile, VSMC phenotype. In the present work the effects of mechanical factors, in the form of circumferential stress and shear stress, on the characteristics of SM contractile phenotype were studied in an organ culture of rabbit aorta. Application of an intralumininal pressure of 80 mm Hg to aortic segments cultured in Dulbecco's modified Eagle's medium containing 20% fetal calf serum for 3 days prevented the decrease in high-molecular-weight caldesmon content (70+/-4% of initial level in nonpressurized vessel, 116+/-17% at 80 mm Hg) and filamin content (80+/-5% in nonpressurized vessel, 100+/-2% at 80 mm Hg). SM myosin and low-molecular-weight caldesmon contents showed no dependence on vessel pressurization. Neither endothelial denudation nor alteration of intraluminal flow rates affected marker protein content in 3-day vessel culture, thus excluding the possibility of any shear or endothelial effects. Maintenance of high high-molecular-weight caldesmon and filamin levels in the organ cultures of pressurized and stretched vessels demonstrates the positive role of mechanical factors in the control of the VSMC differentiated phenotype.

Free-flow electrophoresis for fractionation of Arabidopsis thaliana membranes.

Highly purified tonoplast and plasma membrane vesicles were isolated from microsomes of Arabidopsis thaliana by preparative free-flow electrophoresis. The most electronegative fractions were identified as tonoplast using nitrate-inhibited Mg2+-ATPase as enzyme marker. The least electronegative fractions were identified as plasma membrane using glucan-synthase II, UDPG: sterol-glucosyl-transferase, and vanadate-inhibited Mg2+-ATPase as enzyme markers. Other membrane markers, latent inosine-5'-diphosphatase (Golgi), NADPH-cytochrome-c reductase (endoplasmic reticulum) and cytochrome-c oxidase (mitochondria) were recovered in the fractions intermediate between tonoplast and plasma membrane. Immunoblot analysis of membrane fractions by antibodies directed against tonoplast and plasma membrane proteins confirmed the nature and the purity of the isolated membranes. The cytoskeletal protein actin, which was also identified by immunoblotting, was found to be specifically attached to the plasma membrane vesicles. The structural and functional integrity of the isolated membranes from Arabidopsis thaliana is discussed in the light of results obtained for the location of receptors and enzymes, or for the determination of ligand binding activity.

Differential effects of pressure and flow on DNA and protein synthesis and on fibronectin expression by arteries in a novel organ culture system.

Structural adaptation of the blood vessel wall occurs in response to mechanical factors related to blood pressure and flow. To elucidate the relative roles of pressure, flow, and medium composition, we have developed a novel organ culture system in which rabbit thoracic aorta, held at in vivo length, can be perfused and pressurized at independently varied flow and pressure for several days. Histology and histomorphometry, as well as scanning electron microscopy, revealed a well-preserved wall structure. In arteries perfused and pressurized at 80 mm Hg, endothelial injury led to a 2-fold increase in [3H]thymidine incorporation in the media, which peaked at 3 to 5 days and returned to baseline level at 6 to 8 days. In intact endothelialized vessels cultured for 3 days under no-flow conditions, pressure per se had no effect on DNA synthesis. In contrast, in the presence of serum, total protein synthesis, as assessed by [35S]methionine incorporation into the media, was enhanced 6-fold at 150 mm Hg compared with vessels pressurized at 0 or 80 mm Hg. In intact vessels perfused at a constant flow of 40 mL/min for 3 days, DNA synthesis was unchanged regardless of the pressure level when vessels were cultured in the presence of serum but increased 8-fold at both 80 and 150 mm Hg in the absence of serum. Unlike DNA synthesis, total protein synthesis was enhanced 12-fold by flow regardless of the presence or absence of serum. Expression of fibronectin was markedly enhanced at high transmural pressure, and serum potentiated its expression in the arterial wall. This novel organ culture system of perfused and pressurized vessels allowed identification of differential effects of pressure, flow, and serum on DNA and total protein synthesis, including cellular fibronectin expression.

Pressure and angiotensin II synergistically induce aortic fibronectin expression in organ culture model of rabbit aorta. Evidence for a pressure-induced tissue renin-angiotensin system.

Aortic fibronectin (FN) expression is augmented in hypertension. Increasing evidence suggests that both angiotensin II (Ang II) and mechanical factors may induce vascular remodeling in response to hypertension. We have previously shown that, in vitro, increased transmural pressure enhances FN expression in rabbit aortic media. To investigate the existence of a link between the effects of pressure and Ang II and to explore the mechanisms underlying such a relationship, we quantified the effect of Ang II and Ang II inhibitors on the pressure-dependent FN expression in a 3-day organ culture model of rabbit aorta using immunolabeling analysis and detected FN mRNAs by in situ hybridization. A dose-dependent effect of Ang II on FN expression was observed at both 80 and 150 mm Hg but not at 0 mm Hg (relaxed vessels). One mumol/L Ang II increased the media cross-sectional surface, showing FN expression from 7.9 +/- 0.7% (n = 9) to 18.9 +/- 1.1% (n = 4) at 80 mm Hg (P < .01) and from 17.4 +/- 1.8% (n = 9) to 56.6% +/- 3.6 (n = 4) at 150 mm Hg (P < .001). In situ hybridization revealed that Ang II and pressure upregulated FN mRNA expression. Losartan, an AT1 antagonist, not only blocked the Ang II effect but also inhibited the transmural pressure effect. Angiotensin-converting enzyme inhibition abolished the pressure-dependent FN expression and significantly diminished the effect of pressure in the presence of Ang II. The effect of renin-angiotensin system inhibitors was specific for FN, since neither bFGF nor laminin expression was affected by these agents. Taken together, the results demonstrate that (1) the effect of transmural pressure is mediated by the stimulation of a local renin-angiotensin system, resulting in a net Ang II production in the culture medium, (2) transmural pressure and Ang II act synergistically to enhance vascular FN expression, (3) AT1 receptors mediate both the effects of pressure and of exogenous Ang II, and (4) the effect of Ang II on FN expression is regulated at a pretranslational level.