Norma Risler

Aortic smooth muscle cell proliferation and endothelial nitric oxide synthase activity in fructose-fed rats.

The aim of this study was to evaluate the proliferative behavior of vascular smooth muscle cells in primary culture (pC-SMC) and the endothelial nitric oxide synthase (eNOS) activity in the endothelial lining of the aorta of fructose-fed rats (FFR). This is an experimental model of syndrome X, a cluster of cardiovascular risk factors including hyperinsulinemia, insulin resistance, and hypertension that has been suggested to be of pathophysiologic importance for the development of atherosclerosis. Male Wistar rats were used: Control (n = 12) and FFR (n = 12). After receiving fructose in drinking water (10% w/v) during 8 weeks, biochemical parameters, systolic blood pressure (SBP) and relative heart weight (RHW) were determined. The proliferative effect of 10% fetal calf serum (FCS) was examined in aortic pC-SMC by [3H]thymidine incorporation and by cell counting. Ca2+/calmodulin-dependent NOS activity was estimated in aortic endothelial lining and in heart tissue homogenates by conversion of [3H]arginine into [3H]citrulline. Fructose-fed rats showed hyperinsulinemia (P = .0263), altered glucose tolerance test (P < .001), higher SBP (P < .0001), and RHW (P = .0145), compared to control rats. These animals also showed an increase of 10% FCS-induced [3H]thymidine incorporation (P < .0001) and cell number of aortic pC-SMC (P = .0049) and decreased eNOS activity in both aortic endothelium (P = .0147) and cardiac tissue (P < .0001). These data support the hypothesis that syndrome X is associated to changes in SMC proliferation and endothelial dysfunction, which could be involved in the onset or progression of the atherogenic process.

Effects of enalapril on the vascular wall in an experimental model of syndrome X

Evidence links the insulin resistance syndrome with endothelial dysfunction. Previously, we have described a decreased endothelial nitric oxide synthase (eNOS) activity in both aortic endothelium and cardiac tissue, and an increased proliferation of aortic primary cultured vascular smooth muscle cells (pC-VSMCs), obtained from fructose-fed rats (FFR), an experimental model of syndrome X. Because the participation of the renin-angiotensin system (RAS) in this model is still unclear, the present study examined the effect of chronic administration of an angiotensin converting enzyme (ACE) inhibitor enalapril (E) on pC-VSMCs proliferation and eNOS activity in a conduit artery (aorta) and in resistance vessels (mesenteric vascular bed) from fructose-fed rats. Male Wistar rats were used: Control, FFR, Control + E, and FFR + E (n = 8 in each group). After 8 weeks, tissue samples were obtained and 10% fetal calf serum (FCS) proliferative effect was examined in pC-SMCs of aortic and mesenteric arteries by [(3)H]thymidine incorporation. The eNOS activity was estimated in endothelial lining from both origins by conversion of [(3)H]arginine into [(3)H]citrulline. The FFR aortic and mesenteric pC-VSMCs showed a significantly increased 10% FCS-induced [(3)H]thymidine incorporation compared to controls. The FFR aortic and mesenteric endothelium eNOS activity was significantly decreased. Chronic treatment with E abolished the increased proliferation and restored eNOS activity. These data confirm that changes in VSMCs proliferation and endothelial dysfunction at different levels of the vascular system are involved in syndrome X, and that the inhibition of angiotensin II production can revert those changes, suggesting an important role for RAS and possibly kinins, in the physiopathologic mechanism of this model of syndrome X.

Mechanisms of Cardiovascular Changes in an Experimental Model of Syndrome X and Pharmacological Intervention on the Renin-Angiotensin- System

Various cardiovascular risk factors and disease states similar to those present in type 2 diabetic patients also seem to be present in non-diabetic individuals. This cluster of risk factors has been called syndrome X, also known as metabolic cardiovascular syndrome or insulin resistance syndrome. Vascular wall components changes, including endothelial dysfunction and vascular smooth muscle cell (VSMC) migration and proliferation, could be involved in the cardiovascular alterations associated with this state. Fructose fed rats (FFR) provide a model of dietary-induced insulin resistance, which has been used to assess the pathophysiological mechanisms of the metabolic and cardiovascular changes associated to the syndrome X. FFR have hyperinsulinemia, insulin resistance (altered glucose tolerance test) and hypertriglyceridemia; they also develop moderate hypertension and cardiac hypertrophy. This has been confirmed in male rats of different strains, such as Wistar and Sprague-Dawley, chronically fed with a 60% fructose-chow or 10% fructose in the drinking water. At different levels of the cardiovascular system, FFR exhibit changes in the nitric oxide generation system and in primary cultured proliferation of VSMC from conduit and resistance arteries. These abnormalities were normalized by long-term treatment with pharmacological agents acting on the renin-angiotensin system (RAS), such as angiotensin converting-enzyme inhibitors or angiotensin-AT(1) receptor antagonists, that also lowered blood pressure to control levels and reversed cardiac hypertrophy. Evidence suggests an important role for the RAS in the pathogenic mechanisms involved in this model of syndrome X. Furthermore, beneficial pharmacological intervention seems to be mediated by AT(2) receptors and kinins.

Proteoglycan Production by Vascular Smooth Muscle Cells From Resistance Arteries of Hypertensive Rats

Extracellular matrix (ECM) modifications in the vascular wall contribute to the narrowing of arteries in hypertension. Because direct evidence for the role of proteoglycans (PGs) in the pathological process of resistance-sized arteries has not already been demonstrated, we examined the effect of growth factors on secreted and membrane-bound PG synthesis by cultured mesenteric vascular smooth muscle cells (VSMC) from spontaneously hypertensive rats (SHR) and Wistar rats. After 48 hours of stimulation with angiotensin II (Ang II), platelet-derived growth factor (PDGF-BB), and 10% fetal calf serum (FCS) or 0.1% FCS as control, PG synthesis (in dpm/ng DNA) was evaluated in the medium (M-ECM) and in the cell layer (P-ECM) by a double-isotopic label method with both [(3)H]-glucosamine and [(35)S]-sodium sulfate, which are incorporated into all complex carbohydrates or only into sulfated disaccharides, respectively. VSMC from SHR displayed a significantly lower level of synthesis of M-ECM [(3)H]-PGs than those of Wistar rats in all the experimental groups, including the control group (0. 1% FCS), but no differences in M-ECM [(35)S] uptake were found in any case. In the P-ECM, Ang II was the only factor that produced a lesser effect on [(3)H]-glucosamine and a greater effect on [(35)S]-sodium sulfate uptakes in VSMC from SHR than from Wistar rats. The most prominent change seen in VSMC from SHR was an increased sulfation, assessed by [(35)S]/[(3)H] ratio, in nonstimulated cells and in response to 10% FCS and Ang II but not to PDGF-BB compared with VSMC from Wistar rats. These data indicate the existence of changes in PG modulation in the resistance vessels of SHR, which suggests that PGs may contribute to the development of structural and functional modifications in hypertensive states.

Early changes in proteoglycans production by resistance arteries smooth muscle cells of hypertensive rats

Several functional and structural modifications at the vascular level have been described in spontaneously hypertensive rats (SHR) during the early development of hypertension. In this study, we hypothesize that changes in the extracellular matrix (ECM) could precede the development of hypertension. Synthesis of secreted and membrane-bound sulfated proteoglycans (S-PG) by cultured vascular smooth muscle cells (VSMC) obtained from young spontaneously hypertensive rats (pSHR) mesenteric resistance arteries, during the period preceding the elevation of blood pressure (BP) was tested. After 24 h of stimulation with angiotensin II (Ang II), 10% fetal calf serum (FCS), or 0.1% FCS as control, medium and cell layer S-PG synthesis was evaluated by labeling sulfated disaccharides with [35S] sodium sulfate. To relate this variable with cell proliferation, DNA synthesis was measured by incorporation of [3H]thymidine in the cell lysate. The VSMC from pSHR synthesized more secreted and membrane-bound S-PG than age-matched Wistar rat (pW) cells in the nonstimulated (0.1% FCS) and stimulated (Ang II or 10% FCS) experimental groups. When data were expressed as percent of their own control value, both Ang II and 10% FCS lowered basal secreted and cell-associated S-PG content in VSMC from pSHR, whereas in pW rat cells, these agents produced a small increase or no change. An inverse relationship between proliferation and total S-PG production (secreted plus membrane-bound) was found in pSHR cells, but not in pW cells. In conclusion, the present study demonstrates that changes in S-PG synthesis by VSMC of resistance arteries precede the vascular dysfunction associated with the development of hypertension in SHR.

MAGNESIUM : EFFECTS ON REPERFUSION ARRHYTHMIAS AND MEMBRANE POTENTIAL IN ISOLATED RAT HEARTS

The effects of Mg2+ concentration (Mg2+∘, 0, 1.2, 2.4, and 4.8 mM) on the incidence of reperfusion arrhythmias and on the cellular electrical activity were studied in spontaneously beating rat hearts. The surface electrogram and the membrane potential were recorded in control conditions, during 10 min of regional ischemia (ligature of the left anterior descending coronary artery), and on reflow. Changes in Mg2+∘ did not alter action potential morphology but the depolarization induced by ischemia decreased with increasing Mg2+∘. In hearts perfused with Mg2+ free solution or 1.2 mM subthreshold delayed afterdepolarizations (DADs) were often detected during ischemia. Moreover, DADs could be identified as initial events in the production of extrabeats or tachycardia appearing on reperfusion under these conditions. Chaotic electrical activity during fibrillation precluded the observation of DADs. The overall incidence (1 fibrillation) was similar in both groups. At high Mg2+∘, subthreshold DADs were occasionally observed during ischemia and often on reperfusion where they did not lead to the development of overt arrhythmias. Consequently, the incidence, severity, and duration of arrhythmic episodes on reflow was markedly reduced. Raising Mg2+∘ only on reperfusion did not prevent the development of arrhythmias, whose morphology in the intracellular recordings was similar to that found in hearts perfused without Mg2+ or with 1.2 mM. The recovery of sinus rhythm after 10 min of reperfusion was linearly related to Mg2+∘. Our data strengthen the view that reperfusion arrhythmias belong to the Ca2+ mediated non reentrant type and suggest that Mg2+ counteracts these arrhythmias by depressing cytosolic Ca2+ oscillations. Besides, it appears that raising Mg2+∘ reduces ischemic K+∘ accumulation. The resu ic potential of the Ca2+i oscillations induced by reperfusion.

Vascular Remodeling in Experimental Hypertension

The basic hemodynamic abnormality in hypertension is an increased peripheral resistance that is due mainly to a decreased vascular lumen derived from structural changes in the small arteries wall, named (as a whole) vascular remodeling. The vascular wall is an active, flexible, and integrated organ made up of cellular (endothelial cells, smooth muscle cells, adventitia cells, and fibroblasts) and noncellular (extracellular matrix) components, which in a dynamic way change shape or number, or reorganize in response to physiological and pathological stimuli, maintaining the integrity of the vessel wall in physiological conditions or participating in the vascular changes in cardiovascular diseases such as hypertension. Research focused on new signaling pathways and molecules that can participate in the mechanisms of vascular remodeling has provided evidence showing that vascular structure is not only affected by blood pressure, but also by mechanisms that are independent of the increased pressure. This review will provide an overview of the evidence, explaining some of the pathophysiologic mechanisms participating in the development of the vascular remodeling, in experimental models of hypertension, with special reference to the findings in spontaneously hypertensive rats as a model of essential hypertension, and in fructose-fed rats as a model of secondary hypertension, in the context of the metabolic syndrome. The understanding of the mechanisms producing the vascular alterations will allow the development of novel pharmacological tools for vascular protection in hypertensive disease.