Ellagic Acid prevents vascular dysfunction in small mesenteric arteries of ovariectomized hypertensive rats.

Cardiovascular diseases rank the top causes of death worldwide, with a substantial increase in women compared to men. Such increase can beexplained by the drastic decrease in 17-ß-estradiol hormone during menopause and associated with endothelium-dependent vascular dysfunction. The current treatments for cardiovascular diseases (e.g., hypertension), are only palliative and therefore, feasible, non-invasive options for preventing further vascular damage are needed. The polyphenol ellagic acid (EA) has risen as a candidate with possible vascular protection properties. This study evaluated the effects of EA in small mesenteric arteries of ovariectomized spontaneously hypertensive rats. Our findings showed that EA oral treatment for 4 weeks preserved vasodilation endothelial-dependent in acetylcholine pre-constricted arteries of spontaneously hypertensive rats to the same extent as 17-ß-estradiol treatment, an effect that was abolished in the presence of the nitric oxide synthase inhibitor L-NitroG-L-Arginine Methyl Ester. Moreover, EA induced vascular nitric oxide release, by increasing both the activitation site phosphorylation and total levels of the endothelial nitric oxide synthase. Finally, EA decreased superoxide anion while increased total levels of the antioxidant enzymes Superoxide Dismutase 2 and catalase. We concluded that EA has vasodilation properties acting via endothelial nitric oxide synthase activation and a potential antioxidant effect by stimulating the Superoxide Dismutase 2-catalase pathway.

Ellagic acid prevents myocardial infarction-induced left ventricular diastolic dysfunction in ovariectomized rats.

Estrogen deficiency is associated with increased oxidative stress, which can contribute to left ventricular diastolic dysfunction (LVDD). We hypothesized that oral treatment with ellagic acid (EA), a potent and natural antioxidant compound, can improve MI-induced LVDD in ovariectomized rats, by reducing the formation of reactive oxygen species. Ovariectomized rats MI-induced LVDD followed by treatment with vehicle (DD) or EA (DD + EA) for 4 weeks. Non-LVDD-induced rats treated with vehicle (S) or EA (S + EA) were used as controls. Left ventricular systolic pressure; left ventricular end-diastolic pressure (LVEDP); maximum rate of pressure rise: +dP/dt and fall: -dP/dt) were evaluated in all animals after treatment. Left ventricle superoxide anion formation was quantified in situ by fluorescence. Phospho-CAMKII, SOD2, catalase, and gp91-phox abundances were evaluated by Western blot analyses. SOD (superoxide dismutase) and catalase activities were measured by spectrophotometry. The results showed that the LVEDP was significantly increased in both DD and DD + EA groups compared to S and S + EA. However, LVEDP in the DD + EA group was significantly decreased compared to DD, indicating an EA-mediated effect. In the DD group, superoxide production and gp91-phox protein abundance were increased while SOD2 abundance was decreased when compared to the S and S + EA groups. An increase in SOD activity was also observed in the DD + EA group. EA treatment reduced CaMKII phosphorylation in the DD + EA group compared to the DD. We concluded that EA treatment attenuated diastolic dysfunction in our experimental model, via reduction of reactive oxygen species and CaMKII activity, indicating EA as a promising natural therapeutic option for cardiac dysfunction.

Anti-fibrotic mechanisms of angiotensin AT2 -receptor stimulation.

The angiotensin AT2 -receptor is a main receptor of the protective arm of the renin-angiotensin system. Understanding of this unconventional G-protein coupled receptor has significantly advanced during the past decade, largely because of the availability of a selective non-peptide AT2 -receptor agonist, which allowed the conduct of a multitude of studies in animal disease models. This article reviews such preclinical studies that in their entirety provide strong evidence for an anti-fibrotic effect mediated by activation of the AT2 -receptor. Prevention of the development of fibrosis by AT2 -receptor stimulation has been demonstrated in lungs, heart, blood vessels, kidney, pancreas and skin. In lungs, AT2 -receptor stimulation was even able to reverse existing fibrosis. The article further discusses intracellular signalling mechanisms mediating the AT2 -receptor-coupled anti-fibrotic effect, including activation of phosphatases and subsequent interference with pro-fibrotic signalling pathways, induction of matrix-metalloproteinases and hetero-dimerization with the AT1 -receptor, the TGF-ßRII-receptor or the RXFP1-receptor for relaxin. Knowledge of the anti-fibrotic effects of the AT2 -receptor is of particular relevance because drugs targeting this receptor have entered clinical development for indications involving fibrotic diseases.

The acute blood pressure-lowering effect of amiloride is independent of endothelial ENaC and eNOS in humans and mice.

AIMS: The epithelial sodium channel (ENaC) is expressed in cultured endothelial cells and inhibitory coupling to eNOS activity has been proposed. The present study tested the hypothesis that ENaC blockers increase systemic NO-products and lower blood pressure in patients and mice, depending on eNOS. METHODS: NO-products and cGMP were measured in diabetes patient urine and plasma samples before and after amiloride treatment (20-40 mg for two days, plasma n = 22, urine n = 12 and 5-10 mg for eight weeks, plasma n = 52, urine n = 55). Indwelling catheters were implanted in the femoral artery and vein in mice for continuous arterial blood pressure and heart rate recordings and infusion. RESULTS: Treatment with amiloride for two days increased plasma and urine NO-products, while plasma cGMP decreased and urinary cGMP was unchanged in patient samples. Eight weeks of treatment with amiloride did not alter NO-products and cGMP. In mice, amiloride boli of 5, 50, and 500 µg/kg lowered heart rate and arterial blood pressure significantly and acutely. Benzamil had no effect on pressure and raised heart rate. In hypertensive eNOS-/- and L-NAME-treated mice, amiloride lowered blood pressure significantly. L-NAME infusion significantly decreased NO-products in plasma; amiloride and eNOS-deletion had no effect. An acetylcholine bolus resulted in acute blood pressure drop that was attenuated in eNOS-/- and L-NAME mice. ENaC subunit expressions were not detected consistently in human and mouse arteries and endothelial cells. CONCLUSION: Amiloride has an acute hypotensive action not dependent on ENaC and eNOS and likely related to the heart.

New components of the renin-angiotensin system: alamandine and the MAS-related G protein-coupled receptor D.

The renin-angiotensin system is an important component of the central and humoral mechanisms of blood pressure and hydro-electrolytic balance control. Angiotensin II is a key player of this system. Twenty-five years ago the first manuscripts describing the formation and actions of another peptide of the RAS, angiotensin-(1-7), were published. Since then several publications have shown that angiotensin-(1-7) is as pleiotropic as angiotensin II, influencing the functions of many organs and systems. The identification of the ACE homologue ACE2 and, a few years later, Mas, as a receptor for angiotensin-(1-7) contributed a great deal to establish this peptide as a key player of the RAS. Most of the actions of angiotensin-(1-7) are opposite to those described for angiotensin II. This has led to the concept of two arms of the RAS: one comprising ACE/AngII/AT1R and the other ACE2/Ang-(1-7)/Mas. More recently, we have described the identification of a novel component of the RAS, alamandine, which binds to the Mas-related G protein coupled receptor D. This peptide is formed by decarboxylation of the Asp residue of angiotensin-(1-7), leading to the formation of Ala as the N-terminal amino acid. Alternatively, it can be formed by hydrolysis of Ang A, by ACE2. Its effects include vasorelaxation, central effects similar to those produced by angiotensin-(1-7), blunting of isoproterenol-induced heart fibrosis, and anti-hypertensive action in SHR. The putative enzyme responsible for alamandine formation from angiotensin-(1-7) is under investigation. The identification of this novel component of the RAS opens new venues for understanding its physiological role and opens new putative therapeutic possibilities for treating cardiovascular diseases.

The novel Mas agonist, CGEN-856S, attenuates isoproterenol-induced cardiac remodeling and myocardial infarction injury in rats.

CGEN-856S is a novel Mas agonist. Herein, we examined the effects of this peptide on isoproterenol (ISO)-induced cardiac remodeling and myocardial infarction (MI) injury. We also sought to determine whether CGEN-856S activates the underlying mechanisms related to Mas receptor activation. Heart hypertrophy and fibrosis were induced by ISO (2 mg·kg(-1)·day(-1)) in Wistar rats. After a 7-day treatment period with CGEN-856S (90 µg·kg(-1)·day(-1)) or vehicle, the cardiomyocyte diameter was evaluated in left ventricular sections stained with hematoxylin and eosin, and immunofluorescence labeling and quantitative confocal microscopy were used to quantify the deposition of type I and III collagen and fibronectin in the left ventricles. MI was induced by coronary artery ligation, and CGEN-856S (90 µg·kg(-1)·day(-1)) or saline was administered for 14 days. The Langendorff technique was used to evaluate cardiac function, and left ventricular sections were stained with Masson's trichrome dye to quantify the infarct area. Using Chinese hamster ovary cells stably transfected with Mas cDNA, we evaluated whether CGEN-856S alters AKT and endothelial nitric oxide synthase (eNOS) phosphorylation. CGEN-856S reduced the degree of ISO-induced hypertrophy (13.91±0.17 µm vs. 12.41±0.16 µm in the ISO+CGEN-856S group). In addition, the Mas agonist attenuated the ISO-induced increase in collagen I, collagen III, and fibronectin deposition. CGEN-856S markedly attenuated the MI-induced decrease in systolic tension, as well as in +dT/dt and -dT/dt. Furthermore, CGEN-856S administration significantly decreased the infarct area (23.68±2.78% vs. 13.95±4.37% in the MI+CGEN-856S group). These effects likely involved the participation of AKT and NO, as CGEN-856S administration increased the levels of p-AKT and p-eNOS. Thus, our results indicate that CGEN-856S exerts cardioprotective effects on ISO-induced cardiac remodeling and MI-mediated heart failure in rats through a mechanism likely involving the eNOS/AKT pathway.