Altered heart cytokine profile and action potential modulation in cardiomyocytes from Mas-deficient mice.

The renin-angiotensin system (RAS) is a key hormonal system. In recent years, the functional analysis of the novel axis of the RAS (ACE2/Ang-(1-7)/Mas receptor) revealed that its activation can become protective against several pathologies, including cardiovascular diseases. Mas knockout mice (Mas-KO) represent an important tool for new investigations. Indeed, extensive biological research has focused on investigating the functional implications of Mas receptor deletion. However, although the Mas receptor was identified in neonatal cardiomyocytes and also in adult ventricular myocytes, only few reports have explored the Ang-(1-7)/Mas signaling directly in cardiomyocytes to date. This study investigated the implication of Mas receptor knockout to the cytokine profile, energy metabolism, and electrical properties of mice-isolated cardiomyocytes. Here, we demonstrated that Mas-KO mice have modulation in some cytokines, such as G-CSF, IL-6, IL-10, and VEGF in the left ventricle. This model also presents increased mitochondrial number in cardiomyocytes and a reduction in the myocyte diameter. Finally, Mas-KO cardiomyocytes have altered action potential modulation after diazoxide challenge. Such electrical finding was different from the data showed for the TGR(A1-7)3292 (TGR) model, which overexpresses Ang-(1-7) in the plasma by 4.5, used by us as a control. Collectively, our findings exemplify the importance of understanding the ACE2/Ang-(1-7)/Mas pathway in cardiomyocytes and heart tissue. The Mas-KO mice model can be considered an important tool for new RAS investigations.

The antiobese effect of AT1 receptor blockade is augmented in mice lacking Mas.

We recently showed that the antiobese efficacy of the AT1 receptor blocker telmisartan (TEL) is at least partially related to an Ang(1-7)-dependent mechanism. Ang(1-7) acts via Mas, thus raising the question of whether Mas-deficient (Mas-ko) mice are likewise predisposed to develop diet-induced obesity and, further, whether this can be prevented by TEL treatment. Mas-ko mice and FVB/N wild-type (wt) animals were treated with TEL (8 mg/kg/day) or vehicle while they were fed with high-fat diet (HFD) or chow. Mice were phenotyped regarding body weight, fat mass, insulin sensitivity, and leptin sensitivity. In response to HFD feeding, gain in body weight and impairment of leptin sensitivity were similar between wt and Mas-ko mice. TEL reduced body weight in both strains but effects were stronger in Mas-ko mice. TEL diminished fat mass and restored leptin sensitivity only in Mas-ko mice. Blood glucose was higher in wt than Mas-ko mice fed with HFD while not differing when they were fed with chow. Insulin challenge confirmed that wt mice became insulin resistant when fed with HFD while HFD feeding did not impair insulin sensitivity in Mas-ko mice. TEL had no further effect. Our findings on the influence of TEL on growth and metabolism in Mas-ko mice conflict with our previous findings in rats. We assume that the FVB/N background of the mice may partly explain these inconsistent data. Moreover, it also seems feasible that the MrgD receptor compensates for Mas deficiency.