From mitochondria to disease: role of the renin-angiotensin system.

Mitochondria are energy-producing organelles that conduct other key cellular tasks. Thus, mitochondrial damage may impair various aspects of tissue functioning. Mitochondria generate oxygen- and nitrogen-derived oxidants, being themselves major oxidation targets. Dysfunctional mitochondria seem to contribute to the pathophysiology of hypertension, cardiac failure, the metabolic syndrome, obesity, diabetes mellitus, renal disease, atherosclerosis, and aging. Mitochondrial proteins and metabolic intermediates participate in various cellular processes, apart from their well-known roles in energy metabolism. This emphasizes the participation of dysfunctional mitochondria in disease, notwithstanding that most evidences supporting this concept come from animal and cultured-cell studies. Mitochondrial oxidant production is altered by several factors related to vascular pathophysiology. Among these, angiotensin-II stimulates mitochondrial oxidant release leading to energy metabolism depression. By lowering mitochondrial oxidant production, angiotensin-II inhibition enhances energy production and protects mitochondrial structure. This seems to be one of the mechanisms underlying the benefits of angiotensin-II inhibition in hypertension, diabetes, and aging rodent models. If some of these findings can be reproduced in humans, they would provide a new perspective on the implications that RAS-blockade can offer as a therapeutic strategy. This review intends to present available information pointing to mitochondria as targets for therapeutic Ang-II blockade in human renal and CV disease.

Angiotensin II blockade improves mitochondrial function in spontaneously hypertensive rats.

Angiotensin II can induce oxidant stress by stimulating vascular superoxide production. Hypertension promotes mitochondrial function decline in brain, liver and heart. The aim of this study was to investigate whether a) hypertension is associated to kidney mitochondrial dysfunction, and b) angiotensin II blockade can reverse potential mitochondrial changes in hypertension. Four-month-old male spontaneously hypertensive rats (SHR) received drinking water containing candesartan (7.5 mg/kg/day, SHR+Cand), or no additions (SHR) for 4-months. Eight-month-old Wistar-Kyoto rats (WKY), that received water with no additions, were used as control. Systolic blood pressure, proteinuria, cortical glomerular area, and glomerular and tubulointerstitial alpha-smooth muscle actin labeling, were significantly higher, and creatinine clearance was significantly lower, in SHR relative to WKY and SHR+Cand. In SHR, kidney mitochondria membrane potential, and nitric oxide synthase and cytochrome oxidase activities were significantly lower than in WKY and SHR+Cand. In SHR, mitochondrial hydrogen peroxide production was significantly higher than in WKY and SHR+Cand. The results suggest that, in hypertension, increased mitochondrial oxidant production may mediate kidney mitochondria dysfunction. Candesartan preserved mitochondrial function, probably favoring the maintenance of adequate cellular and tissue function in the kidney. The known renal protective effects of candesartan in hypertension may be related to the improvement of mitochondrial function. This may be an additional or alternative explanation for some of the beneficial effects of AT1 receptor antagonists.