Renovascular Hypertension Induces Myocardial Mitochondrial Damage, Contributing to Cardiac Injury and Dysfunction in Pigs With Metabolic Syndrome.

BACKGROUND: Renovascular hypertension (RVH) often manifest with metabolic syndrome (MetS) as well. Coexisting MetS and hypertension increases cardiovascular morbidity and mortality, but the mechanisms underlying cardiac injury remain unknown. We hypothesized that superimposition of MetS induces myocardial mitochondrial damage, leading to cardiac injury and dysfunction in swine RVH. METHODS: Pigs were studied after 16 weeks of diet-induced MetS with or without RVH (unilateral renal artery stenosis), and Lean controls (n = 6 each). Systolic and diastolic cardiac function were assessed by multidetector CT, and cardiac mitochondrial morphology (electron microscopy) and myocardial function in tissue and isolated mitochondria. RESULTS: Body weight was similarly higher in MetS groups vs. Lean. RVH groups achieved significant stenosis and developed hypertension. Mitochondrial matrix density and adenosine triphosphate production were lower and H2O2 production higher in RVH groups vs. Lean and MetS. Lean + RVH (but not MetS + RVH) activated mitophagy, which was associated with decreased myocardial expression of mitophagy-related microRNAs. MetS groups exhibited higher numbers of intermitochondrial junctions, which could have prevented membrane depolarization/activation of mitophagy in MetS + RVH. Cardiac fibrosis, hypertrophy (increased left ventricular muscle mass), and diastolic function (decreased E/A ratio) were greater in MetS + RVH vs. Lean + RVH. CONCLUSIONS: MetS+RVH induces myocardial mitochondrial damage and dysfunction. MetS + RVH failed to activate mitophagy, resulting in greater cardiac remodeling, fibrosis, and diastolic dysfunction. Mitochondrial injury and impaired mitophagy may constitute important mechanisms and therapeutic targets to ameliorate cardiac damage and dysfunction in patients with coexisting MetS and RVH.

Evaluation of density and distribution of CART-immunoreactive structures in gastrointestinal tract of hypertensive rats.

The prevalence of CART (cocaine- and amphetamine-regulated transcript) throughout the organism, multiplicity of functions fulfilled by that peptide, and the collected evidence confirming CART contribution to blood pressure regulation prompted us to undertake the research aiming to identify, localize, and assess changes in CART-immunopositive structures of the gastrointestinal tract (GI tract) of rats with renovascular hypertension. The two-kidney one-clip model of arterial hypertension was used to evaluate the location and density of CART-containing structures in the stomach (cardia, fundus, and pylorus), duodenum, jejunum, ileum, and colon of hypertensive rats. The study was carried out on the GI tract of 20 rats. Ten rats were subjected to the renal artery clipping procedure and after a 6-week period each of them developed stable hypertension. An immunohistochemical localization of CART was performed on paraffin GI tract sections from all the study animals. CART was detected in the extensive population of neurons, particularly within the myenteric plexuses all along the GI tract, and also in neuroendocrine cells, being especially numerous in the stomach and a few in the small intestine. The hypertension significantly increased the density of CART-positive structures in the rat GI tract. The differences between the hypertensive rats and the control animals concerned not only the density of CART-immunoreactive structures but also the staining intensity. As this study provides novel findings, we are planning further molecular examinations to better understand the impact of hypertension on the functioning and activity of CART in the GI tract.

Norepinephrine kinetics in dogs with experimentally induced renal vascular hypertension.

OBJECTIVE: To determine norepinephrine (NE) kinetics in dogs with experimentally induced renal vascular hypertension. ANIMALS: 4 mixed-breed dogs. PROCEDURE: The study comprised a control and hypertensive period. The hypertensive period followed induction of renal vascular hypertension achieved by surgical placement of clips on both renal arteries to reduce diameter by approximately 80%. Arterial blood pressure, renal clearance, and NE kinetics were measured during each period while dogs were receiving a low-sodium diet. Measurements of NE kinetics and renal clearance during the hypertensive period were made 5 days after induction of hypertension. RESULTS: Five days after induction of hypertension, arterial blood pressure increased by 15 to 20 mm Hg. Mean (+/- SEM) plasma NE concentration and NE spillover rate increased significantly from 151.5+/-14.1 pg/ml and 8.03+/-0.62 ng/kg/min, respectively, during the control period to 631.4+/-30.5 pg/ml and 54.0+/-5.2 ng/kg/min, respectively, during the hypertensive period. Norepinephrine clearance rate also increased (54.0+/-2.4 vs. 86.0+/-9.3 ml/kg/min). Positive associations between mean arterial pressure (MAP) and NE concentration and spillover rate were detected. However, MAP and NE clearance rate were not associated. CONCLUSIONS AND CLINICAL RELEVANCE: Increased blood pressure during the hypertensive period was likely attributable to increased NE spillover rate, which resulted in a significant increase in plasma NE concentration. Analysis of these results suggests that central sympathetic outflow was increased and may be responsible for the pathogenesis of high blood pressure during the acute phase of renal vascular hypertension in dogs.

Níveis séricos dos íons sódio, potássio e cálcio e variaçäo de massa dos ventrículos e rim de ratos com hipertensäo renovascular e/ou submetidos à remoçäo das glândulas submandibulares e sublinguais / Effects of hipertension and/or surgical removal of salivary glands on blood serum concentrations of sodium, potassium and calcium ions and ventricles and kidney in rats

O objetivo deste trabalho é verificar as concentraçöes iônicas de sódio, potássio e cálcio no soro, assim como as massas dos ventrículos e rim de ratos machos (Rattus norvegicus albinus, Wistar) divididos em 4 (quatro) grupos de trabalho, a saber: I. Controle; II. Sem glândulas submandibulares e sublinguais; III. Hipertenso; IV. Hipertenso sem glândulas submandibulares e sublinguais. O modelo para produçäo da hipertensäo foi o de Goldblatt um rim, um "clip". Em relaçäo ao grupo controle (normotenso), observamos alteraçöes nas concentraçöes dos íons sódio (aumento nos grupos II e IV), potássio (aumento nos grupos II e III) e cálcio (diminuiçäo nos grupos III e IV) e nas massas dos ventrículos e do rim esquerdo (aumento nos grupos III e IV) atribuídas à hipertensäo, à remoçäo cirúrgica das glândulas submandibulares e sublinguais e às duas manobras concomitantes