Malnutrition during critical periods in early life may increase the subsequent risk of hypertension and metabolic diseases in adulthood, but the underlying mechanisms are still unclear. We aimed to evaluate the effects of post-weaning protein malnutrition on blood pressure and vascular reactivity in aortic rings (conductance artery) and isolated-perfused tail arteries (resistance artery) from control (fed with Labina®) and post-weaning protein malnutrition rats (offspring that received a diet with low protein content for three months). Systolic and diastolic blood pressure and heart rate increased in the post-weaning protein malnutrition rats. In the aortic rings, reactivity to phenylephrine (10−10–3.10−4 M) was similar in both groups. Endothelium removal or L-NAME (10−4 M) incubation increased the response to phenylephrine, but the L-NAME effect was greater in the aortic rings from the post-weaning protein malnutrition rats. The protein expression of the endothelial nitric oxide isoform increased in the aortic rings from the post-weaning protein malnutrition rats. Incubation with apocynin (0.3 mM) reduced the response to phenylephrine in both groups, but this effect was higher in the post-weaning protein malnutrition rats, suggesting an increase of superoxide anion release. In the tail artery of the post-weaning protein malnutrition rats, the vascular reactivity to phenylephrine (0.001–300 µg) and the relaxation to acetylcholine (10−10–10−3 M) were increased. Post-weaning protein malnutrition increases blood pressure and induces vascular dysfunction. Although the vascular reactivity in the aortic rings did not change, an increase in superoxide anion and nitric oxide was observed in the post-weaning protein malnutrition rats. However, in the resistance arteries, the increased vascular reactivity may be a potential mechanism underlying the increased blood pressure observed in this model.
1. Chronic ouabain administration increases blood pressure and produces a positive inotropic effect. However, the temporal changes capable of affecting both arterial and ventricular pressures and myosin ATPase activity during the induced hypertension have not been determined. 2. The aim of the present study was to investigate the time-course of the induction of hypertension to define when changes occur in Wistar rats treated with 25 mg/kg per day, s.c., ouabain for 3, 7, 15 or 30 days. 3. In anaesthetized rats, diastolic blood pressure increased after 7 days treatment with ouabain and after 15 and 30 days treatment, increases were observed in systolic blood pressure, left ventricular systolic pressure and myosin ATPase activity. After 15 days treatment, heart rate (HR) also increased, but after 30 days treatment HR returned to control levels. However, only after 30 days treatment did the left ventricular positive and negative first derivatives of intraventricular pressure (dP/dt(max) and dP/dt(min), respectively) increase. Increased arterial and left ventricular systolic pressures and myosin ATPase activity observed after 15 days treatment maintained similar levels as those after 30 days treatment. 4. The results suggest that changes in arterial and left ventricular pressures, HR and myosin ATPase activity induced by chronic ouabain treatment are time dependent, increasing after 15 days treatment. After 30 days treatment, the increase in systolic and diastolic arterial and ventricular pressures remained stable, as did inotropism. Normalization of HR after 30 days treatment suggests that during the period from Day 16 to Day 30 ouabain-induced hypertension is dependent, at least in part, on increased sympathetic activity.
Background: Our aim was to evaluate the effects of soybean oil treatment for 15 days on arterial and ventricular pressure, myocardial mechanics and proteins involved in calcium handling.
Methods:Wistar rats were divided in two groups receiving 100 μL of soybean oil (SB) or saline (CT) i.m. for 15 days. Ventricular performance was analyzed in male 12-weeks old Wistar rats by measuring left ventricle diastolic and systolic pressure in isolated perfused hearts according to the Langendorff technique. Protein expression was measured by Western blot analysis.Results: Systolic and diastolic arterial pressures did not differ between CT and SB rats. However, heart rate was reduced in the SB group. In the perfused hearts, left ventricular isovolumetric systolic pressure was higher in the SB hearts. The inotropic response to extracellular Ca 2+ and isoproterenol was higher in the soybean-treated animals than in the control group. Myosin ATPase and Na + -K + ATPase activities, the expression of sarcoplasmic reticulum calcium pump (SERCA2a) and sodium calcium exchanger (NCX) were increased in the SB group. Although the phosfolamban (PLB) expression did not change, its phosphorylation at Ser 16 was reduced while the SERCA2a/PLB ratio was increased.
Conclusions:In summary, soybean treatment for 15 days in rats increases the left ventricular performance without affecting arterial blood pressure. These changes might be associated with an increase in the myosin ATPase activity and SERCA2a expression.
Ouabain, an endogenous digitalis compound, has been detected in nanomolar concentrations in the plasma of several mammals and is associated with the development of hypertension. In addition, plasma ouabain is increased in several hypertension models, and the acute or chronic administration of ouabain increases blood pressure in rodents. These results suggest a possible association between ouabain and the genesis or development and maintenance of arterial hypertension. One explanation for this association is that ouabain binds to the α-subunit of the Na + pump, inhibiting its activity. Inhibition of this pump increases intracellular Na + , which reduces the activity of the sarcolemmal Na + /Ca 2+ exchanger and thereby reduces Ca 2+ extrusion. Consequently, intracellular Ca 2+ increases and is taken up by the sarcoplasmic reticulum, which, upon activation, releases more calcium and increases the vascular smooth muscle tone. In fact, acute treatment with ouabain enhances the vascular reactivity to vasopressor agents, increases the release of norepinephrine from the perivascular adrenergic nerve endings and promotes increases in the activity of endothelial angiotensin-converting enzyme and the local synthesis of angiotensin II in the tail vascular bed. Additionally, the hypertension induced by ouabain has been associated with central mechanisms that increase sympathetic tone, subsequent to the activation of the cerebral renin-angiotensin system. Thus, the association with peripheral mechanisms and central mechanisms, mainly involving the renin-angiotensin system, may contribute to the acute effects of ouabain-induced elevation of arterial blood pressure.
Results demonstrate that low ouabain concentration can decrease vascular reactivity of aortic rings from HF rats. Ouabain was able to increase nitric oxide production in HF rats by triggering a signal transduction PI3K/Akt-dependent pathway and increasing an endothelium-hyperpolarizing factor release.
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