Central administration of the somatostatin analog octreotide induces captopril-insensitive sleep responses.
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The effects of intracerebroventricular injections of the long-lasting somatostatin analog octreotide (Oct) were studied on sleep and behavior in rats. Pyrogen-free physiological saline and Oct (0.001, 0.01, 0.1 microgram) or vehicle were administered at light onset, and the electroencephalogram (EEG), motor activity, and cortical brain temperature were recorded during the 12-h light period. Plasma growth hormone (GH) concentrations were measured in samples taken at 30-min intervals after Oct. Oct (0.01 and 0.1 microgram) suppressed non-rapid eye movement sleep (NREMS) for 1-2 h. NREMS intensity (delta EEG activity during NREMS) dose dependently increased in hour 3 postinjection and thereafter (0.1 microgram). Plasma GH concentrations were suppressed after Oct (0.01 and 0.1 microgram), but pulses of GH secretions occurred 90-120 min postinjection in each rat. Oct (0.1 microgram) enhanced behavioral activity, including prompt drinking followed by grooming, scratching, and feeding. Intracerebroventricular injection of the angiotensin-converting enzyme inhibitor captopril (30 microgram, 10 min before Oct), blocked these behavioral responses but not the Oct-induced sleep alterations. The changes in sleep after intracerebroventricular Oct suggest an intracerebral action site and might result from Oct-induced variations in the sleep-promoting activity of GH-releasing hormone. (+info)
Effect of captopril in L-NAME-induced hypertension on the rat myocardium, aorta, brain and kidney.
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Long-term administration of NG-nitro-L-arginine methyl ester (L-NAME) induces development of hypertension and hypertrophy of the left ventricle in rats. The aim of the present study was to demonstrate the effect of chronic L-NAME treatment on DNA and RNA concentration, and protein synthesis in the rat heart, aorta, brain and kidney and to determine the effect of angiotensin converting enzyme (ACE) inhibitor captopril on these potential alterations. Four groups of rats were investigated: control, L-NAME (40 mg kg-1 day-1), captopril (100 mg kg-1 day-1), and L-NAME (40 mg kg-1 day-1) + captopril (100 mg kg-1 day-1). NO synthase activity in the heart, aorta, brain and kidney was found to be decreased in the L-NAME group. In the group of rats treated with L-NAME + captopril, captopril did not affect NO synthase inhibition. Captopril, however, completely prevented development of hypertension and left ventricular hypertrophy in this group. In the L-NAME group, DNA and RNA concentrations, as well as [14C]leucine incorporation, were significantly increased in all the tissues investigated. In the L-NAME + captopril group, captopril completely prevented the enhancement of DNA and RNA concentrations and [14C]leucine incorporation in all tissues compared to the L-NAME group. Moreover, a significant decrease in RNA concentration and [14C]leucine incorporation below control values was found in the captopril group as well as the L-NAME + captopril group in all the tissues investigated. We conclude that captopril prevented the development of hypertension and increase in nucleic acid concentration and protein synthesis in the heart, aorta, brain and kidney in rats treated with L-NAME + captopril. However, this protective effect of captopril was not associated with increased NO synthase activity in this model of hypertension. (+info)
Effect of angiotensin-converting enzyme inhibition on plasma, urine, and tissue concentrations of hemoregulatory peptide acetyl-Ser-Asp-Lys-Pro in rats.
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The hemoregulatory peptide Acetyl-Ser-Asp-Lys-Pro (AcSDKP) has been reported to accumulate in plasma and urine after the oral administration of angiotensin-converting enzyme (ACE) inhibitors in humans. It is unknown whether such an accumulation also occurs in tissues. We administered captopril (3, 10, or 30 mg/kg) orally for 2 weeks to Wistar rats. In a second experiment, captopril (10 mg/kg) was administered for 9 days and was followed by a 1-h i.v. infusion of either AcSDKP (0.1 or 2 mg/kg) or saline on day 9. Captopril alone dose-dependently increased plasma AcSDKP by a factor of 3 to 5 and urine AcSDKP by a factor of 3. It slightly increased renal and pulmonary AcSDKP concentrations but did not affect AcSDKP concentrations in bone marrow and spleen. The combination of AcSDKP (2 mg/kg) and captopril gave very high AcSDKP concentrations in plasma and urine and increases in AcSDKP concentration by factors of 27 in kidney, 5.5 in lung, and 6.9 in the extracellular fraction of bone marrow. In contrast, no change was observed in the AcSDKP concentration in spleen and in the intracellular fraction of bone marrow. In conclusion, during chronic ACE inhibition in rats, AcSDKP levels slightly increased in organs with high ACE contents. No such increase occurred in hematopoietic organs. AcSDKP had to be combined with captopril to significantly increase its concentration in tissues other than the spleen. The possibility of pharmacologically increasing AcSDKP levels in the extracellular fraction of bone marrow may be of value for protecting hematopoietic cells from the toxicity of cancer chemotherapy. (+info)
Dynamic Ca2+ signalling in rat arterial smooth muscle cells under the control of local renin-angiotensin system.
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1. We visualized the changes in intracellular Ca2+ concentration ([Ca2+]i), using fluo-3 as an indicator, in individual smooth muscle cells within intact rat tail artery preparations. 2. On average in about 45 % of the vascular smooth muscle cells we found spontaneous Ca2+ waves and oscillations ( approximately 0.13 Hz), which we refer to here as Ca2+ ripples because the peak amplitude of [Ca2+]i was about one-seventh of that of Ca2+ oscillations evoked by noradrenaline. 3. We also found another pattern of spontaneous Ca2+ transients often in groups of two to three cells. They were rarely observed and are referred to as Ca2+ flashes because their peak amplitude was nearly twice as large as that in noradrenaline-evoked responses. 4. Sympathetic nerve activity was not considered responsible for the Ca2+ ripples, and they were abolished by inhibitors of either the Ca2+ pump in the sarcoplasmic reticulum (cyclopiazonic acid) or phospholipase C (U-73122). 5. Both angiotensin antagonists ([Sar1,Ile8]-angiotensin II and losartan) and an angiotensin converting enzyme inhibitor (captopril) inhibited the Ca2+ ripples. 6. The extracellular Ca2+-dependent tension borne by unstimulated arterial rings was reduced by the angiotensin antagonist by approximately 50 %. 7. These results indicate that the Ca2+ ripples are generated via inositol 1,4, 5-trisphosphate-induced Ca2+ release from the intracellular Ca2+ stores in response to locally produced angiotensin II, which contributes to the maintenance of vascular tone. (+info)
Highly regulated cell type-restricted expression of human renin in mice containing 140- or 160-kilobase pair P1 phage artificial chromosome transgenes.
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We generated transgenic mice with two P1 artificial chromosomes, each containing the human renin (HREN) gene and extending to -35 and -75 kilobase pairs, respectively. HREN protein production was restricted to juxtaglomerular cells of the kidney, and its expression was tightly regulated by angiotensin II and sodium. The magnitude of the up- and down-regulation in HREN mRNA caused by the stimuli tested was identical to the endogenous renin gene, suggesting tight physiological regulation. P1 artificial chromosome mice were mated with transgenic mice overexpressing human angiotensinogen to determine if there was a chronic compensatory down-regulation of the transgene. Despite a 3-fold down-regulation of HREN mRNA, plasma angiotensin II and blood pressure was modestly elevated in the double transgenic mice. Nevertheless, this elevation was significantly less than a different double transgenic model containing a poorly regulated HREN transgene. The increase in blood pressure, despite the decrease in HREN mRNA, suggests that the HREN gene can partially, but not completely, compensate for excess circulating angiotensinogen. These data suggest the possibility that increases in circulating or tissue angiotensinogen may cause an increase in blood pressure in humans, even in the presence of a functionally active servo-mechanism to down-regulate HREN expression. (+info)
Renal vascular reactivity in mice: AngII-induced vasoconstriction in AT1A receptor null mice.
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The present study describes methodology and its application to evaluate renal reactivity in acute studies on anesthetized mice. Renal blood flow (RBF) was measured using an ultrasonic transit-time flowmeter and a non-cannulating V-shaped probe. An intrarenal artery injection technique established feasibility and reproducibility of studies of renal vascular reactivity to angiotensin II (AngII) in adult wild-type mice. The study also examined whether AngII would affect RBF in mice lacking AT1A receptors due to gene targeting. Mean arterial pressure averaged 83 and 62 mmHg, respectively, in mice with and without AT1A receptors. The RBF was similar in both groups, averaging 7 ml/min per g kidney wt. AngII injection (10-microl bolus) into the renal artery produced transient, dose-dependent, selective reductions in RBF in AT1A knockout mice as well as wild-type mice. The response was considerably greater in mice with AT1A receptors: 10% for 0.1 ng, 30% for 1 ng, and 45% for 5 ng AngII in control animals versus respective decreases of 6, 15, and 17% in knockout mice. In other studies, angiotensin-converting enzyme (captopril) or renin (CP-71362-14) was inhibited. During inhibition of AngII formation, renal vascular reactivity to AngII increased twofold in both groups. Coadministration of the AT1 receptor antagonist losartan (1 to 1000 ng) elicited dose-dependent inhibition of AngII effects, with near maximum blockage of 80 to 90% in both groups of mice. The putative AT2 receptor antagonist PD 123319 inhibited 30 to 40% of AngII-induced vasoconstriction, whereas CGP 42112 had no effect in either group. In conclusion, AngII can elicit renal vasoconstriction, albeit attenuated, in AT1A knockout mice. The weaker RBF effects are most likely due to the absence of the AT1A receptor. Inhibition of the response by AT1 receptor antagonist suggests mediation by the AT1B receptor in these animals. The residual constrictor effect observed during AT1 receptor blockade and sensitive to PD 123319 appears to be mediated by a non-AT1 receptor. (+info)
Effects of ACE inhibition and beta-receptor blockade on energy metabolism in rats postmyocardial infarction.
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Chronic treatment with beta-receptor blockers or angiotensin-converting enzyme (ACE) inhibitors in heart failure can reduce mortality and improve left ventricular function, but the mechanisms involved in their beneficial action remain to be fully defined. Our hypothesis was that these agents prevent the derangement of cardiac energy metabolism. Rats were subjected to myocardial infarction (MI) or sham operation. Thereafter, animals were treated with bisoprolol, captopril, or remained untreated. Two months later, cardiac function was measured in the isolated heart by a left ventricular balloon (pressure-volume curves), and energy metabolism of residual intact myocardium was analyzed in terms of total and isoenzyme creatine kinase (CK) activity, steady-state levels (ATP, phosphocreatine), and turnover rates (CK reaction velocity) of high-energy phosphates (31P nuclear magnetic resonance) and total creatine content (HPLC). Bisoprolol and partially captopril prevented post-MI hypertrophy and partially prevented left ventricular contractile dysfunction. Residual intact failing myocardium in untreated, infarcted hearts showed a 25% decrease of the total, a 26% decrease of MM-, and a 37% decrease of the mitochondrial CK activity. Total creatine was reduced by 15%, phosphocreatine by 21%, and CK reaction velocity by 41%. Treatment with bisoprolol or captopril largely prevented all of these changes in infarcted hearts. Thus the favorable functional effects of beta-receptor blockers and ACE inhibitors post-MI are accompanied by substantial beneficial effects on cardiac energy metabolism. (+info)
Human lung myofibroblast-derived inducers of alveolar epithelial apoptosis identified as angiotensin peptides.
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Earlier work from this laboratory found that fibroblasts isolated from fibrotic human lung [human interstitial pulmonary fibrosis (HIPF)] secrete a soluble inducer(s) of apoptosis in alveolar epithelial cells (AECs) in vitro [B. D. Uhal, I. Joshi, A. True, S. Mundle, A. Raza, A. Pardo, and M. Selman. Am. J. Physiol. 269 (Lung Cell. Mol. Physiol. 13): L819-L828, 1995]. The cultured human fibroblast strains most active in producing the apoptotic activity contained high numbers of stellate cells expressing alpha-smooth muscle actin, a myofibroblast marker. The apoptotic activity eluted from gel-filtration columns only in fractions corresponding to proteins. Western blotting of the protein fraction identified immunoreactive angiotensinogen (ANGEN), and two-step RT-PCR revealed expression of ANGEN by HIPF fibroblasts but not by normal human lung fibroblasts. Specific ELISA detected angiotensin II (ANG II) at concentrations sixfold higher in HIPF-conditioned medium than in normal fibroblast-conditioned medium. Pretreatment of the concentrated medium with purified renin plus purified angiotensin-converting enzyme (ACE) further increased the ELISA-detectable ANG II eightfold. Apoptosis of AECs in response to HIPF-conditioned medium was completely abrogated by the ANG II receptor antagonist saralasin (50 microg/ml) or anti-ANG II antibodies. These results identify the protein inducers of AEC apoptosis produced by HIPF fibroblasts as ANGEN and its derivative ANG II. They also suggest a mechanism for AEC death adjacent to HIPF myofibroblasts [B. D. Uhal, I. Joshi, C. Ramos, A. Pardo, and M. Selman. Am. J. Physiol. 275 (Lung Cell. Mol. Physiol. 19): L1192-L1199, 1998]. (+info)