angiotensin-i and Hypertrophy

Hypertension is associated with alterations in the structure, function, and mechanical properties of large and small arteries. Changes in the endothelium, smooth muscle cell, extracellular matrix, and possibly the adventitia, contribute to complications of hypertension. In large arteries, vascular hypertrophy is found, often with increased stiffness of media components. In small arteries, particularly in mild hypertension, rearrangement of smooth muscle cells around a smaller lumen without changes in media volume (eutrophic remodeling) occurs; in more severe hypertension, hypertrophic remodeling with increased vascular stiffness can be found. Vascular remodeling is accompanied by an increase in the extracellular matrix, particularly collagen deposition. Recent studies have demonstrated that vascular remodeling and endothelial dysfunction of small and large vessels may be normalized by treatment with some antihypertensive agents (angiotensin converting enzyme inhibitors, angiotensin AT(1) receptor antagonists, and long-acting calcium channel blockers). Angiotensin converting enzyme inhibitors have now been shown to improve outcomes in hypertensive patients, an effect that may in part be related to the vascular protective effects reviewed here.

Topics: Angiotensin I; Angiotensin Receptor Antagonists; Angiotensin-Converting Enzyme Inhibitors; Antihypertensive Agents; Arteries; Arterioles; Calcium Channel Blockers; Collagen; Elastic Tissue; Elasticity; Endothelium, Vascular; Extracellular Matrix; Humans; Hypertension; Hypertrophy; Muscle, Smooth, Vascular; Protective Agents; Treatment Outcome; Vascular Diseases

Clinical studies have shown a correlation between thyroid disorders and cardiac diseases. High levels of triiodothyronine (T3) induce cardiac hypertrophy, a risk factor for cardiac complications and heart failure. Previous results have demonstrated that angiotensin-(1-7) is able to block T3-induced cardiac hypertrophy; however, the molecular mechanisms involved in this event have not been fully elucidated. Here, we evidenced the contribution of FOXO3 signaling to angiotensin-(1-7) effects. Angiotensin-(1-7) treatment increased nuclear FOXO3 levels and reduced p-FOXO3 levels (inactive form) in isolated cardiomyocytes. Knockdown of FOXO3 by RNA silencing abrogated the antihypertrophic effect of angiotensin-(1-7). Increased expression of antioxidant enzymes superoxide dismutase 1 (SOD1 and catalase) and lower levels of reactive oxygen species and nuclear factor-κB (NF-κB) were observed after angiotensin-(1-7) treatment in vitro. Consistent with these results, transgenic rats overexpressing angiotensin-(1-7) displayed increased nuclear FOXO3 and SOD1 levels and reduced NF-κB levels in the heart. These results provide a new molecular mechanism responsible for the antihypertrophic effect of angiotensin-(1-7), which may contribute to future therapeutic targets.

Topics: Angiotensin I; Animals; Antioxidants; Catalase; Down-Regulation; Forkhead Box Protein O3; Hypertrophy; Male; Models, Biological; Myocytes, Cardiac; NF-kappa B; Peptide Fragments; Proto-Oncogene Mas; Proto-Oncogene Proteins; Rats, Sprague-Dawley; Rats, Transgenic; Rats, Wistar; Reactive Oxygen Species; Receptors, G-Protein-Coupled; Superoxide Dismutase-1; Triiodothyronine; Up-Regulation

Angiotensin-(1-9) is a peptide from the noncanonical renin-angiotensin system with anti-hypertrophic effects in cardiomyocytes via an unknown mechanism. In the present study we aimed to elucidate it, basing us initially on previous work from our group and colleagues who proved a relationship between disturbances in mitochondrial morphology and calcium handling, associated with the setting of cardiac hypertrophy. Our first finding was that angiotensin-(1-9) can induce mitochondrial fusion through DRP1 phosphorylation. Secondly, angiotensin-(1-9) blocked mitochondrial fission and intracellular calcium dysregulation in a model of norepinephrine-induced cardiomyocyte hypertrophy, preventing the activation of the calcineurin/NFAT signaling pathway. To further investigate angiotensin-(1-9) anti-hypertrophic mechanism, we performed RNA-seq studies, identifying the upregulation of miR-129 under angiotensin-(1-9) treatment. miR-129 decreased the transcript levels of the protein kinase A inhibitor (PKIA), resulting in the activation of the protein kinase A (PKA) signaling pathway. Finally, we showed that PKA activity is necessary for the effects of angiotensin-(1-9) over mitochondrial dynamics, calcium handling and its anti-hypertrophic effects.

Topics: Angiotensin I; Animals; Animals, Newborn; Calcium; Cyclic AMP-Dependent Protein Kinases; Cytosol; Dynamins; Hypertrophy; Intracellular Signaling Peptides and Proteins; MicroRNAs; Mitochondria; Mitochondrial Dynamics; Models, Biological; Myocytes, Cardiac; NFATC Transcription Factors; Norepinephrine; Peptide Fragments; Phosphorylation; Rats, Sprague-Dawley; Signal Transduction; Up-Regulation

The role of angiotensin II type 1 (AT1) receptors in muscle development and hypertrophy remains unclear. This study was designed to reveal the effects that a loss of AT1 receptors has on skeletal muscle development and hypertrophy in mice. Eight-week-old male AT1a receptor knockout (AT1a(-/-)) mice were used for this experiment. The plantaris muscle to body weight ratio, muscle fiber cross-sectional area, and number of muscle fibers of AT1a(-/-) mice was significantly greater than wild type (WT) mice in the non-intervention condition. Next, the functional overload (OL) model was used to induce plantaris muscle hypertrophy by surgically removing the two triceps muscles consisting of the calf, soleus, and gastrocnemius muscles in mice. After 14 days of OL intervention, the plantaris muscle weight, the amount of fiber, and the fiber area increased. However, the magnitude of the increment of plantaris weight was not different between the two strains. Agtr1a mRNA expression did not change after OL in WT muscle. Actually, the Agt mRNA expression level of WT-OL was lower than WT-Control (C) muscle. An atrophy-related gene, atrogin-1 mRNA expression levels of AT1a(-/-)-C, WT-OL, and AT1a(-/-)-OL muscle were lower than that of WT-C muscle. Our findings suggest that AT1 receptor contributes to plantaris muscle development via atrogin-1 in mice.

Topics: Angiotensin I; Angiotensin II; Animals; Gene Expression; Hypertrophy; Male; Mice; Mice, Inbred C57BL; Mice, Knockout; Muscle Proteins; Muscle, Skeletal; Receptor, Angiotensin, Type 1; RNA, Messenger; SKP Cullin F-Box Protein Ligases

Angiotensin-(1-7) (Ang-(1-7))/AT7-Mas receptor axis is an alternative pathway within the renin-angiotensin system (RAS) that generally opposes the actions of Ang II/AT1 receptor pathway. Advanced glycated end product (AGEs) including glucose- and methylglyoxal-modified albumin (MGA) may contribute to the development and progression of diabetic nephropathy in part through activation of the Ang II/AT1 receptor system; however, the influence of AGE on the Ang-(1-7) arm of the RAS within the kidney is unclear. The present study assessed the impact of AGE on the Ang-(1-7) axis in NRK-52E renal epithelial cells. MGA exposure for 48 h significantly reduced the intracellular levels of Ang-(1-7) approximately 50%; however, Ang I or Ang II expression was not altered. The reduced cellular content of Ang-(1-7) was associated with increased metabolism of the peptide to the inactive metabolite Ang-(1-4) [MGA: 175±9 vs.. 115±11 fmol/min/mg protein, p<0.05, n=3] but no change in the processing of Ang I to Ang-(1-7). Treatment with Ang-(1-7) reversed MGA-induced cellular hypertrophy and myofibroblast transition evidenced by reduced immunostaining and protein expression of α-smooth muscle actin (α-SMA) [0.4±0.1 vs. 1.0±0.1, respectively, n=3, p<0.05]. Ang-(1-7) abolished AGE-induced activation of the MAP kinase ERK1/2 to a similar extent as the TGF-β receptor kinase inhibitor SB58059; however, Ang-(1-7) did not attenuate the MGA-stimulated release of TGF-β. The AT7-Mas receptor antagonist D-Ala(7)-Ang-(1-7) abolished the inhibitory actions of Ang-(1-7). In contrast, AT1 receptor antagonist losartan did not attenuate the MGA-induced effects. We conclude that Ang-(1-7) may provide an additional therapeutic approach to the conventional RAS blockade regimen to attenuate AGE-dependent renal injury.

Topics: Albumins; Angiotensin I; Animals; Enzyme Activation; Epithelial Cells; Extracellular Signal-Regulated MAP Kinases; Glycation End Products, Advanced; Hypertrophy; Myofibroblasts; Peptide Fragments; Phosphorylation; Rats; Transforming Growth Factor beta

The renin–angiotensin system (RAS) regulates blood pressure mainly via the actions of angiotensin (Ang)II, generated via angiotensin converting enzyme (ACE). The ACE homologue ACE2 metabolises AngII to Ang1-7, decreasing AngII and increasing Ang1-7, which counteracts AngII activity via the Mas receptor. However, ACE2 also converts AngI to Ang1-9, a poorly characterised peptide which can be further converted to Ang1-7 via ACE. Ang1-9 stimulates bradykinin release in endothelium and has antihypertrophic actions in the heart, attributed to its being a competitive inhibitor of ACE, leading to decreased AngII, rather than increased Ang1-7. To date no direct receptor-mediated effects of Ang1-9 have been described. To further understand the role of Ang1-9 in RAS function we assessed its action in cardiomyocyte hypertrophy in rat neonatal H9c2 and primary adult rabbit left ventricular cardiomyocytes, compared to Ang1-7. Cardiomyocyte hypertrophy was stimulated with AngII or vasopressin, significantly increasing cell size by approximately 1.2-fold (P < 0.05) as well as stimulating expression of the hypertrophy gene markers atrial natriuretic peptide, brain natriuretic peptide, β-myosin heavy chain and myosin light chain (2- to 5-fold, P < 0.05). Both Ang1-9 and Ang1-7 were able to block hypertrophy induced by either agonist (control, 186.4 μm; AngII, 232.8 μm; AngII+Ang1-7, 198.3 μm; AngII+Ang1-9, 195.9 μm; P < 0.05). The effects of Ang1-9 were not inhibited by captopril, supporting previous evidence that Ang1-9 acts independently of Ang1-7. Next, we investigated receptor signalling via angiotensin type 1 and type 2 receptors (AT1R, AT2R) and Mas. The AT1R antagonist losartan blocked AngII-induced, but not vasopressin-induced, hypertrophy. Losartan did not block the antihypertrophic effects of Ang1-9, or Ang1-7 on vasopressin-stimulated cardiomyocytes. The Mas antagonist A779 efficiently blocked the antihypertrophic effects of Ang1-7, without affecting Ang1-9. Furthermore, Ang1-7 activity was also inhibited in the presence of the bradykinin type 2 receptor antagonist HOE140, without affecting Ang1-9. Moreover, we observed that the AT2R antagonist PD123,319 abolished the antihypertrophic effects of Ang1-9, without affecting Ang1-7, suggesting Ang1-9 signals via the AT2R. Radioligand binding assays demonstrated that Ang1-9 was able to bind the AT2R (pKi = 6.28 ± 0.1). In summary, we ascribe a direct biological role for Ang1-9 acting via the AT2R. This has implicatio

Topics: Angiotensin I; Angiotensin II; Animals; Animals, Newborn; Cell Line, Transformed; Cell Survival; Cells, Cultured; HeLa Cells; Humans; Hypertrophy; Myocytes, Cardiac; Peptide Fragments; Rabbits; Rats; Receptor, Angiotensin, Type 2; Signal Transduction

Studies in experimental animals and younger women suggest a protective role for estrogen; however, clinical trials may not substantiate this effect in older females. Therefore, the present study assessed the outcome of ovariectomy in older mRen2. Lewis rats subjected to a high-salt diet for 4 wk. Intact or ovariectomized (OVX, 15 wk of age) mRen2. Lewis rats were aged to 60 wk and then placed on a high-salt (HS, 8% sodium chloride) diet for 4 wk. Systolic blood pressures were similar between groups [OVX 169 +/- 6 vs. Intact 182 +/- 7 mmHg; P = 0.22] after the 4-wk diet; however, proteinuria [OVX 0.8 +/- 0.2 vs. Intact 11.5 +/- 2.6 mg/mg creatinine; P < 0.002, n = 6], renal interstitial fibrosis, glomerular sclerosis, and tubular casts were lower in OVX vs. Intact rats. Kidney injury molecule-1 mRNA, a marker of tubular damage, was 53% lower in the OVX HS group. Independent from blood pressure, OVX HS rats exhibited significantly lower cardiac (24%) and renal (32%) hypertrophy as well as lower C-reactive protein (28%). Circulating insulin-like growth factor-I (IGF-I) levels were not different between the Intact and OVX groups; however, renal cortical IGF-I mRNA and protein were attenuated in OVX rats [P < 0.05, n = 6]. We conclude that ovariectomy in the older female mRen2. Lewis rat conveys protection against salt-dependent increase in renal injury.

Topics: Aging; Angiotensin I; Angiotensin II; Animals; Animals, Congenic; Blood Pressure; C-Reactive Protein; Cell Adhesion Molecules; Disease Models, Animal; Female; Fibrosis; Hypertension; Hypertrophy; Insulin-Like Growth Factor I; Intracellular Signaling Peptides and Proteins; Kidney; Kidney Diseases; Membrane Proteins; Ovariectomy; Peptide Fragments; Proteinuria; Rats; Rats, Inbred Lew; Renin; Renin-Angiotensin System; RNA, Messenger; Sodium Chloride, Dietary

Angiotensin-(1-7) is an endogenous, biologically active peptide of the renin-angiotensin system with vasodilatory, antithrombotic, and antiproliferative properties. This study examined the effects of angiotensin-(1-7) infusion on neointimal formation after stent placement in the rat. Male Wistar rats underwent stent implantation in the abdominal aorta or sham surgery. Subsequently, an osmotic minipump was placed for angiotensin-(1-7) (24 microg/kg per hour) or saline administration. After 4 weeks, histomorphometric and histological analyses were performed, and the endothelial function was measured in isolated thoracic aortic rings. Stent implantation resulted in equal mean injury scores within the groups. The angiotensin-(1-7)-treated group displayed a significant reduction in neointimal thickness (112+/-8 versus 141+/-11 microm; P<0.05), neointimal area (0.51+/-0.05 versus 0.70+/-0.07 mm2; P<0.05), and percentage stenosis (10.4+/-1.0 versus 14.0+/-1.3%; P<0.05) compared with the saline-treated group. Furthermore, angiotensin-(1-7) infusion attenuated the stenting-induced impairment in endothelium-dependent relaxation (42.6+/-3.0 versus 64.5+/-6.0% of phenylephrine maximal contraction; P<0.001). In conclusion, angiotensin-(1-7) treatment attenuates neointimal formation after stent implantation in the rat, combined with an improvement of endothelial function.

Topics: Angiotensin I; Animals; Aorta, Abdominal; Aorta, Thoracic; Hypertrophy; Infusion Pumps, Implantable; Infusions, Intravenous; Male; Methacholine Chloride; Peptide Fragments; Phenylephrine; Rats; Rats, Wistar; Sodium Nitrite; Stents; Tunica Intima; Vasoconstrictor Agents; Vasodilation; Vasodilator Agents

The hypertrophic response of cardiomyocytes exposed to mechanical stretch is assumed to depend on the release of angiotensin (Ang) II from these cells. Here we studied the synthesis of renin-angiotensin system (RAS) components by cardiac cells under basal conditions and after stretch.. Myocytes and fibroblasts were isolated by enzymatic dissociation from hearts of 1-3-day-old Wistar rat strain pups, grown for 1 day in serum-supplemented medium and then cultured in a chemically defined, serum-free medium. Medium and cell lysate were collected 5 days later or after exposure of the cells to cyclic stretch for 24 h. Prorenin, renin and angiotensinogen were measured by enzyme-kinetic assay; Ang I and Ang II were measured by radioimmunoassay after SepPak extraction and HPLC separation.. Prorenin, but none of the other RAS components, could be detected in the medium of both cell types. However, its levels were low and the Ang I-generating activity corresponding with these low prorenin levels could not be inhibited by the specific rat renin inhibitor CH-732, suggesting that it was most likely due to bovine and/or horse prorenin sequestered from the serum-containing medium to which the cells had been exposed prior to the serum-free period. When incubated with Ang I, both myocytes and fibroblasts generated Ang II in a captopril-inhibitable manner. Myocyte and fibroblast cell lysates did not contain prorenin, renin, angiotensinogen, Ang I or Ang II in detectable quantities. Stretch increased myocyte protein synthesis by 20%, but was not accompanied by Ang II release into the medium.. Cardiac myocytes and fibroblasts do not synthesize renin, prorenin or angiotensinogen in concentrations that are detectable or, it not detectable, high enough to result in Ang II concentrations of physiological relevance. These cells do synthesize ACE, thereby allowing the synthesis of Ang II at cardiac tissue sites when renin and angiotensinogen are provided via the circulation. Ang II is not a prerequisite to observe a hypertrophic response of cardiomyocytes following stretch.

Topics: Analysis of Variance; Angiotensin I; Angiotensin II; Angiotensin-Converting Enzyme Inhibitors; Angiotensinogen; Animals; Animals, Newborn; Captopril; Cells, Cultured; Culture Media, Serum-Free; Enzyme Precursors; Fibroblasts; Hypertrophy; Myocardium; Peptidyl-Dipeptidase A; Rats; Rats, Wistar; Renin; Stress, Mechanical

In vitro studies have demonstrated that angiotensin (Ang) II directly stimulates vascular smooth muscle cell (VSMC) growth. However, it is still unclear if Ang II exerts a direct effect on vascular hypertrophy in vivo independent of its effect on blood pressure. In vivo gene transfer provides the opportunity to assess the effects of increased activity of the vascular angiotensin system in the intact animal while avoiding an increase in circulating angiotensin or in blood pressure. Accordingly, we transfected the human angiotensin converting enzyme (ACE) vector into intact rat carotid arteries by the hemagglutinating virus of Japan-liposome method. 3 d after transfection, we detected increased ACE activity in the transfected artery. Immunohistochemistry localized immunoreactive ACE in the medial VSMC as well as in the intimal endothelial cells. The increase in vascular ACE activity was associated with a parallel increase in DNA synthesis as assessed by BrdU (bromo-deoxyuridine) index and vascular DNA content. This increase in DNA synthesis was abolished by the in vivo administration of an Ang II receptor-specific antagonist (DuP 753). Morphometry at 2 wk after transfection revealed an increase in the wall to lumen ratio of the ACE-transfected blood vessel as compared with control vector transfected vessels. This was accompanied by increases in protein and DNA contents without an increase in cell number. Local transfection of ACE vector did not result in systemic effects such as increased blood pressure, heart rate, or serum ACE activity. These morphological changes were abolished by the administration of the Ang II receptor antagonist. In this study, we used in vivo gene transfer to increase local expression of vascular angiotensin converting enzyme and provided proof that increased autocrine/paracrine angiotensin can directly cause vascular hypertrophy independent of systemic factors and hemodynamic effects. This approach has important potentials for defining the role of autocrine/paracrine substances in vascular biology and hypertension.

Topics: Angiotensin I; Angiotensin Receptor Antagonists; Animals; Biphenyl Compounds; Blood Pressure; Carotid Arteries; DNA; Endothelium, Vascular; Gene Transfer Techniques; Genetic Vectors; Heart Rate; Humans; Hypertrophy; Imidazoles; Immunohistochemistry; Liposomes; Losartan; Male; Muscle, Smooth, Vascular; Peptidyl-Dipeptidase A; Rats; Rats, Sprague-Dawley; Reference Values; Tetrazoles; Transfection

Hypertrophy is a fundamental adaptive process employed by postmitotic cardiac and skeletal muscle in response to mechanical load. How muscle cells convert mechanical stimuli into growth signals has been a long-standing question. Using an in vitro model of load (stretch)-induced cardiac hypertrophy, we demonstrate that mechanical stretch causes release of angiotensin II (Ang II) from cardiac myocytes and that Ang II acts as an initial mediator of the stretch-induced hypertrophic response. The results not only provide direct evidence for the autocrine mechanism in load-induced growth of cardiac muscle cells, but also define the pathophysiological role of the local (cardiac) renin-angiotensin system.

Topics: Actins; Angiotensin I; Angiotensin II; Angiotensinogen; Animals; Animals, Newborn; Atrial Natriuretic Factor; Cardiomegaly; Cells, Cultured; Cytoplasmic Granules; Endothelins; Gene Expression Regulation; Genes, fos; Hypertrophy; In Vitro Techniques; Mechanoreceptors; Myocardium; Peptidyl-Dipeptidase A; Rats; Renin; RNA, Messenger; Stress, Mechanical

To investigate the vascular renin-angiotensin system in two-kidney, one clip (2K1C) hypertension, we measured angiotensinogen messenger RNA (mRNA) in the aorta and aortic and plasma angiotensin II (Ang II) concentration in 2K1C rats during early (4 weeks) and chronic (16 weeks) phases. Four weeks after clipping, there was no significant change in aortic angiotensinogen mRNA in both groups. However, the levels of plasma and aortic Ang II in 2K1C rats were significantly elevated compared with levels in control rats (p less than 0.05). Sixteen weeks after clipping, aortic angiotensinogen mRNA in 2K1C rats did not differ compared with the level in control rats. The aortic Ang II level in 2K1C rats was significantly increased compared with that in control rats (p less than 0.05), whereas there was no significant difference in the plasma Ang II level between the groups during this chronic phase. During both phases, morphological studies in 2K1C rats showed arteriosclerotic changes, with a significant increase in the wall-to-lumen ratio (p less than 0.01). The present study is the first to demonstrate an increase in vascular Ang II levels and concomitant morphological arteriosclerotic changes during both the early and chronic phases in 2K1C rats. Together with the results of our previous study that demonstrated an elevation of vascular renin activity during the early phase and increased vascular angiotensin converting enzyme activity during the chronic phase, we conclude that the elevated vascular renin activity and vascular angiotensin converting enzyme activity during each phase may play a dominant role in the increase in vascular Ang II observed during both phases.

Topics: Angiotensin I; Angiotensin II; Angiotensinogen; Animals; Aorta, Abdominal; Hypertension, Renovascular; Hypertrophy; Male; Rats; Rats, Inbred Strains; Renin-Angiotensin System; RNA, Messenger; Veins