Abstract
We aimed to investigate whether atrial natriuretic peptide (ANP) attenuates angiotensin II (Ang II)-induced myocardial remodeling and to clarify the possible molecular mechanisms involved. Thirty-five 8-week-old male Wistar–Kyoto rats were divided into control, Ang II, Ang II + ANP, and ANP groups. The Ang II and Ang II + ANP rats received 1 μg/kg/min Ang II for 14 days. The Ang II + ANP and ANP rats also received 0.1 μg/kg/min ANP intravenously. The Ang II and Ang II + ANP rats showed comparable blood pressure. Left ventricular fractional shortening and ejection fraction were lower in the Ang II rats than in controls; these indices were higher (P < 0.001) in the Ang II + ANP rats than in the Ang II rats. In the Ang II rats, the peak velocity of mitral early inflow and its ratio to atrial contraction-related peak flow velocity were lower, and the deceleration time of mitral early inflow was significantly prolonged; these changes were decreased by ANP. Percent fibrosis was higher (P < 0.001) and average myocyte diameters greater (P < 0.01) in the Ang II rats than in controls. ANP decreased both myocardial fibrosis (P < 0.01) and myocyte hypertrophy (P < 0.01). Macrophage infiltration, expression of mRNA levels of collagen types I and III, monocyte chemotactic protein-1, and a profibrotic/proinflammatory molecule, tenascin-C (TN-C) were increased in the Ang II rats; ANP significantly decreased these changes. In vitro, Ang II increased expression of TN-C and endothelin-1 (ET-1) in cardiac fibroblasts, which were reduced by ANP. ET-1 upregulated TN-C expression via endothelin type A receptor. These results suggest that ANP may protect the heart from Ang II-induced remodeling by attenuating inflammation, at least partly through endothelin 1/endothelin receptor A cascade.
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Introduction
Atrial natriuretic peptide (ANP) was originally identified as a diuretic/natriuretic and vasodilating hormone released by the heart in response to myocardial stretch and overload. Recent reports have demonstrated that ANP exerts various beneficial effects on the heart [1–3], For example. ANP suppresses the renin-angiotensin-aldosterone system (RAAS), endothelin synthesis, and sympathetic nerve activity [4], whereas it enhances adiponectin production and regulates cell growth and apoptosis (reviewed in [5, 6]), as a circulating hormone as well as a local autocrine and/or paracrine factor. Indeed, ANP exhibits therapeutic efficacy against chronic heart failure [7–9], acute heart failure [10–13], and acute myocardial infarction [14–17] in humans as well as rat models of acute myocardial infarction–reperfusion [18] and autoimmune myocarditis [19]. However, the detailed molecular mechanisms of these cardioprotective functions remain uncertain.
Left ventricular (LV) remodeling is an important factor related to the prognosis of heart disease. Histological features of LV remodeling include interstitial fibrosis and myocyte hypertrophy. Enhanced myocardial stiffness caused by increased interstitial fibrosis is known to lead to diastolic heart failure. Recently, increasing attention has been paid to the fact that RAAS overactivation-mediated inflammation plays a significant role in the development of cardiac fibrosis during ventricular remodeling [20–23]. Fibrotic lesions are formed via a multistep process of synthesis and degradation of various extracellular matrix molecules, including tenascin-C (TN-C). TN-C is an extracellular glycoprotein that is weakly expressed in healthy adult hearts, but it is transiently upregulated in association with tissue injury and inflammation [24–30]. This specific expression pattern makes TN-C a valuable marker for inflammatory disease activity [25, 27]. Using a mouse model, we previously reported that TN-C may be involved in the progression of hypertensive myocardial fibrosis and that elevated TN-C expression may be a marker for active progression of fibrosis in the heart [28]. Furthermore, TN-C has diverse biological functions and is considered to be a key molecule during the progression of inflammation and fibrosis (reviewed in [31, 32]). We investigated whether ANP attenuates cardiac fibrosis in a rat model of Ang II-induced ventricular remodeling and the molecular mechanism involved, especially focusing on TN-C. Cardiac function, histological changes, and expression of molecules related to fibrosis and inflammation, which include collagen type I, collagen type III, TN-C, monocyte chemotactic protein-1 (MCP-1), and endothelin-1 (ET-1) were examined in the heart of model rats treated with Ang II with or without ANP. Furthermore, the direct effects of ANP on TN-C synthesis and the signaling pathways involved were studied in cultured cardiac fibroblasts.
Materials and methods
Animal experiments were performed in accordance with the Guide for the Care and Use of Laboratory Animals published by the US National Institutes of Health (publication no. 85-23, revised 1996), and the study was approved by our Institutional Animal Research Committee. Experiments were performed on 8-week-old male Wistar–Kyoto rats that weighed 250–280 g before study initiation. The rats were fed a standard rat-chow diet and had free access to tap water. Thirty-five rats were randomly divided into four treatment groups (control, n = 10; Ang II, n = 10; Ang II + ANP, n = 10, ANP, n = 5). All rats were anesthetized with 3 % isoflurane on a volume-cycled ventilator (Univentor; Bio Research Center, Nagoya, Japan) for small animals. In Ang II and Ang II + ANP groups, a midline incision was made in the lumbar region for insertion of osmotic mini-pumps (model 2002; ALZET, Palo Alto, CA, USA; mean filling volume, 0.234 ml) filled with Ang II (Peptide Institute, Osaka, Japan), which was infused at 1 μg/kg/min for 14 days. The dose used in this study was determined on the basis of preliminary experiments. For the administration of saline or ANP, control, Ang II + ANP, and ANP groups bearing the mini-pump were fitted with a fluid-delivery infusion pump (10 ml Infu-disk; MED-e-CELL, San Diego, CA, USA) attached to the back. These external infusion pumps were filled with saline or carperitide, a recombinant α-human ANP (Daiichi-Sankyo Pharmaceutical, NY, USA), dissolved in distilled water and released at 0.1 μg/kg/min for 14 days. The pump was connected to the right or left jugular vein by a small polyethylene catheter. The rats were weighed on days 0, 3, 6, 10, and 14, and systolic blood pressure and heart rate were measured using a tail-cuff method without anesthesia on the same days. On day 14, the rats were deeply anesthetized with isoflurane and euthanized. The hearts were dissected and weighed, and a part of the ventricle was separated from the heart, frozen in RNAlater (Ambion, Huntington, UK), and stored at −80 °C until use.
Echocardiographic measures of cardiac function
LV function was assessed using a two-dimensional guided M-mode ultrasound system (VIVID7; GE Medical Systems, Tokyo, Japan). Images of the short-axis view of the left ventricle at the level of the papillary muscle were recorded to assess cardiac function. The end-diastolic LV dimension (LVDd) and end-systolic LV dimension (LVDs) were measured directly by echocardiography. The LV fractional shortening (FS) and LV ejection fraction (EF) were calculated as percentages from the LVDd and LVDs values. The LV diastolic function was evaluated by recording the pulse-wave Doppler spectra of transmitral flow. The peak velocity of mitral early inflow (E), its ratio to atrial contraction-related flow peak velocity (E/A), and the deceleration time of mitral early inflow (DcT) were also measured. Echocardiography was performed on the 14th day after study initiation in all rats.
Histological analysis
Histological analysis was performed on five hearts from each group. The left ventricle was removed, fixed in 4 % paraformaldehyde, and embedded in paraffin. Three-micrometer-thick sections were prepared and stained with hematoxylin–eosin for evaluation of myocyte hypertrophy and with Sirius Red for evaluation of myocardial fibrosis. To determine the average myocyte size, the shortest transverse diameter was measured in 50 transverse sections per heart (×200 magnification), which contained the cross section of a myocyte with its nucleus. To determine the percent area of myocardial interstitial and perivascular fibrosis, the Scion imaging system (Scion, Frederick, MD, USA) was used as described previously [28]. To evaluate TN-C expression and the number of macrophages in the myocardium, we performed immunohistochemistry as described previously [33]. In brief, a mouse monoclonal antibody for TN-C (4F10TT; IBL, Gunma, Japan; 1:100 dilution) and a mouse monoclonal antibody against the macrophage marker cluster of differentiation 68 (CD68; DAKO Japan, Tokyo, Japan; 1:100 dilution) were used. Immunoreactivity was evaluated using the avidin–biotin–peroxidase complex method (ScyTek Laboratories, Logan, UT, USA). The reactions were visualized using diaminobenzidine, and nuclei were counterstained with hematoxylin. Quantitative analysis of tissue macrophages was performed using the CD68 antibody stain. For each-specimen, three randomly selected photomicrographs (×400 magnification) of the anterior, lateral, and posterior ventricular walls, as well as the interventricular septum, were examined (12 fields/specimen). The numbers of CD68-positive cells were counted in each region and expressed as the number of inflammatory cells per unit area (1 mm2).
Immunofluorescence double labeling was applied to colocalize TN-C, and either α-smooth muscle actin (SMA)-positive cells or macrophages. Anti-α-SMA mouse monoclonal primary antibodies (Thermo Fisher Scientific, Yokohama, Japan; 1:100 dilution) were used for the detection of α-SMA-positive cells, and anti-CD68 mouse monoclonal primary antibodies (DAKO Japan; 1:100 dilution) were used for detection of macrophages. Biotinylated antimouse immunoglobulins (EPOS; Dako Japan; 1:250 dilution) were then used as part of the enhanced polymer one-step staining system, followed by incubation in streptavidin labeled with Alexa 448 (Molecular Probes, Eugene, OR, USA; 1:300 dilution). For detection of TN-C, anti-TN-C polyclonal rabbit antibody [33], and goat antirabbit immunoglobulins labeled with Alexa 555 (Molecular Probes; 1:300 dilution) were used. Fluoromount (Diagnostic BioSystem, Pleasanton, CA, USA) was used to mount stained sections on coverslips. Laser scanning confocal fluorescence microscopy combined with differential interference contrast imaging was performed using LSM 510 META Ver. 3.2 (Zeiss, Göttingen, Germany). Brightness and contrast adjustments along with necessary cropping were performed using Photoshop Elements 8.0 (Adobe, San José, CA, USA).
Real-time reverse transcription–polymerase chain reaction (real-time RT-PCR)
Total RNA was isolated from five hearts from each group and real-time RT-PCR performed to measure the mRNA expression levels of collagen type I, collagen type III, TN-C, MCP-1, ET-1, and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Quantitative PCR was performed using a Light Cycler (LightCycler FastStart DNA Master PLUS SYBR Green I; Roche Diagnostics; Mannheim, Germany). Amplification specificity was checked using a melting curve according to the manufacturer’s instructions. The mRNA expression of each target was normalized to that of GAPDH. The forward and reverse primers are listed in Table 1.
Cell cultures
Cardiac fibroblasts were obtained from the ventricles of Wistar–Kyoto rats and grown in Iscove’s modified Dulbecco’s medium (IMDM) supplemented with 10 % fetal bovine serum as described previously [34]. The experiments were performed on secondary cultures. Cells were plated in Multiwell 6-well plates (Becton–Dickinson, Franklin Lakes, NJ, USA) at 3 × 105 cells/well for 48 h in serum-free IMDM, and then treated with ET-1 (3 × 10-9, 1 × 10-8, 3 × 10-8, and 1 × 10-7 mol/l) or Ang II (1 × 10−9 mol/l) for 6 h. To determine whether ET-1 is involved in the upregulation of Ang II-induced (1 × 10−9 mol/l) TN-C mRNA expression, the endothelin receptor (ET-R) antagonist bosentan (1 × 10−6 or 1 × 10−5 mol/l) was also used. To clarify the signaling pathways induced by Ang II, we coapplied the selective endothelin A receptor (ET-RA) antagonist BQ 123 (1 × 10−7, 3 × 10−7, and 1 × 10−6 mol/l) and/or the selective endothelin B receptor (ET-RB) antagonist BQ 788 (1 × 10−7, 3 × 10−7, and 1 × 10−6 mol/l). To examine if ANP blocks Ang II-induced TN-C expression, the cells were pretreated with ANP (1 × 10−8 or 1 × 10−7 mol/l) for 6 h and then stimulated with Ang II (1 × 10−9 mol/l) for 6 h. Total RNA was isolated from the treated cells using ISOGEN (Nippon Gene, Toyama, Japan), and the relative ET-1 or TN-C mRNA levels were determined by quantitative real-time RT-PCR.
Statistical analyses
All quantitative data are expressed as means ± standard deviation (SD). Numeric data were statistically evaluated by 1-way analysis of variance, followed by the Tukey–Kramer method for multiple comparisons. A P value less than 0.05 was considered to be statistically significant.
Results
Systolic blood pressure, heart rate, body weight, and heart weight/body weight ratio
The rats were subjected to Ang II infusion for 14 days, with or without administration of ANP. Compared with the controls (114 ± 5 mmHg), the Ang II and Ang II + ANP rats showed elevated SBP (Ang II, 204 ± 36 mmHg; Ang II + ANP, 201 ± 22 mmHg; P < 0.001). The Ang II rats had a significantly higher heart rate than the controls (control, 338 ± 12 beats/min; Ang II, 432 ± 53 beats/min; P < 0.001). In addition, the Ang II and Ang II + ANP rats had significantly lower body weights than the controls (control, 317 ± 18 g; Ang II, 216 ± 46 g; Ang II + ANP, 225 ± 45 g; P < 0.001). The Ang II rats had a significantly greater average heart weight/body weight ratio than the controls (control, 3.20 ± 0.55 mg/g; Ang II, 4.20 ± 1.02 mg/g; P < 0.05). The Ang II + ANP rats had a slightly, but not significantly, lower heart weight/body weight ratio compared with the Ang II rats (Ang II + ANP, 4.04 ± 0.78 mg/g; P = 0.90; Table 2). There were no significant differences between controls and ANP-alone rats in systolic blood pressure, heart rate, body weight, and heart weight/body weight ratio.
Ang II and Ang II + ANP rats showed comparable blood pressure and heart rate throughout the time course (Fig. 1).
Cardiac function
LVFS and EF were significantly lower in the Ang II rats than in the controls (P < 0.001), whereas the Ang II + ANP rats exhibited significantly higher LVFS and EF than the Ang II rats (P < 0.001). On the basis of Doppler spectra for transmitral flow, the Ang II rats showed significant decreases in E and E/A ratio, in addition to a significant prolongation of the DcT, compared with the controls (E, P < 0.001; E/A, P < 0.001; DcT, P < 0.001). Coadministration of ANP reversed the Ang II-mediated suppression of E and the E/A ratio, as well as the decreased DcT (E, P = 0.22; E/A, P = 0.30; DcT, P < 0.001; Table 2), indicating that ANP can partially reverse Ang II-induced ventricular dysfunction. There were no significant differences between controls and ANP-alone rats in echocardiographic parameters.
Myocyte hypertrophy
The average myocyte diameter was significantly greater in the Ang II rats than in the controls (P < 0.001). ANP coadministration significantly decreased myocyte diameter (P < 0.01; Fig. 2a, b). Compared with controls, the average myocyte diameter in ANP-alone rats showed no significant difference.
Myocardial fibrosis
The percent areas of myocardial fibrosis were significantly greater in the Ang II-treated rats than in the controls (P < 0.001). ANP coadministration significantly decreased interstitial fibrosis (P < 0.01; Fig. 3a, b). The mRNA levels of fibrotic indicators collagen type I (Fig. 3c) and collagen type III (Fig. 3d) were higher in the Ang II rats than in the controls, whereas ANP coadministration significantly decreased the mRNA levels of collagen type I (Fig. 3c) and collagen type III (Fig. 3d).
Compared with controls, the percent areas of myocardial fibrosis in ANP-alone rats showed no significant difference. In addition, the mRNA levels of collagen type I and collagen type III of ANP-alone rats also showed no significant difference.
Cardiac inflammation
Immunostaining for TN-C is shown in Fig. 4a. The average TN-C-positive area was larger in the Ang II rats than in the controls, and again TN-C immunoreactivity was decreased by ANP coadministration. Similarly, the total number of CD68-positive cells per unit area (1 mm2) was significantly greater in the Ang II rats than in the controls (P < 0.001; Fig. 4b, d). This increase was significantly decreased by ANP coadministration (P < 0.05; Fig. 4b, d). mRNA levels of TN-C (Fig. 4c) and MCP-1 (Fig. 4e) were increased in the Ang II rats compared with the controls, whereas ANP coadministration significantly decreased both TN-C (Fig. 4c) and MCP-1 (Fig. 4e) mRNA levels. Compared with controls, TN-C-positive area and the total number of CD68-positive cells in ANP-alone rats showed no significant difference. In addition, the mRNA levels of TN-C and MCP-1 of ANP-alone rats also showed no significant difference. The mRNA level of ET-1 was higher in the Ang II rats than in the controls. The mRNA level of ET-1 was decreased in the Ang II + ANP rats compared with the Ang II rats, but the difference was not statistically significant (P = 0.38, data not shown).
Confocal laser scanning microscopy
In the fibrotic area shown in Fig. 4a, b, by confocal laser scanning microscopy a large number of CD68-positive macrophages and α-SMA-positive cells, presumably myofibroblasts, was observed. We then compared whether TN-C immunopositivity colocalized with CD68 and α-SMA positivity. Most of the α-SMA-positive cells were found to be negative for TN-C staining (Fig. 5a), and CD68-positive macrophages were negative for TN-C staining (Fig. 5b).
Effects of ANP on TN-C synthesis by cardiac fibroblasts in culture
The effects of Ang II on TN-C and ET-1 gene expression, and the role of ET-1 receptors in Ang II- and ANP-mediated regulation of TN-C gene expression, were examined in cultured cardiac fibroblasts by quantitative real-time RT-PCR. Ang II administration increased TN-C mRNA expression, and ANP coadministration significantly reversed this upregulation (Fig. 6a). In addition, Ang II increased ET-1 mRNA expression, whereas ANP coadministration significantly reversed this upregulation (Fig. 6b). Treatment of cultured cells with ET-1 significantly increased TN-C mRNA expression in a dose-dependent manner (Fig. 6c). Upregulation of Ang II-induced TN-C mRNA expression was significantly blocked by the ET-R antagonist bosentan and the ET-RA antagonist BQ123 (Fig. 6d, e), but not by the ET-RB antagonist BQ 788 (Fig. 6f).
Discussion
The present study clearly demonstrated that ANP treatment attenuates Ang II-induced cardiac inflammation, fibrosis, and hypertrophy, and improves systolic and/or diastolic cardiac function of the rat model.
It has been suggested that ANP may inhibit adverse cardiac remodeling by preventing cardiomyocyte hypertrophy and fibrosis based on G kinase activation [19, 35–37] in experiments using cultured cells and a natriuretic peptide receptor-deficient mice [38–40]. In our present study, ANP administration to rats significantly reversed Ang II-induced myocyte hypertrophy and fibrosis, which supports previous findings. Furthermore, we found that ANP obviously reduced infiltration of macrophages as well as expression of TN-C, an inflammatory marker, induced by Ang II administration.
The clinical significance of RAAS-mediated chronic myocardial inflammation is well recognized (reviewed in [41]). Inflammation and fibrosis are closely related; indeed, multiple factors associated with chronic inflammation are believed to induce fibrosis. Among these factors, matricellular proteins, a category of extracellular matrix molecules, have attracted considerable attention [31, 42]. Matricellular proteins do not contribute to the formation of fibers or basement membrane but rather serve as biological mediators by interacting directly with cells or regulating the activities of growth factors, cytokines, proteases, and other extracellular matrix proteins [43, 44]. TN-C is a typical matricellular protein expressed transiently at restricted sites during embryonic development, tissue injury, inflammation, and fibrosis [45, 46]. Several lines of evidence suggest that TN-C could act as a profibrotic and proinflammatory modulator by enhancing macrophage activity [31, 47, 48]. In fact, deletion of the TN-C gene in mice attenuates hepatitis and liver fibrosis [49], rheumatoid arthritis [50], and fibrosis after myocardial infarction [51].
Several reports have suggested that ANP may have an anti-inflammatory effect [52, 53] and may inhibit macrophage activity [54]. We proposed that ANP may weaken inflammation by downregulation of TN-C, a modulator of inflammation.
In general, major sources of TN-C in myocardium could be the interstitial fibroblasts, as we have previously reported [25, 33]. Ang II upregulates TN-C expression in cultured cardiac fibroblasts as well as proinflammatory cytokines, growth factors, and reactive oxygen species [28]. We speculate that Ang II may stimulate interstitial fibroblasts to induce TN-C expression, which is reduced by ANP.
Using cultured cardiac fibroblasts, we found that ANP suppressed TN-C expression induced by Ang II. We investigated the role of ET-1 in Ang II/TN-C signaling because several recent studies have linked ET-1 to fibrosis, inflammation, and cardiovascular remodeling in the downstream signaling of Ang II [55]. Furthermore, it is well known that ANP suppresses gene expression of ET-1 of cardiac fibroblasts, as an autocrine/paracrine factor [56, 57], attributable to G kinase [56]. We first confirmed that Ang II upregulated ET-1 expression, which was suppressed by ANP, as reported previously [56]. Second, we examined if ET-1 is involved in TN-C upregulation by Ang II in fibroblasts. Dual ET-R and ET-RA blockade significantly suppressed TN-C upregulation, whereas ET-RB blockade did not. Conversely, ET-1 increased TN-C expression. Taken together, these in vitro results suggested that ANP may suppress Ang II-induced TN-C synthesis, at least in part, by inhibiting the ET-1/ET-RA signaling pathway (Fig. 7). Recent reports have suggested that TN-C may enhance several signaling pathways, such as ET-1/ET-RA [58], transforming growth factor β [59], and platelet-derived growth factor [60] pathways. ANP may exert cardioprotective effects, at least partially, by suppressing TN-C that may modulate these inflammatory/fibrotic signaling cascades by creating a positive feedback loop (Fig. 7).
In the present study, we also clearly demonstrated that ANP treatment significantly attenuated cardiac hypertrophy without affecting blood pressure. As our group has previously reported, ANP can also suppress Ang II-induced cardiac hypertrophy by inhibiting the ET-1/ET-RA cascade [61, 62]. Therefore, ANP may exert a protective effect on cardiac interstitial cells as well as on cardiomyocytes, at least partly via the ET-1/ET-RA cascade.
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Acknowledgments
The authors thank M. Namikata for providing technical assistance, and also thank Dr Y. Ito (Division of Life Sciences, Department of Anatomy and Cell Biology, Osaka Medical College) for her excellent advice on confocal laser scanning microscopy, and A. Yamaki (ASUBIO Pharma Co., Ltd) for helpful discussion on the protocol design. This work was supported by JSPS Grants-in-Aid for Scientific Research #21590927(to K. I-Y.), and a research grant for intractable diseases from the Ministry of Health, Labor and Welfare of Japan (to K. I-Y. and Y. K.). Part of the study was also supported by a grant by Daiichi-Sankyo Co. Ltd.
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Fujita, S., Shimojo, N., Terasaki, F. et al. Atrial natriuretic peptide exerts protective action against angiotensin II-induced cardiac remodeling by attenuating inflammation via endothelin-1/endothelin receptor A cascade. Heart Vessels 28, 646–657 (2013). https://doi.org/10.1007/s00380-012-0311-0
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DOI: https://doi.org/10.1007/s00380-012-0311-0