CLINICAL PERSPECTIVE

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(Circulation. 2005;112:1636-1643.)
© 2005 American Heart Association, Inc.

Vascular Medicine

Deletion of Angiotensin II Type 2 Receptor Exaggerated Atherosclerosis in Apolipoprotein E–Null Mice

Masaru Iwai, MD, PhD; Rui Chen, MD, PhD; Zhen Li, MD, PhD; Tetsuya Shiuchi, PhD; Jun Suzuki, MD, PhD; Ayumi Ide, BS; Masahiro Tsuda, MD, PhD; Midori Okumura, MD; Li-Juan Min, MD; Masaki Mogi, MD, PhD; Masatsugu Horiuchi, MD, PhD

From the Department of Molecular and Cellular Biology, Division of Medical Biochemistry and Cardiovascular Biology, Ehime University School of Medicine, Shitsukawa, Tohon, Ehime, Japan.

Correspondence to Masatsugu Horiuchi, MD, PhD, Department of Molecular and Cellular Biology, Division of Medical Biochemistry and Cardiovascular Biology, Ehime University School of Medicine, Shitsukawa, Tohon, Ehime 791-0295, Japan. E-mail horiuchi{at}m.ehime-u.ac.jp

Received November 29, 2004; revision received April 21, 2005; accepted June 13, 2005.

	Abstract

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Background— The role of angiotensin II (Ang II) type 2 (AT₂) receptor in atherosclerosis was explored with the use of AT₂ receptor/apolipoprotein E (ApoE)–double-knockout (AT₂/ApoE-DKO) mice, with a focus on oxidative stress.

Methods and Results— After treatment with a high-cholesterol diet (1.25% cholesterol) for 10 weeks, ApoE-knockout (KO) mice developed atherosclerotic lesions in the aorta. In AT₂/ApoE-DKO mice receiving a high-cholesterol diet, the atherosclerotic changes were further exaggerated, without significant changes in plasma cholesterol level and blood pressure. In the atherosclerotic lesion, an increase in superoxide production, NADPH oxidase activity, and expression of p47^phox was observed. These changes were also greater in AT₂/ApoE-DKO mice. An Ang II type 1 (AT₁) receptor blocker, valsartan, inhibited atherosclerotic lesion formation, superoxide production, NADPH oxidase activity, and p47^phox expression; these inhibitory effects were significantly weaker in AT₂/ApoE-KO mice. We further examined the signaling mechanism of the AT₂ receptor–mediated antioxidative effect in cultured fetal vascular smooth muscle cells. NADPH oxidase activity and phosphorylation and translocation of p47^phox induced by Ang II were inhibited by valsartan but enhanced by an AT₂ receptor blocker, PD123319.

Conclusions— These results suggest that AT₂ receptor stimulation attenuates atherosclerosis through inhibition of oxidative stress and that the antiatherosclerotic effect of valsartan could be at least partly due to AT₂ receptor stimulation by unbound Ang II.

Key Words: angiotensin • atherosclerosis • receptors • oxidative stress

	Introduction

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Angiotensin II (Ang II) is a potent regulator of the cardiovascular system and is involved in vascular inflammation, oxidative stress, and cell proliferation, which are critical steps in atherosclerosis.^1,2 Results of clinical studies also suggest that blockade of Ang II type 1 (AT₁) receptor decreases events related to atherosclerosis.^1,2 We have previously demonstrated that atherosclerotic lesions in apolipoprotein E–null (ApoE-knockout [KO]) mice with deletion of the AT_1a receptor were significantly attenuated.³ However, the role of the type 2 (AT₂) receptor in atherosclerosis is not yet totally clear. Previous reports suggest that AT₂ receptor expression is decreased in most tissues after birth but increased again in certain pathological conditions.⁴ Stimulation of this increased AT₂ receptor appears to regulate neointimal formation, cell proliferation, and inflammation in vascular injury and myocardial infarction.^5–7 We have previously demonstrated that beneficial organ-protective effects of AT₁ receptor blockers are at least partly due to AT₂ receptor stimulation.^5,8 AT₂ receptor stimulation interacts with AT₁ receptor stimulation at intracellular signaling molecules, such as through activation of phosphatases.⁹ AT₁ receptor stimulation is known to activate NADPH oxidase, thereby inducing oxidative stress,^3,10 whereas the role of the AT₂ receptor in regulation of oxidative stress is poorly known.

ApoE-KO mice are widely used as an animal model of atherosclerosis. Treatment with a high-cholesterol diet induces atherosclerotic lesions predominantly in the aorta. Previous reports have shown that oxidative stress plays an important role in endothelial cell dysfunction and atherosclerotic formation.¹¹ Activation of NADPH oxidase produces superoxide, which then causes oxidation of membrane lipids and activates protein kinases.^12–14

In the present study we investigated the possible role of the AT₂ receptor in atherosclerosis using AT₂ receptor/ApoE–double-knockout (AT₂/ApoE-DKO) mice. The results suggested that AT₂ receptor stimulation might be involved in atherosclerotic changes partly through oxidative stress and that the antiatherosclerotic effect of valsartan could be at least partly due to AT₂ receptor stimulation by unbound Ang II.

	Methods

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Animals and Treatment
To generate AT₂/ApoE-DKO mice (backcrossed >10 times), ApoE-KO (B6.129P2-Apoe^tm1Unc, Jackson Laboratory, Bar Harbor, Maine, backcrossed 10 times) mice and AT₂-KO mice (based on C57BL/6J strain)⁵ were bred to yield mice heterozygous at the ApoE locus and heterozygous (female) and hemizygous (male) at the AT₂ receptor loci because the AT₂ receptor is located on the X chromosome. These mice were crossed and intercrossed to yield AT₂^–/– ApoE^–/– mice. The Animal Studies Committee of Ehime University approved the following experimental protocol. The animals were housed in a room with a 12-hour light/dark cycle, and temperature was maintained at 25°C. Adult male mice were given a standard diet (MF, Oriental Yeast) or high-cholesterol diet (1.25% cholesterol, 10% coconut oil in MF) for 10 weeks from 6 weeks of age and water ad libitum. Valsartan (provided by Novartis Pharma AG) (1 mg/kg per day), an AT₁ receptor–selective AT₁ receptor blocker, was administered with an osmotic minipump (Alzet model 1002, DURECT Corporation) implanted intraperitoneally as described previously.⁵ Plasma cholesterol level was measured by the cholesterol oxidase method (Cholesterol E-test, WAKO Chemical Industries, Ltd). Blood pressure was measured by the indirect tail-cuff method with a blood pressure monitor (MK-1030, Muromachi Kikai Co Ltd).

Determination of Atherosclerotic Lesion Size
The mice were killed at the age of 16 weeks, and the atherosclerotic lesions were analyzed as described previously.^3,15,16 The aorta was perfused with PBS by cardiac puncture, and then the aorta was dissected and cleaned of adherent connective tissue. The proximal portion of the thoracic aorta up to the aortic origin (aortic arch) was isolated, cleaned of the adherent connective tissue, embedded in Shandon M-1 Embedding Matrix (Thermo Electron Corporation), and stored at –80°C until use or fixed in 10% neutral buffered formalin overnight.

The area of atherosclerotic lesions in the proximal aorta and the lipid area in the area of aortic wall and the atherosclerotic lesions were determined by means of cross sections taken intermittently throughout 2 to 3 mm of the aortic arch with oil red O staining and counterstaining with hematoxylin. Quantitative analysis was performed with Densitograph Imaging Software (ATTO Corporation). Lesions in the descending aorta were also analyzed. The excised aorta (from aortic arch to iliac bifurcation) was dissected free from surrounding tissues and opened longitudinally. Atherosclerotic lesion area was quantified by analyzing the open luminal surface of oil red O–stained aorta with Densitograph Imaging Software. The amount of lesion formation in each animal was measured as the percentage of lesion area per total area of the aortic endothelial surface. The mean value of 5 sections was taken as the value for each animal.

Immunohistochemical staining of AT₁ and AT₂ receptors was performed with antibodies (Santa Cruz Biotechnology, Inc) and detected with diaminobenzidine.

Superoxide Detection
Frozen, enzymatically intact, 10-µm-thick sections of cross sections of the proximal aorta were incubated with dihydroethidium (10 µmol/L) in PBS for 30 minutes at 37°C in a humidified chamber protected from light.^3,17 Dihydroethidium is oxidized on reaction with superoxide to ethidium, which binds to DNA in the nucleus and fluoresces red. For ethidium detection, a 543-nm argon laser combined with a 500- to 550-nm bandpass filter was used. The intensity of fluorescence was normalized by staining the control section from the same aorta in each assay.

Immunofluorescent Staining
Immunofluorescence was assessed with the use of fresh-frozen sections. Sections were incubated with anti-p47^phox antibody, washed, and incubated with biotin-labeled secondary antibodies, then incubated with Cy3-labeled streptavidin. Serial sections treated with secondary antibodies alone did not show specific staining. Samples were examined with a Zeiss Axioskop microscope equipped with a computer-based imaging system.³ The intensity of fluorescence was expressed as pixels for fluorescence and normalized by staining the control section from the same aorta in each assay.

Cell Culture and Treatment
Fetal vascular smooth muscle cells (VSMCs) were prepared from the thoracic aorta of Sprague-Dawley rat fetuses (embryonic day 20) and cultured in Dulbecco’s modified Eagle’s medium (DMEM; Life Technologies Inc) supplemented with 10% fetal bovine serum (FBS) as previously described.¹⁸ All the experiments were performed with the use of cells at the second passage. Rat fetal VSMCs were grown in 10% FBS-DMEM to a subconfluent state and incubated for an additional 24 hours in serum-free DMEM to reach a quiescent state. In some experiments, adult VSMCs were isolated from adult Sprague-Dawley rat thoracic aorta (9 weeks of age; Clea Japan Inc) as previously described, exclusively expressing the AT₁ receptor but not AT₂ receptor.¹⁹ Adult VSMCs at passage 3 to 8 were used for the experiments. Subconfluent adult VSMCs were serum-starved for 48 hours to induce a quiescent state before the experiments.

The cells were incubated with Ang II (10^–7 mol/L) for the indicated times. In some experiments, VSMC were treated with an AT₁ receptor blocker, valsartan (10^–5 mol/L) (provided by Novartis Pharma AG, Basel, Switzerland), or an AT₂ receptor blocker, PD123319 (10^–5 mol/L) (Sigma Chemical Co), for 15 minutes and further incubated with Ang II in the presence of valsartan or PD123319. AT₁ and AT₂ receptor binding was measured as previously described.¹⁸

Measurement of NADPH Oxidase Activity in Aortic Tissue and Cultured Cell
An aortic arch sample was rapidly removed with the intact endothelium, homogenized in 500 µL ice-cold Tris-sucrose buffer (10 mmol/L Tris, pH 7.1, 340 mmol/L sucrose, 1 mmol/L EDTA, 1 mmol/L phenylmethylsulfonyl fluoride, 10 µg/mL aprotinin) and incubated for 30 minutes. Samples were centrifuged (15 000g, 10 minutes, 4°C), and the supernatant (20 µg protein) was added to reaction buffer (78 µmol/L cytochrome c [Sigma-Aldrich], 100 µmol/L NADPH [Sigma Chemical Co], with or without 1000 U/mL superoxide dismutase [Sigma Chemical Co]), and then incubated at 37°C for 60 minutes. NADPH oxidase activity was quantified from the absorbance with or without superoxide dismutase as previously described.²⁰

NADPH oxidase activity in cultured cell sample was measured as previously described with slight modification.²¹ Cell samples were centrifuged, and the pellet was resuspended in ice-cold Tris-sucrose buffer. NADPH oxidase activity was measured in a luminescence assay with 5 µmol/L lucigenin as the electron acceptor, with the use of 100 µmol/L NADPH as the substrate. Chemiluminescence was monitored with a luminometer (AB-2200, ATTO Corporation) for 5 minutes after the addition of cell extract.

Membrane Preparations From Fetal VSMCs
The membrane fraction of fetal VSMCs was isolated by the method of differential centrifugation based on standard protocols, as previously described.²² The cell homogenate was lightly centrifuged to remove unbroken parts and the nuclei-enriched fraction and then centrifuged for 60 minutes at 100 000g to obtain the membrane fraction. The pellets were suspended in homogenization buffer, and protein concentration was determined before immunoblotting.

Immunoprecipitation and Immunoblotting
Equal amounts of protein were incubated at 4°C with anti-p47^phox antibodies (Santa Cruz Biotechnology) for 3 hours with constant agitation and then further incubated with protein G-Sepharose 4 Fast Flow (Amersham Pharmacia Biotech) for 1 hour. For immunoblotting, the membrane fraction, whole-cell lysate, and immunoprecipitates were subjected to SDS-PAGE and transferred to nitrocellulose membranes. The membranes were incubated with anti-phosphoserine specific monoclonal antibodies (Sigma Chemical Co), anti-Rac1 antibodies (Upstate Biotechnology Inc), or anti-p47^phox antibodies and then visualized with an ECL detection kit (Amersham Pharmacia Biotech).

Statistical Analysis
Values are expressed as mean±SE in the text and figures. The data were analyzed by ANOVA. If a statistically significant effect was found, Newman-Keuls test was performed to detect the difference between the groups. A value of P<0.05 was considered statistically significant.

	Results

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Atherosclerotic Lesion Formation in AT₂/ApoE-DKO Mice
Treatment with a high-cholesterol diet for 10 weeks markedly increased plasma cholesterol level but did not significantly affect blood pressure in ApoE-KO mice (Table). In AT₂/ApoE-DKO mice, blood pressure and plasma cholesterol level were not significantly different from those in ApoE-KO mice, both before and after treatment with high-cholesterol diet (Table).

View this table: [in this window] [in a new window]   Systolic Blood Pressure and Plasma Concentration of Cholesterol in ApoE-KO and AT2/ApoE-DKO Mice

After treatment with high-cholesterol diet for 10 weeks, atherosclerotic lesions and lipid accumulation were observed in the proximal aorta of ApoE-KO mice (Figure 1A and 1B) as well as in descending aorta (Figure 1C). In our experimental schedule, ApoE-KO mice treated with normal standard diet did not show apparent atherosclerotic changes. In the atherosclerotic lesions in ApoE-KO mice, expression of the AT₁ and AT₂ receptors determined by immunohistochemical staining was increased not only in the lesion but also in the aortic wall (Figure 2). Treatment with valsartan did not seem to change AT₁ and AT₂ receptor expression apparently (Figure 2). AT₁ receptor expression in AT₂/ApoE-DKO mice was increased to a degree similar to that in ApoE-KO mice (data not shown). In AT₂/ApoE-DKO mice receiving a normal standard diet, the atherosclerotic area and lipid accumulation in the proximal aorta were not significantly different from those in ApoE-KO mice. However, after mice received a high-cholesterol diet, the atherosclerotic area and lipid accumulation in the proximal aorta were further enhanced compared with those in ApoE-KO mice (Figure 1).

View larger version (52K): [in this window] [in a new window]   Figure 1. Atherosclerotic changes in ApoE-KO and AT2/ApoE-DKO mice after treatment with high-cholesterol diet for 10 weeks. Animals received a normal standard diet or high-cholesterol diet containing 1.25% cholesterol for 10 weeks, and aortic samples were obtained as described in Methods. Frozen sections of the proximal aorta were prepared and stained with oil red O to determine lipid deposition and counterstained with hematoxylin to measure the lesion area. A, Representative staining of the proximal aorta with oil red O in ApoE-KO and AT2/ApoE-DKO mice with or without treatment with an AT1 receptor blocker, valsartan. Magnification x200. a, ApoE-KO mouse with normal standard diet (n=7). b, ApoE-KO mouse with high-cholesterol diet (n=8). c, ApoE-KO mouse with high-cholesterol diet and valsartan (n=6). d, AT2/ApoE-DKO mouse with normal standard diet (n=5). e, AT2/ApoE-DKO mouse with high-cholesterol diet (n=7). f, AT2/ApoE-DKO mouse with high-cholesterol diet and valsartan (n=6). Bar=100 µm. B, Morphological measurement of atherosclerotic lesion area (top) and lipid deposition (bottom) in cross sections of proximal aorta. C, Morphological measurement of atherosclerotic plaque area in descending aorta. Plaque area was measured as the percentage of lesion (fat-positive) area per total area of the aortic endothelial surface. Quantitative analysis of aortic samples was performed with the use of imaging software as described in Methods. The mean value of 5 sections was taken as the value for each animal. Values are mean±SE of morphometric measurements. Val indicates valsartan (1 mg/kg per day); HCD, high-cholesterol diet. *P<0.05 vs high-cholesterol diet in ApoE-KO and AT2/ApoE-DKO mice, respectively; **P<0.05 vs ApoE-KO mice with high-cholesterol diet; P<0.05 vs ApoE KO+valsartan.

View larger version (117K): [in this window] [in a new window]   Figure 2. Immunohistochemical detection of AT1 and AT2 receptors in proximal aorta of ApoE-KO mice after treatment with high-cholesterol diet. Aortic samples were obtained as in Figure 1. Expression of AT1 and AT2 receptors in the proximal aorta were detected with immunohistochemical staining with anti-AT1 and anti-AT2 antibodies as described in Methods. a, b, c, Immunostaining of AT1 receptor. d, e, f, Immunostaining of AT2 receptor. a, d, Normal standard diet. b, e, High-cholesterol diet. c, f, High-cholesterol diet and valsartan. Bar=100 µm.

Changes in Oxidative Stress in Atherosclerotic Lesion of AT₂/ApoE-DKO Mice
Figure 3 shows the in situ detection of superoxide in the proximal aorta with the use of dihydroethidium. Superoxide production was increased in the atherosclerotic aorta of ApoE-KO mice receiving high-cholesterol diet compared with those receiving a normal diet. This increase in superoxide production was further exaggerated in AT₂/ApoE-DKO mice, not only in the atherosclerotic lesion but also in smooth muscle cells (Figure 3). NADPH oxidase activity and expression of the NADPH oxidase subunit, p47^phox, were also increased in the atherosclerotic aorta (Figures 4 and 5). In parallel with the changes in superoxide production, NADPH oxidase activity and expression of p47^phox were further enhanced in the lesion area and aortic wall of AT₂/ApoE-DKO mice.

View larger version (37K): [in this window] [in a new window]   Figure 3. In situ detection of superoxide in proximal aorta of ApoE-KO and AT2/ApoE-DKO mice treated with high-cholesterol diet. Aortic samples were obtained as in Figure 1. Superoxide production in the proximal aorta was detected as red fluorescence after incubation with dihydroethidium as described in Methods. A, Representative fluorescent staining of superoxide with dihydroethidium in the proximal aorta of ApoE-KO and AT2/ApoE-DKO mice with or without treatment with an AT1 receptor blocker, valsartan. Magnification x200. a, ApoE-KO mouse with normal standard diet. b, ApoE-KO mouse with high-cholesterol diet. c, ApoE-KO mouse with high-cholesterol diet and valsartan. d, AT2/ApoE-DKO mouse with normal standard diet. e, AT2/ApoE-DKO mouse with high-cholesterol diet. f, AT2/ApoE-DKO mouse with high-cholesterol diet and valsartan. Bar=100 µm. B, Fluorescence intensity produced by superoxide in cross sections of proximal aorta. Quantitative analysis was performed with the use of imaging software as described in Methods. The mean value of 5 sections was taken as the value for each animal. Values are mean±SE of morphometric measurements (n=5 to 8). Val indicates valsartan (1 mg/kg per day); HCD, high-cholesterol diet. *P<0.05 vs high-cholesterol diet in ApoE-KO and AT2/ApoE-DKO mice, respectively; **P<0.05 vs ApoE-KO mice with high-cholesterol diet; P<0.05 versus ApoE KO+valsartan.

View larger version (14K): [in this window] [in a new window]   Figure 4. Changes in NADPH oxidase activity in aorta of ApoE-KO and AT2/ApoE-DKO mice treated with high-cholesterol diet. Protein samples were prepared, and NADPH oxidase activity was measured as described in Methods. Values are mean±SE of morphometric measurements (n=4 to 6). Val indicates valsartan (1 mg/kg per day); HCD, high-cholesterol diet. *P<0.05 vs high-cholesterol diet in ApoE-KO and AT2/ApoE-DKO mice, respectively; **P<0.05 vs ApoE-KO mice with high-cholesterol diet; P<0.05 vs ApoE KO+valsartan.

View larger version (39K): [in this window] [in a new window]   Figure 5. Immunofluorescent staining of p47phox in proximal aorta of ApoE-KO and AT2/ApoE-DKO mice treated with high-cholesterol diet. Aortic samples were obtained as in Figure 1. Expression of p47phox in the proximal aorta was detected with immunofluorescent staining with the use of anti-p47phox antibodies as described in Methods. A, Representative fluorescent staining of p47phox in the proximal aorta of ApoE-KO and AT2/ApoE-DKO mice with or without treatment with an AT1 receptor blocker, valsartan. Magnification x200. a, ApoE-KO mouse with normal standard diet. b, ApoE-KO mouse with high-cholesterol diet. c, ApoE-KO mouse with high-cholesterol diet and valsartan. d, AT2/ApoE-DKO mouse with normal standard diet. e, AT2/ApoE-DKO mouse with high-cholesterol diet. f, AT2/ApoE-DKO mouse with high-cholesterol diet and valsartan. Bar=100 µm. B, Fluorescence intensity of p47phox in cross sections of proximal aorta. Quantitative analysis was performed with the use of imaging software as described in Methods. The mean value of 5 sections was taken as the value for each animal. Values are mean±SE of morphometric measurements (n=5 to 8). Val indicates valsartan (1 mg/kg per day); HCD, high-cholesterol diet. *P<0.05 vs high-cholesterol diet in ApoE-KO and AT2/ApoE-DKO mice, respectively; **P<0.05 vs ApoE-KO mice with high-cholesterol diet; P<0.05 vs ApoE KO+valsartan.

Effect of Valsartan on Atherosclerotic Changes in AT₂/ApoE-DKO Mice
Treatment with an AT₁ receptor blocker, valsartan, at a dose of 1 mg/kg per day inhibited atherosclerotic lesion formation and lipid accumulation as well as superoxide production, NADPH oxidase activity, and NADPH oxidase expression in the aorta of ApoE-KO mice given a high-cholesterol diet (Figure 1 and Figures 3 to 5). However, these inhibitory effects of valsartan on atherosclerosis were significantly weaker in AT₂/ApoE-DKO mice (60.0% versus 38.6% inhibition of proximal lesion area, 55.3% versus 19.8% inhibition of proximal lipid deposition, and 91.8% versus 53.5% inhibition of plaque area in descending aorta for ApoE-KO and AT₂/ApoE-DKO mice, respectively; P<0.05; Figure 1B and 1C). Similar attenuation of the inhibitory action of valsartan in AT₂/ApoE-DKO mice was observed for superoxide production (81.2% versus 53.7% inhibition for ApoE-KO and AT₂/ApoE-DKO mice, respectively; P<0.05), NADPH oxidase activation (35.8% versus 12.2% inhibition for ApoE-KO and AT₂/ApoE-DKO mice, respectively; P<0.05), and p47^phox expression (68.4% versus 47.4% inhibition for ApoE-KO and AT₂/ApoE-DKO mice, respectively; P<0.05) in Figures 3B, 4, and 5B.

Effect of AT₂ Receptor Stimulation on NADPH Oxidase Activity in Fetal VSMCs
We next examined the signaling mechanism of action of AT₂ receptor stimulation on NADPH oxidase activity using rat fetal VSMCs, which expressed both AT₁ and AT₂ receptors (AT₁ receptor, 11.21±0.42 fmol/10⁶ cells; AT₂ receptor, 6.58±1.09 fmol/10⁶ cells), as previously described.¹⁸ Ang II increased NADPH oxidase activity in fetal VSMCs after 3 hours of stimulation. An AT₁ receptor blocker, valsartan, inhibited the Ang II–mediated increase in NADPH oxidase activity (Figure 6). However, NADPH oxidase activity induced by Ang II was further increased in the presence of PD123319 after 30 minutes. Neither valsartan nor PD123319 alone influenced NADPH oxidase activity (Figure 6A). Moreover, when the cells were pretreated with valsartan, PD123319 did not enhance NADPH oxidase activity at 30 minutes after Ang II stimulation (Figure 6B; Ang II, 119.3±3.2%; Ang II+valsartan, 100.5±3.2%; Ang II+valsartan+PD123319, 101.2±2.1%, expressed as percentages from basal level; n=5). The Ang II receptor subtype detected by receptor binding assay was not significantly changed in these experimental conditions (data not shown).

View larger version (27K): [in this window] [in a new window]   Figure 6. A, NADPH oxidase activity in fetal VSMCs stimulated by Ang II with or without valsartan and PD123319. Fetal VSMCs were prepared from the thoracic aorta of Sprague-Dawley rat fetuses (embryonic day 20) and cultured as described in Methods. After 16 hours of incubation with 0.1% FBS-DMEM, Ang II (10–7 mol/L) was added, and cells were incubated for the indicated times. Valsartan (10–5 mol/L) or PD123319 (10–5 mol/L) was added 15 minutes before stimulation with Ang II. NADPH oxidase activity was measured as described in Methods. Data are mean±SE from 4 separate experiments. *P<0.05 vs 0 hours; **P<0.01 vs 0 hours. B, NADPH oxidase activity in adult VSMCs stimulated by Ang II for 3 hours with or without valsartan and PD123319. Adult VSMCs were prepared from the thoracic aorta of adult Sprague-Dawley rat and cultured as described in Methods. After 16 hours of incubation with 0.1% FBS-DMEM, Ang II (10–7 mol/L) was added, and cells were incubated for 3 hours. Valsartan (10–5 mol/L) or PD123319 (10–5 mol/L) was added 15 minutes before stimulation with Ang II. NADPH oxidase activity was measured as described in Methods. Data are mean±SE from 4 separate experiments. *P<0.05 vs control.

On the other hand, the same dose of valsartan completely inhibited the effect of Ang II on NADPH oxidase activation even in adult VSMCs (Figure 6B), which dominantly expressed AT₁ receptor (9.10±0.59 fmol/10⁶ cells) and AT₂ receptor (0.08±0.02 fmol/10⁶ cells), as previously reported.¹⁹

Effect of AT₂ Receptor Stimulation on p47^phox Subunit of NADPH Oxidase, Rac1, and Akt in Fetal VSMCs
The effects of AT₁ or AT₂ receptor stimulation on serine phosphorylation of the p47^phox subunit of NADPH oxidase was examined in fetal VSMCs (Figure 7A). Ang II stimulation for 10 minutes significantly increased serine phosphorylation of p47^phox. Valsartan decreased Ang II–mediated serine phosphorylation of p47^phox, whereas treatment with PD123319 further increased it (Figure 7A). Moreover, Ang II stimulation significantly increased translocation of p47^phox and Rac1 to the plasma membrane fraction of fetal VSMCs. This translocation was attenuated by the addition of valsartan but was further increased by the addition of PD123319 (Figure 7B and 7C). Ang II–mediated Akt phosphorylation in fetal VSMCs was also inhibited by valsartan but was enhanced by PD123319 (Figure 7D).

View larger version (37K): [in this window] [in a new window]   Figure 7. Effect of AT1 and/or AT2 receptor stimulation on Ang II–mediated signaling pathway for NADPH oxidase activation in fetal VSMCs. Fetal VSMCs were cultured and treated with Ang II with or without valsartan and PD123319 as in Figure 4. A, Phosphorylation of p47phox. B, Translocation of p47phox to plasma membrane. C, Translocation of Rac1 to plasma membrane. D, Phosphorylation of Akt. Top panels show a representative immunoblot, and bottom panels show densitometric measurements of 4 separate experiments. Data are mean±SE. *P<0.05 vs control; **P<0.01 vs control.

	Discussion

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To explore the role of AT₂ receptor stimulation in the pathogenesis of atherosclerosis using ApoE-KO mice, we generated a new strain in which the AT₂ receptor is deleted (AT₂/ApoE-DKO mice). The present study showed that atherosclerotic changes were aggravated in AT₂/ApoE-DKO mice compared with ApoE-single-KO mice. The atherosclerotic change was associated with an increase in oxidative stress determined by superoxide production, NADPH oxidase activity, and NADPH oxidase subunit expression. These changes were also further enhanced in AT₂/ApoE-DKO mice. In in vitro experiments in which fetal VSMCs were used, AT₂ receptor stimulation inhibited NADPH oxidase activity and expression and/or translocation of subunits of NADPH oxidase. These results indicate that AT₂ receptor stimulation plays an important role in atherosclerotic lesion formation through regulation of oxidative stress.

It is reported that AT₁ receptor stimulation is involved in the development of atherosclerosis in ApoE-KO mice. Indeed, it was previously reported that atherosclerotic changes were significantly attenuated in AT_1a/ApoE-KO mice.^3,23 The effects of AT₁ receptor stimulation appear to be mediated by inflammatory responses, oxidative stress, and cell proliferation.^3,5 In contrast, previous results suggest that AT₂ receptor stimulation exerts antiinflammatory and antiproliferative effects on the vasculature.^4,5,7 However, the effect of AT₂ receptor stimulation on oxidative stress is still an enigma. In the present study in which AT₂/ApoE-DKO mice were used, it was indicated that a lack of AT₂ receptor induced significant enlargement of atherosclerotic lesions after treatment with a high-cholesterol diet. This enlargement in AT₂/ApoE-DKO mice did not depend on changes in systemic blood pressure and plasma cholesterol level, suggesting that AT₂ receptor stimulation inhibits atherosclerotic changes in ApoE-KO mice. This effect of the AT₂ receptor stimulation seems to be mediated at least in part by oxidative stress as well as inflammatory response (Figures 3 to 5).^3,5,8 In contrast, it has very recently been reported that AT₂ receptor deficiency had no effect on atherosclerosis lesion area in LDL receptor–deficient mice.²⁴ This apparently different result for the role of AT₂ receptor from that in the present report might be due to the difference in animal model, although future study is necessary to clarify the detailed mechanism of AT₂ receptor function.

Oxidative stress, including production of reactive oxygen species, plays an important role in the pathogenesis of atherosclerosis.²⁵ Previous studies suggest that NADPH oxidase is a key enzyme in superoxide production and that the enzyme activity is regulated by expression of its subunit.²⁶ It is also reported that AT₁ receptor stimulation activated reactive oxygen species production in vascular cells in vitro as well as in vivo.^26,27 In the mouse microvascular endothelial NADH/NADPH system, Ang II stimulated NADH/NADPH oxidase activity through serine phosphorylation of p47^phox and its enhanced binding to p22^phox.²⁸ In the present study superoxide production, NADPH oxidase activity, and expression of an NADPH oxidase subunit, p47^phox, were markedly increased in atherosclerotic lesions (Figures 3 to 5). This increase in oxidative stress was located not only in the lesion but also in aortic smooth muscle cells. The increase in superoxide production, NADPH oxidase activity, and p47^phox expression was further enhanced in AT₂/ApoE-DKO mice, similar to the change in atherosclerotic lesion area (Figures 3 to 5). These results suggest that the antiatherosclerotic effects of AT₂ receptor stimulation are mediated at least partly through modulation of oxidative stress.

In cultured fetal VSMCs, blockade of the AT₂ receptor by PD123319 significantly enhanced the Ang II–induced increase in NADPH oxidase activity, whereas an AT₁ receptor blocker, valsartan, inhibited it. Moreover, PD123319 did not enhance NADPH oxidase activity after pretreatment of cells with valsartan. Because PD123319 or valsartan alone did not affect basal NADPH activity, these results indicate that AT₂ receptor stimulation antagonized AT₁ receptor–mediated NADPH oxidase activation. AT₁ receptor stimulation seems to be a prerequisite for the AT₂ receptor to exert its inhibitory effect on NADPH oxidase activation. It is well known that serine phosphorylation of the p47^phox subunit of NADPH oxidase plays a critical role in the activation of NADPH oxidase.^28,29 In our experiments the regulation of NADPH oxidase activity appeared to be mediated by phosphorylation of p47^phox and translocation of Rac1 to the plasma membrane (Figure 7). The mechanism of action of AT₂ receptor stimulation on NADPH oxidase activity includes, at least in part, the inhibition of the activation and translocation of NADPH oxidase subunits. The detailed pathway of intracellular signaling after NADPH oxidase mediated by AT₂ receptor has not yet been clarified. However, blockade of the AT₂ receptor increased the phosphorylation of Akt in fetal VSMCs. Previous reports also indicate the important role of Akt in the action of oxidative stress.³⁰ These results suggest that Akt activation mediates intracellular signaling in the aorta to produce atherosclerosis and that AT₂ receptor stimulation exerts an inhibitory action by regulation of oxidative stress, at least in part, through Akt activation. Taken together, our results provide novel insights into the pathogenesis of atherosclerosis regulated by distinct Ang II receptor subtypes. More detailed analysis of the AT₂ receptor–mediated antiatherosclerotic effect would contribute to the development of a new rationale for therapeutic concepts.

	Acknowledgments

 
This work was supported by grants from the Ministry of Education, Science, Sports, and Culture of Japan, Cardiovascular Research Foundation, Mitsubishi Pharma Research Foundation, Takeda Science Foundation, and Novartis Foundation of Gerontological Research.

	References

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CLINICAL PERSPECTIVE

The detailed mechanism of atherosclerosis formation and roles of angiotensin II (Ang II) receptor subtypes are not yet clear. Results of clinical studies also suggest that blockade of Ang II type 1 (AT₁) receptor decreases events related to atherosclerosis. The results in our previous reports suggest that Ang II type 2 (AT₂) receptor stimulation induces beneficial effects in cardiovascular remodeling, which could be expected with an AT₁ receptor blocker. In the present study we examined the role of AT₂ receptor stimulation in atherosclerosis formation. Apolipoprotein E–deficient (ApoE-knockout [KO]) mice treated with a high-cholesterol diet are commonly used as an animal model of atherosclerosis. For this study we generated double gene–knockout mice, which lack both AT₂ receptor and ApoE (AT₂/ApoE-DKO mice). Compared with ApoE-KO mice, less enhancement of atherosclerotic formation and the weaker antiatherosclerotic effect of an AT₁ receptor blocker, valsartan, in AT₂/ApoE-DKO mice indicated that the inhibitory action of AT₂ receptor stimulation on atherosclerosis plays a role and the involvement of AT₂ receptor stimulation is associated with the effects of AT₁ receptor blockers. Because the cardiovascular system also expresses AT₂ receptor in humans, especially in diseased states such as vascular injury and atherosclerosis, our results suggest the therapeutic beneficial effects of AT₂ receptor stimulation on atherosclerosis. Our results propose a possibility of therapeutic use of AT₂ receptor stimulant for patients with atherosclerosis. Although a selective AT₂ receptor agonist has not yet been developed for the clinical setting, the development of a stable AT₂ receptor agonist might provide us with a new therapeutic tool for cardiovascular disease.

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