This Article Abstract Full Text (PDF) All Versions of this Article: 42/2/206    most recent 01.HYP.0000082814.62655.85v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Privratsky, J. R. Articles by Ren, J. Search for Related Content PubMed PubMed Citation Articles by Privratsky, J. R. Articles by Ren, J. Pubmed/NCBI databases Compound via MeSH Substance via MeSH Hazardous Substances DB GLUCOSE SODIUM LAURYL SULFATE Related Collections Contractile function ACE/Angiotension receptors Calcium cycling/excitation-contraction coupling Cell signalling/signal transduction Myocardial cardiomyopathy disease Type 2 diabetes

(Hypertension. 2003;42:206.)
© 2003 American Heart Association, Inc.

Scientific Contributions

AT₁ Blockade Prevents Glucose-Induced Cardiac Dysfunction in Ventricular Myocytes

Role of the AT₁ Receptor and NADPH Oxidase

Jamie R. Privratsky; Loren E. Wold; James R. Sowers; Mark T. Quinn; Jun Ren

From the Department of Pharmacology, Physiology, and Therapeutics, University of North Dakota School of Medicine and Health Sciences (J.R.P., L.E.W., J.R.), Grand Forks; the Department of Medicine and Biochemistry, State University of New York Downstate Medical Center (J.R.S.), Brooklyn Veteran Affairs, Brooklyn; and the Department of Veterinary Molecular Biology, Montana State University (M.T.Q.), Bozeman.

Correspondence to Dr Jun Ren, Associate Professor, Division of Pharmaceutical Sciences, University of Wyoming College of Health Sciences, Laramie, WY 82071-3375. E-mail jren{at}uwyo.edu

	Abstract

Top Abstract Introduction Methods Results Discussion References

 
Enhanced tissue angiotensin (Ang) II levels have been reported in diabetes and might lead to cardiac dysfunction through oxidative stress. This study examined the effect of blocking the Ang II type 1 (AT₁) receptor on high glucose–induced cardiac contractile dysfunction. Rat ventricular myocytes were maintained in normal- (NG, 5.5 mmol/L) or high- (HG, 25.5 mmol/L) glucose medium for 24 hours. Mechanical and intracellular Ca²⁺ properties were assessed as peak shortening (PS), time to PS (TPS), time to 90% relengthening (TR₉₀), maximal velocity of shortening/relengthening (±dL/dt), and intracellular Ca²⁺ decay (). HG myocytes exhibited normal PS; decreased ±dL/dt; and prolonged TPS, TR₉₀, and . Interestingly, the HG-induced abnormalities were prevented with the AT₁ blocker L-158,809 (10 to 1000 nmol/L) but not the Janus kinase-2 (JAK2) inhibitor AG-490 (10 to 100 µmol/L). The only effect of AT₁ blockade on NG myocytes was enhanced PS at 1000 nmol/L. AT₁ antagonist-elicited cardiac protection against HG was nullified by the NADPH oxidase activator sodium dodecyl sulfate (80 µmol/L) and mimicked by the NADPH oxidase inhibitors diphenyleneiodonium (10 µmol/L) or apocynin (100 µmol/L). Western blot analysis confirmed that the protein abundance of NADPH oxidase subunit p47^phox and the AT₁ but not the AT₂ receptor was enhanced in HG myocytes. In addition, the HG-induced increase of p47^phox was prevented by L-158,809. Enhanced reactive oxygen species production observed in HG myocytes was prevented by AT₁ blockade or NADPH oxidase inhibition. Collectively, our data suggest that local Ang II, acting via AT₁ receptor–mediated NADPH oxidase activation, is involved in hyperglycemia-induced cardiomyocyte dysfunction, which might play a role in diabetic cardiomyopathy.

Key Words: glucose • cardiac function • cardiomyopathy • oxidases • angiotensin II

	Introduction

Top Abstract Introduction Methods Results Discussion References

 
Diabetic cardiomyopathy, one of the leading causes of increased morbidity and mortality in the diabetic population, is defined as a phenotypic change(s) in cardiac muscle, independent of micro- and macrovascular disease, coronary artery disease, and hypertension.^1–3 It is characterized by prolongation of action potential duration, delayed cytosolic Ca²⁺ clearance, and impaired ventricular function, especially during diastole.^4–6 Several factors have been postulated to contribute to the pathogenesis of diabetic cardiomyopathy, including hyperglycemia, insulin resistance, and free-radical damage,^3,4 among which hyperglycemia is considered one of the most important factors in the onset of diabetic cardiomyopathy.^4,7

The renin-angiotensin system (RAS) plays a major role in the regulation of blood pressure and other cardiovascular functions. Enhanced RAS activity has been demonstrated in several cardiovascular diseases, such as diabetes and hypertension, and might play a role in the pathogenesis of congestive heart failure, coronary insufficiency, and hypertensive cardiomyopathy.⁸ The hypertrophic and growth-promoting effects of angiotensin (Ang) II are mediated primarily through its type I receptor (AT₁).⁸ Enhanced tissue RAS action is thought to contribute to cardiovascular disease in diabetes, including diabetic cardiomyopathy.⁸ In addition, AT₁ receptor stimulation induces the generation of oxygen-derived free radicals, which can have detrimental effects.^9,10 Several postreceptor signaling pathways have been demonstrated to be coupled to the AT₁ receptor, including Janus kinase (JAK)/signal transducer and activator of transcription (STAT) and NADPH oxidase.^11,12 The JAK/STAT proteins might transmit intracellular signals elicited by various kinds of cytokines and growth factors in a wide variety of cell types.¹³ On the other hand, NADPH oxidase is a membrane-bound enzyme that catalyzes the electron reduction of oxygen, with NADH or NADPH as electron donors.^14,15 Nevertheless, the precise role of Ang II and its downstream signaling in the onset of cardiac dysfunction, especially in diabetes, is poorly understood. We have established an in vitro model of diabetic cardiomyopathy by culturing ventricular myocytes in a high-glucose (HG) medium for 24 hours.¹⁶ The aim of the present study was to determine the effect of AT₁ receptor blockade with the AT₁ receptor–specific antagonist L-158,809 on glucose toxicity–induced cardiac mechanical dysfunction and the potential signaling pathways involved.

	Methods

Top Abstract Introduction Methods Results Discussion References

 
Isolation and Culture of Ventricular Myocytes
The experimental procedures were approved by the institutional Animal Care and Use Committee of the University of North Dakota. Ventricular myocytes were isolated from adult, male Sprague-Dawley rats (200 to 250 g; Harlan, Indianapolis, Ind) under sterile conditions by collagenase (176 U/mL) and hyaluronidase (0.1 mg/mL) perfusion through the coronaries and were further digested by trypsin (0.02 mg/mL) after the tissue was minced. Isolated myocytes were plated on glass coverslips precoated with laminin (10 µg/mL) and maintained for 24 hours in a defined medium consisting of medium 199 with Earle’s salts containing 25 mmol/L HEPES and NaHCO₃ supplemented with albumin (2 mg/mL), L-carnitine (2 mmol/L), creatine (5 mmol/L), taurine (5 mmol/L), insulin (0.1 µmol/L), penicillin (100 U/mL), streptomycin (100 µg/mL), and gentamicin (100 µg/mL). This medium also contained either normal-glucose (NG, 5.5 mmol/L) or HG (25.5 mmol/L) concentrations. The HG concentration is comparable to serum glucose levels in severely diabetic rats. Subsets of each medium were also supplemented with the AT₁ antagonist L-158,809 (10 to 1000 nmol/L; Merck Research Laboratories, Rahway, NJ), the JAK2 inhibitor AG-490 (10 and 100 µmol/L), the NADPH oxidase activator sodium dodecyl sulfate (SDS, 80 µmol/L), the NADPH oxidase substrate NADPH (100 µmol/L), or the NADPH inhibitors diphenyleneiodonium (DPI, 10 µmol/L) or apocynin (10 µmol/L). The myocytes in either NG or HG medium were incubated overnight at 37°C under 100% humidity and 5% CO₂.¹⁶

Cell Shortening and Relengthening
Mechanical properties of ventricular myocytes were assessed with the use of a commercially available system (IonOptix, MyoCam system, IonOptix Corp).¹⁶ In brief, cells were placed in a Warner chamber mounted on the stage of an inverted microscope (Olympus IX-70) and superfused (1 mL/min at 30°C) with a buffer containing (in mmol/L) 131 NaCl, 4 KCl, 1 CaCl₂, 1 MgCl₂, 10 glucose, and 10 HEPES, at pH 7.4. Cells were field-stimulated with a suprathreshold voltage at a frequency of 0.5 Hz. The myocytes being studied were displayed on the computer monitor with the IonOptix MyoCam camera. SoftEdge software (IonOptix) was used to capture changes in cell length during shortening and relengthening.

Intracellular Ca²⁺ Fluorescence Measurements
A separate cohort of myocytes was loaded with fura 2-AM (0.5 µmol/L) for 10 minutes, and fluorescence measurements were recorded with a dual-excitation fluorescence photomultiplier system (IonOptix), as described.¹⁶ Myocytes were placed in a chamber on an inverted microscope (Olympus IX-70) at 30°C and imaged through a Fluor 40x oil objective. Cells were exposed to light emitted by a 75-W lamp and passed through either a 360- or a 380-nm filter (bandwidths were ±15 nm) while being stimulated to contract at 0.5 Hz. Fluorescence emissions were detected between 480 and 520 nm by a photomultiplier tube after first illuminating the cells at 360 nm for 0.5 second and then at 380 nm for the duration of the recording protocol (333-Hz sampling rate). The 360-nm excitation scan was repeated at the end of the protocol, and qualitative changes in intracellular Ca²⁺ concentration were inferred from the ratio of the fluorescence intensity at the 2 wavelengths.

Western Blot Analysis
Membrane proteins from NG- or HG-cultured myocytes were extracted as described.¹⁷ Myocytes were collected and sonicated, and the supernatants were centrifuged at 7000g for 30 minutes at 4°C. Total cell homogenates from the pellets were used for immunoblotting of the NADPH oxidase subunit p47^phox and AT₁ and AT₂ receptors. We confirmed that these membrane fractions did not contain any detectable collagens. Membrane proteins (50 µg/lane) were separated on 10% (AT₁ and AT₂) or 15% (p47^phox) SDS-polyacrylamide gels in a Minigel apparatus (Mini-Protean II, Bio-Rad) and transferred to polyvinylidene difluoride membranes. The membranes were blocked with 3% BSA with Tris-buffered saline–Tween-20 solution for 60 minutes and then incubated overnight with anti-p47^phox (1:1000), anti-AT₁ (1:500), or anti-AT₂ (1:500) antibodies. Monoclonal antibody recognizing the NADPH oxidase subunit p47^phox has been previously described.¹⁸ Anti-AT₁ (monoclonal) and anti-AT₂ (polyclonal) antibodies were obtained from Abcam Limited and Santa Cruz Biotechnology, respectively. The antigens were detected by the luminescence method with a commercially available substrate (Supersignal West Dura extended duration substrate, Pierce Co). After immunoblotting, the film was scanned and the intensity of immunoblot bands was detected with a densitometer (Bio-Rad model GS-800).

Analysis of ROS Production by Myocytes
Production of cellular reactive oxygen species (ROS) was evaluated by analyzing the changes in fluorescence intensity resulting from oxidation of the intracellular fluoroprobe 5-(6)-chloromethyl-2',7'-dichlorodihydrofluorescein diacetate (CM-H₂DCFDA).¹⁹ In brief, isolated myocytes from each group were loaded with 1 µmol/L of the nonfluorescent dye H₂DCFDA (Molecular Probes) at 37°C for 30 minutes. The myocytes were rinsed, and the fluorescence intensity was then measured with a fluorescence microplate reader at an excitation wavelength of 480 nm and an emission wavelength of 530 nm (Molecular Devices). Untreated cells showed no fluorescence and were used to determine background fluorescence, which was subtracted from the treated samples. The final fluorescence intensity was normalized to the protein content in each myocyte group and was expressed as the percentage of the fluorescence intensity of the NG group.

Data Analysis
For each experimental series, data are presented as mean±SEM. Statistical significance (P<0.05) for each variable was estimated by ANOVA. A Dunnett test was used for post hoc analysis when required.

	Results

Top Abstract Introduction Methods Results Discussion References

 
Effect of L-158,809 on Mechanical and Fluorescence Properties of NG and HG Myocytes
As previously reported,¹⁶ maintaining myocytes for 24 hours in NG or HG medium had no significant effects on cell phenotype (data not shown). Myocyte shape, resting cell length, and the presence of distinct, cellular striations were comparable between NG and HG myocytes. Myocytes from the HG group exhibited significantly depressed maximal velocities of shortening/relengthening (±dL/dt) and prolonged duration of shortening and relengthening (time to peak shortening [TPS] and time to 90% relengthening [TR₉₀]) associated with comparable peak shortening (PS), consistent with previous observations.¹⁶ Cotreatment with the AT₁ receptor antagonist L-158,809 (10 to 1000 nmol/L) significantly attenuated the HG-induced decreases in ±dL/dt and the prolongation of TPS and TR₉₀ (Figure 1). Low levels of L-158,809 (10 and 100 nmol/L) exerted no effect on PS, whereas the highest level of L-158,809 examined (1000 nmol/L) significantly enhanced PS (Figure 1). Figure 2 shows that myocytes maintained in HG medium displayed similar baseline intracellular Ca²⁺ fura-2 fluorescence intensity (FFI) and electrically stimulated increases in FFI (FFI) associated with slowed intracellular Ca²⁺ decay compared with myocytes maintained in NG medium. L-158,809 (10 nmol/L) exerted no effect on baseline FFI and FFI but prevented the HG-induced prolongation of intracellular Ca²⁺ decay.

View larger version (60K): [in this window] [in a new window]   Figure 1. Effects of the AT1 antagonist L-158,809 on HG-induced mechanical dysfunction in myocytes maintained in NG or HG medium with or without L-158,809 (10 to 1000 nmol/L). A, PS; B, ±dL/dt; C, TPS; and D, TR90. Values are mean±SEM, n=59 to 137 cells/group. *P<0.05 vs NG or HG alone; #P<0.05 vs respective NG.

View larger version (21K): [in this window] [in a new window]   Figure 2. Effects of the AT1 antagonist L-158,809 (10 nmol/L) on HG-induced intracellular Ca2+ abnormalities in myocytes maintained in NG or HG medium. A, Baseline intracellular Ca2+ FFI; B, electrically stimulated FFI; C, Ca2+i decay rate (). Values are mean±SEM, n=53 to 63 cells/group. #P<0.05 vs NG.

Effect of JAK2 and NADPH Oxidase Inhibition on HG-Induced Mechanical Dysfunction
To evaluate the signaling involved in L-158,809–induced protection from HG-induced cardiac mechanical dysfunction, myocytes were coincubated in NG or HG medium with the JAK2 inhibitor AG-490 (10 and 100 µmol/L) and the NADPH oxidase inhibitors DPI (10 µmol/L) or apocynin (100 µmol/L). The selectivity of apocynin, a methoxy-substituted catechol, on NADPH oxidase has been well documented.²⁰ It impedes the assembly of the p47^phox and p67^phox subunits within the membrane NADPH oxidase complex. As shown in Figure 3, neither concentration of AG-490 significantly affected mechanical function in myocytes maintained in either NG or HG medium. However, both DPI and apocynin prevented the HG-induced prolongation of TPS and TR₉₀, suggesting that activation of an NADPH oxidase might be involved in HG-induced cardiac contractile dysfunction.

View larger version (43K): [in this window] [in a new window]   Figure 3. Effects of the JAK2 inhibitor AG-490 (10 and 100 µmol/L; A and B) and the NADPH oxidase inhibitors DPI (10 µmol/L; C and D) and apocynin (100 µmol/L; E and F) on HG-induced cardiac contractile abnormalities in ventricular myocytes. A, C, E, TPS; B, D, F, TR90. Values are mean±SEM, n=35 to 56 cells/group. #P<0.05 vs NG.

Effect of NADPH Oxidase Activation on Myocyte Mechanics
To further evaluate the role of NADPH oxidase in HG-induced cardiac mechanical dysfunction, SDS (80 µmol/L), an activator of NADPH oxidase,²¹ was coincubated with the NG or HG myocytes. SDS itself prolonged TPS and TR₉₀ in NG myocytes, which was not prevented by coincubation with the AT₁ antagonist L-158,809 (Figure 4). Consistently, short-term (30-minute) incubation with the NADPH oxidase donor/substrate NADPH (100 µmol/L) significantly prolonged both TPS (NG, 141±8 vs NG+NADPH, 170±7 ms; n=19 cells/group, P<0.05) and TR₉₀ (NG, 301±20 vs NG+NADPH, 432±39 ms; n=19 cells/group, P<0.05). These results suggest that NADPH oxidase activation might play a key role in cardiac myocyte contractile dysfunction, reminiscent of that triggered by the HG culture.

View larger version (57K): [in this window] [in a new window]   Figure 4. Effects of the NADPH oxidase activator SDS (80 µmol/L) on HG-induced cardiac contractile abnormalities in ventricular myocytes maintained in either NG or HG medium with or without the AT1 antagonist L-158,809 (10 nmol/L). A, TPS; B, TR90, n=48 to 66 cells/group; C, Representative blots showing immunostaining with anti-NADPH oxidase (p47phox) antibodies; D, Western blot of the p47phox subunit of NADPH oxidase in ventricular myocytes maintained in NG or HG medium with or without the AT1 antagonist L-158,809 (10 nmol/L), the NADPH oxidase activator SDS (80 µmol/L), or inhibitor DPI (10 µmol/L), n=8 isolations; E, Western blot of AT1 receptor in ventricular myocytes maintained in NG or HG medium with or without L-158,809 (10 nmol/L), SDS (80 µmol/L), or the NADPH oxidase inhibitor apocynin (100 µmol/L); F, Western blot of AT2 receptor in ventricular myocytes maintained in NG or HG medium with or without L-158,809, SDS, or apocynin. Inserts in E and F show representative blots, n=5 isolations. Values are mean±SEM. #P<0.05 vs NG; *P<0.05 vs respective NG alone.

Immunoblot Analysis of AT₁/AT₂ Receptors and NADPH Oxidase Subunit p47^phox
Western blot analysis indicated that maintaining myocytes in HG medium for 24 hours directly enhanced expression of the NADPH oxidase subunit p47^phox as well as the AT₁ receptor. In contrast, expression of the AT₂ receptor was unaffected. Interestingly, the HG-induced elevation in p47^phox expression was blocked by L-158,809 and DPI but was enhanced by SDS (Figure 4). SDS itself also induced an increased expression of the AT₁ receptor. These data are consistent with the stimulatory and inhibitory effects of the NADPH oxidase activator and inhibitor and strongly suggest a role for NADPH oxidase activity in HG-induced cardiac myocyte contractile dysfunction.

ROS Production in NG and HG Myocytes in the Presence of L-158,809, SDS, or Apocynin
As shown in Figure 5, ROS production was enhanced in 24-hour HG-cultured myocytes, which was blocked by the AT₁ antagonist L-158,809 (10 nmol/L) and the NADPH oxidase inhibitor apocynin (100 µmol/L). In comparison, ROS production was stimulated by SDS (80 µmol/L). These data suggest that the HG-induced cardiac mechanical dysfunction might be mediated, at least in part, by HG-induced production of ROS in ventricular myocytes. The observation that the HG-induced elevation in ROS generation was abolished by L-158,809 and apocynin further indicates that the AT₁ receptor and NADPH oxidase might play significant roles in HG-induced cardiac dysfunction.

View larger version (28K): [in this window] [in a new window]   Figure 5. Measurement of ROS production in ventricular myocytes maintained in either NG or HG medium for 24 hours with or without the AT1 antagonist L-158,809 (10 nmol/L), the NADPH oxidase activator SDS (80 µmol/L), or the NADPH oxidase inhibitor apocynin (100 µmol/L). Cells were loaded with the intracellular fluoroprobe CM-H2DCFDA (1 µmol/L) at 37°C for 30 minutes. Values are mean±SEM, n=6 cultures. #P<0.05 vs NG.

	Discussion

Top Abstract Introduction Methods Results Discussion References

 
Novel results from this study indicated a potential role of Ang II via the AT₁ receptor in the glucose toxicity–induced cardiac mechanical and intracellular Ca²⁺ dysfunction, simulating in vivo diabetic cardiomyopathy. These data further suggest that upregulation of AT₁ but not the AT₂ receptor, local activation of NADPH oxidase but not JAK/STAT, and generation of ROS might be involved in HG-induced cardiomyocyte dysfunction. Although the expression and function of NADPH oxidase have been documented in peripheral vascular tissue,^9,12,14 its function in the heart remains poorly understood. Our current study provides compelling evidence that both the AT₁ receptor and NADPH oxidase are involved in glucose toxicity–induced cardiac contractile dysfunction.

Diabetic cardiomyopathy is characterized by a prolonged duration of contraction/relaxation and intracellular Ca²⁺ clearing.^4,6 Findings from our current study revealed that prolonged TPS and TR₉₀ were associated with slowed intracellular Ca²⁺ clearance in myocytes maintained in HG medium for 24 hours. These data are reminiscent of in vivo diabetes and are consistent with our earlier observations.¹⁶ More important, the HG-induced cardiomyocyte dysfunction was abrogated by coincubation with the AT₁ antagonist L-158,809 and NADPH oxidase inhibitors DPI and apocynin. Ang II is well known to cause myocyte hypertrophy and apoptosis, both in vitro and in vivo. Current data suggest that the hyperglycemia-induced cardiac myopathies might be mediated via the AT₁ receptor, consequently causing NADPH oxidase activation and ROS generation. A functional role for NADPH oxidase in the oxidant response to Ang II was suggested by our observation that the NADPH oxidase activator SDS and the NADPH oxidase donor/substrate NADPH mimicked the effect of HG in myocytes maintained in NG medium.

Although the mechanism(s) of action underlying the role of the RAS and AT₁ in HG-induced cardiomyocyte dysfunction is not fully understood at this time, a plausible explanation is that hyperglycemia promotes ROS generation (as shown in our study) and myocyte apoptosis through AT₁-mediated NADPH oxidase activation induced by the local RAS.^22,23 The AT₁ receptor is a G protein–coupled receptor that mediates most of the known biologic effects of Ang II. Both local production of Ang II and AT₁ receptor expression are significantly increased in cardiac myocytes and vessels in streptozotocin-induced diabetic rats²⁴ and in vascular smooth muscle cells exposed to high glucose levels,²⁵ which are consistent with our findings. Activation of the AT₁ receptor might ‘turn on" NADPH oxidase and consequently enhance ROS, such as superoxide anion, which can react with nitric oxide, leading to its inactivation by producing peroxynitrite.¹⁰ Peroxynitrite is known to directly oxidize membrane components such as arachidonic acid, thus altering membrane integrity and cardiac function.¹⁰ JAK and STAT proteins have been demonstrated to be directly coupled to the AT₁ receptor, and Ang II is known to directly stimulate tyrosine phosphorylation and activation of JAK2 and the STAT family.²⁶ However, the lack of effect of the JAK2-specific inhibitor AG-490 on HG-induced cardiomyocyte dysfunction does not favor any involvement of JAK/STAT in HG-induced cardiac dysfunction, at least in our current experimental setting. It is rather surprising that inhibition of NADPH oxidase activity with DPI abolished the HG-induced upregulation of p47^phox protein expression itself. The mechanism of action is unknown, although a possible "feedback regulatory mechanism" of NADPH oxidase might be postulated for this observation.

We are currently investigating the underlying cellular mechanisms associated with HG-induced cardiomyocyte dysfunction and the signaling mechanisms contributing to these changes. To date, few studies have used a cell-culture system to address the pathogenesis of diabetes-related cardiac dysfunction. Our in vitro "diabetic" model allows us to explore the direct actions of HG, independent of other complications associated with diabetes, such as hyperlipidemia, hyper- or hypoinsulinemia, and hypothyroidism that might also contribute to depressed myocardial function. This work provides evidence that Ang II and NADPH oxidase might be considered important targets for the prevention and treatment of diabetic cardiomyopathy.

Perspectives
The findings from our present study indicate that the Ang II system (especially its membrane receptors) and postreceptor signaling pathway NADPH oxidase might play critical roles in the onset of hyperglycemia-induced oxidative stress and contractile dysfunction in the heart. These results should have a significant clinical implication in the use of AT₁ receptor–specific antagonists for the prevention and treatment of diabetic cardiomyopathy.

	Acknowledgments

 
This work was supported in part by grants from the American Diabetes Association and the Max Baer Heart Fund (to J.R.) and National Institutes of Health grants NIH R01 HL66575 (to M.T.Q.) and NIH R01-HL63904-01 (to J.R.S.). L-158,809 was generously provided by Merck & Co, Inc, Rahway, NJ. The authors would like to thank Jinhong Duan and Nicholas Aberle II for technical assistance.

	Footnotes

 
The first 2 authors contributed equally to this work.

Received December 2, 2002; first decision January 8, 2003; accepted June 11, 2003.

	References

Top Abstract Introduction Methods Results Discussion References

 
1. Grundy SM, Benjamin IJ, Burke GL, Chaiot A, Eckel RH, Howrda BV, Mitch W, Smith SC, Sowers JR. Diabetes and cardiovascular disease: a statement for healthcare professionals from the American Heart Association. Circulation. 1999; 100: 1134–1146.[Free Full Text]

2. Cai L, Kang YJ. Oxidative stress and diabetic cardiomyopathy. Cardiovasc Toxicol. 2001; 1: 181–193.[CrossRef][Medline] [Order article via Infotrieve]

3. Francis GS. Diabetic cardiomyopathy: fact or fiction? Heart. 2001; 85: 247–248.[Free Full Text]

4. Ren J, Davidoff AJ. Diabetes rapidly induces contractile dysfunctions in isolated ventricular myocytes. Am J Physiol Heart Circ Physiol. 1997; 272: H148–H158.[Abstract/Free Full Text]

5. Dutta K, Podolin DA, Davidson MB, Davidoff AJ. Cardiomyocyte dysfunction in sucrose-fed rats is associated with insulin resistance. Diabetes. 2001; 50: 1186–1192.[Abstract/Free Full Text]

6. Wold LE, Relling DP, Colligan PB, Scott GI, Hintz KK, Ren BH, Epstein PN, Ren J. Characterization of contractile function in diabetic hypertensive cardiomyopathy in adult rat ventricular myocytes. J Mol Cell Cardiol. 2001; 33: 1719–1726.[CrossRef][Medline] [Order article via Infotrieve]

7. Rodrigues B, Cam MC, McNeill JH. Metabolic disturbances in diabetic cardiomyopathy. Mol Cell Biochem. 1998; 180: 53–57.[CrossRef][Medline] [Order article via Infotrieve]

8. Dzau VJ. Theodore Cooper Lecture: tissue angiotensin and pathobiology of vascular disease: a unifying hypothesis. Hypertension. 2001; 37: 1047–1052.[Abstract/Free Full Text]

9. Nickenig G, Harrison DG. The AT₁-type angiotensin receptor in oxidative stress and atherogenesis, part I: oxidative stress and atherogenesis. Circulation. 2002; 105: 393–396.[Free Full Text]

10. Sowers JR. Hypertension, angiotensin II, and oxidative stress. N Engl J Med. 2002; 346: 1999–2001.[Free Full Text]

11. Mascareno E, Siddiqui MA. The role of Jak/STAT signaling in heart tissue renin-angiotensin system. Mol Cell Biochem. 2000; 212: 171–175.[CrossRef][Medline] [Order article via Infotrieve]

12. Wang HD, Xu S, Johns DG, Du Y, Quinn MT, Cayatte AJ, Cohen RA. Role of NADPH oxidase in the vascular hypertrophic and oxidative stress response to angiotensin II in mice. Circ Res. 2001; 88: 947–953.[Abstract/Free Full Text]

13. Schindler C. Transcriptional responses to polypeptide ligands: the Jak-STAT pathway. Annu Rev Biochem. 1995; 64: 621–651.[Medline] [Order article via Infotrieve]

14. Griendling KK, Sorescu D, Lassegue B, Ushio-Fukai M. Modulation of protein kinase activity and gene expression by reactive oxygen species and their role in vascular physiology and pathophysiology. Arterioscler Thromb Vasc Biol. 2000; 20: 2175–2183.[Abstract/Free Full Text]

15. Griendling KK, Ushio-Fukai M. Reactive oxygen species as mediators of angiotensin II signaling. Regul Pept. 2000; 91: 21–27.[CrossRef][Medline] [Order article via Infotrieve]

16. Ren J, Dominguez LJ, Sowers JR, Davidoff AJ. Metformin but not glyburide prevents high glucose-induced prolonged relaxation in cultured cardiomyocytes. Diabetes. 1999; 48: 2059–2065.[Abstract]

17. Norby FL, Wold LE, Duan J, Hintz KK, Ren J. IGF-I attenuates diabetes-induced cardiac contractile dysfunction in ventricular myocytes. Am J Physiol Endocrinol Metab. 2002; 283: E658–E666.[Abstract/Free Full Text]

18. DeLeo FR, Ulman KV, Davis AR, Jutila KL, Quinn MT. Assembly of the human neutrophil NADPH oxidase involves binding of p67phox and flavocytochrome b to a common functional domain in p47phox. J Biol Chem. 1996; 271: 17013–17020.[Abstract/Free Full Text]

19. Touyz RM, Schiffrin EL. Increased generation of superoxide by angiotensin II in smooth muscle cells from resistance arteries of hypertensive patients: role of phospholipase D-dependent NAD(P)H oxidase-sensitive pathways. J Hypertens. 2001; 19: 1245–1254.[CrossRef][Medline] [Order article via Infotrieve]

20. Meyer JW, Schmitt ME. A central role for the endothelial NADPH oxidase in atherosclerosis. FEBS Lett. 2000; 472: 1–4.[CrossRef][Medline] [Order article via Infotrieve]

21. Sasaki J, Hiura M, Yamaguchi M, Sakai M, Aoki K, Abe H, Okamura N, Ishibashi S. Activation mechanism of NADPH oxidase by SDS in intact guinea pig neutrophils. Arch Biochem Biophys. 1994; 315: 16–23.[CrossRef][Medline] [Order article via Infotrieve]

22. Fiordaliso F, Leri A, Cesselli D, Limana F, Safai B, Nadal-Ginard B, Anversa P, Kajstura J. Hyperglycemia activates p53 and p53-regulated genes leading to myocyte cell death. Diabetes. 2001; 50: 2363–2375.[Abstract/Free Full Text]

23. Ceriello A, Quagliaro L, D’Amico M, Di Filippo C, Marfella R, Nappo F, Berrino L, Rossi F, Giugliano D. Acute hyperglycemia induces nitrotyrosine formation and apoptosis in perfused heart from rat. Diabetes. 2002; 51: 1076–1082.[Abstract/Free Full Text]

24. Sechi LA, Griffin CA, Schambelan M. The cardiac renin-angiotensin system in STZ-induced diabetes. Diabetes. 1994; 43: e1180–e1184.

25. Sodhi CP, Kanwar YS, Sahai A. Hypoxia and high glucose upregulate AT1 receptor expression and potentiate ANG II-induced proliferation in VSM cells. Am J Physiol Heart Circ Physiol. 2003; 284: H846–H852.[Abstract/Free Full Text]

26. Marrero MB, Schieffer B, Paxton WG, Heerdt L, Berk BC, Delafontaine P, Bernstein KE. Direct stimulation of Jak/STAT pathway by the angiotensin II AT1 receptor. Nature. 1995; 375: 247–250.[CrossRef][Medline] [Order article via Infotrieve]

This article has been cited by other articles:

				A. Whaley-Connell, J. Habibi, S. A. Cooper, V. G. DeMarco, M. R. Hayden, C. S. Stump, D. Link, C. M. Ferrario, and J. R. Sowers Effect of renin inhibition and AT1R blockade on myocardial remodeling in the transgenic Ren2 rat Am J Physiol Endocrinol Metab, July 1, 2008; 295(1): E103 - E109. [Abstract] [Full Text] [PDF]

				J.-M. Li, M. Mogi, J. Iwanami, L.-J. Min, K. Tsukuda, A. Sakata, T. Fujita, M. Iwai, and M. Horiuchi Temporary Pretreatment With the Angiotensin II Type 1 Receptor Blocker, Valsartan, Prevents Ischemic Brain Damage Through an Increase in Capillary Density Stroke, July 1, 2008; 39(7): 2029 - 2036. [Abstract] [Full Text] [PDF]

				H. M. Siragy and J. Huang Renal (pro)renin receptor upregulation in diabetic rats through enhanced angiotensin AT1 receptor and NADPH oxidase activity Exp Physiol, May 1, 2008; 93(5): 709 - 714. [Abstract] [Full Text] [PDF]

				L. R. Peterson, P. Herrero, J. McGill, K. B. Schechtman, Z. Kisrieva-Ware, D. Lesniak, and R. J. Gropler Fatty Acids and Insulin Modulate Myocardial Substrate Metabolism in Humans With Type 1 Diabetes Diabetes, January 1, 2008; 57(1): 32 - 40. [Abstract] [Full Text] [PDF]

				S. A. Cooper, A. Whaley-Connell, J. Habibi, Y. Wei, G. Lastra, C. Manrique, S. Stas, and J. R. Sowers Renin-angiotensin-aldosterone system and oxidative stress in cardiovascular insulin resistance Am J Physiol Heart Circ Physiol, October 1, 2007; 293(4): H2009 - H2023. [Abstract] [Full Text] [PDF]

				F. Dong, Q. Li, N. Sreejayan, J. M. Nunn, and J. Ren Metallothionein Prevents High-Fat Diet Induced Cardiac Contractile Dysfunction: Role of Peroxisome Proliferator Activated Receptor {gamma} Coactivator 1{alpha} and Mitochondrial Biogenesis Diabetes, September 1, 2007; 56(9): 2201 - 2212. [Abstract] [Full Text] [PDF]

				S. Stas, A. Whaley-Connell, J. Habibi, L. Appesh, M. R. Hayden, P. R. Karuparthi, M. Qazi, E. M. Morris, S. A. Cooper, C. D. Link, et al. Mineralocorticoid Receptor Blockade Attenuates Chronic Overexpression of the Renin-Angiotensin-Aldosterone System Stimulation of Reduced Nicotinamide Adenine Dinucleotide Phosphate Oxidase and Cardiac Remodeling Endocrinology, August 1, 2007; 148(8): 3773 - 3780. [Abstract] [Full Text] [PDF]

				A. Whaley-Connell, G. Govindarajan, J. Habibi, M. R. Hayden, S. A. Cooper, Y. Wei, L. Ma, M. Qazi, D. Link, P. R. Karuparthi, et al. Angiotensin II-mediated oxidative stress promotes myocardial tissue remodeling in the transgenic (mRen2) 27 Ren2 rat Am J Physiol Endocrinol Metab, July 1, 2007; 293(1): E355 - E363. [Abstract] [Full Text] [PDF]

				J. Habibi, A. Whaley-Connell, M. A. Qazi, M. R. Hayden, S. A. Cooper, A. Tramontano, J. Thyfault, C. Stump, C. Ferrario, R. Muniyappa, et al. Rosuvastatin, a 3-Hydroxy-3-Methylglutaryl Coenzyme A Reductase Inhibitor, Decreases Cardiac Oxidative Stress and Remodeling in Ren2 Transgenic Rats Endocrinology, May 1, 2007; 148(5): 2181 - 2188. [Abstract] [Full Text] [PDF]

				E. Arikawa, R. C.W. Ma, K. Isshiki, I. Luptak, Z. He, Y. Yasuda, Y. Maeno, M. E. Patti, G. C. Weir, R. A. Harris, et al. Effects of Insulin Replacements, Inhibitors of Angiotensin, and PKC{beta}'s Actions to Normalize Cardiac Gene Expression and Fuel Metabolism in Diabetic Rats Diabetes, May 1, 2007; 56(5): 1410 - 1420. [Abstract] [Full Text] [PDF]

				Z. Guo, Z. Xia, J. Jiang, and J. H. McNeill Downregulation of NADPH oxidase, antioxidant enzymes, and inflammatory markers in the heart of streptozotocin-induced diabetic rats by N-acetyl-L-cysteine Am J Physiol Heart Circ Physiol, April 1, 2007; 292(4): H1728 - H1736. [Abstract] [Full Text] [PDF]

				P. S. Hansen, R. J. Clarke, K. A. Buhagiar, E. Hamilton, A. Garcia, C. White, and H. H. Rasmussen Alloxan-induced diabetes reduces sarcolemmal Na+-K+ pump function in rabbit ventricular myocytes Am J Physiol Cell Physiol, March 1, 2007; 292(3): C1070 - C1077. [Abstract] [Full Text] [PDF]

				C. X. Fang, S. Wu, and J. Ren Intracerebral Hemorrhage Elicits Aberration in Cardiomyocyte Contractile Function and Intracellular Ca2+ Transients Stroke, July 1, 2006; 37(7): 1875 - 1882. [Abstract] [Full Text] [PDF]

				Y. Liao, S. Takashima, H. Zhao, Y. Asano, Y. Shintani, T. Minamino, J. Kim, M. Fujita, M. Hori, and M. Kitakaze Control of plasma glucose with alpha-glucosidase inhibitor attenuates oxidative stress and slows the progression of heart failure in mice Cardiovasc Res, April 1, 2006; 70(1): 107 - 116. [Abstract] [Full Text] [PDF]

				M. Zhang, A. L. Kho, N. Anilkumar, R. Chibber, P. J. Pagano, A. M. Shah, and A. C. Cave Glycated Proteins Stimulate Reactive Oxygen Species Production in Cardiac Myocytes: Involvement of Nox2 (gp91phox)-Containing NADPH Oxidase Circulation, March 7, 2006; 113(9): 1235 - 1243. [Abstract] [Full Text] [PDF]

				F. Dong, X. Zhang, and J. Ren Leptin Regulates Cardiomyocyte Contractile Function Through Endothelin-1 Receptor-NADPH Oxidase Pathway Hypertension, February 1, 2006; 47(2): 222 - 229. [Abstract] [Full Text] [PDF]

				Y Shimoni, D Hunt, M Chuang, K. Y Chen, G Kargacin, and D. L Severson Modulation of potassium currents by angiotensin and oxidative stress in cardiac cells from the diabetic rat J. Physiol., August 15, 2005; 567(1): 177 - 190. [Abstract] [Full Text] [PDF]

				A. Ceriello, R. Assaloni, R. Da Ros, A. Maier, L. Piconi, L. Quagliaro, K. Esposito, and D. Giugliano Effect of Atorvastatin and Irbesartan, Alone and in Combination, on Postprandial Endothelial Dysfunction, Oxidative Stress, and Inflammation in Type 2 Diabetic Patients Circulation, May 17, 2005; 111(19): 2518 - 2524. [Abstract] [Full Text] [PDF]

				V. Pastukh, S. Wu, C. Ricci, M. Mozaffari, and S. Schaffer Reversal of hyperglycemic preconditioning by angiotensin II: role of calcium transport Am J Physiol Heart Circ Physiol, April 1, 2005; 288(4): H1965 - H1975. [Abstract] [Full Text] [PDF]

				C. Zeng, Z. Yang, Z. Wang, J. Jones, X. Wang, J. Altea, A. J. Mangrum, U. Hopfer, D. R. Sibley, G. M. Eisner, et al. Interaction of Angiotensin II Type 1 and D5 Dopamine Receptors in Renal Proximal Tubule Cells Hypertension, April 1, 2005; 45(4): 804 - 810. [Abstract] [Full Text] [PDF]

				M. Iwai, H.-W. Liu, R. Chen, A. Ide, S. Okamoto, R. Hata, M. Sakanaka, T. Shiuchi, and M. Horiuchi Possible Inhibition of Focal Cerebral Ischemia by Angiotensin II Type 2 Receptor Stimulation Circulation, August 17, 2004; 110(7): 843 - 848. [Abstract] [Full Text] [PDF]

				L. Raimondi, P. De Paoli, E. Mannucci, G. Lonardo, L. Sartiani, G. Banchelli, R. Pirisino, A. Mugelli, and E. Cerbai Restoration of Cardiomyocyte Functional Properties by Angiotensin II Receptor Blockade in Diabetic Rats Diabetes, July 1, 2004; 53(7): 1927 - 1933. [Abstract] [Full Text] [PDF]

				I. Kusaka, G. Kusaka, C. Zhou, M. Ishikawa, A. Nanda, D. N. Granger, J. H. Zhang, and J. Tang Role of AT1 receptors and NAD(P)H oxidase in diabetes-aggravated ischemic brain injury Am J Physiol Heart Circ Physiol, June 1, 2004; 286(6): H2442 - H2451. [Abstract] [Full Text] [PDF]

				J. R. Sowers Insulin resistance and hypertension Am J Physiol Heart Circ Physiol, May 1, 2004; 286(5): H1597 - H1602. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) All Versions of this Article: 42/2/206    most recent 01.HYP.0000082814.62655.85v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Privratsky, J. R. Articles by Ren, J. Search for Related Content PubMed PubMed Citation Articles by Privratsky, J. R. Articles by Ren, J. Pubmed/NCBI databases Compound via MeSH Substance via MeSH Hazardous Substances DB GLUCOSE SODIUM LAURYL SULFATE Related Collections Contractile function ACE/Angiotension receptors Calcium cycling/excitation-contraction coupling Cell signalling/signal transduction Myocardial cardiomyopathy disease Type 2 diabetes