OBJECTIVE

Vascular endothelial growth factor (VEGF), which is associated with the stimulation of angiogenesis and collateral vessel synthase, is one of the crucial factors involved in cardiac remodeling in type 2 diabetes.

RESEARCH DESIGN AND METHODS

We investigated VEGF inhibition by dRK6 on the heart in an animal model of type 2 diabetes. Male db/db and db/m mice either were treated with dRK6 starting at 7 weeks of age for 12 weeks (db/db-dRK6 and db/m-dRK6) or were untreated.

RESULTS

Cardiac dysfunction and hypertrophy were noted by echocardiogram and molecular markers in the db/db-dRK6 mice. The presence of diabetes significantly suppressed the expression of VEGF receptor (VEGFR)-1 and VEGFR-2, phospho-Akt, and phospho-endothelial nitric oxide synthase (eNOS) in the heart. In db/db-dRK6 mice, dRK6 completely inhibited VEGFR-2, phospho-Akt, and phospho-eNOS expression, whereas no effect on VEGFR-1 was observed. Cardiac fibrosis, microvascular scarcity associated with an increase in apoptotic endothelial cells, and inflammation were prominent, as well as increase in antiangiogenic growth factors. Cardiac 8-hydroxy-deoxyguanine and hypoxia-inducible factor-1α expression were significantly increased. No such changes were found in the other groups, including the db/m-dRK6 mice. The number of apoptotic human umbilical vein endothelial cells was increased by dRK6 in a dose-dependent manner only at high glucose concentrations, and this was associated with a decrease in phospho-Akt and phospho-eNOS related to oxidative stress.

CONCLUSIONS

Our results demonstrated that systemic blockade of VEGF by dRK6 had deleterious effects on the heart in an animal model of type 2 diabetes; dRK6 induced downregulation of the VEGFR-2 and Akt-eNOS axis and enhancement of oxidative stress.

Vascular endothelial growth factor (VEGF), especially VEGF-A, is an important mediator of neovascularization, as well as a key factor for maintaining the integrity of endothelial cells in physiologic and pathologic conditions. Two important VEGF receptor tyrosine kinases have been identified and their functions described (VEGF receptor [VEGFR]-1 or Flt-1 and VEGFR-2 or KDR/Flk-1) (1). The deregulation of VEGF results in reduced activation of endothelial nitric oxide synthase (eNOS) and increased production of reactive oxygen species (ROS), which upregulates the expression of procoagulant, prothrombotic, and proinflammatory mediators (2). Several VEGF inhibitors are currently under evaluation or have already been approved for the treatment of age-related macular degeneration and macular edema (3), various cancers (4,5), and diabetic microvascular complications (3). However, there is a growing realization that VEGF inhibitors have significant side effects on the kidney and blood pressure and have been associated with thrombotic microangiopathy, which are typically downstream consequences of suppression of the endothelial Akt-eNOS signaling pathway (4). Impaired cardiac function has been observed in some patients on anti-VEGF therapy (4).

Diabetic cardiomyopathy (DCM) is a clinical condition associated with ventricular dysfunction; DCM develops in patients with diabetes in the absence of atherosclerosis and hypertension (6,,9). Left ventricular diastolic and systolic dysfunction and alterations in the coronary microcirculation, as well as interstitial fibrosis, are characteristics of DCM because of a reduced microvasculature (10,12). There continues to be debate about the role of VEGF with regard to the heart in diabetic patients. Expression of VEGF and VEGFR-2 in the human heart, and in streptozotocin-induced diabetic animals, has been shown to be significantly decreased because of loss of insulin-induced VEGFR-eNOS axis activation (13,15), which is followed by an increase of apoptosis in endothelial cells, a decrease in the number of circulating endothelial progenitor cells, decreased capillary density, and impaired myocardial perfusion (14,16). Downregulation of VEGF in the heart is associated with an increased risk for cardiovascular morbidity and mortality in diabetic patients (16). Both increased and unaltered serum or plasma VEGF levels were observed in type 1 and 2 diabetic patients versus control subjects (17,18). On the other hand, the serum VEGF level is increased in patients with diabetic symptomatic polyneuropathy, overt diabetic nephropathy, and coronary artery disease, particularly related to the extent of myocardial damage (19,21).

dRK6 is an arginine-rich anti-VEGF hexapeptide and a d-amino acid derivative of RK6 (Arg-Arg-Lys-Arg-Arg-Arg). dRK6 binds with VEGF-A and can thereby block the interaction between VEGF-A (mainly VEGF165 and VEGF121) and the VEGFRs. In a previous study, dRK6 showed significant inhibition of VEGF-induced angiogenesis and retarded the growth and metastasis of colon carcinoma cells without direct cytotoxicity (22). dRK6 is stable, and its half-life at 37°C in the serum is 13.5 h (22). Previous results demonstrated that a subcutaneous injection of dRK6 (25–50 μg) every other day for 3 weeks reduced the incidence and severity of collagen-induced arthritis in a dose-dependent manner without any toxicity (22,23).

Therefore, we determined whether systemic VEGF blockade, using dRK6, could lead to structural and functional deterioration of the heart in db/db mice in a murine model of type 2 diabetes.

Experimental methods.

All experiments were performed according to the institutional animal care guidelines, and the investigation conformed with the Guide for the Care and Use of Laboratory Animals published by the U.S. Institutes of Health (National Institutes of Health Publication No. 85–23, revised 1996). Six-week-old male C57BLKS/J db/db and db/m mice were purchased from Jackson Laboratories (Bar Harbor, ME); db/m mice were used as controls in all of the experiments. Fifty micrograms of dRK6 was administered three times per week by intraperitoneal injection to db/m (db/m-dRK6) or db/db (db/db-dRK6) mice (n = 8) beginning at 7 weeks of age for 12 weeks (n = 8). The diabetic db/db (db/db) and nondiabetic db/m control groups (db/m) received only PBS.

After 12 weeks of treatment, the systolic blood pressure was determined by the noninvasive tail cuff system in conscious mice (IITC Life Science, Woodland Hill, CA) after a 5-day accommodation. At the end of the study, the animals were anesthetized and killed.

Measurement of serum parameters.

Blood was collected from the left ventricle and centrifuged; the plasma was stored at −70°C for subsequent analyses. The A1C was measured by high-pressure liquid chromatography (BioRad, Richmond, CA). The total cholesterol, triglycerides, free fatty acids (FFAs), and insulin concentrations were measured by an autoanalyzer (Wako, Osaka, Japan). We also measured the serum VEGF concentration using an ELISA kit (Komabiotech, Seoul, South Korea).

Assessment of heart function.

During the last week of the study, we performed an echocardiogram to evaluate the heart function and size in the animals using a Hewlett-Packard Sonus 4500 ultrasound machine (Agilent Technologies, Edmonton, AB, Canada) while the animals were anesthetized according to a procedure previously reported (24).

Light microscopy.

The heart samples were collected after systemic perfusion with PBS and then fixed in 4% paraformaldehyde. To examine the effect of dRK6 on cardiac fibrosis, the analysis was performed on trichrome-stained heart sections as described previously (25). Ten consecutive heart cross-sections were photographed by an examiner who was blinded to the source of the tissue using a digital camera (Olympus DP11; Olympus America, Melville, NY).

Immunohistochemistry for connective tissue growth factor, platelet-endothelial cell adhesion molecule-1, thrombospondin-1, transferase-mediated dUTP nick-end labeling, F4/80, and 8-hyrdoxy-deoxyguanosine (8-OH-dG).

We performed immunohistochemistry for connective tissue growth factor (CTGF), F4/80, platelet-endothelial cell adhesion molecule (PECAM)-1, thrombospondin-1, transferase-mediated dUTP nick-end labeling (TUNEL), and 8-hyrdoxy-deoxyguanosine (8-OH-dG). Five- μm thick sections were incubated overnight with anti-CTGF as a profibrotic growth factor (1:250 in blocking solution; Abcam, Cambridge, U.K.), anti–PECAM-1 as a mouse endothelial cell marker (1:50; BD Bioscience, San Diego, CA), antithrombospondin-1 as an antiendothelial cell growth factor (1:100; Lab Vision, Fremont, CA), the in situ TUNEL assay as an apoptotic marker (Apoptag Plus, Intergen, New York, NY), anti-F4/80 as an inflammatory cell marker (1:50; Serotek, Oxford, U.K.), and 8-OH-dG as a marker of oxidative DNA damage (1:100; JalCA, Shizuoka, Japan) in a humidified chamber at 4°C. Antibodies were localized with the ABC technique (Vector, Buringame, CA). We also measured 8-OH-dG levels from the purified DNA of the hearts performed with an ELISA kit.

For the quantification of the proportions of the areas stained, ∼20 views were randomly located in the middle portion of the myocardium of each slide (Scion Image Beta 4.0.2; Frederick, MD). The endothelial cells that were positive for apoptosis exhibited an intense brown nuclear (TUNEL-positive) and a red cytoplasmic colorimetric (PECAM-1–positive) reaction product. The number of cells positive for the TUNEL reaction was determined in the myocardium under ×400 magnification.

Immunofluorescent staining for the hypoxia-inducible factor-1α.

To evaluate the hypoxic injury to the heart, we performed hypoxia-inducible factor (HIF)-1α immunofluorescent staining of the heart (1:50; Novous Biological, Littleton, CO). For quantification of the proportion of the area stained, ∼20 views (×200 magnification), randomly located in the middle portion of the myocardium of each slide, were also examined (Scion Image Beta 4.0.2).

Western blot and semi-quantitative RT-PCR for total- and phospho-eNOS (Ser1177), total- and phospho-Akt (Ser473), VEGFR-1, VEGFR-2, CTGF, and HIF-1α.

Western blot analysis was performed using the following antibodies: total Akt, phospho-Akt (Ser473), total eNOS, and phospho-eNOS (Ser1177; all from Cell Signaling Technology, Danvers, MA) and HIF-1α, CTGF, and β-actin (all from Abcam, Cambridge, U.K.). Protein for HIF-1α from nuclear fractions of the hearts was isolated using a nuclear extraction kit (Cayman Chemical, Ann Arbor, MI) following the manufacturer's protocol. We also performed RT-PCR to assess the levels of gene expression of VEGFR-1 and -2, HIF-1α, CTGF, and 18r rRNA as an internal control. Primers for amplification of VEGFR-1 and -2, HIF-1α, CTGF, and 18r rRNA are listed in the supplemental data available in an online appendix at http://diabetes.diabetesjournals.org/cgi/content/full/db09-0136/DC1.

Quantitative PCR for atrial natriuretic factor, B-type natriuretic peptide, α-myosin heavy chain, and β-myosin heavy chain.

Total reactive nitrogen species was performed using an ABI PRISM Sequence Detector System 7500 (Applied Biosystems, Foster City, CA). The PCR primers for atrial natriuretic factor (ANF), B-type natriuretic peptide (BNP), α-myosin heavy chain (MHC), and β-MHC are listed in the supplemental data.

TUNEL assay, 8-iso-PGF and 8-OH-dG levels in the human umbilical vein endothelial cell culture.

Human umbilical vein endothelial cells (HUVECs) were cultured in RPMI 1640 supplemented with 10% FBS and 15 mg/500 ml of endothelial cell growth supplement (Sigma, St. Louis, MO) at 37°C in a humidified, 5% CO2/95% air atmosphere. Apoptosis was quantified with the in situ cell death detection kit, using a TUNEL assay (Chemicon International, Temecula, CA). After treatment with different concentrations of d-glucose in the media (5 and 30 mmol/l per liter of d-glucose and d-glucose [5 mmol/l per liter] + d-mannitol [25 mmol/l per liter]) with 0, 10−6, 10−8, or 10−10 mmol/l dRK6 for 48 h, the number of TUNEL-positive cells was counted in 10 randomly chosen fields at a magnification of ×400. We also performed Western blot analysis using 10−8 mmol/l dRK6 for 48 h with the following antibodies: total Akt, phospho-Akt (Ser473), total eNOS, and phospho-eNOS (Ser1177). To evaluate the direct effects of dRK6 on oxidative stress, we also measured the concentrations of 8-iso-PGF and 8-OH-dG in the cell culture media.

Statistical analysis.

Data are expressed as the means ± SD. The differences between the groups were examined for statistical significance using ANOVA with the Bonferroni's correction (SPSS 11.5; Chicago, IL). Nonnormally distributed data were analyzed by the nonparametric unpaired Mann-Whitney U test. A P value ≤0.05 was considered a statistically significant difference.

Body weight, heart weight, mean systolic blood pressure, and the hematocrit.

The body weights of the db/db mice with or without dRK6 treatment were heavier than the db/m mice at the end of the experiment (P < 0.01, Table 1). There was a slightly heavier heart weight in the db/db-dRK6 group compared with the other groups, but the difference was not statistically significant. There was no significant difference in mean systolic blood pressure (SBP) between the db/m and db/db mice with or without dRK6 treatment.

TABLE 1

Influence of dRK6 on physiologic and biochemical parameters and serum lipid profiles in db/db and db/m mice

db/mdb/m-RK6db/dbdb/db-RK6
Body weight (g) 31.6 ± 1.2 31.2 ± 1.3 50.3 ± 5.8* 42.4 ± 5.9* 
Heart weight (g) 0.12 ± 0.04 0.11 ± 0.05 0.12 ± 0.04 0.14 ± 0.05 
Mean SBP (mmHg) 95.6 ± 5.4 97.6 ± 3.5 99.1 ± 6.2 102.3 ± 5.0 
Hematocrit (%) 34.0 ± 2.9 35.6 ± 3.4 39.8 ± 5.2 38.6 ± 6.4 
Glucose (mmol/l) 11.2 ± 1.1 11.8 ± 1.9 58.0 ± 5.9 57.6 ± 7.8 
A1C (%) 4.3 ± 0.2 4.1 ± 0.3 12.7 ± 1.2 13.6 ± 1.0 
Total cholesterol (mmol/l) 1.66 ± 0.38 1.53 ± 0.34 2.08 ± 0.37 1.92 ± 0.31 
Triglycerides (mg/dl) 60 ± 16 66 ± 20 103 ± 27 114 ± 21 
FFAs (mEq/l) 1.45 ± 0.34 1.57 ± 0.55 3.18 ± 1.03 3.76 ± 1.19 
Insulin (pg/ml) 0.17 ± 0.13 0.19 ± 0.14 0.50 ± 0.14 0.33 ± 0.21 
Serum VEGF (pg/ml) 1.25 ± 1.73 23.5 ± 7.7§ 6.6 ± 3.9 29.6 ± 8.5§ 
db/mdb/m-RK6db/dbdb/db-RK6
Body weight (g) 31.6 ± 1.2 31.2 ± 1.3 50.3 ± 5.8* 42.4 ± 5.9* 
Heart weight (g) 0.12 ± 0.04 0.11 ± 0.05 0.12 ± 0.04 0.14 ± 0.05 
Mean SBP (mmHg) 95.6 ± 5.4 97.6 ± 3.5 99.1 ± 6.2 102.3 ± 5.0 
Hematocrit (%) 34.0 ± 2.9 35.6 ± 3.4 39.8 ± 5.2 38.6 ± 6.4 
Glucose (mmol/l) 11.2 ± 1.1 11.8 ± 1.9 58.0 ± 5.9 57.6 ± 7.8 
A1C (%) 4.3 ± 0.2 4.1 ± 0.3 12.7 ± 1.2 13.6 ± 1.0 
Total cholesterol (mmol/l) 1.66 ± 0.38 1.53 ± 0.34 2.08 ± 0.37 1.92 ± 0.31 
Triglycerides (mg/dl) 60 ± 16 66 ± 20 103 ± 27 114 ± 21 
FFAs (mEq/l) 1.45 ± 0.34 1.57 ± 0.55 3.18 ± 1.03 3.76 ± 1.19 
Insulin (pg/ml) 0.17 ± 0.13 0.19 ± 0.14 0.50 ± 0.14 0.33 ± 0.21 
Serum VEGF (pg/ml) 1.25 ± 1.73 23.5 ± 7.7§ 6.6 ± 3.9 29.6 ± 8.5§ 

Data are means ± SD.

*P < 0.01,

P < 0.001,

P < 0.05 vs. dm and dm-dRK6.

§P < 0.001 vs. dm and P < 0.05 vs. db/db.

Fasting blood glucose, A1C, serum lipids, insulin levels, and serum VEGF.

As expected, there were significant increases in the fasting blood glucose (FBG) and A1C, total cholesterol, triglycerides, FFAs, and insulin concentrations in the db/db and db/db-dRK6 mice compared with the db/m and db/m-dRK6 mice (P < 0.05, P < 0.01, or P < 0.001, respectively; Table 1). By contrast, there was no such difference observed between the db/db mice and db/db-dRK6 mice. There were significant increases in the serum VEGF concentrations in the db/m-dRK6 and the db/db-dRK6 mice compared with the db/m and db/db control mice (P < 0.001 and P < 0.05, respectively). These findings suggest that VEGF blockade with dRK6 significantly increased the circulating VEGF concentrations.

Assessment of heart function.

To assess heart function, we performed echocardiograms on the mice in the study groups (Fig. 1,A). There were no significant differences in the diastolic interventricular wall thickness (IVSTd), left ventricular posterior wall thickness (LVPWTd), and left ventricular mass (LVM) among the db/m, db/m-dRK6, and db/db mice. By contrast, these parameters in the db/db-dRK6 mice were markedly increased compared with the other groups (P < 0.05, Fig. 1,B). Molecular markers of cardiac hypertrophy (ANF, BNP, α-MHC, and β-MHC) were also elevated in the db/db-dRK6 mice (P < 0.05, Fig. 1,D). These results suggest that dRK6 treatment caused development of cardiac hypertrophy. Diabetic db/db mice also exhibited a persistent decrease in fractional shortening (P < 0.05, Fig. 1 C) compared with the db/m mice. There was a more prominent decrease in the fractional shortening, mean velocity of circumferential fiber shortening (Vcf), and peak E/A ratio in the db/db-dRK6 mice. These findings demonstrate that treatment with dRK6 had a negative effect on the cardiac function in the presence of diabetes.

FIG. 1.

Representative M-mode echocardiograms in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment (A). Echocardiographic changes in IVSTd and LVPWTd, LVM (B), fractional shortening, mean Vcf, and peak E/A ratio (C). Quantitative RT-PCR analysis for ANF, BNP, α-MHC, and β-MHC transcript levels in hearts (D) from diabetic db/db and nondiabetic db/m mice without (db/db, db/m) or with dRK6 treatment (db/db-dRK6, db/m-dRK6) for 12 weeks beginning at 7 weeks of age. *P < 0.05, **P < 0.01 compared with other groups.

FIG. 1.

Representative M-mode echocardiograms in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment (A). Echocardiographic changes in IVSTd and LVPWTd, LVM (B), fractional shortening, mean Vcf, and peak E/A ratio (C). Quantitative RT-PCR analysis for ANF, BNP, α-MHC, and β-MHC transcript levels in hearts (D) from diabetic db/db and nondiabetic db/m mice without (db/db, db/m) or with dRK6 treatment (db/db-dRK6, db/m-dRK6) for 12 weeks beginning at 7 weeks of age. *P < 0.05, **P < 0.01 compared with other groups.

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Effect of dRK6 on VEGFR-1 and -2, Akt, and eNOS on the heart.

As shown in Fig. 2,A–C, there were marked decreases in the expression of VEGFR-1 and -2 mRNA in the db/db control mice compared with the db/m mice. In addition, dRK6 treatment completely abolished the expression of VEGFR-2 mRNA and protein in db/db-dRK6 mice. By contrast, there was no change in the expression of VEGFR-1 mRNA in db/db-dRK6 mice; no such changes were detected in db/m-dRK6 mice. There was significantly decreased expression of phospho-Akt protein, eNOS mRNA, and phospho-eNOS protein in db/db mice compared with db/m mice (Fig. 2 D–G). Consistent with the VEGFR-2 findings, dRK6 treatment completely inhibited expression of phospho-Akt/eNOS protein in db/db-dRK6 mice.

FIG. 2.

RT-PCR for VEGF-R1, VEGF-R2 (A), eNOS (D) mRNA, and 18s rRNA expression in the hearts of diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. Quantitative assessment of the expression of VEGF-R1 (B), VEGF-R2 mRNA (C), and eNOS mRNA (F) to 18s rRNA ratios in the hearts of the study groups. Western blot analysis of the total and phospho-Akt and phospho-eNOS (D) and quantitative assessment of the expression of total and phospho-Akt (E) and phospho-eNOS protein (G). *P < 0.05 compared with other groups, **P < 0.01 compared with other groups, #P < 0.05 compared with the db/db group, +P < 0.05 compared with the db/m group; n = 4.

FIG. 2.

RT-PCR for VEGF-R1, VEGF-R2 (A), eNOS (D) mRNA, and 18s rRNA expression in the hearts of diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. Quantitative assessment of the expression of VEGF-R1 (B), VEGF-R2 mRNA (C), and eNOS mRNA (F) to 18s rRNA ratios in the hearts of the study groups. Western blot analysis of the total and phospho-Akt and phospho-eNOS (D) and quantitative assessment of the expression of total and phospho-Akt (E) and phospho-eNOS protein (G). *P < 0.05 compared with other groups, **P < 0.01 compared with other groups, #P < 0.05 compared with the db/db group, +P < 0.05 compared with the db/m group; n = 4.

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Histologic examination of the heart and effects on connective tissue growth factor.

In the db/m and db/db control mice, there was no apparent cardiac fibrosis observed, which was likely because of the short period of diabetes exposure (Fig. 3,A and B). However, dRK6 treatment markedly increased the cardiac fibrosis observed in the db/db-dRK6 mice (P < 0.05, Fig. 3,D and E). By contrast, there was no such change observed in the db/m-dRK6 mice (Fig. 3,B). We also performed immunostaining, Western blot, and RT-PCR for CTGF to evaluate the expression of profibrotic and inflammatory growth factors in the heart. Compared with the increased myocardial fibrosis in the heart, the positive staining for CTGF was significantly increased in the db/db-dRK6 mice compared with the db/db and db/m-dRK6 mice (P < 0.05, Fig. 4,A–E). Consistent with the immunostaining results, the expression of CTGF mRNA and protein levels was also significantly increased in the db/db-dRK6 mice (Fig. 4 F and G). These findings suggest that CTGF is one of the major profibrotic growth factors in dRK6-induced cardiac fibrosis.

FIG. 3.

Cardiac histopathology in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment (Trichrome stain, ×100). The histopathology shows marked cardiac fibrosis in diabetic db/db-dRK6 (D) compared with nondiabetic db/m and db/m-dRK6 mice (A and B) and db/db control mice (C). Original magnification ×200. Quantitative assessment of the areas of fibrosis in the myocardial tissue of the study groups (E). *P < 0.01 compared with the other groups; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

FIG. 3.

Cardiac histopathology in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment (Trichrome stain, ×100). The histopathology shows marked cardiac fibrosis in diabetic db/db-dRK6 (D) compared with nondiabetic db/m and db/m-dRK6 mice (A and B) and db/db control mice (C). Original magnification ×200. Quantitative assessment of the areas of fibrosis in the myocardial tissue of the study groups (E). *P < 0.01 compared with the other groups; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

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FIG. 4.

Immunohistochemical staining for CTGF in the myocardial tissue of nondiabetic db/m and diabetic db/db mice (B and D, respectively) with or without dRK6 treatment (A and C, respectively; ×200). Original magnification ×200. E: Quantitative assessment of CTGF immunostaining in the myocardial tissue of the study groups. F: Expression of CTGF protein, mRNA, and 18s rRNA in the hearts of the study groups. Quantitative assessment of the expression of CTGF mRNA (G) and protein (H). *P < 0.05, **P < 0.01 compared with the other groups, #P < 0.01 compared with the db/db group; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

FIG. 4.

Immunohistochemical staining for CTGF in the myocardial tissue of nondiabetic db/m and diabetic db/db mice (B and D, respectively) with or without dRK6 treatment (A and C, respectively; ×200). Original magnification ×200. E: Quantitative assessment of CTGF immunostaining in the myocardial tissue of the study groups. F: Expression of CTGF protein, mRNA, and 18s rRNA in the hearts of the study groups. Quantitative assessment of the expression of CTGF mRNA (G) and protein (H). *P < 0.05, **P < 0.01 compared with the other groups, #P < 0.01 compared with the db/db group; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

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Immunohistochemistry for PECAM-1, TUNEL, thrombospondin-1, and F4/80.

To evaluate vascular homeostasis, we performed immunohistochemistry staining for PECAM-1, PECAM-1+TUNEL, and thrombospondin-1. There were no changes in the expression of PECAM-1 in db/db mice. By contrast, dRK6 treatment in db/db-dRK6 mice was associated with a decrease in expression of PECAM-1 in the myocardium, reflecting a decrease in endothelial cells (Fig. 5,A–E). It is well known that thrombospondin-1 is an antiangiogenic peptide; therefore, we evaluated the expression of thrombospondin–1 in the heart. The expression of thrombospondin-1 was significantly increased in the db/db-dRK6 mice compared with the db/m, db/m-dRK6, and db/db mice (P < 0.05, Fig. 5,F–J). Further evaluation of the effects of endothelial cell apoptosis on the rare vessels in the heart was assessed by double immunostaining with PECAM-1+TUNEL in the heart. It was difficult to find TUNEL-positive stained endothelial cells in the db/m, db/m-dRK6, and db/db mice. By contrast, an increased number of TUNEL-positive cells were found in the db/db-dRK6 mice (P < 0.001, Fig. 5 K–O).

FIG. 5.

Myocardial morphology and immunohistochemical staining for PECAM-1, thrombospondin, TUNEL+PECAM-1, and F4/80 in the hearts of diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. A representative photomicrograph of myocardial immunostaining for PECAM-1 in nondiabetic db/m (A), db/m-dRK6 (B), diabetic db/db (C), and db/db-dRK6 mice (D, ×200). Original magnification ×200. Representative immunostains for thrombospondin-1 (F–I, ×200), PECAM-1+TUNEL (a dark-brown nuclear for TUNEL-positive and a red cytoplasm for PECAM-1–positive; open arrow, K–N, ×400) and F4/80 (open arrow, P–S, ×400) in diabetic and nondiabetic db/db and db/m mice with or without dRK6 treatment. Quantitative assessment of PECAM-1 (E), thrombospondin-1 (J), PECAM-1+TUNEL (O), and F4/80 (T) immunoreactivity in diabetic db/db and nondiabetic db/m mice without or with dRK6 treatment. *P < 0.05, **P < 0.01 compared with the other groups. (A high-quality color digital representation of this figure is available in the online issue.)

FIG. 5.

Myocardial morphology and immunohistochemical staining for PECAM-1, thrombospondin, TUNEL+PECAM-1, and F4/80 in the hearts of diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. A representative photomicrograph of myocardial immunostaining for PECAM-1 in nondiabetic db/m (A), db/m-dRK6 (B), diabetic db/db (C), and db/db-dRK6 mice (D, ×200). Original magnification ×200. Representative immunostains for thrombospondin-1 (F–I, ×200), PECAM-1+TUNEL (a dark-brown nuclear for TUNEL-positive and a red cytoplasm for PECAM-1–positive; open arrow, K–N, ×400) and F4/80 (open arrow, P–S, ×400) in diabetic and nondiabetic db/db and db/m mice with or without dRK6 treatment. Quantitative assessment of PECAM-1 (E), thrombospondin-1 (J), PECAM-1+TUNEL (O), and F4/80 (T) immunoreactivity in diabetic db/db and nondiabetic db/m mice without or with dRK6 treatment. *P < 0.05, **P < 0.01 compared with the other groups. (A high-quality color digital representation of this figure is available in the online issue.)

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Only mild macrophage infiltration, as assessed by F4/80-positive staining, was observed in the myocardium of db/mb-dRK6 and db/db mice. By contrast, F4/80 immunostaining was markedly increased in the myocardium of db/db-dRK6 mice (P < 0.001, Fig. 4 P–T).

Effect of dRK6 on HIF-1α and 8-OH-dG.

There was no difference in expression of HIF-1α in the hearts of db/m, db/m-dRK6, and db/db mice. However, in db/db-dRK6 mice, expression of HIF-1α was significantly increased compared with the other groups (P < 0.001, Fig. 6,A–E). The expression of HIF-1α protein and mRNA levels in the heart significantly increased in db/db-dRK6 mice (Fig. 6,F–H). Diabetic db/db mice and db/m-dRK6 mice had increased immunostaining of 8-OH-dG in the myocardial cells compared with db/m mice (Fig. 6,I). In the myocardium, increased expression of 8-OH-dG (dark brown nucleus) in db/db mice was markedly accentuated by treatment with dRK6 (Fig. 6,L and M). The 8-OH-dG levels in the DNA from the hearts were significantly increased compared with db/db mice (Fig. 6 M), the levels of which were also increased compared with db/m mice. These findings suggest that dRK6 treatment increased oxidative stress in the hearts, especially in mice with diabetes.

FIG. 6.

Immunofluorescent staining for HIF-1α in the heart. Representative pictures illustrating expression in nondiabetic db/m (A), db/m-dRK6 (B), diabetic db/db (C), and db/db-dRK6 mice (D) in myocytes. Original magnification ×200. E: Quantitative assessment of HIF-1α immunoreactivity in the myocardial cells in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. **P < 0.001 compared with the other groups. F: Expression of HIF-1α protein, mRNA, and 18s rRNA in the hearts of the study groups. Quantitative assessment of the expression of HIF-1α mRNA (G) and protein (H). *P < 0.05, **P < 0.01 compared with the other groups, #P < 0.01 compared with the db/db group; n = 4. Immunohistochemical expression of 8-OH-dG protein in myocardial cells. In diabetic db/db mice (K), 8-OH-dG protein is markedly accentuated in the myocardium (dark nucleus) compared with nondiabetic db/m and db/db-dRK6 mice (I and J, respectively). More prominent 8-OH-dG immunostaining is seen in the db/db-dRK6 mice compared with the diabetic db/db mice (L). Original magnification ×200. M: Quantitative assessment of 8-OH-dG levels in the DNA from the hearts. *P < 0.05, compared with db/m, **P < 0.01 compared with db/m and P < 0.05 compared with db/m-dRK6 and db/db; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

FIG. 6.

Immunofluorescent staining for HIF-1α in the heart. Representative pictures illustrating expression in nondiabetic db/m (A), db/m-dRK6 (B), diabetic db/db (C), and db/db-dRK6 mice (D) in myocytes. Original magnification ×200. E: Quantitative assessment of HIF-1α immunoreactivity in the myocardial cells in diabetic db/db and nondiabetic db/m mice with or without dRK6 treatment. **P < 0.001 compared with the other groups. F: Expression of HIF-1α protein, mRNA, and 18s rRNA in the hearts of the study groups. Quantitative assessment of the expression of HIF-1α mRNA (G) and protein (H). *P < 0.05, **P < 0.01 compared with the other groups, #P < 0.01 compared with the db/db group; n = 4. Immunohistochemical expression of 8-OH-dG protein in myocardial cells. In diabetic db/db mice (K), 8-OH-dG protein is markedly accentuated in the myocardium (dark nucleus) compared with nondiabetic db/m and db/db-dRK6 mice (I and J, respectively). More prominent 8-OH-dG immunostaining is seen in the db/db-dRK6 mice compared with the diabetic db/db mice (L). Original magnification ×200. M: Quantitative assessment of 8-OH-dG levels in the DNA from the hearts. *P < 0.05, compared with db/m, **P < 0.01 compared with db/m and P < 0.05 compared with db/m-dRK6 and db/db; n = 4. (A high-quality color digital representation of this figure is available in the online issue.)

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Effect of dRK6 on HUVEC apoptosis.

To examine the direct role of dRK6 on HUVECs, we investigated whether dRK6 induced apoptosis of the HUVECs using TUNEL assay with different doses of dRK6 (10−6, 10−8, and 10−10 mmol/l) and various concentrations of glucose in the media (5 and 30 mmol/l of d-glucose, and 5 mmol/l d-glucose + 25 mmol/l mannitol) for 48 h. Only at a concentration of 30 mmol/l of d-glucose were the HUVEC TUNEL-positive cells significantly increased in a dose-dependent manner (P < 0.01, Fig. 7). Treatment with dRK6 completely inhibited the expression of phospho-Akt and phospho-eNOS protein with high glucose concentrations in the media (Fig. 7,B). However, there was no significant difference in phospho-Akt and phospho-eNOS protein expression for concentrations of 5 mmol/l d-glucose or 5 mmol/l d-glucose + 25 mmol/l mannitol treated with or without dRK6. As shown in Fig. 6 F and G, the 8-iso-PGF and 8-OH-dG concentrations were increased with high glucose concentrations, which were further increased by dRK6 treatment (3.0- and 3.5-fold, respectively). However, these changes were not observed at concentrations of 5 mmol/l d-glucose (low glucose) or 5 mmol/l d-glucose + 25 mmol/l mannitol.

FIG. 7.

The effect of dRK6 on apoptosis in the HUVECs, determined by in situ TUNEL assay. Representative pictures of TUNEL-positive HUVECs (A, original magnification ×200). The apoptosis of HUVECs treated with different doses of dRK6 (10−6, 10−8, and 10−10 mmol/l) and concentrations of glucose in the media (5 and 30 mmol/l of d-glucose, and 5 mmol/l d-glucose + 25 mmol/l mannitol) for 48 h (B). Representative Western blots for total and phospho-Akt and phospho-eNOS (C–E). 8-Iso-PGF (F) and 8-OH-dG (G) concentrations of cell culture media in each group. *P < 0.05, **P < 0.01 compared with HG or HG+dRK6. NG, 5 mmol/l of d-glucose; HG, 30 mmol/l d-glucose; MN, 5 mmol/l d-glucose + 25 mmol/l mannitol; +dRK6, treated with dRK6. *P < 0.05, **P < 0.01 compared with the other groups; n = 4. HG, high glucose; NG, normal glucose. (A high-quality color digital representation of this figure is available in the online issue.)

FIG. 7.

The effect of dRK6 on apoptosis in the HUVECs, determined by in situ TUNEL assay. Representative pictures of TUNEL-positive HUVECs (A, original magnification ×200). The apoptosis of HUVECs treated with different doses of dRK6 (10−6, 10−8, and 10−10 mmol/l) and concentrations of glucose in the media (5 and 30 mmol/l of d-glucose, and 5 mmol/l d-glucose + 25 mmol/l mannitol) for 48 h (B). Representative Western blots for total and phospho-Akt and phospho-eNOS (C–E). 8-Iso-PGF (F) and 8-OH-dG (G) concentrations of cell culture media in each group. *P < 0.05, **P < 0.01 compared with HG or HG+dRK6. NG, 5 mmol/l of d-glucose; HG, 30 mmol/l d-glucose; MN, 5 mmol/l d-glucose + 25 mmol/l mannitol; +dRK6, treated with dRK6. *P < 0.05, **P < 0.01 compared with the other groups; n = 4. HG, high glucose; NG, normal glucose. (A high-quality color digital representation of this figure is available in the online issue.)

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A growing number of drugs that inhibit VEGF signaling are being considered for the treatment of cancer and diabetic microvascular complications. These agents are generally well tolerated but sometimes may be accompanied by serious side effects. Most of the side effects are associated with downstream effects of suppression of VEGF-NO signaling through the inhibition of VEGF-A and VEGFR-2 signals in the endothelial cells of normal organs (4). Therefore, we evaluated the role of VEGF inhibition using dRK6 in the development and progression of cardiac adverse effects in a model of type 2 diabetes (db/db mice). In db/db mice, systemic dRK6 administration completely inhibited the cardiac VEGFR-2–Akt-eNOS axis, which subsequently caused the development of systolic dysfunction, cardiac fibrosis, and hypertrophy. From one perspective, the deterioration caused by dRK6 might be related to the regression of blood vessels, which was associated with an increase in antiangiogenic growth factors, such as thrombospondin-1, transforming growth factor (TGF)-β, and CTGF. These events were accompanied by an increase in endothelial cell apoptosis, inflammatory cell infiltration, and myocardial fibrosis. In addition, these pathologic alterations led to the aggravation of hypoxic and oxidative stress in the myocardium accompanied by metabolic abnormalities. However, no such changes were observed in the diabetic control or db/m-dRK6 mice. By using in vitro HUVECs, we have shown that dRK6 had potent apoptotic effects on endothelial cells, which were associated with inhibition of the phospho–Akt-eNOS axis and enhancement of oxidative stress.

To date, the effects of systemic inhibition of VEGF on the heart remain uncertain. Previous findings from studies of the structural and functional changes in the organs of the normal adult mouse, after inhibition of VEGF signaling, revealed little or no capillary regression was detected in the brain, retina, skeletal muscle, lung, or myocardium (26,27). Consistent with these findings, our study also demonstrated that there was no change in the microvasculature in the heart of nondiabetic db/m mice. However, there was significant regression of the microvasculature of the heart in the diabetic mice, which resulted in cardiac fibrosis and cardiac dysfunction. These findings suggest that diabetes may be a critical determinant of the adverse effects on the heart caused by systemic anti-VEGF therapy.

It has been shown that downregulation of expression of myocardial VEGF and VEGFR-1 and -2 preceded all other characteristic features of DCM (10). These findings suggest that downregulation of VEGF and VEGFR-2 is involved in the microvascular homeostasis of the myocardium and thereby play a central role in the pathogenesis of DCM. In addition, continuous and prolonged VEGF blockade caused by deterioration of the DCM in mice with type 2 diabetes appears to relate to the downregulation of the VEGFR-2–Akt-eNOS axis. The relationship between VEGF expression, the microvasculature, and cardiac function has been clearly demonstrated in experiments on transgenic mice lacking VEGF isoforms, VEGF164 and VEGF188. These mice exhibit impaired myocardial angiogenesis and subsequently developed severe left ventricular dysfunction (28,29). There is growing evidence from animal models and patient studies that DCM can result from microcirculatory defects in the absence of epicardial coronary artery stenosis (30). These findings suggest that decreased VEGF expression might play a significant role in the development of microvascular defects, ischemia, and fibrosis in the pathogenesis of DCM (13).

An important question with regard to VEGF blockade is whether its effects on the heart are through metabolic abnormalities and/or whether there is a direct effect of VEGF on the cardiac microvasculature. Continuous damage to endothelial cells by metabolic abnormalities, including hyperglycemia, advanced glycosylation end products, and FFAs, ultimately leads to cell loss, reduced blood flow, hypoxia, and tissue ischemia (31,32). The results of our in vitro study suggest that metabolic abnormalities, especially hyperglycemia, have deleterious effects on the heart related to VEGF blockade.

It is well known that hypoxia plays a key role in all diabetes-related complications (33). Hyperglycemia-induced oxidative stress is a major risk factor for the development of microvascular pathology in the diabetic myocardium and results in myocardial cell death, hypertrophy, fibrosis, endothelial dysfunction, and even death via the phosphatidylinositol 3-kinase and Akt signaling pathways (34,35). Numerous studies have shown that Akt promotes cardioprotection and inhibits cell apoptosis by regulation of multiple substrates (36,37). Akt phosphorylates and inactivates proapoptotic proteins including glycogen synthase kinase-3β and caspase-9, the upstream activator of caspase-3 (38,39). Akt also activates the antiapoptotic Bcl-2 protein, which is associated with phosphorylation of NOS and increases in the production of NO. Therefore, downregulation of the Akt-eNOS axis by dRK6 might relate to endothelial cell apoptosis in diabetic db/db mice.

Under hypoxic conditions, HIF-1α is stabilized, translocates into the nucleus, dimerizes with HIF-1β, and up-regulates the genes involved in angiogenesis, glycolytic energy metabolism, cell proliferation, and survival (40,41). In the present study, the markedly upregulated expression of nuclear HIF-1α after treatment with dRK6 suggests that the dRK6-induced hypoxic conditions in the heart and HIF-1α function to prevent excessive ROS production under conditions of chronic hypoxia. These results indicate that continuous VEGF blockade by dRK6 under diabetic conditions ultimately leads to the accumulation of reactive oxygen species and oxidative stress leading to increased expression of 8-OH-dG in the heart.

Previous reports have demonstrated that db/db mice usually have no gross cardiac hypertrophy at 3 months (42,43); isolated working hearts as well as studies using magnetic resonance imaging, however, indicate that significant left ventricular dysfunction develops in the hearts of db/db mice at much earlier ages. In this study, in contrast to the db/db control mice, systemic inhibition with dRK6 resulted in more severe systolic dysfunction and gross cardiac hypertrophy and fibrosis in the db/db mice at 5 months of age. The data from our study showed that the direct effects of VEGF blockade, as well as the metabolic abnormalities associated with diabetes such as hyperglycemia, dyslipidemia, and hyperinsulinemia, might be important to the development of pathologic conditions, including severe cardiac hypertrophy, fibrosis, and inflammation.

Data regarding circulating VEGF levels in diabetes are highly discrepant. One study reported that plasma VEGF levels were higher in type 2 diabetics that in controls (20). In another study, plasma VEGF levels were elevated only in type 2 diabetic patients with characteristics of atherosclerosis (21). In our study, there were sixfold higher serum VEGF levels in db/db mice compared with db/m mice. dRK6 treatment also increased the serum VEGF level independently from diabetic conditions. It is well known that as VEGF is a paracrine mediator, systemic levels may not adequately reflect changes in the local VEGF system (44). Therefore, elevated plasma VEGF levels after dRK6 treatment might be a consequence of feedback of systemic VEGF-VEGFR inhibition.

In summary, our results indicate that the systemic dRK6 completely inhibited endogenous cardioprotective mechanisms through suppression of the VEGF-R2 and Akt-eNOS axis in the heart of mice with type 2 diabetes and subsequently led to cardiac systolic dysfunction resulting from cardiac fibrosis and hypertrophy, which were related to the regression of the microvasculature in the heart. These changes were accompanied by intracardiac hypoxia and oxidative stress. Therefore, the protective role of VEGF appears to be predominantly dependent on its ability to stimulate activation of Akt-eNOS in the endothelial cells in tissues. Further clinical investigations are needed to evaluate whether VEGF inhibition using anti-VEGF agents for the treatment of age-related macular diseases, various cancers, and diabetic microvascular complications has robust effects on the heart, especially in patients with type 2 diabetes.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

This study was supported by the Catholic Medical Center Research Foundation (to C.W.P.) and the Basic Science Research Program through the National Research Foundation (NRF) of Korea funded by the Ministry of Education, Science and Technology (R01-2009-0073171).

No potential conflicts of interest relevant to this article were reported.

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Supplementary data