The mechanisms for the development of diabetic cardiomyopathy remain largely unknown. Methylglyoxal (MG) can accumulate and promote inflammation and vascular damage in diabetes. We examined if overexpression of the MG-metabolizing enzyme glyoxalase 1 (GLO1) in macrophages and the vasculature could reduce MG-induced inflammation and prevent ventricular dysfunction in diabetes. Hyperglycemia increased circulating inflammatory markers in wild-type (WT) but not in GLO1-overexpressing mice. Endothelial cell number was reduced in WT-diabetic hearts compared with nondiabetic controls, whereas GLO1 overexpression preserved capillary density. Neuregulin production, endothelial nitric oxide synthase dimerization, and Bcl-2 expression in endothelial cells was maintained in the hearts of GLO1-diabetic mice and corresponded to less myocardial cell death compared with the WT-diabetic group. Lower receptor for advanced glycation end products and tumor necrosis factor-α (TNF-α) levels were also observed in GLO1-diabetic versus WT-diabetic mice. Over a period of 8 weeks of hyperglycemia, GLO1 overexpression delayed and limited the loss of cardiac function. In vitro, MG and TNF-α were shown to synergize in promoting endothelial cell death, which was associated with increased angiopoietin 2 expression and reduced Bcl-2 expression. These results suggest that MG in diabetes increases inflammation, leading to endothelial cell loss. This contributes to the development of diabetic cardiomyopathy and identifies MG-induced endothelial inflammation as a target for therapy.
Introduction
In patients with type 2 and type 1 diabetes, cardiovascular complications are the main cause of morbidity and mortality. Although an increased incidence of atherosclerosis and coronary artery disease (CAD) is a primary reason for this, many patients suffer from clinically significant ventricular dysfunction even in the absence of these conditions. This ventricular dysfunction has been termed diabetic cardiomyopathy and is defined as myocardial left ventricular (LV) dysfunction independent of atherosclerosis and CAD (1). Diabetic cardiomyopathy is a major cause of heart failure in people with diabetes. Despite the lack of CAD, a strong association exists between diabetic cardiomyopathy and the presence of microvascular complications (2). For example, inflammation, endothelial dysfunction, abnormal vascular remodeling, and an impaired angiogenic response have all been linked to the myocardial apoptosis, fibrosis, and hypertrophy seen in diabetic cardiomyopathy (3), although the mechanisms involved have not been clearly defined.
The activation of endothelial cells (ECs) from a quiescent phenotype to a vasoconstrictive, proinflammatory, and proapoptotic state leads to the inability of the endothelium to properly function (4). In diabetes, ECs are directly exposed to excessive and/or fluctuating blood glucose levels, and hyperglycemia is a known contributing factor to the loss of endothelial function (5). This exposure can stimulate the generation of reactive oxygen species (ROS) and the production of toxic by-products of glycolysis, primarily methylglyoxal (MG), leading to the formation of advanced glycation end products (AGEs) (6). Under normal physiological conditions, MG is metabolized by the glyoxalase system, whereby glyoxalase 1 (GLO1), together with glyoxalase 2 and glutathione, reduce MG to d-lactate, thus preventing MG accumulation (7). In diabetes, the production of MG is accelerated while its detoxification is slowed (due to reduced GLO1 activity), leading to MG accumulation (8,9). Elevated MG levels have been shown to promote inflammatory responses that activate ECs and lead to EC dysfunction and vascular damage (10,11). In fact, MG alone can cause endothelial damage similar to that induced by high glucose (HG) (12–14).
The endothelium plays an important role in cardiomyocyte viability and function and in myocardial homeostasis (15,16). EC death can lead to repeated episodes of ischemia and myocardial infarction, the death of cardiomyocytes, and the development of ventricular dysfunction leading to heart failure (17). However, the link between MG-induced inflammation, EC damage, and cardiac function in diabetes remain unknown. The current study used mice that overexpress human GLO1(hGLO1) in macrophages and the vasculature (18–20) to investigate the connection between increased vascular MG, the ensuing inflammation in ECs, and the development of ventricular dysfunction in the diabetic heart.
Research Design and Methods
All studies were performed according to protocols approved by the University of Ottawa Animal Care Committee and in accordance with the National Institutes of Health Guide for the Care and Use of Laboratory Animals.
Animal Model
As described previously (18–20), C57BL/6 mice that overexpress hGLO1 were used. The cDNA encoding hGlo1 with an amino terminal c-myc epitope tag was cloned into the Not1-digested PEP8 plasmid, so that the hGlo1 insert was under the control of the murine preproendothelin promoter. Experiments were performed on 8- to 10-week-old male heterozygous GLO1 mice and their wild-type (WT) littermates. Mice were fed the Teklad Global 2019 Extruded Rodent Diet (Harlan) and kept in a 12/12 h light/dark cycle.
Induction of Diabetes Using Streptozotocin
Mice received an intraperitoneal injection of 50 mg/kg of streptozotocin (STZ) (Sigma-Aldrich) or vehicle only (citrate buffer control) for 5 consecutive days. Four groups of mice were generated: WT-control, GLO1-control, WT-diabetic, and GLO1-diabetic. Fasting blood glucose measurements were taken 7 days after the last STZ injection and again after the animals were killed. Mice with glucose levels above 15 mmol/L at the beginning of the study were considered hyperglycemic (diabetic). Both diabetic groups had increased fasting blood glucose levels at the end of the study (∼20 mmol/L), with no significant difference between them (Table 2).
Serum Analysis
ELISA assay kits (RayBiotech, Inc.) were used to measure blood serum levels of markers for endothelial inflammation (soluble intercellular adhesion molecule 1 [ICAM-1], vascular cell adhesion molecule 1 [VCAM-1], and E-selectin, presented as pg/mL of serum) at 8 weeks post-STZ, following the manufacturer’s protocol.
Heart Digestion and Cell Separation
Whole hearts were harvested from killed animals and digested using digestion buffer, as previously described (21). After 30 min of digestion at 37°C, the cell suspension was filtered and plated onto tissue culture dishes for 2 h. This period allowed for the removal of the adherent fibroblast population. The nonadherent cells were incubated with sheep anti-rabbit IgG magnetic Dynabeads beads (Invitrogen) coated with CD31 antibody (Abcam) for 30 min at 4°C. The CD31+ cells were pulled down using a magnet and constituted the EC fraction. The remainder of the cells from the CD31+ cell sort was enriched for cardiomyocytes, with 80% of the cells confirmed to be cardiomyocytes by troponin staining and flow cytometry (data not shown).
GLO1 Activity
GLO1 activity was determined by measuring the rate of formation of S-d-lactoylglutathione from hemithioacetal, as previously described (20). Briefly, the assay mixture containing MG (7.9 mmol/L) was equilibrated to room temperature, and the reaction was initiated by the addition of lysate (10–50 mg). GLO1 activity is recorded as the mmol/L concentration of S-d-lactoylglutathione formed/min/mg of lysate protein (concentration determined by the bicinchoninic acid protein assay). GLO1 activity was measured in the whole heart, enriched cardiomyocyte cell population, and primary EC culture. Because number of ECs that could be obtained from myocardial tissue was insufficient for performing the GLO1 activity assay, ECs isolated from the aorta were used. GLO1 activity is presented as fold-change compared with the WT mice.
Western Blot
Protein expression analysis was determined by Western blots, as described previously (20). The levels of c-myc, tumor necrosis factor-α (TNF-α), receptor for AGE (RAGE), and neuregulin in the heart were assessed (antibodies from Abcam). For the detection of endothelial nitric oxide synthase (eNOS) dimers, polyacrylamide electrophoresis was performed using monomer/dimer-specific antibodies (Abcam) at low temperature (4°C), as previously described (22). Levels of angiopoietin 2 (antibody from Abcam) were assessed in lysates of human cardiac ECs (HCECs) after 24 h culture in different conditions (see live/dead assay). Densitometry data were analyzed using ImageJ software and normalized to tubulin expression.
Carbonyl Stress Measurements
Using an OxiSelect Protein Carbonyl ELISA kit, whole heart lysates were probed for total protein carbonyl content, according to the manufacturer’s protocol. Briefly, equal concentrations of protein lysates were loaded onto the plate and then transformed chemically to 2,4-dinitrophenyl (DNP) hydrazone and probed with an anti-DNP antibody, followed by a horseradish peroxidase–conjugated secondary antibody. The protein carbonyl content of the samples was determined by comparison against a standard curve of the predetermined reduced and oxidized BSA standards and expressed as nmol of carbonyl protein per mg of total protein.
Histology and Immunohistochemistry
Hearts were collected, perfused with saline, and then flash frozen in optimal cutting temperature compound for immunostaining of ECs by using von Willebrand factor (vWF), CD68, and CD31 antibodies (Abcam), and for cell death by using a TUNEL kit (Roche) or fixed in 4% formalin and embedded in paraffin in situ hybridization (ISH) (see ish) and RAGE staining (Abcam). Visualization was performed, as described previously (20), using a Zeiss Axiophot microscope equipped with a Hamamatsu C5985 chilled CCD camera, and MetaMorph 4.01 imaging software (Molecular Devices). Cell counts were determined and averaged from five random fields of view (FOV).
ISH
ISH was performed, as previously described (23), using digoxigenin-labeled antisense RNA riboprobes prepared by in vitro transcription from linearized plasmids containing complete or partial cDNA sequences for hGlo1 and endothelin. Briefly, sections of heart tissue were hybridized overnight at 65°C in a humidified chamber, washed stringently, and incubated with an alkaline phosphatase-conjugated anti-digoxigenin antibody. Staining was performed using Nitro blue tetrazolium (Roche) and 5-bromo-4-chloro-3-indolyl phosphate (Roche) and analyzed on an Axioplan microscope. Digital images were captured using an AxioVision 2.05 camera (Zeiss).
Echocardiography
At 4 and 8 weeks post-STZ administration, LV ejection fraction (LVEF), fractional shortening (FS), and other heart-function measurements were determined by echocardiography on long-axis views with a Vevo 770 system (VisualSonics) in B mode with the use of a 707B series real-time microvisualization scanhead probe.
Macrophage Isolation and Culture
As previously described (24), bone marrow–derived (BMD) macrophages (BMDMs) were generated from tibia bone marrow of WT and GLO1 male mice (8–10 weeks old). BMDMs were maintained for 1 week in DMEM with 10% FBS, 15% L929 media containing macrophage colony-stimulating factor and penicillin-streptomycin. After 72 h of additional culture with or without 5 μmol/L MG, the release of TNF-α by BMDMs was assessed in culture supernatants by ELISA (eBioscience). Values were normalized to TNF-α content in the BMDM groups without MG treatment.
EC Culture
Cryopreserved Clonetics HCECs (Lonza) were grown in endothelial growth medium with the 2MV BulletKit media. All experiments were performed using cells at passage 2–4 in standard incubator conditions at 37°C and 5% CO2 under normoxic conditions.
Cell Transfection
HCECs were seeded in 12-well plates (0.5 million cells/plate) using standard culture medium. After 24 h, the media was changed to Opti-MEM medium (Thermo Fisher), and cells were transfected with 20 μg plasmid DNA-lipofectin complex using the mammalian transfection kit (Thermo Fisher). The pCMV6-AC-GFP mammalian vector with COOH-terminal tGFP tag and hGLO1 cloning vector were obtained from OriGene. Transfection media was changed after 4 h, and cells were left to recover for 24 h. Transfection efficiency was 43% as determined by the GFP+-to-GFP− cell ratio, and a ninefold increase in hGLO1 expression was confirmed by PCR.
Live/Dead Assay
After 24 h of exposure to 30 mmol/L HG or 5 µmol/L MG, with or without 10 ng/mL TNF-α in the media, cells were washed with PBS and stained with propidium iodide (PI) (Invitrogen) for 30 min, according to the manufacturer’s protocol, and imaged using a Zeiss Axiophot microscope. Cells whose nuclei were stained with PI (red) were considered dead, and those labeled green were considered positive for GLO1 transfection. For quantification, the total number of cells and the number of dead GFP+ and dead GFP− cells were counted in four random FOV per well.
Carbonyl Stress Measurements of HCECs
HCECs (50,000/well) were lysed after 24 h exposure to 30 mmol/L HG or 5 μmol/L MG with or without 10 ng/mL TNF-α. Protein carbonyl content was determined using the OxySelect ELISA kit according to the manufacturer’s protocol.
RNA Extraction, cDNA Synthesis, and Quantitative PCR
Total RNA was extracted from CD31+ cells separated from mouse hearts and blood mononuclear cells (GLO1 and WT mice) using Trizol reagent (Invitrogen), following the manufacturer’s instructions. First-strand cDNA was synthesized from RNA (2 mg) using GoScript reverse transcriptase (Promega) and random hexamer primers (IDT). Levels of Bcl-2 mRNA in CD31+ cells and hGLO1 in mononuclear cells were assessed by real-time quantitative PCR (qPCR) using LightCycler 480 SYBR Green I Master (Roche) and a LightCycler 480 Real-Time PCR system (Roche). Relative changes in mRNA expression of target genes were determined using the ΔΔCt method and expressed as levels relative to the combined average values of 18S and Gapdh.
Statistical Analysis
Results are expressed as means ± SEM. Statistical analyses were performed using SigmaStat software. Comparisons between two groups were made by an unpaired two-tailed Student t test. For multiple group comparisons, a one-way ANOVA with a post hoc Student-Newman-Keuls test was performed. Statistical significance was given for P < 0.05.
Results
Increased GLO1 Expression and Activity in the Hearts of GLO1 Mice
It was confirmed that hGlo1 is not overexpressed in the cardiomyocytes of our transgenic mice. ISH demonstrated that the vasculature in the myocardial sections of GLO1 mice stained positive for hGlo1, whereas hGlo1 staining was not observed in the WT mice. The expression pattern of hGlo1 was similar to that of endothelin and vWF (Fig. 1A). When GLO1 activity was examined, the whole heart of transgenic mice exhibited a 1.8-fold increase in activity compared with the WT hearts (Fig. 1B). After heart digestion and cell isolation, no difference in GLO1 activity was detected in cardiomyocytes between GLO1 and WT mice, but aortic ECs extracted from GLO1 mice showed a 5.5-fold increase in GLO1 activity compared with the WT group (Fig. 1B). The presence of hGLO1 in aorta ECs was also confirmed by Western blot for the c-myc tag, which was not detected in the cardiomyocyte population (Fig. 1C). Expression of the hGlo1 gene was also found in the blood mononuclear cell fraction (mainly monocytes) of GLO1 mice but not in their WT littermates (data not shown).
Hyperglycemia-Induced Endothelial Inflammation Is Reduced by GLO1 Overexpression
After 8 weeks of hyperglycemia, WT-diabetic mice had increased circulating levels of the EC inflammation markers E-selectin, VCAM-1, and ICAM-1 compared with WT nondiabetic mice by 1.5-, 1.2-, and 1.4-fold, respectively (P ≤ 0.04) (Table 1). GLO1 overexpression in the vasculature restored circulating levels of E-selectin, VCAM-1, and ICAM-1 to that of the nondiabetic mice (P = 0.2–0.7). Compared with the WT-diabetic mice, there was a significant reduction in the level of VCAM-1 (P < 0.001) and a trend for reduced E-selectin and ICAM-1 (both P = 0.1) in the serum of GLO1-diabetic mice (Table 1).
. | WT-control . | GLO1-control . | WT-diabetic . | GLO1-diabetic . |
---|---|---|---|---|
E-selectin (pg/mL) | 758.9 ± 22.6 | 956.1 ± 156.0 | 1,149.4 ± 51.5* | 825.7 ± 172.4 |
VCAM-1 (pg/mL) | 39.0 ± 0.7 | 39.1 ± 0.7 | 45.0 ± 0.6† | 39.8 ± 1.3 |
ICAM-1 (pg/mL) | 14.3 ± 0.3 | 15.4 ± 1.1 | 19.9 ± 1.7‡ | 17.4 ± 0.1 |
. | WT-control . | GLO1-control . | WT-diabetic . | GLO1-diabetic . |
---|---|---|---|---|
E-selectin (pg/mL) | 758.9 ± 22.6 | 956.1 ± 156.0 | 1,149.4 ± 51.5* | 825.7 ± 172.4 |
VCAM-1 (pg/mL) | 39.0 ± 0.7 | 39.1 ± 0.7 | 45.0 ± 0.6† | 39.8 ± 1.3 |
ICAM-1 (pg/mL) | 14.3 ± 0.3 | 15.4 ± 1.1 | 19.9 ± 1.7‡ | 17.4 ± 0.1 |
ELISA measurement of EC inflammation markers in blood serum of mice at 8 weeks post-STZ (n = 3).
*P = 0.002 vs. WT-control.
†P < 0.001 vs. all other groups.
‡P ≤ 0.04 vs. WT-control and GLO1-control.
Inflammation Is Reduced in the Heart of Diabetic GLO1 Mice
To further explore the consequence of hyperglycemia in the heart, carbonyl stress was evaluated. ROS accumulation (not related only to MG accumulation) leads to protein oxidation and the formation of carbonyl groups on proteins, which can be measured by protein carbonyl assays. Carbonyl stress was increased in the whole heart of the WT-diabetic (by 2.5-fold) and GLO1-diabetic (1.8-fold) groups (P ≤ 0.008) compared with the nondiabetic mice (Fig. 2A). There was a trend for less carbonyl stress in the GLO1-diabetic versus WT-diabetic mice by 20% (P = 0.1). Immunohistochemistry staining of tissue sections showed increased RAGE expression throughout the tissue in the WT-diabetic heart compared with the other groups (Fig. 2B). The myocardial protein content of RAGE was also increased only in the hearts from WT-diabetic mice versus all other groups by ≥1.8-fold (P ≤ 0.02) (Fig. 2C). Both diabetic groups had greater expression of the inflammatory cytokine TNF-α (3.5-fold for WT-diabetic and 2-fold for GLO1-diabetic) compared with nondiabetic controls (P ≤ 0.02) (Fig. 2D), but the GLO1-diabetic mice exhibited lower TNF-α versus the WT-diabetic group (P = 0.04). No difference was observed in the number of CD68+ macrophages in the hearts of GLO1-diabetic versus WT-diabetic mice, but there was a trend for increased accumulation of macrophages in the diabetic mice by approximately twofold compared with nondiabetic controls (P ≤ 0.1) (Fig. 2E).
TNF-α Secretion Reduced in Macrophages From GLO1 Mice
In vitro studies were performed to help explain the observation that TNF-α levels were reduced in the hearts of GLO1-diabetic mice despite having similar numbers of recruited macrophages compared with the WT-diabetic group. BMDMs from WT and GLO1 mice were cultured with or without 5 μmol/L MG, and the TNF-α content was measured in the supernatants by ELISA. BMDMs from WT mice had increased TNF-α secretion when exposed to MG compared with all other groups (P ≤ 0.03) (Fig. 2F), whereas TNF-α secretion from BMDMs of GLO1 mice did not differ from BMDMs without MG exposure (Fig. 2F).
Increased GLO1 Activity Preserves EC Numbers and Prevents Cell Death in the Diabetic Mouse Heart
The number of ECs in the myocardium was assessed in tissue sections by vWF and CD31 staining. At 8 weeks post-STZ treatment, the number of vWF+ ECs per FOV was reduced in WT-diabetic hearts (by 40%) compared with the other groups (P ≤ 0.001) (Fig. 3A and B). Similar results were obtained with CD31+ staining (data not shown; P ≤ 0.02). Notably, despite the presence of hyperglycemia, GLO1-diabetic mice had no loss of ECs compared with the nondiabetic animals. CD31+ ECs were sorted from harvested heart myocardium, and the mRNA level of the antiapoptotic gene Bcl-2 was determined. Bcl-2 expression was downregulated in WT-diabetic ECs compared with all other groups, whereas levels were not significantly different in CD31+ cells from GLO1-diabetic mice compared with the nondiabetic controls (Fig. 3C). Apoptotic cells, determined by TUNEL staining, were more numerous in the hearts of WT-diabetic mice as early as 4 weeks post-STZ injection (up to 8.6-fold greater compared with all other groups, P ≤ 0.02) (Fig. 3D). By 8 weeks post-STZ, the number of TUNEL+ cells in WT-diabetic mice increased to 10-fold greater than controls (P ≤ 0.006). For GLO1-diabetic mice, there was no difference in the number of apoptotic cells at 4 weeks compared with the nondiabetic mice. However, at 8 weeks, GLO1-diabetic mice had a 4.1-fold increase in TUNEL+ cells compared with control mice (P = 0.045), but this was still fewer (2.5-fold less) than in WT-diabetic mice (P = 0.008) (Fig. 3D).
Production of EC Proteins Is Preserved in GLO1-Diabetic Mice
EC proteins important for the support of a healthy myocardium (eNOS and neuregulin) were maintained in GLO1-diabetic mice. Specifically, the protein levels of eNOS, implicated in the regulation of vascular function and promotion of cardiomyocyte survival (25), were preserved in GLO1-diabetic mice (Fig. 4A). Current research suggests that only the dimeric form of eNOS is able to generate NO, whereas the ROS-induced monomeric form of eNOS produces superoxide instead (22). Although eNOS dimerization was reduced by 50% in WT-diabetic mice (P ≤ 0.04), GLO1-diabetic mice maintained a level of dimeric eNOS similar to nondiabetic mice (P = 0.63) (Fig. 4A). The growth factor neuregulin produced in ECs is important in promoting cardiomyocyte function and survival (26). In WT-diabetic mice, neuregulin levels were ∼75% less than in nondiabetic mice (P ≤ 0.05) (Fig. 4B), but neuregulin expression was not significantly different between the GLO1-diabetic mice and controls.
GLO1 Overexpression in the Vasculature Delays STZ-Induced LV Dysfunction
There was no difference in LV function between WT and transgenic mice at baseline. At 4 weeks post-STZ, WT-diabetic mice exhibited reduced FS compared with all other groups (P ≤ 0.045) (Fig. 5A). At 8 weeks, decreased LVEF and FS were observed in WT-diabetic and GLO1-diabetic mice compared with the nondiabetic mice (P ≤ 0.03); however, LVEF and FS were significantly greater in GLO1-diabetic versus WT-diabetic mice (P ≤ 0.01) (Fig. 5A and B). At 8 weeks, an increase in the heart-to-body mass ratio was found in both diabetic groups (5 ± 0.09 mg/g in WT-diabetic and 5 ± 0.21 mg/g in GLO1-diabetic mice compared with 4.4 ± 0.1 mg/g in nondiabetic mice, P ≤ 0.02). This was most probably associated with body mass differences between the groups (nondiabetic mice weighed 26 ± 0.4 g, and diabetic mice weighed 20 ± 0.5 g, P < 0.001). Furthermore, the heart weight was reduced in both diabetic groups (P = 0.04). At 4 weeks, WT-diabetic mice showed reduced stroke volume, reduced cardiac output, and lowered diastolic end pressure compared with all other groups (P ≤ 0.02) (Table 2), showing the first signs of heart failure. There was no difference in LV wall thickness or systolic end volume among the groups, but cardiac output, stroke volume, and diastolic end volume were all decreased at 8 weeks in both diabetic groups compared with control animals (P ≤ 0.03) (Table 2). Still, between the two diabetic groups, cardiac output and stroke volume were significantly better in the GLO1 mice (P ≤ 0.04) (Table 2), confirming the partial preservation of heart function by protection of the vasculature from MG.
. | WT-control . | GLO1-control . | WT-diabetic . | GLO1-diabetic . | ||||
---|---|---|---|---|---|---|---|---|
4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | |
Wall thickness (mm) | 0.87 ± 0.01 | 0.88 ± 0.01 | 0.87 ± 0.01 | 0.87 ± 0.01 | 0.83 ± 0.01 | 0.83 ± 0.01 | 0.85 ± 0.01 | 0.85 ± 0.01 |
Cardiac output (mL) | 13.6 ± 0.7 | 12.2 ± 1.4 | 12.5 ± 0.7 | 11.2 ± 0.7 | 9.6 ± 0.2* | 6.8 ± 0.5† | 10.9 ± 0.2 | 8.4 ± 0.19‡§ |
Stroke volume (mL) | 34.6 ± 1.9 | 33.6 ± 1.8 | 32.4 ± 0.9 | 30.4 ± 1.8 | 21.4 ± 0.9* | 20.5 ± 0.9† | 29.6 ± 0.4 | 24.8 ± 1.2‡§ |
End volume (mL) | ||||||||
Diastole | 50.1 ± 1.6 | 49.7 ± 2.3 | 50.7 ± 3.2 | 48.9 ± 2.8 | 37.9 ± 0.8* | 38.4 ± 1.1† | 46.0 ± 2.2 | 39.3 ± 2.4‡ |
Systole | 16.5 ± 0.7 | 18.1 ± 2.7 | 15.9 ± 2.1 | 18.5 ± 1.8 | 16.5 ± 0.8 | 16.7 ± 1.7 | 17.8 ± 0.2 | 15.8 ± 1.0 |
Blood glucose level (mmol/L) | n/a | 5.4 ± 0.2 | n/a | 5.8 ± 0.3 | 19.5 ± 1.9 | 20.7 ± 1.1† | 14.9 ± 1.7 | 19.1 ± 1.3† |
. | WT-control . | GLO1-control . | WT-diabetic . | GLO1-diabetic . | ||||
---|---|---|---|---|---|---|---|---|
4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | 4 weeks . | 8 weeks . | |
Wall thickness (mm) | 0.87 ± 0.01 | 0.88 ± 0.01 | 0.87 ± 0.01 | 0.87 ± 0.01 | 0.83 ± 0.01 | 0.83 ± 0.01 | 0.85 ± 0.01 | 0.85 ± 0.01 |
Cardiac output (mL) | 13.6 ± 0.7 | 12.2 ± 1.4 | 12.5 ± 0.7 | 11.2 ± 0.7 | 9.6 ± 0.2* | 6.8 ± 0.5† | 10.9 ± 0.2 | 8.4 ± 0.19‡§ |
Stroke volume (mL) | 34.6 ± 1.9 | 33.6 ± 1.8 | 32.4 ± 0.9 | 30.4 ± 1.8 | 21.4 ± 0.9* | 20.5 ± 0.9† | 29.6 ± 0.4 | 24.8 ± 1.2‡§ |
End volume (mL) | ||||||||
Diastole | 50.1 ± 1.6 | 49.7 ± 2.3 | 50.7 ± 3.2 | 48.9 ± 2.8 | 37.9 ± 0.8* | 38.4 ± 1.1† | 46.0 ± 2.2 | 39.3 ± 2.4‡ |
Systole | 16.5 ± 0.7 | 18.1 ± 2.7 | 15.9 ± 2.1 | 18.5 ± 1.8 | 16.5 ± 0.8 | 16.7 ± 1.7 | 17.8 ± 0.2 | 15.8 ± 1.0 |
Blood glucose level (mmol/L) | n/a | 5.4 ± 0.2 | n/a | 5.8 ± 0.3 | 19.5 ± 1.9 | 20.7 ± 1.1† | 14.9 ± 1.7 | 19.1 ± 1.3† |
Echocardiography results for various cardiac function parameters assessed at 4 and 8 weeks post-STZ (n = 6–8 per group).
n/a, not applicable.
*P ≤ 0.02 vs. all other groups at 4 weeks.
†P ≤ 0.01 vs. WT- and GLO1-control at 8 weeks.
‡P ≤ 0.03 vs. WT- and GLO1-control at 8 weeks.
§P ≤ 0.04 vs. WT-diabetic at 8 weeks.
HG or MG and TNF-α Synergize to Induce EC Death
From our in vivo observations, we hypothesized that HG/MG increases the sensitivity of ECs to TNF-α death signals. To elucidate possible mechanisms, carbonyl stress was first assessed by ELISA in cultures of human ECs. Protein carbonyls were increased in ECs treated with HG or MG for 24 h, regardless of the presence or absence of TNF-α (P ≤ 0.04) (Fig. 6A). The expression of Ang-2 and Bcl-2, potentially involved in the combined effect of HG or MG with or without TNF-α on cell death, was then examined. ECs exposed to HG or MG with or without TNF-α had increased expression of Ang-2 protein compared with their respective control cultures (P ≤ 0.05) (Fig. 6B). Notably, the combination of MG and TNF-α increased Ang-2 expression in ECs by 3.3-fold compared with cells exposed to MG without TNF-α (P = 0.049) (Fig. 6B). The exposure of ECs to MG or HG conditions also reduced mRNA expression of the antiapoptotic gene Bcl-2, regardless of the presence or absence of TNF-α (P ≤ 0.04) (Fig. 6C). Finally, the combined effect of HG or MG with or without TNF-α on EC death was evaluated. The percentage of apoptotic cells (PI+) was increased for ECs treated for 24 h with HG or MG in the presence of TNF-α (P ≤ 0.04) (Fig. 6D). Notably, ECs transfected with GLO1/GFP were protected when cultured under these same conditions, with significantly less cell death observed in MG, HG+TNF-α, and MG+TNF-α conditions compared with their respective nontransfected controls (P ≤ 0.02) (Fig. 6D).
Discussion
The aim of this study was to elucidate a link between MG, EC inflammation, and reduced cardiac function. To this end, we used a transgenic mouse model in which the vasculature is protected from MG by GLO1 overexpression. We demonstrated that GLO1 overexpression in the vasculature of hyperglycemic (type I diabetic) mice: 1) reduced vascular inflammation; 2) preserved cardiac EC viability and protein production (Bcl-2, eNOS, and neuregulin); 3) reduced overall cell death in the myocardium; and 4) delayed and limited the loss of cardiac function. These results highlight the importance of MG-induced endothelial inflammation in the development of ventricular dysfunction in diabetes.
To establish that our GLO1 mice provided a good model for this study, we confirmed that the localization of hGlo1 and the associated increase in GLO1 activity were both restricted to the ECs and the vasculature of the myocardium. Furthermore, Western blot analysis of whole heart tissue showed no difference in the levels of MG-H1 (the major product of MG-specific glycation) between GLO1 and WT mice (data not shown). Thus, cardiomyocytes in GLO1 mice are expected to still be susceptible to the harmful effects of HG and MG accumulation, and changes in heart function after STZ was administered can be attributed to protection conferred by the ECs and vasculature. In addition, as discussed later in this section, reduced MG in monocytes and/or macrophages of GLO1 mice may also alleviate the effects of diabetes.
To assess the presence and severity of EC activation and inflammation, we measured the levels of the soluble adhesion molecules VCAM-1, ICAM-1, and E-selectin in blood serum. The release of VCAM-1, ICAM-1, and E-selectin into the circulation is an indicator of EC inflammation and/or cell death (27,28). Notably, GLO1 overexpression protected the ECs in diabetic mice, because increased VCAM-1, ICAM-1, and E-selectin levels were not present in the GLO1-diabetic mice as they were in the WT-diabetic group.
Myocardial inflammation is one of the main contributors to heart failure (29). In the current study, the increased carbonyl stress, RAGE expression, and inflammatory cytokine production (TNF-α) provided evidence of inflammation in the WT-diabetic mice. The overexpression of GLO1 reduced this inflammatory state but did not completely prevent it. The level of carbonyl stress is an indirect measure of oxidative stress through the detection of carbonylated proteins (30). Because the cardiomyocytes in GLO1 mice were not protected from MG, it is reasonable to expect that their level of carbonyl stress would be similar to that of WT-diabetic mice. Cardiomyocytes represent the largest contributor to myocardial mass, yet the hearts of GLO1 mice exhibited a trend for reduced levels of carbonylated proteins. Whether this result is exclusively from reduced carbonyl stress in the vasculature or also through an undetermined secondary protective effect conferred to cardiomyocytes by the ECs was not elucidated in the current study. Regardless, this highlights the importance of ECs and the vasculature in the overall regulation of inflammation and stress in the diabetic heart.
The loss of EC number and function in diabetes is well described (31) and largely occurs due to the accumulation of MG (32,33). In our study, the detrimental effect of hyperglycemia on ECs was evident: the number of vWF+ and CD31+ ECs was reduced in the hearts of WT-diabetic mice, and neuregulin and eNOS expression was reduced. However, the number of vWF+ and CD31+ ECs was preserved in the GLO1-diabetic mice compared with the nondiabetic groups, suggesting that increased MG caused EC loss in the heart. The improved survival of ECs in GLO1-diabetic mice may be related to the preserved mRNA levels of the antiapoptotic gene Bcl-2, which have been shown to be modified by MG (34). In addition to improved EC survival, the levels of neuregulin and eNOS in cardiac ECs were maintained in GLO1-diabetic but not in WT-diabetic mice compared with the nondiabetic controls.
Neuregulin produced by ECs closely adjoined to cardiomyocytes in the adult heart helps to regulate cardiomyocyte contractility and survival under stress conditions (35). It has been shown that neuregulin is reduced in diabetes (36), but ours is the first study to show that protecting ECs from MG can prevent this effect. Diabetes also reduces the amount of dimeric eNOS (22). The lack of this form of eNOS reduces NO production, which negatively affects the regulation of vascular function and the response of cardiomyocytes to stress while increasing the deleterious production of superoxide. Changes in NO/redox-based signaling contribute to cardiovascular dysfunction and programmed cell death (25). Mechanisms by which MG affects eNOS status have been reported. For example, MG modifications of hypoxia-inducible factor 1α have been shown to reduce eNOS expression in BMD endothelial progenitor cells, which was prevented by GLO1 overexpression (37). GLO1 can reduce the inhibitory phosphorylation of eNOS caused by MG and neutralize vascular aging (38). In our study, the overexpression of GLO1 preserved the eNOS dimerization process. It should be noted that neuregulin and NO are just two components involved in EC-cardiomyocyte signaling and that other factors not evaluated in the current study may contribute to the superior cardiac function observed in GLO1-diabetic mice. However, because GLO1 overexpression maintained EC number and production of eNOS and neuregulin, altered expression of these other potential contributing factors must also likely be a consequence of modified MG levels.
A similar observation was made for TNF-α expression: levels were elevated in the hearts of WT-diabetic mice and reduced by overexpressing GLO1. TNF-α is produced mainly in macrophages, and elevated levels of TNF-α in patients with diabetes are associated with micro- and macrovascular complications (39). MG has been shown to stimulate the production and secretion of TNF-α from macrophages (40), which was also observed in our in vitro BMDMs studies. The GLO1- and WT-diabetic groups had a trend for increased numbers of macrophages in the heart compared with nondiabetic mice; but notably, the blood mononuclear cells (this study) and macrophages of GLO1 mice (18) have been shown to have increased GLO1 expression. Therefore, GLO1 overexpression in macrophages may be contributing to reduced inflammation and cell death in GLO1 mice in the current study. This could potentially make them less susceptible to MG-induced TNF-α production and provides a plausible explanation for the reduced TNF-α level in the hearts of GLO1-diabetic mice. This scenario is supported by in vitro data showing that macrophages from GLO1 mice did not increase TNF-α secretion when exposed to MG, unlike the macrophages from WT mice. Consequently, because TNF-α induces EC dysfunction and apoptosis (41), less TNF-α secreted by macrophages may contribute to the improved health of the ECs and vasculature observed in GLO1 mice. Although reduced compared with WT-diabetic mice, TNF-α levels in GLO1-diabetic mice were still greater than in nondiabetic mice. This suggests that TNF-α may be originating from another source, such as cardiomyocytes, which has been previously reported (42).
In vitro studies were performed to further elucidate a mechanism for MG-induced EC inflammation and death. The results showed that MG increased carbonyl stress and Ang-2 protein, reduced Bcl-2 expression in HCECs, and acted synergistically with TNF-α to induce death. HG has been shown to increase the expression of Ang-2, ICAM, and VCAM in ECs, and HG-induced Ang-2 expression sensitizes ECs to the proinflammatory effects of TNF-α (43,44). Similarly, in this study, Ang-2 protein expression increased in ECs exposed to HG or MG, and levels increased further in cells with combined MG+TNF-α treatment. These results provide mechanistic insight into the observation that WT-diabetic mice had increased TNF-α levels and EC death, whereas GLO1-diabetic mice did not have a similar loss of ECs. The lower TNF-α levels in GLO1-diabetic mice, along with possible reduced Ang-2 in ECs, may be contributing to reduce endothelial inflammation and preventing cell death. Notably, transfecting ECs with GLO1 completely protected them from death when cultured in combined HG or MG+TNF-α conditions, whereas a significant increase in cell death was seen for the nontransfected cells, thus supporting the in vivo observations.
Increased RAGE and RAGE ligand expression can further propagate inflammation and result in long-term complications of diabetes (45). RAGE is expressed in cardiomyocytes, vascular cells, fibroblasts, and infiltrating inflammatory cells in diabetes (46). Ligand binding of RAGE initiates a positive feedback loop whereby the receptor-ligand interaction triggers increased RAGE expression (47). Previous studies have shown that increased GLO1 activity reduces the accumulation of MG-derived AGEs (18,48). Furthermore, the production of endogenous RAGE ligands, such as S100 calgranulins and high mobility group box 1, is increased by hyperglycemia, which can be prevented by GLO1 overexpression (49). In our study, the expression of RAGE protein in GLO1-diabetic mice was reduced compared with the WT-diabetic group, despite similar levels of hyperglycemia. This may be associated with lower levels of RAGE ligands (e.g., MG-derived AGEs, high mobility group box 1, S100 calgranulins) in the GLO1 mice, thus reducing the positive-feedback upregulation of RAGE expression. Such a mechanism may be contributing to the observed decrease in inflammation in the GLO1-diabetic mice.
Protecting the vascular system from the effects of MG through GLO1 overexpression resulted in reduced overall cell death in the mouse heart. Although apoptosis was increased in WT-diabetic mice at 4 and 8 weeks post-STZ injection, GLO1-diabetic mice exhibited an increase in apoptotic TUNEL+ cells only at 8 weeks but were still fewer than in the WT-diabetic group. Cardiomyocyte loss is an important mechanism in the process of myocardial remodeling, cardiac fibrosis, reduced heart function, and ultimately, heart failure (50). A previous study showed that ubiquitous overexpression of GLO1 in rats could attenuate cardiac fibrosis that otherwise developed in WT-diabetic rats after 16 weeks (48). We did not detect significant fibrosis in our WT-diabetic mice (1.3-fold, P = 0.1; data not shown), possibly because 8 weeks may be premature for full fibrosis development. Nevertheless, we observed reduced LV function in WT-diabetic mice as early as 4 weeks post-STZ, which was prevented in GLO1-diabetic mice.
Consistent with previous studies (2,48), the data presented here demonstrate the damaging effect of diabetes on cardiac function in mice. Evaluation of our mice at 4 and 8 weeks post-STZ allowed us to detect differences in the early stages of reduced cardiac function. LVEF and FS were already reduced after 4 weeks of hyperglycemia, which worsened along with other measures of cardiac function (cardiac output, systolic and diastolic end volume, heart weight) by 8 weeks compared with nondiabetic mice. Heart function of the GLO1-diabetic mice was superior to that of the WT-diabetic group, with a delay in the onset of functional loss (observed only at 8 weeks), which was also of lesser magnitude. Although the chosen mouse model allowed us to isolate the effects of hyperglycemia and MG on heart function in a relatively short period, a limitation is that hyperglycemia was maintained throughout the study protocol, which is not necessarily representative of patients with diabetes who develop heart failure after longer periods of fluctuating glucose levels.
In summary, our findings suggest that preventing EC inflammation can improve myocardial function in the setting of hyperglycemia and MG accumulation. The complete mechanism(s) responsible for reduced inflammation and the protection against EC loss is complex, but our study identified some pathways that may be involved (e.g., GLO1 overexpression reduces TNF-α–mediated effects). Therefore, protecting the vasculature from MG may be a target for future studies and therapy to postpone and reduce the development of heart failure in diabetes.
Article Information
Acknowledgment. The authors thank Rick Seymour (University of Ottawa Heart Institute) for technical support.
Funding. This work was supported by operating grants from the Heart & Stroke Foundation of Canada (000225 to R.W.M. and E.J.S.), the Canadian Institutes of Health Research (FRN 125678 to E.J.S.), and the National Institutes of Health (DK-020541 to F.G. and M.B.). B.V. was supported by a Canadian Graduate Scholarship from the Canadian Institutes of Health Research and B.M. by a research fellowship from the Heart & Stroke Foundation of Canada.
Duality of Interest. No potential conflicts of interest relevant to this article were reported.
Author Contributions. M.B., R.W.M., and E.J.S. designed the research. B.V., B.M., F.G., K.M., and N.J.R.B. performed the research. B.V., B.M., M.B., R.W.M., and E.J.S. analyzed data and wrote the manuscript. E.J.S. is the guarantor of this work and, as such, had full access to all data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.