Ceramide-Induced Impairment of Endothelial Function Is Prevented by CuZn Superoxide Dismutase Overexpression
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《动脉硬化血栓血管生物学》
From the Departments of Internal Medicine (S.P.D., F.M.F.) and Pharmacology (F.M.F.), Cardiovascular Center, The University of Iowa Carver College of Medicine, Iowa City.
Correspondence to Sean P. Didion, PhD, Department of Internal Medicine, 2000 Medical Laboratories, The University of Iowa Carver College of Medicine, Iowa City, IA 52242. E-mail sean-didion@uiowa.edu
Abstract
Objective— Ceramide is an important intracellular second messenger that may also increase superoxide. The goal of this study was to determine whether overexpression of CuZn superoxide dismutase (SOD) protects against ceramide-induced increases in vascular superoxide and endothelial dysfunction.
Methods and Results— Carotid arteries from CuZnSOD-transgenic (CuZnSOD-Tg) and nontransgenic littermates were examined in vitro. Immunohistochemistry confirmed that CuZnSOD protein was greater in carotid artery from CuZnSOD-Tg compared with nontransgenic mice. Ceramide (N-acetyl-D-sphingosine; 1 and 10 μmol/L) produced concentration-dependent impairment (P<0.05) of vasorelaxation in response to the endothelium-dependent agonist acetylcholine (ACh) in nontransgenic mice. For example, 100 μmol/L ACh relaxed arteries from nontransgenic mice by 96±4% and 52±5% in the presence of vehicle and 10 μmol/L ceramide, respectively. In contrast, ceramide (1 or 10 μmol/L) had no effect (P>0.05) on responses of carotid artery to ACh in CuZnSOD-Tg mice. Ceramide had no effect on nitroprusside- or papaverine-induced relaxation in CuZnSOD-Tg or nontransgenic mice. Ceramide increased superoxide in arteries from nontransgenic vessels, and this effect was prevented by polyethyleneglycol-SOD (50 U/mL) or overexpression of CuZnSOD.
Conclusions— These results suggest that ceramide-induced increases in superoxide impair endothelium-dependent relaxation, and that select overexpression of the CuZn isoform of SOD prevents ceramide-induced oxidative stress in vessels.
Ceramide, an important intracellular second messenger, has been found to increase superoxide. The results of the present study indicate that ceramide-induced increases in superoxide impairs endothelium-dependent relaxation and that select overexpression of the CuZn isoform of superoxide dismutase is very effective in preventing ceramide-induced oxidative stress in vessels.
Key Words: carotid artery ? genetically altered mice ? nitric oxide ? reactive oxygen species ? SOD1
Introduction
Ceramide, a sphingolipid second messenger, appears to be involved in the cellular signaling response to inflammatory stimuli or injury.1 For example, lipopolysaccharide (LPS) and tumor necrosis factor- (TNF-) have been associated with increases in ceramide and superoxide.2,3 It has been suggested that the increase in superoxide in response to these inflammatory stimuli may be mediated by ceramide.2,3 More recently, ceramide has been identified as having functional effects in cardiovascular physiology and disease, particularly atherosclerosis.4–13
Experimentally, exposure of blood vessels to exogenous ceramide (eg, C2-ceramide, which mimics many of the effects of endogenous ceramide) has been shown to inhibit endothelium-dependent relaxation.14–18 This effect may be mediated by superoxide-mediated inactivation of endothelium-derived NO.14,17,19 Several potential sources of superoxide exist within the vascular wall of which mitochondria and NAD(P)H-oxidase have been implicated as sources of superoxide in response to ceramide.14,17,20–23 Because increases in superoxide in response to ceramide are thought to be attributable (at least in part) to intracellular sources (ie, mitochondria and NAD(P)H oxidase), we anticipated that overexpression of CuZn superoxide dismutase (SOD; the predominant intracellular SOD)24 would be effective in preventing ceramide-induced increases in vascular superoxide and dysfunction. Thus, the first goal of the present study was to examine the hypothesis that ceramide produces increases in superoxide and endothelial dysfunction in carotid arteries. The second goal was to determine whether overexpression of CuZnSOD prevents ceramide-induced endothelial dysfunction and the accompanying increase in superoxide. To accomplish these goals, we examined vascular responses and superoxide levels in response to ceramide in genetically altered mice that overexpress CuZnSOD.
Methods
Experimental Animals
Mice (male and female) used for this study were derived from breeding male hemizygous CuZnSOD (human)-transgenic (C57BL/6-TgN(SOD1)10Cje) with female C57BL/6J mice obtained from The Jackson Laboratory. Two groups of mice were studied: CuZnSOD-transgenic (CuZnSOD-Tg) and their nontransgenic littermates. Nontransgenic (n=58) and CuZnSOD-Tg (n=43) mice were of similar age (8 months) and body weight (32 g; P>0.05). Genotype was ascertained by polymerase chain reaction of DNA isolated from tail biopsy samples as described on The Jackson Laboratory web site.25 All experimental protocols were approved by the University of Iowa animal care and use committee.
Vascular Studies
Rings of carotid artery (4 rings per mouse) from nontransgenic and CuZnSOD-Tg mice were studied in organ chambers as described previously.26–28 After a 45-minute equilibration period, 2 rings were incubated with vehicle (dimethylsulfoxide [DMSO]), and 2 rings were incubated with N-acetyl-D-sphingosine (C2-ceramide; 1 or 10 μmol/L) a cell-permeable, biologically active form of ceramide for 30 minutes before and during generation of concentration-response curves. As a control for possible nonspecific effects of ceramide, arteries from nontransgenic mice (in separate experiments) were incubated with vehicle (DMSO) and D-erythro-N-acetylsphinganine (dihydroceramide; 10 μmol/L), a cell-permeable but biologically inactive form of ceramide.29
After equilibration, vessels were contracted submaximally (50% to 60% of maximum) with the thromboxane analogue 9,11-dideoxy-11a,9a-epoxy-methanoprostaglandin F2 (U46619). After reaching a stable contraction plateau, concentration-response curves were generated for the endothelium-dependent dilator acetylcholine (ACh; 10 nmol/L to 100 μmol/L) and for the endothelium-independent dilators nitroprusside (0.1 nmol/L to 100 μmol/L) and papaverine (a non-NO–dependent dilator; 0.01 to 10 μmol/L). At the end of each experiment, a full concentration-response curve to U46619 (0.03 to 3.0 μg/mL) was generated to determine the maximal contractile response of each vessel.
Because overexpression of CuZnSOD may increase hydrogen peroxide (a dilator in many vessels), we assessed the role of hydrogen peroxide and NO in mediating responses of carotid arteries in nontransgenic and CuZnSOD-Tg mice under control conditions and in the presence of ceramide. Thus, responses to ACh and nitroprusside were examined in rings of carotid artery incubated with catalase (a scavenger of hydrogen peroxide; 300 U/mL) or NG-nitro-L-arginine (L-NNA, an NO synthase inhibitor; 100 μmol/L) in the presence of vehicle or ceramide (10 μmol/L).
Detection of Superoxide
Superoxide levels were evaluated in carotid artery using hydroethidine-based confocal microscopy as described previously.26,27 Briefly, sections of carotid artery from nontransgenic (n=22) and CuZnSOD-Tg (n=10) mice were preincubated with either vehicle or ceramide (10 μmol/L) for 30 minutes. In some experiments, sections of carotid artery from nontransgenic (n=6) mice were also incubated with polyethyleneglycol (PEG)-SOD (50 U/mL) for 30 minutes. Carotid arteries were frozen in optimal cutting temperature compound (OCT), sectioned (30 μm) onto glass slides, and incubated with hydroethidine (2 μmol/L) for 30 minutes. Positive staining (ethidium; red fluorescence) of carotid artery sections for superoxide was determined with a Bio-Rad MRC-1024 laser scanning confocal microscope equipped with a krypton/argon laser. Fluorescence was detected with a 585-nm long-pass filter. Laser settings were identical for acquisition of images, and vessels from nontransgenic and CuZnSOD-Tg mice treated with vehicle or ceramide were processed and imaged in parallel to avoid potential artifactual differences caused by tissue processing. Relative increases in the hydroethidine signal were determined using Scion Image software for the personal computer (version 4.02). Ethidium fluorescence was normalized to cross-sectional area of the vessel wall for each section.
Immunohistochemistry for CuZnSOD
Carotid arteries from nontransgenic and CuZnSOD-Tg mice were frozen in OCT and serially sectioned (8 μm) on a cryostat and mounted on microscope slides. Sections were fixed in 2% paraformaldehyde for 15 minutes. Slides were first treated with 3% hydrogen peroxide and rinsed in PBS followed by 8% BSA to quench endogenous peroxidase and to block nonspecific binding of protein, respectively. Slides were then incubated overnight (4°C) with an anti-human CuZnSOD polyclonal antibody (1:250 dilution; provided by Dr Larry Oberley, University of Iowa). Slides were then incubated with a biotinylated anti-rabbit IgG (Kit PK-6101; Vector Laboratories) for 30 minutes. After the slides were rinsed with PBS, avidin-horseradish peroxidase complex (Vector Laboratories) was applied for 30 minutes, followed by incubation with diaminobenzidine. Slides were counterstained with Harrison’s hematoxylin and examined for positive staining of CuZnSOD (brown color) by light microscopy.
Drugs
ACh, catalase, ceramide, dihydroceramide, L-NNA, nitroprusside, papaverine, and PEG-SOD were obtained from Sigma, and all were dissolved in saline with the exception of ceramide and dihydroceramide, which were dissolved in DMSO (final concentration <0.01%). U46619 was obtained from Cayman Chemical and dissolved in 100% ethanol, with subsequent dilution being made with saline. Hydroethidine was obtained from Molecular Probes and dissolved in DMSO at a concentration of 0.1 mol/L. All other reagents were of standard laboratory grade.
Statistical Analysis
All data are expressed as means±SE. Relaxation to ACh, nitroprusside, and papaverine is expressed as a percent relaxation to U46619-induced contraction. Comparisons of relaxation and contraction were made using ANOVA followed by Bonferroni’s multiple comparison test. Comparison of ethidium fluorescence was made using paired t tests. Statistical significance was accepted at P<0.05.
Results
CuZnSOD Expression in Carotid Artery
Consistent with the presence of endogenous mouse CuZnSOD, immunohistochemistry for CuZnSOD revealed light staining (brown color) for CuZnSOD within the wall of carotid arteries from nontransgenic mice (Figure 1). In arteries from CuZnSOD-Tg mice, immunostaining for CuZnSOD (representing endogenous mouse and human CuZnSOD) was markedly increased (Figure 1).
Figure 1. Immunohistochemical staining with a polyclonal CuZnSOD antibody (bottom panels) or without the CuZnSOD antibody (negative control; top panels) in carotid artery of nontransgenic and CuZnSOD-Tg mice. Sections were counterstained with Harrison’s hematoxylin. Results are representative of experiments from 3 mice of each genotype. Bar=100 μm.
Ceramide Produces Endothelial Dysfunction in Nontransgenic Mice
In nontransgenic mice, ACh produced concentration-dependent relaxation of carotid arteries precontracted with U46619 (Figures 2 and 3 A). This response was markedly attenuated by L-NNA; Figure 3A) but not by catalase (data not shown). These findings suggest that relaxation of the carotid artery to ACh in nontransgenic mice is normally mediated by NO and is consistent with our previous findings in eNOS-deficient mice.28
Figure 2. Representative tracings of response of carotid artery (precontracted with U-44619) responses to ACh from nontransgenic and CuZnSOD-Tg mice treated with either vehicle (top tracings) or 10 μmol/L ceramide (bottom tracings). Relaxation to ACh was reduced in carotid arteries from nontransgenic mice but not CuZnSOD-Tg mice incubated with ceramide compared with vehicle-treated vessels.
Figure 3. A, Relaxation of carotid arteries from nontransgenic and CuZnSOD-Tg mice incubated with vehicle (control; n=8), incubated with 1 μmol/L ceramide (n=8) or 100 μmol/L L-NNA (n=3) to the endothelium-dependent agonist ACh. Relaxation to ACh in nontransgenic but not CuZnSOD-Tg mice is impaired to ACh, particularly at the higher concentrations, in the presence of ceramide. Relaxation to ACh is markedly attenuated in the presence of L-NNA in carotid arteries from nontransgenic and CuZnSOD-Tg mice. Values mean±SE; *P<0.05 vs con-trol. B, Relaxation of carotid arteries from nontransgenic (n=8) and CuZnSOD-Tg (n=8) mice incubated with vehicle (control) and incubated with 1 μmol/L ceramide to the endothelium-independent agonist nitroprusside. Values mean±SE; P>0.05.
In vessels treated with ceramide (1 μmol/L), relaxation in response to higher concentrations of ACh was inhibited by 25%. For example, relaxation to 100 μmol/L ACh was 92±6% and 71±6% in vehicle-treated and ceramide-treated (1 μmol/L) vessels, respectively (Figure 3A). This effect was selective because vasorelaxation to nitroprusside (Figure 3B) and papaverine (data not shown) was not affected by 1 μmol/L ceramide.
A higher concentration of ceramide (10 μmol/L) produced greater impairment (50% inhibition) of ACh-induced relaxation in arteries from nontransgenic mice (Figures 2 and 4A). For example, 100 μmol/L ACh-induced relaxation was 96±4% and 52±5% in the vehicle- and ceramide-treated vessels, respectively (Figure 4A). Relaxation to ACh in the presence of ceramide was markedly reduced (90%) by L-NNA but not affected by catalase, suggesting that the residual response to ACh in the presence of ceramide is mediated by NO (Figure 4A). Relaxation to nitroprusside (Figure 4B) was similar in nontransgenic mice in either the absence or presence of 10 μmol/L ceramide (as well as in the absence or presence of catalase or L-NNA; data not shown), demonstrating selectivity.
Figure 4. A, Relaxation of carotid arteries from nontransgenic and CuZnSOD-Tg mice incubated with vehicle (control; n=8), 10 μmol/L ceramide (n=8), 10 μmol/L ceramide plus catalase (300 U/mL; n=5), or 10 μmol/L ceramide plus L-NNA (n=5) to the endothelium-dependent agonist ACh. L-NNA but not catalase markedly reduced responses of carotid arteries from nontransgenic and CuZnSOD-Tg mice to ACh (in the presence of ceramide). Values mean±SE; *P<0.05 vs control. B, Relaxation of carotid arteries from nontransgenic (n=8) and CuZnSOD-Tg (n=8) mice incubated with vehicle (control) or 10 μmol/L ceramide to the endothelium-dependent agonist nitroprusside. Values mean±SE; P>0.05.
Incubation of vessels with either vehicle or dihydroceramide (an inactive form of ceramide; 10 μmol/L) had no effect on relaxation to ACh (Figure 5), nitroprusside (Figure 5), or papaverine (data not shown) in nontransgenic mice, providing strong evidence that the endothelial dysfunction observed in this model was attributable to direct effects of ceramide.
Figure 5. Relaxation of carotid arteries from nontransgenic (n=8) mice incubated with either vehicle (control) or 10 μmol/L dihydroceramide (DHC), the biologically inactive form of C2-ceramide to ACh and nitroprusside. Values mean±SE; P>0.05.
Overexpression of CuZnSOD Protects Against Ceramide-Induced Endothelial Dysfunction
In CuZnSOD-Tg mice, ACh produced concentration-dependent relaxation, which was similar to that produced in nontransgenic mice (Figures 2 and 3 A). This response was markedly attenuated by L-NNA (Figure 3A) but not by catalase (data not shown). These findings suggest that relaxation of the carotid artery to ACh is mediated very predominantly by NO in CuZnSOD-Tg mice.
In contrast to the effects of ceramide (1 and 10 μmol/L) on endothelial function in nontransgenic mice, ceramide-induced endothelial dysfunction was completely prevented by overexpression of CuZnSOD, as evidenced by normal responses to ACh in CuZnSOD-Tg mice (Figures 3A and 4A). This response to ACh in the presence of 10 μmol ceramide was markedly attenuated by L-NNA but not catalase (Figure 4A), indicating the response is mediated by NO. Relaxation in response to nitroprusside (Figures 3B and 4 B) was similar in CuZnSOD-Tg mice in either the absence or presence of 10 μmol/L ceramide (as well as in the absence or presence of catalase or L-NNA; data not shown).
Ceramide-Induced Increases in Superoxide Are Prevented by Overexpression of CuZnSOD
Basal superoxide levels, as detected by hydroethidine-based confocal microscopy, were similar in carotid arteries from nontransgenic and CuZnSOD-Tg mice (Figure 6). Preincubation of carotid arteries from nontransgenic mice with ceramide (10 μmol/L) increased the hydroethidine signal (11±3 and 18±5x103 relative units in vehicle- and ceramide-treated arteries, respectively; P<0.05; Figure 6). The hydroethidine signal was reduced by PEG-SOD in vehicle- and ceramide-treated nontransgenic vessels (5±1 and 5±1x103 relative units, respectively; P<0.05). Thus, ceramide-induced increases in hydroethidine staining appear to be a result of superoxide and do not appear to be attributable to any nonspecific shifts in baseline fluorescence. In addition, increases in the hydroethidine signal in response to ceramide were not observed in carotid arteries from CuZnSOD-Tg mice (Figure 6), suggesting that overexpression of CuZnSOD is sufficient to prevent ceramide-induced increases in superoxide.
Figure 6. Representative confocal fluorescent sections of carotid arteries from nontransgenic (left, top, and bottom panels) and CuZnSOD-Tg (right, top, and bottom panels) mice preincubated with either vehicle or ceramide (10 μmol/L for 30 minutes) and then incubated with hydroethidine (2 μmol/L for 30 minutes) for detection of superoxide. In nontransgenic mice, relatively equal levels of fluorescence were detected throughout the vessel wall (left top panel). Similarly, in CuZnSOD-Tg mice, fluorescence was noted throughout the vessel wall (right, top panel). However, fluorescence was higher in carotid artery after ceramide treatment in nontransgenic (left, bottom panel) but not CuZnSOD-Tg (right, bottom panel) mice compared with carotid artery from vehicle-treated, nontransgenic mice. E indicates endothelium; A, adventitia. Bar=100 μm.
Discussion
There are several major new findings of the present study. First, although immunohistochemistry revealed that CuZnSOD protein is markedly increased in CuZnSOD-Tg mice, relaxation of the carotid artery to ACh was unaltered by overexpression of CuZnSOD. This finding suggests that overexpression of CuZnSOD does not alter endothelial function under normal conditions. Second, ceramide impairs endothelial function in nontransgenic mice. Overexpression of CuZnSOD protected against ceramide-induced endothelial dysfunction. Third, ceramide increased superoxide levels in carotid artery of nontransgenic but not CuZnSOD transgenic mice. These findings combined with the functional responses seen in the CuZnSOD-Tg mice provide direct evidence that ceramide-induced superoxide formation produces endothelial dysfunction, possibly resulting from superoxide-mediated inactivation of NO bioavailability.
Ceramide-Induced Endothelial Dysfunction
Ceramide has been shown to have direct effects on vascular tone that appear to vary depending on the species and vascular bed.15,16,18,30,31 In addition, acute incubation with ceramide has been shown to impair endothelium-dependent relaxation.14,17,18 Consistent with these findings, we found that incubation of carotid arteries from nontransgenic mice with ceramide impaired relaxation to ACh in a concentration-dependent manner. The concentrations of ceramide used to inhibit endothelium-dependent relaxation in our study (1 and 10 μmol/L) have been shown previously to approximate levels of ceramide achieved in cells after exposure to TNF-.3,32 Thus, the concentrations of ceramide used in the present study are physiologically relevant. In addition, we found that dihydroceramide, a cell-permeable but biologically inactive form of ceramide, had no effect on vascular responses to either endothelium-dependent or -independent stimuli, suggesting that the effects of ceramide are selective.
Mechanism of Ceramide-Induced Vascular Dysfunction
It has been shown previously that selective overexpression of CuZnSOD increases CuZnSOD protein and activity levels in nonvascular tissue and aorta from CuZnSOD-Tg mice.33–37 Consistent with these findings, we found using immunohistochemistry that CuZnSOD protein is markedly increased in carotid arteries from CuZnSOD-Tg mice compared with nontransgenic mice. In relation to vascular function, ACh produced concentration-dependent relaxation in carotid arteries from CuZnSOD-Tg that was similar to that observed in nontransgenic mice under basal conditions. In carotid arteries from nontransgenic and CuZnSOD-Tg mice, relaxation in response to ACh was attenuated by 90% in the presence of L-NNA. In contrast, catalase had no effect on responses to ACh in either nontransgenic or CuZnSOD-Tg mice. These findings provide evidence that relaxation to ACh is mediated by NO in nontransgenic and CuZnSOD-Tg mice, and that overexpression of CuZnSOD does not alter this response.
On the basis of studies using pharmacological approaches only, it has been suggested that ceramide-induced endothelial dysfunction is attributable to increases in superoxide, with concomitant reductions in endothelial-derived NO.14,17,19 To test this concept with a genetic and perhaps more definitive approach, we examined the effect of ceramide in CuZnSOD-Tg mice. Overexpression of CuZnSOD completely prevented the ceramide-induced endothelial dysfunction that was observed in nontransgenic mice (ie, relaxation to ACh in carotid arteries from CuZnSOD-Tg mice was similar in vessels treated with either ceramide or vehicle). Furthermore, in CuZnSOD-Tg mice, relaxation in response to ACh in the presence of ceramide was markedly attenuated by L-NNA but not catalase, suggesting that overexpression of CuZnSOD prevents ceramide-induced impairment of an NO-mediated response. The use of CuZnSOD-Tg mice also extends pharmacological studies in that it demonstrates that select overexpression of the major intracellular isoform of SOD per se is sufficient to protect endothelial function in response to ceramide.
In cells in culture, ceramide produces increases in superoxide.19,20,22 In the present study, ceramide increased superoxide in carotid arteries from nontransgenic mice as detected using hydroethidine. Thus, our findings are in agreement with the observation that ceramide increased superoxide in coronary artery.14,17 Consistent with our hypothesis and our functional data, ceramide did not increase superoxide in carotid artery from CuZnSOD-Tg mice, suggesting that selective overexpression of CuZnSOD is sufficient to prevent the increase in superoxide in response to ceramide. Our finding that prevention of ceramide-induced endothelial dysfunction in CuZnSOD-Tg mice provides direct evidence that increases in superoxide in response to ceramide are functionally important.
In the present study, superoxide was detected using hydroethidine-based confocal microscopy in sections from frozen tissue, a method shown previously to be a sensitive assay for detection of superoxide in vascular tissue.38,39 For example, we and others have shown previously that scavengers of superoxide (PEG-SOD, Tiron, gene transfer of CuZnSOD or extracellular [EC]-SOD) are efficacious in reducing or preventing the increases in the hydroethidine signal associated with various stimuli.26,39,40 Consistent with these previous findings, PEG-SOD or overexpression of CuZnSOD was also very effective in reducing the hydroethidine signal in response to ceramide in the present study, providing strong evidence that the increase in the hydroethidine signal was attributable to superoxide.
We recognize that there are potential limitations associated with the hydroethidine assay.38–44 First, because all current methods of superoxide detection (eg, lucigenin- and coelentrazine-enhanced chemiluminescence, electron-spin resonance, cyctochrome c reductase, etc) rely on the use of detector compounds, they are indirect measurements of superoxide. Second, hydroethidine can be oxidized by cytochrome c, which may result in overestimation of the superoxide signal.41 Third, it has been suggested that tissue sectioning may result in overestimation of the hydroethidine signal at the cut edge.44 In addition, freezing of tissue before sectioning may result in artifactual changes in the hydroethidine signal. In the present study, we attempted to minimize these potential artifacts because the hydroethidine signal was determined at a focal plane away from the edge of each tissue section and because tissues from each group were processed and imaged in parallel. Such an approach is used commonly by many laboratories and was used in control- and ceramide-treated groups. Fourth, hydroethidine itself can dismute superoxide to hydrogen peroxide, which may result in underestimation of the superoxide signal.41 Thus, the hydroethidine assay is a qualitative but not quantitative method of superoxide detection.38 Finally, we would point out that results obtained with hydroethidine have been confirmed using other methods of superoxide detection in many studies and have generally been very insightful for the study of vascular disease.
Functional Implications
The present study suggests that selective overexpression of CuZnSOD prevents ceramide-induced increases in superoxide and endothelial dysfunction. Increases in ceramide have been described in diseases associated with inflammation. For example, angiotensin II, endothelin, LPS, and TNF- all increase ceramide levels and are known to impair endothelium-dependent relaxation via a mechanism that may involve increased superoxide.2–4,45 In addition, ceramide has also been shown to accumulate within atherosclerotic lesions, which are clearly associated with increases in vascular oxidative stress and impairment of vascular function.9–11,13,40,46 Thus, increases in ceramide may promote endothelial dysfunction. In summary, our results indicate that ceramide impairs endothelium-dependent relaxation via increases in superoxide, and that select overexpression of the CuZn isoform of SOD is very effective in preventing ceramide-induced oxidative stress in vessels.
Acknowledgments
This work was supported by National Institutes of Health grants NS-24621, HL-38901, and HL-62984. S.P.D. was supported by DK-25295 and a national scientist development grant from the American Heart Association (0230327N). We thank Dale Kinzenbaw and Pamela Tompkins for excellent technical assistance. We thank Dr Larry Oberley for providing the CuZnSOD antibody, and Norma Sinclair and the University of Iowa Transgenic Facility (under the direction of Dr Curt D. Sigmund) for genotyping services.
Received February 25, 2004; accepted October 27, 2004.
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Correspondence to Sean P. Didion, PhD, Department of Internal Medicine, 2000 Medical Laboratories, The University of Iowa Carver College of Medicine, Iowa City, IA 52242. E-mail sean-didion@uiowa.edu
Abstract
Objective— Ceramide is an important intracellular second messenger that may also increase superoxide. The goal of this study was to determine whether overexpression of CuZn superoxide dismutase (SOD) protects against ceramide-induced increases in vascular superoxide and endothelial dysfunction.
Methods and Results— Carotid arteries from CuZnSOD-transgenic (CuZnSOD-Tg) and nontransgenic littermates were examined in vitro. Immunohistochemistry confirmed that CuZnSOD protein was greater in carotid artery from CuZnSOD-Tg compared with nontransgenic mice. Ceramide (N-acetyl-D-sphingosine; 1 and 10 μmol/L) produced concentration-dependent impairment (P<0.05) of vasorelaxation in response to the endothelium-dependent agonist acetylcholine (ACh) in nontransgenic mice. For example, 100 μmol/L ACh relaxed arteries from nontransgenic mice by 96±4% and 52±5% in the presence of vehicle and 10 μmol/L ceramide, respectively. In contrast, ceramide (1 or 10 μmol/L) had no effect (P>0.05) on responses of carotid artery to ACh in CuZnSOD-Tg mice. Ceramide had no effect on nitroprusside- or papaverine-induced relaxation in CuZnSOD-Tg or nontransgenic mice. Ceramide increased superoxide in arteries from nontransgenic vessels, and this effect was prevented by polyethyleneglycol-SOD (50 U/mL) or overexpression of CuZnSOD.
Conclusions— These results suggest that ceramide-induced increases in superoxide impair endothelium-dependent relaxation, and that select overexpression of the CuZn isoform of SOD prevents ceramide-induced oxidative stress in vessels.
Ceramide, an important intracellular second messenger, has been found to increase superoxide. The results of the present study indicate that ceramide-induced increases in superoxide impairs endothelium-dependent relaxation and that select overexpression of the CuZn isoform of superoxide dismutase is very effective in preventing ceramide-induced oxidative stress in vessels.
Key Words: carotid artery ? genetically altered mice ? nitric oxide ? reactive oxygen species ? SOD1
Introduction
Ceramide, a sphingolipid second messenger, appears to be involved in the cellular signaling response to inflammatory stimuli or injury.1 For example, lipopolysaccharide (LPS) and tumor necrosis factor- (TNF-) have been associated with increases in ceramide and superoxide.2,3 It has been suggested that the increase in superoxide in response to these inflammatory stimuli may be mediated by ceramide.2,3 More recently, ceramide has been identified as having functional effects in cardiovascular physiology and disease, particularly atherosclerosis.4–13
Experimentally, exposure of blood vessels to exogenous ceramide (eg, C2-ceramide, which mimics many of the effects of endogenous ceramide) has been shown to inhibit endothelium-dependent relaxation.14–18 This effect may be mediated by superoxide-mediated inactivation of endothelium-derived NO.14,17,19 Several potential sources of superoxide exist within the vascular wall of which mitochondria and NAD(P)H-oxidase have been implicated as sources of superoxide in response to ceramide.14,17,20–23 Because increases in superoxide in response to ceramide are thought to be attributable (at least in part) to intracellular sources (ie, mitochondria and NAD(P)H oxidase), we anticipated that overexpression of CuZn superoxide dismutase (SOD; the predominant intracellular SOD)24 would be effective in preventing ceramide-induced increases in vascular superoxide and dysfunction. Thus, the first goal of the present study was to examine the hypothesis that ceramide produces increases in superoxide and endothelial dysfunction in carotid arteries. The second goal was to determine whether overexpression of CuZnSOD prevents ceramide-induced endothelial dysfunction and the accompanying increase in superoxide. To accomplish these goals, we examined vascular responses and superoxide levels in response to ceramide in genetically altered mice that overexpress CuZnSOD.
Methods
Experimental Animals
Mice (male and female) used for this study were derived from breeding male hemizygous CuZnSOD (human)-transgenic (C57BL/6-TgN(SOD1)10Cje) with female C57BL/6J mice obtained from The Jackson Laboratory. Two groups of mice were studied: CuZnSOD-transgenic (CuZnSOD-Tg) and their nontransgenic littermates. Nontransgenic (n=58) and CuZnSOD-Tg (n=43) mice were of similar age (8 months) and body weight (32 g; P>0.05). Genotype was ascertained by polymerase chain reaction of DNA isolated from tail biopsy samples as described on The Jackson Laboratory web site.25 All experimental protocols were approved by the University of Iowa animal care and use committee.
Vascular Studies
Rings of carotid artery (4 rings per mouse) from nontransgenic and CuZnSOD-Tg mice were studied in organ chambers as described previously.26–28 After a 45-minute equilibration period, 2 rings were incubated with vehicle (dimethylsulfoxide [DMSO]), and 2 rings were incubated with N-acetyl-D-sphingosine (C2-ceramide; 1 or 10 μmol/L) a cell-permeable, biologically active form of ceramide for 30 minutes before and during generation of concentration-response curves. As a control for possible nonspecific effects of ceramide, arteries from nontransgenic mice (in separate experiments) were incubated with vehicle (DMSO) and D-erythro-N-acetylsphinganine (dihydroceramide; 10 μmol/L), a cell-permeable but biologically inactive form of ceramide.29
After equilibration, vessels were contracted submaximally (50% to 60% of maximum) with the thromboxane analogue 9,11-dideoxy-11a,9a-epoxy-methanoprostaglandin F2 (U46619). After reaching a stable contraction plateau, concentration-response curves were generated for the endothelium-dependent dilator acetylcholine (ACh; 10 nmol/L to 100 μmol/L) and for the endothelium-independent dilators nitroprusside (0.1 nmol/L to 100 μmol/L) and papaverine (a non-NO–dependent dilator; 0.01 to 10 μmol/L). At the end of each experiment, a full concentration-response curve to U46619 (0.03 to 3.0 μg/mL) was generated to determine the maximal contractile response of each vessel.
Because overexpression of CuZnSOD may increase hydrogen peroxide (a dilator in many vessels), we assessed the role of hydrogen peroxide and NO in mediating responses of carotid arteries in nontransgenic and CuZnSOD-Tg mice under control conditions and in the presence of ceramide. Thus, responses to ACh and nitroprusside were examined in rings of carotid artery incubated with catalase (a scavenger of hydrogen peroxide; 300 U/mL) or NG-nitro-L-arginine (L-NNA, an NO synthase inhibitor; 100 μmol/L) in the presence of vehicle or ceramide (10 μmol/L).
Detection of Superoxide
Superoxide levels were evaluated in carotid artery using hydroethidine-based confocal microscopy as described previously.26,27 Briefly, sections of carotid artery from nontransgenic (n=22) and CuZnSOD-Tg (n=10) mice were preincubated with either vehicle or ceramide (10 μmol/L) for 30 minutes. In some experiments, sections of carotid artery from nontransgenic (n=6) mice were also incubated with polyethyleneglycol (PEG)-SOD (50 U/mL) for 30 minutes. Carotid arteries were frozen in optimal cutting temperature compound (OCT), sectioned (30 μm) onto glass slides, and incubated with hydroethidine (2 μmol/L) for 30 minutes. Positive staining (ethidium; red fluorescence) of carotid artery sections for superoxide was determined with a Bio-Rad MRC-1024 laser scanning confocal microscope equipped with a krypton/argon laser. Fluorescence was detected with a 585-nm long-pass filter. Laser settings were identical for acquisition of images, and vessels from nontransgenic and CuZnSOD-Tg mice treated with vehicle or ceramide were processed and imaged in parallel to avoid potential artifactual differences caused by tissue processing. Relative increases in the hydroethidine signal were determined using Scion Image software for the personal computer (version 4.02). Ethidium fluorescence was normalized to cross-sectional area of the vessel wall for each section.
Immunohistochemistry for CuZnSOD
Carotid arteries from nontransgenic and CuZnSOD-Tg mice were frozen in OCT and serially sectioned (8 μm) on a cryostat and mounted on microscope slides. Sections were fixed in 2% paraformaldehyde for 15 minutes. Slides were first treated with 3% hydrogen peroxide and rinsed in PBS followed by 8% BSA to quench endogenous peroxidase and to block nonspecific binding of protein, respectively. Slides were then incubated overnight (4°C) with an anti-human CuZnSOD polyclonal antibody (1:250 dilution; provided by Dr Larry Oberley, University of Iowa). Slides were then incubated with a biotinylated anti-rabbit IgG (Kit PK-6101; Vector Laboratories) for 30 minutes. After the slides were rinsed with PBS, avidin-horseradish peroxidase complex (Vector Laboratories) was applied for 30 minutes, followed by incubation with diaminobenzidine. Slides were counterstained with Harrison’s hematoxylin and examined for positive staining of CuZnSOD (brown color) by light microscopy.
Drugs
ACh, catalase, ceramide, dihydroceramide, L-NNA, nitroprusside, papaverine, and PEG-SOD were obtained from Sigma, and all were dissolved in saline with the exception of ceramide and dihydroceramide, which were dissolved in DMSO (final concentration <0.01%). U46619 was obtained from Cayman Chemical and dissolved in 100% ethanol, with subsequent dilution being made with saline. Hydroethidine was obtained from Molecular Probes and dissolved in DMSO at a concentration of 0.1 mol/L. All other reagents were of standard laboratory grade.
Statistical Analysis
All data are expressed as means±SE. Relaxation to ACh, nitroprusside, and papaverine is expressed as a percent relaxation to U46619-induced contraction. Comparisons of relaxation and contraction were made using ANOVA followed by Bonferroni’s multiple comparison test. Comparison of ethidium fluorescence was made using paired t tests. Statistical significance was accepted at P<0.05.
Results
CuZnSOD Expression in Carotid Artery
Consistent with the presence of endogenous mouse CuZnSOD, immunohistochemistry for CuZnSOD revealed light staining (brown color) for CuZnSOD within the wall of carotid arteries from nontransgenic mice (Figure 1). In arteries from CuZnSOD-Tg mice, immunostaining for CuZnSOD (representing endogenous mouse and human CuZnSOD) was markedly increased (Figure 1).
Figure 1. Immunohistochemical staining with a polyclonal CuZnSOD antibody (bottom panels) or without the CuZnSOD antibody (negative control; top panels) in carotid artery of nontransgenic and CuZnSOD-Tg mice. Sections were counterstained with Harrison’s hematoxylin. Results are representative of experiments from 3 mice of each genotype. Bar=100 μm.
Ceramide Produces Endothelial Dysfunction in Nontransgenic Mice
In nontransgenic mice, ACh produced concentration-dependent relaxation of carotid arteries precontracted with U46619 (Figures 2 and 3 A). This response was markedly attenuated by L-NNA; Figure 3A) but not by catalase (data not shown). These findings suggest that relaxation of the carotid artery to ACh in nontransgenic mice is normally mediated by NO and is consistent with our previous findings in eNOS-deficient mice.28
Figure 2. Representative tracings of response of carotid artery (precontracted with U-44619) responses to ACh from nontransgenic and CuZnSOD-Tg mice treated with either vehicle (top tracings) or 10 μmol/L ceramide (bottom tracings). Relaxation to ACh was reduced in carotid arteries from nontransgenic mice but not CuZnSOD-Tg mice incubated with ceramide compared with vehicle-treated vessels.
Figure 3. A, Relaxation of carotid arteries from nontransgenic and CuZnSOD-Tg mice incubated with vehicle (control; n=8), incubated with 1 μmol/L ceramide (n=8) or 100 μmol/L L-NNA (n=3) to the endothelium-dependent agonist ACh. Relaxation to ACh in nontransgenic but not CuZnSOD-Tg mice is impaired to ACh, particularly at the higher concentrations, in the presence of ceramide. Relaxation to ACh is markedly attenuated in the presence of L-NNA in carotid arteries from nontransgenic and CuZnSOD-Tg mice. Values mean±SE; *P<0.05 vs con-trol. B, Relaxation of carotid arteries from nontransgenic (n=8) and CuZnSOD-Tg (n=8) mice incubated with vehicle (control) and incubated with 1 μmol/L ceramide to the endothelium-independent agonist nitroprusside. Values mean±SE; P>0.05.
In vessels treated with ceramide (1 μmol/L), relaxation in response to higher concentrations of ACh was inhibited by 25%. For example, relaxation to 100 μmol/L ACh was 92±6% and 71±6% in vehicle-treated and ceramide-treated (1 μmol/L) vessels, respectively (Figure 3A). This effect was selective because vasorelaxation to nitroprusside (Figure 3B) and papaverine (data not shown) was not affected by 1 μmol/L ceramide.
A higher concentration of ceramide (10 μmol/L) produced greater impairment (50% inhibition) of ACh-induced relaxation in arteries from nontransgenic mice (Figures 2 and 4A). For example, 100 μmol/L ACh-induced relaxation was 96±4% and 52±5% in the vehicle- and ceramide-treated vessels, respectively (Figure 4A). Relaxation to ACh in the presence of ceramide was markedly reduced (90%) by L-NNA but not affected by catalase, suggesting that the residual response to ACh in the presence of ceramide is mediated by NO (Figure 4A). Relaxation to nitroprusside (Figure 4B) was similar in nontransgenic mice in either the absence or presence of 10 μmol/L ceramide (as well as in the absence or presence of catalase or L-NNA; data not shown), demonstrating selectivity.
Figure 4. A, Relaxation of carotid arteries from nontransgenic and CuZnSOD-Tg mice incubated with vehicle (control; n=8), 10 μmol/L ceramide (n=8), 10 μmol/L ceramide plus catalase (300 U/mL; n=5), or 10 μmol/L ceramide plus L-NNA (n=5) to the endothelium-dependent agonist ACh. L-NNA but not catalase markedly reduced responses of carotid arteries from nontransgenic and CuZnSOD-Tg mice to ACh (in the presence of ceramide). Values mean±SE; *P<0.05 vs control. B, Relaxation of carotid arteries from nontransgenic (n=8) and CuZnSOD-Tg (n=8) mice incubated with vehicle (control) or 10 μmol/L ceramide to the endothelium-dependent agonist nitroprusside. Values mean±SE; P>0.05.
Incubation of vessels with either vehicle or dihydroceramide (an inactive form of ceramide; 10 μmol/L) had no effect on relaxation to ACh (Figure 5), nitroprusside (Figure 5), or papaverine (data not shown) in nontransgenic mice, providing strong evidence that the endothelial dysfunction observed in this model was attributable to direct effects of ceramide.
Figure 5. Relaxation of carotid arteries from nontransgenic (n=8) mice incubated with either vehicle (control) or 10 μmol/L dihydroceramide (DHC), the biologically inactive form of C2-ceramide to ACh and nitroprusside. Values mean±SE; P>0.05.
Overexpression of CuZnSOD Protects Against Ceramide-Induced Endothelial Dysfunction
In CuZnSOD-Tg mice, ACh produced concentration-dependent relaxation, which was similar to that produced in nontransgenic mice (Figures 2 and 3 A). This response was markedly attenuated by L-NNA (Figure 3A) but not by catalase (data not shown). These findings suggest that relaxation of the carotid artery to ACh is mediated very predominantly by NO in CuZnSOD-Tg mice.
In contrast to the effects of ceramide (1 and 10 μmol/L) on endothelial function in nontransgenic mice, ceramide-induced endothelial dysfunction was completely prevented by overexpression of CuZnSOD, as evidenced by normal responses to ACh in CuZnSOD-Tg mice (Figures 3A and 4A). This response to ACh in the presence of 10 μmol ceramide was markedly attenuated by L-NNA but not catalase (Figure 4A), indicating the response is mediated by NO. Relaxation in response to nitroprusside (Figures 3B and 4 B) was similar in CuZnSOD-Tg mice in either the absence or presence of 10 μmol/L ceramide (as well as in the absence or presence of catalase or L-NNA; data not shown).
Ceramide-Induced Increases in Superoxide Are Prevented by Overexpression of CuZnSOD
Basal superoxide levels, as detected by hydroethidine-based confocal microscopy, were similar in carotid arteries from nontransgenic and CuZnSOD-Tg mice (Figure 6). Preincubation of carotid arteries from nontransgenic mice with ceramide (10 μmol/L) increased the hydroethidine signal (11±3 and 18±5x103 relative units in vehicle- and ceramide-treated arteries, respectively; P<0.05; Figure 6). The hydroethidine signal was reduced by PEG-SOD in vehicle- and ceramide-treated nontransgenic vessels (5±1 and 5±1x103 relative units, respectively; P<0.05). Thus, ceramide-induced increases in hydroethidine staining appear to be a result of superoxide and do not appear to be attributable to any nonspecific shifts in baseline fluorescence. In addition, increases in the hydroethidine signal in response to ceramide were not observed in carotid arteries from CuZnSOD-Tg mice (Figure 6), suggesting that overexpression of CuZnSOD is sufficient to prevent ceramide-induced increases in superoxide.
Figure 6. Representative confocal fluorescent sections of carotid arteries from nontransgenic (left, top, and bottom panels) and CuZnSOD-Tg (right, top, and bottom panels) mice preincubated with either vehicle or ceramide (10 μmol/L for 30 minutes) and then incubated with hydroethidine (2 μmol/L for 30 minutes) for detection of superoxide. In nontransgenic mice, relatively equal levels of fluorescence were detected throughout the vessel wall (left top panel). Similarly, in CuZnSOD-Tg mice, fluorescence was noted throughout the vessel wall (right, top panel). However, fluorescence was higher in carotid artery after ceramide treatment in nontransgenic (left, bottom panel) but not CuZnSOD-Tg (right, bottom panel) mice compared with carotid artery from vehicle-treated, nontransgenic mice. E indicates endothelium; A, adventitia. Bar=100 μm.
Discussion
There are several major new findings of the present study. First, although immunohistochemistry revealed that CuZnSOD protein is markedly increased in CuZnSOD-Tg mice, relaxation of the carotid artery to ACh was unaltered by overexpression of CuZnSOD. This finding suggests that overexpression of CuZnSOD does not alter endothelial function under normal conditions. Second, ceramide impairs endothelial function in nontransgenic mice. Overexpression of CuZnSOD protected against ceramide-induced endothelial dysfunction. Third, ceramide increased superoxide levels in carotid artery of nontransgenic but not CuZnSOD transgenic mice. These findings combined with the functional responses seen in the CuZnSOD-Tg mice provide direct evidence that ceramide-induced superoxide formation produces endothelial dysfunction, possibly resulting from superoxide-mediated inactivation of NO bioavailability.
Ceramide-Induced Endothelial Dysfunction
Ceramide has been shown to have direct effects on vascular tone that appear to vary depending on the species and vascular bed.15,16,18,30,31 In addition, acute incubation with ceramide has been shown to impair endothelium-dependent relaxation.14,17,18 Consistent with these findings, we found that incubation of carotid arteries from nontransgenic mice with ceramide impaired relaxation to ACh in a concentration-dependent manner. The concentrations of ceramide used to inhibit endothelium-dependent relaxation in our study (1 and 10 μmol/L) have been shown previously to approximate levels of ceramide achieved in cells after exposure to TNF-.3,32 Thus, the concentrations of ceramide used in the present study are physiologically relevant. In addition, we found that dihydroceramide, a cell-permeable but biologically inactive form of ceramide, had no effect on vascular responses to either endothelium-dependent or -independent stimuli, suggesting that the effects of ceramide are selective.
Mechanism of Ceramide-Induced Vascular Dysfunction
It has been shown previously that selective overexpression of CuZnSOD increases CuZnSOD protein and activity levels in nonvascular tissue and aorta from CuZnSOD-Tg mice.33–37 Consistent with these findings, we found using immunohistochemistry that CuZnSOD protein is markedly increased in carotid arteries from CuZnSOD-Tg mice compared with nontransgenic mice. In relation to vascular function, ACh produced concentration-dependent relaxation in carotid arteries from CuZnSOD-Tg that was similar to that observed in nontransgenic mice under basal conditions. In carotid arteries from nontransgenic and CuZnSOD-Tg mice, relaxation in response to ACh was attenuated by 90% in the presence of L-NNA. In contrast, catalase had no effect on responses to ACh in either nontransgenic or CuZnSOD-Tg mice. These findings provide evidence that relaxation to ACh is mediated by NO in nontransgenic and CuZnSOD-Tg mice, and that overexpression of CuZnSOD does not alter this response.
On the basis of studies using pharmacological approaches only, it has been suggested that ceramide-induced endothelial dysfunction is attributable to increases in superoxide, with concomitant reductions in endothelial-derived NO.14,17,19 To test this concept with a genetic and perhaps more definitive approach, we examined the effect of ceramide in CuZnSOD-Tg mice. Overexpression of CuZnSOD completely prevented the ceramide-induced endothelial dysfunction that was observed in nontransgenic mice (ie, relaxation to ACh in carotid arteries from CuZnSOD-Tg mice was similar in vessels treated with either ceramide or vehicle). Furthermore, in CuZnSOD-Tg mice, relaxation in response to ACh in the presence of ceramide was markedly attenuated by L-NNA but not catalase, suggesting that overexpression of CuZnSOD prevents ceramide-induced impairment of an NO-mediated response. The use of CuZnSOD-Tg mice also extends pharmacological studies in that it demonstrates that select overexpression of the major intracellular isoform of SOD per se is sufficient to protect endothelial function in response to ceramide.
In cells in culture, ceramide produces increases in superoxide.19,20,22 In the present study, ceramide increased superoxide in carotid arteries from nontransgenic mice as detected using hydroethidine. Thus, our findings are in agreement with the observation that ceramide increased superoxide in coronary artery.14,17 Consistent with our hypothesis and our functional data, ceramide did not increase superoxide in carotid artery from CuZnSOD-Tg mice, suggesting that selective overexpression of CuZnSOD is sufficient to prevent the increase in superoxide in response to ceramide. Our finding that prevention of ceramide-induced endothelial dysfunction in CuZnSOD-Tg mice provides direct evidence that increases in superoxide in response to ceramide are functionally important.
In the present study, superoxide was detected using hydroethidine-based confocal microscopy in sections from frozen tissue, a method shown previously to be a sensitive assay for detection of superoxide in vascular tissue.38,39 For example, we and others have shown previously that scavengers of superoxide (PEG-SOD, Tiron, gene transfer of CuZnSOD or extracellular [EC]-SOD) are efficacious in reducing or preventing the increases in the hydroethidine signal associated with various stimuli.26,39,40 Consistent with these previous findings, PEG-SOD or overexpression of CuZnSOD was also very effective in reducing the hydroethidine signal in response to ceramide in the present study, providing strong evidence that the increase in the hydroethidine signal was attributable to superoxide.
We recognize that there are potential limitations associated with the hydroethidine assay.38–44 First, because all current methods of superoxide detection (eg, lucigenin- and coelentrazine-enhanced chemiluminescence, electron-spin resonance, cyctochrome c reductase, etc) rely on the use of detector compounds, they are indirect measurements of superoxide. Second, hydroethidine can be oxidized by cytochrome c, which may result in overestimation of the superoxide signal.41 Third, it has been suggested that tissue sectioning may result in overestimation of the hydroethidine signal at the cut edge.44 In addition, freezing of tissue before sectioning may result in artifactual changes in the hydroethidine signal. In the present study, we attempted to minimize these potential artifacts because the hydroethidine signal was determined at a focal plane away from the edge of each tissue section and because tissues from each group were processed and imaged in parallel. Such an approach is used commonly by many laboratories and was used in control- and ceramide-treated groups. Fourth, hydroethidine itself can dismute superoxide to hydrogen peroxide, which may result in underestimation of the superoxide signal.41 Thus, the hydroethidine assay is a qualitative but not quantitative method of superoxide detection.38 Finally, we would point out that results obtained with hydroethidine have been confirmed using other methods of superoxide detection in many studies and have generally been very insightful for the study of vascular disease.
Functional Implications
The present study suggests that selective overexpression of CuZnSOD prevents ceramide-induced increases in superoxide and endothelial dysfunction. Increases in ceramide have been described in diseases associated with inflammation. For example, angiotensin II, endothelin, LPS, and TNF- all increase ceramide levels and are known to impair endothelium-dependent relaxation via a mechanism that may involve increased superoxide.2–4,45 In addition, ceramide has also been shown to accumulate within atherosclerotic lesions, which are clearly associated with increases in vascular oxidative stress and impairment of vascular function.9–11,13,40,46 Thus, increases in ceramide may promote endothelial dysfunction. In summary, our results indicate that ceramide impairs endothelium-dependent relaxation via increases in superoxide, and that select overexpression of the CuZn isoform of SOD is very effective in preventing ceramide-induced oxidative stress in vessels.
Acknowledgments
This work was supported by National Institutes of Health grants NS-24621, HL-38901, and HL-62984. S.P.D. was supported by DK-25295 and a national scientist development grant from the American Heart Association (0230327N). We thank Dale Kinzenbaw and Pamela Tompkins for excellent technical assistance. We thank Dr Larry Oberley for providing the CuZnSOD antibody, and Norma Sinclair and the University of Iowa Transgenic Facility (under the direction of Dr Curt D. Sigmund) for genotyping services.
Received February 25, 2004; accepted October 27, 2004.
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