eNOS Protects from Atherosclerosis Despite Relevant Superoxide Production by the Enzyme in apoE−/− Mice

Background All three nitric oxide synthase (NOS) isoforms are expressed in atherosclerotic plaques. NOS enzymes in general catalyse NO production. However, under conditions of substrate and cofactor deficiency, the enzyme directly catalyse superoxide formation. Considering this alternative chemistry, the effects of NOS on key events in spontaneous hyperlipidemia driven atherosclerosis have not been investigated yet. Here, we evaluate how endothelial nitric oxide synthase (eNOS) modulates leukocyte/endothelial- (L/E) and platelet/endothelial- (P/E) interactions in atherosclerosis and the production of nitric oxide (NO) and superoxide by the enzyme. Principal Findings Intravital microscopy (IVM) of carotid arteries revealed significantly increased L/E-interactions in apolipoproteinE/eNOS double knockout mice (apoE−/−/eNOS−/−), while P/E-interactions did not differ, compared to apoE−/−. eNOS deficiency increased macrophage infiltration in carotid arteries and vascular cell adhesion molecule-1 (VCAM-1) expression, both in endothelial and smooth muscle cells. Despite the expression of other NOS isoforms (inducible NOS, iNOS and neuronal NOS, nNOS) in plaques, Electron Spin Resonance (ESR) measurements of NO showed significant contribution of eNOS to total circulating and vascular wall NO production. Pharmacological inhibition and genetic deletion of eNOS reduced vascular superoxide production, indicating uncoupling of the enzyme in apoE−/− vessels. Conclusion Overt plaque formation, increased vascular inflammation and L/E- interactions are associated with significant reduction of superoxide production in apoE−/−/eNOS−/− vessels. Therefore, lack of eNOS does not cause an automatic increase in oxidative stress. Uncoupling of eNOS occurs in apoE−/− atherosclerosis but does not negate the enzyme's strong protective effects.


Introduction
Atherosclerosis is a consequence of chronic inflammation of the vessel wall [1]. One of the key events is the recruitment of leukocytes and the adhesion of platelets to the endothelium overlying the plaque [2,3]. Nitric oxide (NO), an important physiological regulator of vascular homeostasis is implicated in the pathophysiology of atherosclerosis [4]. In atherosclerotic plaques all three NO-synthase (NOS) isoforms are expressed: the neuronal (nNOS, NOSI), the inducible (iNOS, NOSII) and the endothelial (eNOS, NOSIII) [5]. In contrast, in normal arteries eNOS is the predominant NOS isoform [6]. While all NOS isoforms produce NO by catalytic conversion of L-arginine to NO and L-citrulline, the isoforms differ in catalytic activity, gene regulation and the cellular compartment. Complicating the interpretation of the role of NOS, all three isoforms can themselves produce superoxide (termed ''uncoupling''), instead of NO, when substrate or cofactor is limited [7,8,9]. eNOS and nNOS are constitutive enzymes producing low concentrations of NO. We previously showed that both, eNOS and nNOS significantly inhibit atherosclerosis in apoE 2/2 mice [10,11]. In contrast to these protective effects, iNOS produces high concentrations of NO, which serves important roles in host defence against tumor cells and pathogens, but also contributes to tissue damage in chronic inflammation and increases apoE 2/2 atherosclerosis [12,13].
In addition, NO is a potential regulator of platelet activation, platelet aggregation and P/E-interactions and multiple lines of evidence suggest that platelets promote atherosclerosis [20,21,22]. In hypercholesterolemic animal models, platelet adhesion to the endothelium occurs before plaques are visible [19,23]. Platelets adhere to endothelial von Willebrand Factor (vWF) via glycoproteins (GP) and blockade of platelet GPIba profoundly reduces lesion formation in apoE 2/2 mice [19]. Whether eNOS influences P/E-interactions in atherosclerotic vessels on top of the changes reported in apoE 2/2 compared to C57BL/6J wild type mice is currently unknown.
Because of the changes in gene expression and the alternative chemistry of NOS in atherosclerosis (NO vs. superoxide production), the role of each NOS isoform on key events of atherosclerosis can not be predicted. The anti-atherosclerotic and anti-adhesive properties of NO depend on its bioavailability, which is determined by the balance between its synthesis and degradation. In situations of increased oxidative stress, low NO bioavailability can result from NO's reaction with superoxide, giving rise to peroxynitrite formation [24], which in turn contributes to oxidative stress [25]. Oxidation of the NOS cofactor tetrahydrobiopterin (BH 4 ) causes ''uncoupling'' of eNOS in vitro and may be a major source of vascular superoxide production promoting atherosclerosis [26,27,28].
The current study investigates the specific contribution of eNOS to L/E-and P/E-interactions in atherosclerosis. The effects of eNOS deletion on total vascular NO and superoxide productions in atherosclerotic apoE 2/2 mice were studied with an aim to determine which of these two radicals largely determine the key events in atherosclerosis. Our results show that eNOS plays a major role in protection against atherosclerosis despite the fact that the enzyme is ''uncoupled'' and contributes to relevant superoxide as well as nitric oxide production.

Ethics statement
All procedures performed were approved by the ethics committee of University of Würzburg (Approval No. 54-2531.01-40/07).

Mice
Animals were backcrossed for 10 generations to the C57BL/6J genetic background. eNOS 2/2 , provided by Paul Huang [10], and apoE 2/2 (Jackson Laboratories, Bar Harbor, ME, USA) were crossed to generate double heterozygous mice. Offsprings were crossed and progenies were genotyped for eNOS by southern blotting and for apoE by polymerase chain reaction. apoE 2/2 and apoE 2/2 /eNOS 2/2 were weaned at 21 days and fed a westerntype diet for 18 weeks (42% of total calories from fat; 0.15% cholesterol; Harlan Teklad, USA). For clear visualisation of L/Einteractions through the vessel wall, IVM studies were performed after 10 weeks of western-type diet, prior to macroscopic lesion development in this vessel segment. Animals were maintained in pathogen free facility with 12 hours light/dark cycle.

Assessment of L/E and P/E-interactions by IVM studies
L/E-and P/E-interactions were assessed in vivo by use of video fluorescence microscopy [19]. Mice were anesthetized by intraperitoneal injection of a solution of midazolame (5 mg/kg body weight; Ratiopharm), medetomidine (0.5 mg/kg body weight; Pfizer), and fentanyl (0.05 mg/kg body weight; CuraMed Pharma GmbH). Due to easy accessibility, the carotid bifurcation was chosen for IVM studies. The right common carotid artery was carefully exposed, from 3 mm distal to 7 mm proximal to the carotid bifurcation. Tissues were continuously superfused with a thermostated bicarbonate-buffered saline solution, equilibrated with 5% CO 2 in nitrogen, to maintain a physiological pH. Polyethylene catheters were implanted into the right jugular vein for intravenous injections.
For platelet isolation, blood was collected from the retro-orbital venous plexus of a donor mouse using heparin containing syringes. Blood was centrifuged at 400 g for 5 minutes. The supernatant was centrifuged at 250 g for 6 minutes to obtain platelet rich plasma. Subsequently, the platelets were isolated by centrifugation of the platelet rich plasma. The platelet pellet was re-suspended in PBS (pH 7.4) and incubated for 2 minutes with the fluorochrome carboxyfluorescein diacetate succinimidyl ester (CFSE, Molecular Probes). Labelled platelets were centrifuged and pellets were resuspended in PBS and stored at room temperature until use. The suspension was adjusted to a final concentration of 50610 6 platelets per 250 ml and infused intravenously into a recipient mouse. As reported earlier, platelet preparation did not increase Pselectin expression, indicating absence of platelet activation due to preparation procedures [29]. Leukocytes were stained in vivo by intravenous injection of 100 ml 0.02% rhodamine 6G (Molecular Probes). The carotid artery was visualized using a Zeiss Axiotech microscope (water immersion objective: 206, W 206/0.5; Zeiss) with a mercury lamp for epi-illumination. The experiments were done as previously described [19]. L/E-and P/E-interactions were determined at high magnification (500-fold) in a 200 mm6100 mm area. L/E-and P/E-interactions were studied 200 mm proximal to the carotid bifurcation, at a predilection site for plaque development, which did not show macroscopic lesions at the time of IVM.
All images were videotaped and evaluated off-line, using a computer-assisted image analysis program (Cap Image 7.1; Dr. H. Zeintl, Ingenieurbüro Dr. Zeintl, Heidelberg, Germany). The cells that make an initial contact with the vessel wall followed by slow surface translocation (with several further contacts) with a velocity significantly lower than the centreline velocity were defined as 'rolling cells'. Transiently adherent cells were defined as cells crossing an imaginary perpendicular through the vessel at a velocity significantly lower than the centreline velocity and were quantified as cells per mm 2 endothelial surface. Cells that did not move or detach from the endothelial surface within 20 seconds of observation were defined as firmly adherent cells. All experiments were performed by a blinded operator.

Evaluation of VCAM-1 RNA expression
Total RNA was isolated from the carotid arteries using a RNA Miniprep Kit (Stratagene, CA, USA). cDNA was synthesised from total RNA using the First Strand cDNA synthesis kit (Fermentas GmbH, Germany). mRNA expression of VCAM-1 and CD14 was quantified by real-time PCR (iCycler, Bio-Rad Laboratories, USA). PCR amplification was performed for 40 cycles at primer annealing of 60uC. VCAM-1 and CD14 expression was

Histochemistry and immunohistochemistry
The area of the carotid arteries studied by IVM was stained with Oil red O. Additionally, immunohistochemistry for VCAM-1 and macrophages were done. The carotid arteries isolated from the anesthetized animals were embedded in Tissue-TekH (Sakura Finetek, NL) and snap-frozen in liquid nitrogen. 5 mm sections were cut and air dried. Sections were stained with Oil red O or fixed in acetone for immunohistochemistry. Immunostaining for macrophage was performed using a mouse macrophage/monocyte monoclonal primary antibody (MOMA-2, Chemicon Int.) and for VCAM-1 using an anti-mouse VCAM-1 antibody (R&D systems). The macrophage and VCAM-1 stainings were visualised using DAB (Vector laboratories).

Histomorphometry
Photomicrographs of the carotid artery were taken with a Leitzcamera mounted on a light microscope (Carl-Zeiss, Jena, Germany). Pictures were digitalized and transferred to a PC for planimetry using Image Pro Plus (Version 4.1; Media Cybernetics). All images were analysed at 400-fold magnification. Macrophage positive areas and lipid rich areas in the common carotid artery, in an area corresponding to the one used for IVM studies, were measured. Results were expressed as % positively stained plaque area.

Double immunofluorescence
To investigate the cellular compartment of VCAM-1 expression, cryosections of the aortic arch of apoE 2/2 and apoE 2/2 / eNOS 2/2 mice were fixed with acetone. Following blocking procedures, cross reactivity of secondary antibodies with the alternating primary antibodies was ruled out. Expression of VCAM-1 protein in endothelial and smooth muscle cells was examined by double immunofluorescence. Slides were incubated with rat anti-VCAM-1 primary (BD Bioscience, 1:20) followed by biotinylated rabbit anti-rat secondary antibody (Vector, 1:50) and subsequently stained with streptavidin-texas red complex. After washing, slides were incubated with the antibodies directed against endothelial cells (rat anti-mouse CD 31, BD Bioscience, 1:100) or vascular smooth muscle cells (a-actin, Sigma, 1:60). The latter antibodies were directly labelled with fluoresceinisothiocyanate (FITC, green). Finally, all sections were mounted with 49,6diamidino-2-phenylindole (DAPI) mounting media and examined with a confocal microscope (Zeiss).

Hemodynamics of the carotid circulation
The animals were anesthetized and the common carotid artery was visualized by duplex colour ultrasonography using an ultrasound system with a 15 MHz transducer (NICE, Toshiba Medical Systems, The Netherlands). The resistance index of the common carotid artery was calculated as the difference between the maximum systolic (V sys ) and the end-diastolic flow velocity (V dia ) divided by V sys .

Measurement of vascular NO production by electron paramagnetic spintrapping
Detection of NO in the aorta was performed using colloid iron (II) diethyldithiocarbamate (Fe(DETC) 2 ) according to a method which we adapted for detection of baseline NO production in aortic rings of apoE 2/2 mice [30]. Briefly, animals were anesthetized with pentobarbital (80 mg/kg i.p.) and the aorta was perfused with 2 ml of Krebs-Hepes Buffer (KHB) through the left ventricle. The aorta was removed rapidly and placed in a petridish containing KHB. Perivascular fatty tissue was removed while the aorta was maintained at 4uC in KHB using a cold plate (Noxygen Science Transfer & Diagnostics, Denzlingen, Germany). The aorta was cut into 2 mm rings and placed in one well of a 24 well plate containing KHB. Subsequently, the aortic rings were incubated in the colloidal Fe-(DETC) 2 spin trap solution for 1 hour. The spin trap was freshly prepared by mixing equal amounts of deoxygenated 1.6 mM FeSO 4 and 3.2 mM DETC solutions. For pharmacological NOS inhibition samples were incubated with the NOS inhibitor, NG-nitro-L-arginine methyl ester (L-NAME) for 30 minutes at 37uC prior to the addition of spin trap. ESR measurements were done using a bench top e-scan ESR spectroscope (Bruker BioSpin GmbH, Germany). The instrumental settings were as follows: Centre field: 3308 G.

Measurement of NO bioavailability in the blood stream
Nitrosyl hemoglobin, a reaction product of deoxygenated hemoglobin with NO is an in vivo marker for NO bioavailability in the circulation [31] and can be detected as a characteristic triplet peak by ESR spectroscopy. Blood samples were prepared according to a published method [32]. Briefly, the venous blood was drawn from the right ventricle. Following centrifugation at 2000 g (Eppendorf AG, Germany) the red cell cast was frozen in syringes and transferred into a finger dewar containing liquid nitrogen. The spectra were acquired using an X-band EMX spectroscope (Bruker BioSpin GmbH, Germany) with the following instrument settings: Centre field: 3340 G.

Measurement of intracellular superoxide production by HPLC-detection of oxyethidium
Superoxide production was measured by incubating vessel rings in KHB containing 50 mM dihydroethidium for 1 hour at 37uC [33]. Aortic rings were then homogenized in ice cold methanol, filtered and separated by reverse phase High Performance Liquid Chromatography (HPLC) using a C-18 column (Nucleosil 250, 4.5 mm; Sigma-Aldrich) along with an AKTA HPLC system (Amersham Biosciences, GE Healthcare). Oxyethidium, the reaction product of superoxide and dihydroethidium was quantitated with a fluorescence detector (Jasco, UK) at an excitation wavelength of 510 nm and emission wavelength of 595 nm. The amount of oxyethidium formed was normalised to the protein content of the samples.

Measurement of vascular superoxide production by ESR
Production of superoxide was measured in aortic rings according to a previously published protocol [34] using the above mentioned e-scan spectroscope. Superoxide production was assessed by pre incubating aortic rings with PEG-SOD (100 U/ ml) parallel to the spin trap 1-hydroxy-3-methoxycarbonyl-2,2,5,5tetramethylpyrrolidine (CMH) in KHB for 1 hour at 37uC. The conversion of CMH to CM. radical in the PEG-SOD untreated samples was used to determine the total production of reactive oxygen species (ROS). The instrumental settings were as follows:

Western blot analysis
Aortic protein was isolated using RIPA buffer and western blots were performed using a monoclonal rabbit anti-eNOS, anti-nNOS (BD Biosciences) and a polyclonal anti-iNOS (Santa Cruz Biotechnology, Inc.) antibodies. To confirm equal loading of protein a goat anti-a-actin-antibody (Santa Cruz Biotechnology, Inc.) was used. Blots were analysed densitometrically using Scan Pack software (Biometra, Gottingen, Germany) and the density of protein bands for iNOS and nNOS were normalised to the corresponding a-actin bands of the same blots. Low temperature SDS-PAGE followed by western blot was done as mentioned previously for eNOS dimer/monomer protein detection [35].

Statistical analyses
All data were expressed as mean6SE. Two way ANOVA was used for repeated measures, followed by Scheffe's F-test (Stat View 4.51, Abacus Concepts, Inc., Berkley, CA, USA). Student's t-test was used for unpaired data. A probability value of p#0.05 was considered significant.

NO from eNOS influences macrophage infiltration into the vessel wall
To evaluate whether increased VCAM-1 expression in the carotid artery results in increased mononuclear leukocyte infiltration into the vessel wall we assessed CD14 expression by real time PCR. apoE 2/2 /eNOS 2/2 showed a striking increase in CD14 expression, compared to apoE 2/2 controls (4.263.3, n = 12 vs. 1.060.43, n = 17, p,0.00002, Figure 3a). This finding was supported by an increase of the macrophage positive staining areas in vessels of apoE 2/2 /eNOS 2/2 (5.160.98% positively stained plaque area, n = 10), compared to apoE 2/2 (2.260.48% positively stained plaque area, n = 9, p = 0.02, Figure 3b). Planimetry of the Oil red O positive, lipid rich areas in the vessel wall proximal to the carotid bifurcation showed no significant difference between apoE 2/2 (8.164.0% positively stained plaque area, n = 9) and apoE 2/2 /eNOS 2/2 animals (5.062.5% positively stained plaque area, n = 7, p = 0.56). The latter finding documents similar amounts of fatty streaks in the area of carotid artery chosen for IVM measurements.

Discussion
Chronic eNOS deficiency significantly increases leukocyte rolling, transient and firm adhesion in apoE 2/2 /eNOS 2/2 , compared to apoE 2/2 controls. Increased L/E-interactions were not due to differences in local plaque burden, as both genotypes showed similar amounts of fatty streaks in carotid artery segments used for IVM at an early time point. Duplex ultrasonography studies documented similar hemodynamics in the carotid circulation of both genotypes. Therefore, the increase in L/E-interactions in apoE 2/2 /eNOS 2/2 animals is not secondary to alterations of flow dynamics.
To the best of our knowledge this is the first study investigating the role of eNOS in L/E-interactions in spontaneous hyperlipidemia driven atherosclerosis. We show that lack of endogenous NO production by eNOS accelerates L/E-interactions in apoE atherosclerosis. Our data is in line with previous studies showing that endogenous NO production inhibits L/E-interactions in the microvasculature [15,16]. We previously reported that atherosclerosis is accelerated in apoE 2/2 /eNOS 2/2 and that this increase in lesion formation is not secondary to increased blood pressure in this genotype [10,36]. Therefore, increased atherosclerosis development in apoE 2/2 /eNOS 2/2 animals is likely due to local changes like increased endothelial activation and L/E-interactions reported here.
VCAM-1 expression is a hallmark of endothelial cell activation [37]. In atherosclerosis, the interaction of macrophage very late antigen-4 (VLA-4) and endothelial VCAM-1 mediates monocyte firm adhesion. Upregulation of VCAM-1 expression following treatment of human saphenous vein endothelial cells with the NOS inhibitor L-NAME, suggests tonic suppression of adhesion molecule expression by NO [18]. In contrast, our study of microvascular endothelial cells from eNOS 2/2 mice showed that eNOS deletion alone does not induce adhesion molecule expression or increase L/E-interactions, suggesting that eNOS serves a permissive role in endothelial activation [38]. The data presented here indicates that eNOS deletion increases VCAM-1 expression not only in the endothelium, causing endothelial activation and recruitment of leukocytes, but also in medial smooth muscle cells. Figure 6. eNOS is uncoupled and contributes to vascular production of superoxide in apoE 2/2 mice. a) HPLC measurements showed lower levels of superoxide production in apoE 2/2 /eNOS 2/2 (n = 13) vs. apoE 2/2 (n = 23). Superoxide levels were higher in apoE 2/2 (n = 23) compared to C57BL/6J (n = 14). Interestingly, superoxide levels were significantly lower in apoE 2/2 /eNOS 2/2 (n = 13) compared to eNOS 2/2 (n = 12). b) L-NAME inhibited superoxide production in apoE 2/2 (n = 15) but not in C57BL/6J (n = 17) and apoE 2/2 /eNOS 2/2 (n = 12) aortas. c) Specific inhibition of eNOS using L-NIO resulted in significant reduction of superoxide production in apoE 2/2 (n = 19). d) Total ROS production using ESR showed a significant increase in ROS levels in apoE 2/2 (n = 23) compared to C57BL/6J (n = 12) and apoE 2/2 /eNOS 2/2 (n = 15). e) Consistently, SOD inhibitable superoxide production measured by ESR also showed significant increase in superoxide levels in apoE 2/2 (n = 23) compared to C57BL/6J (n = 12) and apoE 2/2 / eNOS 2/2 (n = 15). 1 p,0.05, *p,0.01, **p,0.001, ***p,0.0001, NS denotes non-significance. f) Uncoupling of eNOS in apoE 2/2 compared to C57BL/ 6J aorta shown by western blot of eNOS protein dimer/monomer. doi:10.1371/journal.pone.0030193.g006 IVM studies in apoE 2/2 mice suggest that P/E-interactions are an important trigger for plaque formation [19,39,40]. Since NO was shown to inhibit platelet activation and aggregation in vitro, we studied the importance of eNOS derived NO in the modulation of P/E-interactions in atherosclerosis. Our study shows no difference in platelet rolling, transient, or firm adhesion to the endothelium in apoE 2/2 /eNOS 2/2 mice, compared to apoE 2/2 controls. This suggests that the dramatically increased atherosclerosis in apoE 2/2 /eNOS 2/2 , compared to apoE 2/2 [10,41], is not caused by increased platelet adhesion and subsequent events. Therefore, although platelets accelerate plaque formation in apoE 2/2 mice, they may not contribute to the increased plaque formation in apoE 2/2 /eNOS 2/2 . Spin trapping of NO by Fe-(DETC) 2 using ESR, considered the utmost specific and sensitive method for detection of NO in biological systems, showed that eNOS contributes significantly to total vascular NO production in atherosclerosis. We recently reported that the significant increase in vascular NO production observed in apoE 2/2 compared to C57BL/6J mice is due to iNOS [42]. Interestingly, apoE 2/2 /eNOS 2/2 mice had significantly higher NO levels compared to eNOS 2/2 mice. This increase in NO production is likely mediated by iNOS since aortic iNOS protein expression was increased in apoE 2/2 /eNOS 2/2 compared to apoE 2/2 (Figure 7). In contrast, we did not observe changes in expression levels of nNOS in apoE 2/2 and apoE 2/2 / eNOS 2/2 (Figure 7). Consistent with the reduction of endothelial NO production, the in vivo concentration of circulating nitrosyl hemoglobin, reflecting bioavailable NO in the circulation, was markedly reduced in apoE 2/2 /eNOS 2/2 mice. Considering the expression of all three NOS isoforms in atherosclerotic plaques, our results are not easily predictable because of several reasons. First, increased L/E-interactions, macrophage infiltration, increased vascular iNOS expression and plaque area secondary to eNOS deletion could have also resulted in increased cytotoxic NO formation by iNOS. Secondly, the deletion of eNOS could have changed the bioavailability of substrate and co-factor, thereby influencing the chemistry of iNOS and nNOS. Our data suggest that eNOS is an important source of vascular and circulating NO in apoE 2/2 mice, despite all these possibilities. The residual NO detectable by the characteristic triplet ESR peak in apoE 2/2 / eNOS 2/2 indicates residual NO production by iNOS and possibly nNOS in the vessel wall.
Our assessment of vascular superoxide formation using two independent techniques revealed a significant reduction of superoxide production following genetic eNOS deletion (chronic) in apoE 2/2 . Inhibition of NOS isoforms using L-NAME resulted in significant reduction of superoxide production in apoE 2/2 but not in C57BL/6J and apoE 2/2 /eNOS 2/2 , suggesting that NOS is uncoupled only in atherogenic apoE 2/2 mice. Additionally, acute pharmacological inhibition of eNOS using L-NIO reduced superoxide formation in apoE 2/2 . The reduction of vascular superoxide in apoE 2/2 /eNOS 2/2 reflects the contribution of endothelial, eNOS derived superoxide production. Since both, significant NO and superoxide production by eNOS is detectable in apoE 2/2 mice we conclude that eNOS is partially uncoupled during atherosclerosis development in this model. In support of this our eNOS western blots showed increased eNOS monomer, an indirect measure of eNOS uncoupling in apoE 2/2 mice. As shown in eNOS over-expressing apoE 2/2 mice, increased superoxide generation by uncoupled eNOS may accelerate atherosclerosis [43]. However, despite decreased vascular superoxide formation in our apoE 2/2 /eNOS 2/2 model, these animals develop increased atherosclerosis, suggesting that the atheroprotective effect of decreased superoxide production does not outweigh the proatherogenic effects of NO deficiency. In other words, we made the intriguing observation that the increased eNOS derived superoxide formation does not override the damage caused by a concomitant decrease of NO production following eNOS deletion. Ample evidence implicates increased superoxide production in atherosclerosis [44,45]. Our data is consistent with Figure 7. Vascular expression of NOS isoforms. Significantly increased expression of iNOS protein in the aorta of apoE 2/2 /eNOS 2/2 (n = 10) compared to apoE 2/2 mice (n = 10). The protein levels of nNOS did not differ between apoE 2/2 (n = 10) apoE 2/2 /eNOS 2/2 (n = 11). * p,0.05, NS denotes non-significance. doi:10.1371/journal.pone.0030193.g007 this hypothesis since we observed increased superoxide production in apoE 2/2 compared to C57BL/6J animals. Therefore, eNOS uncoupling is a key source of superoxide production in the apoE 2/2 model.
The major findings of our study indicate that lack of eNOS reduces vessel wall oxidative stress in atherosclerosis despite accelerated plaque formation, increased vascular inflammation and L/E-interactions in apoE 2/2 /eNOS 2/2 vessels. P/E-interactions do not differ between apoE 2/2 and apoE 2/2 /eNOS 2/2 , indicating that lack of NO production does not increase platelet interactions on top of the apoE 2/2 background. Uncoupling of eNOS occurs in apoE 2/2 atherosclerosis but does not negate the enzyme's strong protective effects. Hence, eNOS derived NO can still play a protective role in a system of high oxidative stress, potentially associated with increased peroxynitrite formation.