From the Division of Endocrinology and Metabolism and Cardiovascular Research Center, University of Virginia, Charlottesville, Virginia 22908
Received for publication, February 3, 2003 , and in revised form, April 11, 2003.
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ABSTRACT |
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INTRODUCTION |
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Endothelial activation and monocyte/endothelial adhesion are key early
events in vascular inflammation
(35).
Monocytes are the primary inflammatory cells that are localized to human
atherosclerotic plaques (6,
7). During inflammation,
monocytes are recruited to sites of endothelial cell injury and roll along the
vascular endothelium, where they become activated by soluble or surface-bound
chemokines. The monocytes adhere firmly to the endothelium and transmigrate
through the ECs monolayer
(810).
The selectins E, L, and P are involved in mediating monocyte rolling along the
endothelium, and 1 and
2 integrins are
involved in mediating firm adhesion. Endothelial vascular cell adhesion
molecule 1 (VCAM-1),1
an alternatively spliced form of fibronectin, connecting segment-1 (CS-1 FN),
and intercellular adhesion molecule (ICAM-1) also mediate firm adhesion of
monocytes
(1114).
Murine 12/15 lipoxygenase (12/15LO) incorporates molecular oxygen in a stereospecific manner into arachidonic and linoleic acids to generate 12- and 15S-hydroxyeicosatetraenoic acids (12S-HETE/15S-HETE) and 9S- and 13S-hydroxyoctadecaenoic acids (9S-HODE/13S-HODE) (1517). There is now considerable evidence to support a role for 12/15LO in promoting diabetes and atherosclerosis (1821). Bleich and colleagues (18) found that mice deficient in 12/15LO were resistant to development of streptozotocin-induced diabetes. We have shown that aortic ECs cultured chronically in elevated glucose (to simulate the diabetic endothelium in vitro) produced significant elevations in 12S-HETE (11). Importantly, using a catalytic ribozyme to cleave and inactivate 12/15LO mRNA, we showed that disruption of the 12/15LO mRNA in glucose-cultured ECs in vitro significantly reduced 12S-HETE production and blocked monocyte adhesion to ECs (22).
Striking evidence for the role of 12/15LO in atherogenesis came from the studies of Funk and colleagues (19, 21, 23), who showed that disruption of the 12/15LO gene in mice significantly reduced atherosclerosis development in vivo. Several groups have shown that the human 15LO enzyme oxidizes low density lipoproteins (LDL) in vitro (20, 24, 25). Cathcart and colleagues (26) found that 12/15LO activity in monocytes produced superoxide that mediated oxidation of LDL. 12/15LO protein has been localized to aortic atherosclerotic lesions in rabbits and in humans (27, 28) and is responsible for production of oxidized lipid adducts localized within atherosclerotic plaques (29, 30).
In the current study, we examined early inflammatory events that mediate vascular complications in vivo using diabetic db/db mice. We found that db/db mice produce significant amounts of 12/15LO eicosanoid products in vivo. We found that aortic endothelial cells from these mice are "pre-activated" to bind monocytes. Blocking of the 12/15LO pathway in endothelial cells of the db/db mice prevented monocyte/endothelial interactions. The results of this study indicate that products of the 12/15LO pathway mediate monocyte/endothelial interactions in diabetes.
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EXPERIMENTAL PROCEDURES |
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MiceYoung 10-week-old male db/db (BKS.Cg-m+/+Leprdb) mice were obtained from Jackson Laboratories (stock number 000642). The db/db mice were on a pure C57BLKS/J background strain; thus 10-week-old male C57BLKS/J mice from Jackson Laboratories (stock number 000662) were used as controls. Mice were fed rodent chow and housed in micro-isolator cages in a pathogen-free facility. All experiments followed Association for Assessment and Accreditation of Laboratory Animal Care International (AAALAC) guidelines and approval for use of rodents was obtained from University of Virginia.
Eicosanoid Measurement in UrineFor extraction of lipids from urine, 0.5 ml of urine from each mouse was added to 40 nmol of internal standard nonphysiological 8-HETE in siliconized screw-capped glass tubes. The pH was adjusted to pH 3 using 1 N HCl; 2.25 ml of ethyl acetate was added and tubes were centrifuged at 3000 rpm. The ethyl acetate phase was transferred to a 5-ml glass vial and dried under nitrogen. The dried lipid phase was dissolved in 0.2 ml of acetonitrile and diluted with 0.8 ml of water. Free fatty acids were separated from phospholipids and neutral lipids using two C18 Bond-Elute columns, (1 ml, 50 mg; Varian). Samples were loaded onto the first column, and polar phospholipids were eluted with 30% acetonitrile; free fatty acids and neutral lipids were eluted with 0.4 ml of 90% acetonitrile. These fractions were diluted with 0.9 ml of water and reapplied to a fresh column, and the free fatty acids alone were eluted using 0.6 ml of ethyl acetate.
The fluorescence derivatives of the free fatty acids were formed using 8 mg of 2-(2,3-naphthalimino)ethyltrifluoromethanesulfonate dissolved in 0.5 ml of acetonitrile. The reaction mixes were dried with nitrogen, resuspended in 0.4 ml of acetonitrile, diluted with 0.6 ml of water, and applied to a third Bond-Elut column. The fatty acid derivatives were eluted with 0.6 ml of ethyl acetate, evaporated under nitrogen, and resuspended in 100 µl of methanol for HPLC analysis. HPLC separation and analysis was performed using a C18 Waters symmetry column and eluting isocratically for 100 min at solvent B = 61%, where B = 50% methanol/tetrahydrofuran plus 0.1% acetic acid and A = 0.1% acetic acid following related protocols of Roman et al. (31). Peaks were detected fluorometrically at an excitation wavelength of 259 nm and emission wavelength of 394 nm. The area ratio of sample HETE area/internal standard (8-HETE) area was plotted against nanograms of HETE injected, and unknown sample HETE values were calculated from their area ratios. All HETEs (5-, 12-, and 15-HETE) and HODEs (9- and 13-HODE) were baseline separated using this elution protocol. HETE and HODE measurements in urine were normalized to milligrams of creatinine.
Isolation of Mouse Aortic Endothelial CellsAortic endothelial cells from C57BLKS/J and db/db mice were harvested from mouse aorta under sterile conditions. The aorta was excised; all peri-adventitial fat was removed, and the aortic pieces were placed onto Matrigel in DMEM plus 15% heat-inactivated FBS following the methods outlined by Shi and colleagues (32, 33). After 3 days, the aortic explants were removed, and the endothelial cells were allowed to grow in DMEM plus 15% heat-inactivated FBS supplemented with 180 µg/ml heparin and 20 µg/ml endothelial cell growth supplement. At confluency, the cells were passaged using Dispase and then cultured for 2 days in DMEM plus 15% heat-inactivated FBS containing D-valine to eliminate possible fibroblast contamination. After 2 days, the ECs were returned to growth medium without D-valine and allowed to grow to confluency. Mouse endothelial cell cultures were tested for purity at passage 2 using either Von Willebrand factor staining or di-acetylated LDL uptake and were used in experiments from passages 3 to 6.
Mouse Monocyte Adhesion AssayOur laboratory has recently
developed a monocyte adhesion assay that utilizes primary MAECs and WEHI78/24
cells. WEHI78/24 cells are a mouse monocytoid cell line that has been fully
characterized by McEvoy and colleagues
(34,
35). WEHI were cultured in
DMEM plus 10% heat-inactivated FBS. WEHI cells are labeled with calcein-AM
using standard methods described by the manufacturer (Molecular Probes). For
the adhesion assay, MAECs were cultured to confluency in a 48-well plate and
incubated with 35,000 calcein-labeled WEHI cells/well for 30 min at 37 °C.
Nonadherent cells were rinsed, and adherent cells were fixed with 1%
glutaraldehyde. The number of adherent monocytes within a 10 x 10
eyepiece grid at x40 magnification was counted using epifluorescence
microscopy. As a positive control for monocyte adhesion, MAECs were incubated
with 10 units/ml recombinant murine TNF (R&D Systems #410-MT) for 4
h. For studies using blocking antibodies or peptides, WEHI cells were
incubated for 15 min at 37 °C with CS-1 peptide (10 µg/ml, EILDVPST),
antibody to
4 integrin (clone PS/2, 20 µg/ml), antibody
to
2 integrin (clone GAME-46, 20 µg/ml), or isotype
control antibody prior to adding to MAECs for adhesion assay. In some studies,
VCAM-1 antibody (clone MK2.7, 20 µg/ml) to block endothelial VCAM-1, ICAM-1
antibody (clone YN1.1, 20 µg/ml) to block endothelial ICAM-1, or isotype
control antibody was added to ECs for 4 h at 37 °C. To block 12/15LO
activity in ECs, MAECs were infected at a multiplicity of infection of 50 for
48 h with the recombinant adenoviral vectors, AdRZ (expresses 12/15LO
ribozyme) or AdLacZ control
(22), or incubated with the
pharmacological inhibitor CDC (10 µM) for 4 h at 37 °C prior
to performing a monocyte adhesion assay.
Flow CytometryC57BLKS/J and db/db MAECs at passage 4 were collected in PBS by gentle scraping using a cell scraper. 150,000 cells per sample were analyzed for each antibody. Cells were incubated for 30 min at 4 °C with 1:100 dilution of antibody (FITC anti-mouse VCAM-1 and FITC anti-mouse ICAM-1 or isotype control antibody). After incubation, cells were rinsed 3x in PBS and fixed in paraformaldehyde. Samples were analyzed using a FACSCalibur cell sorter. Analyses were performed using a single FITC-labeled antibody per tube. Unstained and isotype control antibodies were included in analyses as controls.
Human Endothelial Cell CultureHuman aortic endothelial cells (HAECs) were obtained from aortic rings of explanted donor hearts (11). HAECs were cultured for 7 days in Medium 199 containing 20% heat-inactivated FBS, 20 µg/ml endothelial cell growth supplement, and 90 µg/ml heparin in the presence of 5.5 mM glucose (NG) or 25 mM glucose (HG) for 7 days. The 7-day, 25 mM HG incubation condition was chosen because monocyte adhesion to endothelial cells was maximal at this concentration of glucose and time of incubation (11). For studies using chemical uncouplers of mitochondrial function, HAECs were cultured as described above and treated for 7 days with 0.5 µM carbonyl cyanide m-chlorophenylhydrazone or 10 µM thenoyltrifluoroacetone.
12S-HETE Detection by ImmunoassayHAECs grown in 100-mm dishes in normal (5 mM) or high glucose (25 mM) media were incubated for 30 min in medium 199 with 0.2% fatty acid-free bovine serum albumin. The dishes were iced, and their media were collected, acidified, and extracted into ethanol. Cells were washed once with ice-cold PBS containing 100 µM EDTA and then scraped and pelleted. The cell pellets were deacylated with methanolic sodium hydroxide for 1 h and extracted on C18 Bond-Elut columns. 12S-HETE levels were quantitated by a specific immunoassay (Assay Designs, Inc.). The antibody in this kit is specific for 12S-HETE, with less than 0.1% cross-reactivity with other eicosanoids.
Statistical AnalysesData for all experiments were analyzed by ANOVA and Fisher's protected least significant difference test using the StatView 6.0 software program. Data are represented as the mean ± S.E. of eight mice per group unless otherwise noted in the figure legends. Monocyte adhesion data are represented as the mean ± S.E. of six experiments unless otherwise noted in the figure legends.
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RESULTS |
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Adhesion Molecule Expression on db/db Mouse Endothelial
CellsWe have previously shown in human ECs that glucose increases
deposition of CS-1 fibronectin on the apical surface of human ECs
(11). Currently there are no
available reagents to measure CS-1 FN expression in the mouse. To indirectly
examine the role of CS-1 FN in mediating monocyte adhesion to mouse aortic
ECs, we used a peptide that specifically blocks CS-1-mediated monocyte
adhesion (13). This peptide
blocks the LDV binding site for CS-1 FN on VLA-4
(13). As shown in
Fig. 2, monocyte adhesion to
db/db ECs was decreased 70% in presence of CS-1 FN
blocking peptide. TNF
(10 units/ml) was added to C57BLKS/J ECs as a
positive control to show maximal binding in the adhesion assay. Blocking
antibody to VCAM-1 (37) also
significantly reduced adhesion to db/db ECs by 50%. We also
examined the contributions of ICAM-1 and
2 integrins on
mediating monocyte/endothelial interactions in db/db mice.
As shown in Fig. 2, we found
that blocking either
2 integrin or ICAM-1 reduced
db/db-mediated monocyte adhesion by
50%. However,
blocking antibody to
4 integrin
(37) on monocytes completely
prevented adhesion, suggesting that adhesion was primarily mediated through
VLA-4 on monocytes. VLA-4 contains binding sites for both VCAM-1 and CS-1 FN
(11)
(38). Thus, monocyte adhesion
in db/db mice is primarily mediated through VLA-4 on
monocytes and VCAM-1 and CS-1 fibronectin on the ECs surface, although ICAM-1
and
2 integrins also are involved in
db/db-mediated adhesion.
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Diabetic db/db Mice Have Increased Production of 12/15LO Eicosanoid ProductsWe have previously shown that HAECs cultured chronically in elevated glucose show increased production of 12S-HETE and 15S-HETE, the primary products of the 12/15LO enzyme (11). We have also shown that exogenous addition of these eicosanoids to HAECs stimulated monocyte adhesion (11). We examined whether diabetic db/db mice would have increased production of 12/15LO eicosanoid products in vivo. Urine was collected for 24 h from control C57BLKS/J and diabetic db/db mice. Using novel fluorescent HPLC techniques for quantitation of eicosanoids (see "Experimental Procedures"), we found a dramatic 5-fold increase in the amounts of 12S-HETE and 15S-HETE produced in the db/db mice (Fig. 3). 9S-HODE and 13S-HODE production was increased 2-fold in the db/db mice in vivo (Fig. 3). These eicosanoid products are generated by the 12/15LO enzyme in mice; the platelet 12LO enzyme does not produce 9S-HODE and 13S-HODE (15). There was no change in levels of 5S-HETE (a product of the 5LO pathway; Fig. 3) or in cyclooxygenase enzyme products (data not shown) in the db/db mice.
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Because we saw a large increase in the production of 12/15LO eicosanoids in db/db mice in vivo and based upon our previous work, which indicated that 12S-HETE can stimulate monocyte/endothelial adhesion, we examined whether there was an increase in 12/15LO protein in db/db mice. As shown in Fig. 4, there was approximately a 2-fold increase in the level of 12/15LO protein in aorta of db/db mice. We also found increased expression of 12/15LO in kidney of db/db mice (data not shown). Thus, ECs from db/db mice have increased expression of 12/15LO protein that leads to increased 12/15LO eicosanoid production in vivo.
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Monocyte Adhesion to ECs of Diabetic db/db Mice Is Caused by 12/15LO ExpressionTo determine that 12/15LO products were directly responsible for the increased monocyte adhesion observed with db/db ECs, we inhibited expression of 12/15LO using an adenovirus expressing a ribozyme to 12/15LO (designated AdRZ) as well as using the 12/15LO inhibitor CDC. CDC blocks platelet 12LO and 12/15LO expression in ECs (39). The DNA:RNA hammerhead ribozyme was generated to recognize the first 7 bp of the porcine leukocyte 12LO and murine 12/15LO mRNA sequences (22). We inserted the ribozyme into an adenoviral vector for transfection into primary ECs. We have previously used this adenoviral ribozyme construct to block 12LO expression in porcine ECs in vitro (22). Using the 12/15LO ribozyme, we found that 12/15LO was primarily responsible for mediating monocyte/endothelial adhesion in response to glucose (22). As shown in Fig. 5, addition of the 12/15LO inhibitor CDC or the AdRZ to db/db ECs completely blocked monocyte adhesion (p < 0.009). These data indicate that monocyte adhesion in diabetic db/db mice is mediated through the 12/15LO enzyme pathway.
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We next examined expression of VCAM-1 and ICAM-1 on db/db mouse ECs using flow cytometry. Surface expression of VCAM-1 and ICAM-1 was not increased on db/db ECs compared with control ECs (50.5% expression on CTR ECs versus 49.2% expression on db/db ECs for ICAM-1, and 78.1% expression on CTR ECs versus 74.4% expression on db/db ECs for VCAM-1). We examined whether the inhibitor CDC would reduce expression of VCAM-1 or ICAM-1 and found no reduction of adhesion molecule expression on db/db ECs by CDC (Fig. 6).
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Production of 12/15LO Products Is Mediated by ROS in ECsTo examine how the 12/15LO enzyme may be regulated by glucose, we treated HAECs with chemical uncouplers of the mitochondrial electron transport chain. Thenoyltrifluoroacetone (TTFA) inhibits Complex II of the electron transport chain, and carbonyl cyanide m-chlorophenylhydrazone (CCCP) disrupts the proton gradient through uncoupling of mitochondrial oxidative phosphorylation (40). As shown in Fig. 7, glucose increases ROS production in HAECs. Both TTFA and CCCP inhibited glucose-mediated production of 12S-HETE in HAECs. These data suggest that production of 12S-HETE in diabetic ECs is regulated by ROS production.
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DISCUSSION |
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A quite exciting finding was that diabetic db/db mice have a severalfold increase in production of 12/15LO products in vivo. The reasons for this increased production are unknown yet could relate to presumably to either 1) increased activity of the murine 12/15LO in vivo in the diabetic db/db mice or 2) increased hydrolysis of cellular phospholipids by cytosolic phospholipase A2 (PLA2) to release free arachidonic and linoleic acids as well as HETEs and HODEs into the cytoplasm. Spector and colleagues have reported that 12S-HETE is rapidly incorporated into cellular membrane phospholipids, especially phosphatidylcholine (48, 49). This 12S-HETE can be released by action of PLA2. Several groups have reported increased action of PLA2 in diabetes (5052). Still others have reported regulation of PLA2 by other lipoxygenases (53). Based upon our data in Fig. 4, we believe that much of the increase in 12/15LO eicosanoids produced in these mice come from an up-regulation of the 12/15LO enzyme level in db/db mice. We have previously shown that human aortic endothelial cells cultured chronically in elevated glucose have significant production of 12S-HETE and 15S-HETE (54). Subsequently, we have found an increase in 12/15LO protein in the glucose-cultured HAECs (data not shown). However, in the db/db mice, we have not yet ruled out that some of the observed increase in 12/15LO products is also due to modulation of cytosolic PLA2 activity. We will examine this possibility in db/db mice.
Interestingly, we found that monocyte adhesion to endothelial cells was significantly increased in diabetic db/db mice. Under normal conditions, endothelial cells do not bind monocytes unless stimulated to do so. We found a significant increase in monocyte adhesion to unstimulated db/db ECs, suggesting that the db/db mouse ECs are pre-activated to bind monocytes. In diabetes, monocyte/endothelial adhesion is accelerated due to hyperglycemia and increased oxidative stress (5559). Our original observations in normal human aortic ECs in vitro were that glucose stimulated monocyte/endothelial adhesion and that glucose also increased production of 12/15LO products (11). Another study by our group (22) indicates that blocking of the 12/15LO pathway in HAECs in vitro blocked monocyte adhesion. In our current study, inhibition of the murine 12/15LO in diabetic db/db ECs completely prevented diabetes-mediated monocyte/endothelial interactions (Fig. 5). Taken together, these studies provide novel, strong evidence that glucose regulates monocyte/endothelial interactions in diabetes through modulation of 12/15LO.
We clearly found involvement of both 4
1
interactions with VCAM-1 and CS-1 FN and
2 integrin
interactions with ICAM-1 in mediating monocyte/endothelial interactions in
db/db mice. Interestingly, expression of endothelial VCAM-1
and ICAM-1 was not increased in db/db mice. Currently, there
are no available reagents to measure expression of CS-1 FN on mouse
endothelium, so we could not determine whether CS-1 FN was increased on ECs of
db/db mice. We did find that both CS-1 FN and VCAM-1
contributed to monocyte/endothelial adhesion
(Fig. 2). Blocking of both
epitopes for CS-1 FN and VCAM-1 on WEHI monocytes completely prevented
monocyte adhesion. We also found that ICAM-1 and
2 integrin
played a role in db/db-mediated monocyte adhesion. The exact
quantification of
4
1 integrin-mediated
interactions with CS-1 FN and VCAM-1 versus
2
integrin-mediated interactions with ICAM-1 in contributing to
db/db-mediated monocyte adhesion was not measured in the
current study. However, although not done in a quantitative manner, we did
find that blocking of
4
1 integrin
completely prevented monocyte/endothelial adhesion in
db/db ECs, whereas blocking of
2 integrins
did not completely prevent adhesion. Additional studies are necessary
to address this issue. Nevertheless, we were clearly able to illustrate that
all three of these key counter-receptors on endothelial cells (CS-1 FN,
VCAM-1, and ICAM-1) are important in regulating monocyte adhesion in
db/db mice.
The signaling pathways by which 12/15LO products stimulate endothelial activation are unclear but probably involve reactive oxygen species production. Brownlee and colleagues (40) have shown that glucose stimulates ROS production in endothelial cells. Stimulation of 12/15LO activity generates superoxide as well (26, 29). As shown in Fig. 7, inhibitors of ROS production in ECs blocked 12S-HETE production. These data suggest that 12/15LO activity is modulated through ROS production. Thus, our hypothesis is that glucose activates ROS production in ECs, which subsequently activates 12/15LO. Studies have shown regulation of the 12/15LO gene by the transcription factors Sp1 and AP-1 as well as by specific mitogen-activate protein kinases, all of which are activated by cellular oxidative stress (6065). Studies to define the regulation of 12/15LO by glucose and ROS are underway in the laboratory.
It will be very important to examine monocyte/endothelial interactions using Type 1 diabetes mouse models, because vascular complications remain a major cause of death in Type 1 diabetic patients. The Akita mouse is a model of Type 1 diabetes that develops vascular complications (6668). It is reasonable to presume that we will find similar changes in monocyte/endothelial adhesion in Type 1 mouse models. Preliminary studies by our laboratory have found that monocytes from patients with Type 1 diabetes are pre-activated to bind human ECs in vitro (data not shown). Studies to examine changes in monocyte/endothelial interactions in the db/db mouse as it progresses from Type 2 to Type 1 diabetes as well as in the Akita mouse are planned.
In summary, diabetic db/db mice have significant
elevations in 12S-HETE and 13S-HODE, products of the 12/15LO
enzyme pathway. Aortic endothelial cells from these mice have increased
monocyte adhesion. This adhesion is primarily due to interactions between CS-1
FN and VCAM-1 on the ECs surface, and its counter-ligand VLA-4 on monocytes,
although ICAM-1 and 2 integrins also participate. Inhibition
of the 12/15LO enzyme in diabetic db/db ECs blocked monocyte
adhesion, indicating that products of this pathway in ECs are primary
mediators of monocyte/endothelial interactions. Thus, regulation of the
12/15LO pathway in the vasculature may provide therapeutic benefit for
prevention of vascular complications of diabetes.
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FOOTNOTES |
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To whom correspondence should be addressed: Cardiovascular Research Center,
University of Virginia, P. O. Box 801394, 415 Lane Rd., MR5 Rm. G123,
Charlottesville, VA 22908. Tel.: 434-982-4065; Fax: 434-924-2828; E-mail:
cch6n{at}virginia.edu.
1 The abbreviations used are: VCAM-1, vascular cell adhesion molecule 1;
CS-1, connecting segment-1; FN, fibronectin; ICAM-1, intercellular adhesion
molecule 1; 12/15LO, 12/15 lipoxygenase; ECs, endothelial cells; LDL, low
density lipoprotein; FITC, fluorescein isothiocyanate; CDC,
cinnamyl-3,4-dihydroxy--cyanocinnamate; ROS, reactive oxygen species;
HPLC, high-performance liquid chromatography; HETE, hydroxyeicosatetraenoic
acid; HODE, hydroxyoctadecaenoic acid; PBS, phosphate-buffered saline; ANOVA,
analysis of variance; DMEM, Dulbecco's modified Eagle's medium; FBS, fetal
bovine serum; MAECs, mouse aortic endothelial cells; HAECs, human aortic
endothelial cells; TNF, tumor necrosis factor; CTR, control; TTFA,
thenoyltrifluoroacetone; CCCP, carbonyl cyanide
m-chlorophenylhydrazone; PLA2, phospholipase A2.
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ACKNOWLEDGMENTS |
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REFERENCES |
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