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J. Biol. Chem., Vol. 282, Issue 5, 2891-2898, February 2, 2007

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Compensatory Mechanism for Homeostatic Blood Pressure Regulation in Ephx2 Gene-disrupted Mice^*

Ayala Luria¹, Steven M. Weldon, Alisa K. Kabcenell, Richard H. Ingraham, Damian Matera, Huiping Jiang^¶, Rajan Gill^||, Christophe Morisseau^**, John W. Newman^||1, and Bruce D. Hammock^**2

From the Departments of Entomology and ^||Nutrition and the ^**Cancer Research Center, University of California, Davis, California 95616, the Departments of ^¶Translational Science and Cardiovascular Disease, Boehringer Ingelheim Pharmaceuticals Inc., Ridgefield, Connecticut 06877, and the United State Department of Agriculture, ARS, Western Human Nutrition Research Center, Davis, California 95616

Received for publication, August 22, 2006 , and in revised form, November 28, 2006.

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Arachidonic acid-derived epoxides, epoxyeicosatrienoic acids, are important regulators of vascular homeostasis and inflammation, and therefore manipulation of their levels is a potentially useful pharmacological strategy. Soluble epoxide hydrolase converts epoxyeicosatrienoic acids to their corresponding diols, dihydroxyeicosatrienoic acids, modifying or eliminating the function of these oxylipins. To better understand the phenotypic impact of Ephx2 disruption, two independently derived colonies of soluble epoxide hydrolase-null mice were compared. We examined this genotype evaluating protein expression, biofluid oxylipin profile, tissue oxylipin production capacity, and blood pressure. Ephx2 gene disruption eliminated soluble epoxide hydrolase protein expression and activity in liver, kidney, and heart from each colony. Plasma levels of epoxy fatty acids were increased, and fatty acid diols levels were decreased, while measured levels of lipoxygenase- and cyclooxygenase-dependent oxylipins were unchanged. Liver and kidney homogenates also show elevated epoxide fatty acids. However, in whole kidney homogenate a 4-fold increase in the formation of 20-hydroxyeicosatetraenoic acid was measured along with a 3-fold increase in lipoxygenase-derived hydroxylation and prostanoid production. Unlike previous reports, however, neither Ephx2-null colony showed alterations in basal blood pressure. Finally, the soluble epoxide hydrolase-null mice show a survival advantage following acute systemic inflammation. The data suggest that blood pressure homeostasis may be achieved by increasing production of the vasoconstrictor, 20-hydroxyeicosatetraenoic acid in the kidney of the Ephx2-null mice. This shift in renal metabolism is likely a metabolic compensation for the loss of the soluble epoxide hydrolase gene.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Soluble epoxide hydrolase (sEH)³ is a ubiquitous enzyme found in many tissues such as liver, kidney, heart, and ovary (1). sEH catalyzes the degradation of endogenous epoxy lipids such as epoxyeicosatrienoic acids (EETs) to their less active diols (dihydroxyeicosatrienoic acids, DHETs) and hence plays a critical role in the control of EET levels (2). These epoxy lipids are potent vasodilators, regulating cerebral and renal homodynamic and blood pressure (3–5). In addition, EETs inhibit platelet aggregation (6), promote fibrinolysis (7) and have anti-inflammatory properties (8, 9). Whereas deletion of the sEH gene, Ephx2, has been reported to reduce blood pressure in male mice (10), the inhibition of endogenous EET hydrolysis may provide pharmacological benefit in hypertension and acute inflammation (11).

The human Ephx2 gene encodes sEH and consists of 19 exons encoding 555 amino acids (12). There is 73% homology between the human and mouse sEH protein sequences (13), with 100% conservation in the catalytic residues (14). Each monomer of the homodimeric mouse sEH has two distinct domains (14, 15). The N-terminal domain exhibits phosphatase activity, and the C-terminal domain is responsible for the epoxide hydrolase activities (16, 17). Whereas the endogenous role of the phosphatase domain has yet to be elucidated, lipophilic phosphates appear to be excellent substrates (17–19).

Extensive investigations in recent years have established a role for cytochrome P450 (CYP)-derived eicosanoids in the regulation of blood pressure (11). The CYP-derived eicosanoids are synthesized throughout the body but act in a paracrine and autocrine fashion to regulate cellular function. In particular, the kidney and vascular endothelium produce significant levels of CYP-derived eicosanoids with effects on renal tubular transport function and vascular reactivity. Altered levels of renal EETs and hydroxyeicosatetraenoic acids (HETEs) are associated with changes in blood pressure (20–22). Furthermore, CYP epoxygenase activity is increased in animal models of hypertension, including the spontaneously hypertensive rats (21) and a high salt diet (23). The elevation in EET biosynthesis in these models could be a consequence of elevated blood pressure and might represent a compensatory response of the animal to deleterious increases in blood pressure. Moreover, inhibition of epoxygenases by clotrimazole leads to salt-dependent hypertension (24) and an inability to increase P450 epoxygenase activity with excess dietary salt intake in Dahl salt-sensitive rats might contribute to the hypertensive phenotype of these animals (23). In addition, with the onset of obesity-related hypertension the renal expression of CYP epoxygenases declines, while CYP omega hydroxylase and cyclooxygenase 2 expression increase (25, 26). Therefore, it would appear that the interplay of epoxygenase, -hydroxylases, and cyclooxygenase in the kidney are important determinants of blood pressure control.

To expand on the phenotypic characterization of the Ephx2-null mouse, animals were obtained from two independently derived and housed colonies of mice. The two colonies were either derived at the National Institutes of Health (10), or by Lexicon Genetics Inc. (The Woodlands, Texas). The latter, was exclusively for Boehringer Ingelheim Pharmaceuticals Inc. (Ridgefield, CT). Previous studies have shown that attenuation of endogenous EETs hydrolysis via sEH inhibition is a potentially useful pharmacological strategy for blood pressure regulation (4, 9, 27). In this regard, our main goal for this study was to perform a broad profile of the Ephx2-null phenotype and subsequently to evaluate blood pressure regulation under resting state as well as stressed conditions. We hypothesized that elevated endogenous EETs would have an advantageous role in blood pressure homeostasis and protect the overall health of the animal under abnormal conditions in which blood pressure is compromised.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Animals and Genotypic Analysis—Mice on a 129X1/SvJ x C57BL/6 background with targeted disruption in the Ephx2 gene were obtained from Chris Sinal, Dalhousie University, Halifax, NS, Canada under a National Cancer Institute Material Transfer Agreement 1-16268-04 (10). These mice backcrossed onto a C57BL6 genetic background three generations prior to use in this study. This colony is referred as the NIH colony, and was used to rederive a new colony by embryo transfer. Routine genotyping of sEH-null mice was performed as published (10) using the following primers F1, 5'-TGAGATTGGCACGACCCTA-3'; R2, 5'-TTGAAACCTGGGCTGGACG-3'; and Neo R3, 5'-AGTTCATTCAGGGCACCG-3'. Primer F1/R2 predicts a 290-base pair product for the wild type allele (Fig. 1A). For the null allele, primers F1/R3 predict a 560-base pair product of a neomycin resistance sequence as described previously (Fig. 1A and Ref. 10).

A second colony of sEH-null mice was independently derived for Boehringer Ingelheim Pharmaceuticals, Inc. The heterozygous Ephx2 founder mice were created at Lexicon Genetics Inc. by gene trapping using random insertional mutagenesis with retroviral vector VICTR48 as described by Zambrowicz et al. (28). The integration site of the targeting cassette is in intron two. The heterozygous Ephx2 mice were then mated to establish a colony in the C57BL/6 albino x 129Sv/Ev mixed genetic background. Once obtained, Ephx2-null homozygotes were paired for subsequent breeding. Mice were maintained on sterile normal rodent diet (PicoLab rodent 20 from LabDiet, Richmond, IN) and bottled water ad libitum. Mice at age of 12–20 weeks were used and matched wild type mice were purchased from Taconic Farms. These animals were housed and bred in the Department of Cardiovascular Disease at Boehringer Ingelheim Pharmaceuticals, Inc. and are referred to as the BI colony.

BI Colony Blood Pressure—All procedures were conducted in accordance with approved IACUC protocols. Mean blood pressure (BP) and heart rate (HR) were monitored continuously in conscious, unrestrained female (20 weeks old) and male (12–20 weeks old) wild type and sEH-null mice using DSI telemetry (St. Paul, MN). Mice were surgically implanted with DSI TA11PA-20 telemetry transmitters and allowed to recover for a minimum of 7 days prior to study. Following recovery, mice were singly housed in plastic boxes placed directly on top of the telemetry receiver. Mean BP and HR data were recorded for 60 s every 20 min for the duration of the monitoring period. Individual mean BP and HR data were averaged over a 12-h cycle.

NIH Colony Blood Pressure and LPS Challenge—All procedures were conducted in accordance with approved IACUC protocols. Mean systolic blood pressure (SBP) and HR were measured in conscious, restrained wild type and Ephx2-null mice, starting at 8 weeks of age. Systolic blood pressure was measured by tail cuff plethysmography using a BP-2000 blood pressure analysis system (Visitech Systems, Apex, NC). Mice (n = 4 per genotype) were trained for 6 days to become acclimated to the Visitech System. For SBP and HR, twenty measurements were recorded daily and the last ten measurements averaged for a given mouse.

Western Blot Analysis—The expression of sEH or CYP4A proteins were analyzed by homogenization of tissues as described earlier (29). Briefly, protein concentrations were determined using the Pierce bicinchoninic acid protein assay. Protein aliquots from each tissue were resolved on 10–12% sodium dodecyl sulfate-polyacrylamide gels, transferred to nitrocellulose membranes, and immunoblotted with polyclonal antibodies against human sEH ((30); 1:1,000) or polyclonal antibodies against rat CYP4A (Chemicon International, Temecula, CA) followed by horseradish peroxidase-conjugated secondary antibody (1:10,000). -Actin antibodies (1:10,000) were purchased from Sigma, followed by anti-mouse horseradish peroxidase-conjugated secondary antibody (1:10,000). Chemiluminescent detection using ECL reagent from Amersham Biosciences (Piscataway, NJ) was carried out on x-ray film.

sEH Activity Assay—Soluble epoxide hydrolase activity was performed as previously described (29). Briefly, homogenates were diluted with sodium phosphate (100 mM, pH 7.4; 0.1 mg/ml bovine serum albumin) and chilled (on ice) until assayed. Assays were initiated by adding 1 µl of 5 mM [2-³H]-trans-1,3-diphenylpropene oxide (³H-tDPPO; [S]_final = 50 µM) in N,N'-dimethyl-formamide to 100 µl of tissue homogenate. Tubes were incubated at 30 °C for 5 min. Reactions were quenched with 60 µl of methanol and 200 µl of isooctane (31). Controls for interfering glutathione-transferase activity were prepared as described previously, but were quenched with 60 µl of methanol and 200 µl of hexanol (31). A 40-µl aliquot of the aqueous phase was analyzed for the presence of the radioactive diol product by liquid scintillation counting. Reactions were performed in triplicate. Results are means ± S.D. of three separate experiments.

Sample Collection and Oxylipin Extraction—Blood was collected from phenobarbital-anesthetized mice by cardiac puncture in EDTA-rinsed syringes. Each sample was immediately spun (10 min, 400 x g), and the plasma was separated and stored at –80 °C until analysis. Urine was collected from male Ephx2-null or wild type mice (n = 3) housed 24 h in metabolic chambers. Food and water were provided ad lib. Urine was collected into dry ice-chilled tubes containing butylated hydroxytoluene and EDTA at 0.2 mg and 10 mg of triphenylphosphine. Samples were stored at –80 °C until analysis. Oxylipins were extracted by solid phase extraction. Detailed protocols are provided as Supplemental Data under "Oxylipin extraction" (32).

Oxylipin Production Assay—Polyunsaturated fatty acid oxidase activities were determined in S9 fractions using modifications of previously reported procedures (29). Fatty acid epoxygenase, -hydroxylase, mid-chain hydroxylase, and prostaglandin synthase activities were obtained simultaneously. Briefly, aliquots (2 mg of protein) were suspended in 100 µl of 0.1 M sodium phosphate buffer (pH 7.4) and incubated (30 °C, 30 min) with or without arachidonic acid (100 µM) in the presence of an NADPH regenerating system. Reactions were halted with methanol containing analytical surrogates, and samples were centrifuged to remove precipitated protein. Arachidonate oxidation products were quantified in the isolated supernatant by HPLC/MS/MS. In the absence of arachidonic acid, no oxidation products were detected. Each reaction was performed in duplicate and mean specific activities were expressed in fmol/min/mg protein.

Oxylipin Analysis—Epoxides, diols, alcohols, and ketones of linoleate and arachidonate were quantified in all samples. Thromboxanes and prostaglandins were also measured in plasma and tissue production assays, but not urine because of matrix-dependent ion suppression. These oxylipins were quantified by HPLC/MS/MS using internal standard methods (32). Detailed protocols including HPLC (supplemental Table S1) and mass spectroscopy (supplemental Table S2) parameters are provided as Supplemental Data. Plasma and urine epoxide and diol surrogate recoveries were acceptable in all samples (see supplemental Table S3). Recoveries of tetradeuterated 6-keto-prostaglandin F1 (d4–6-keto-PGF1 ) were acceptable in plasma (see supplemental Table S3) and used to quantify 6-keto-PGF1. Epoxide surrogate hydrolysis was less than 3% for all assays. Reagent blanks showed background levels below detection limit, and analytical replicates showed precision to be within 15% for greater than 80% of the analytes present at levels greater than ten times the method detection limits.

Statistics—Values are expressed as mean ± S.D. or S.E., as indicated. Data were analyzed by Student's t test or ANOVA, as indicated under the figure legends. Values were considered significantly different if p < 0.05.

View larger version (60K): [in this window] [in a new window]   FIGURE 1. Ephx2-null mice of the NIH and BI colonies lack a complete sEH gene and express no detectable sEH protein. A, representative genotype analysis of wild type and Ephx2-null mice from the NIH colony. Negative and positive controls show no band product or a 290-bp band, respectively. Genomic DNA of sEH amplified from mouse tail shows a 290-bp gene product of sEH from NIH colony wild type. The Ephx2-null mice show a higher gene product of 560 bp from the neomycin resistant gene. Genotypic analysis was performed in all mice in each breeding colony. B, tissue distribution of sEH protein from wild type and Ephx2-null mice from both colonies. Immunoblots demonstrate expression of the 62.5 kDa protein in heart (H), kidney (K), and liver (L) of wild type (+/+) and lack of sEH protein expression in Ephx2-null mice (–/–) of both colonies.

	RESULTS

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View larger version (18K): [in this window] [in a new window]   FIGURE 2. Elimination of sEH protein expression fails to cause detectable alteration in blood pressure. A, mean blood pressure (BP) and heart rate (HR) were recorded via telemetry (12-h averages) in wild type and Ephx2-null mice from the BI colony. B, mean systolic blood pressure (SBP) and HR were recorded by tail cuff measurements in the NIH colony. Results are presented as mean ± S.E. for: Ephx2+/+ (n = 9); Ephx2–/– (n = 11); Ephx2+/+ (n = 4) and Ephx2–/– (n = 5) in the BI colony and mean ± S.E. for: Ephx2+/+ (n = 4) and Ephx2–/– (n = 4) in the NIH colony. Significant differences are indicated by ANOVA with Tukey-Kramer for telemetry and single factor ANOVA for tail cuff plethysmography (p < 0.05).

View larger version (38K): [in this window] [in a new window]   FIGURE 3. Plasma oxylipin substrate:product ratios in the wild type and Ephx2-null mice. Plasma epoxide:diol ratios were elevated in Ephx2-null mice over the wild type in both the linoleate (EpOME:DHOME) and arachidonate series (EET:DHET). Conversely the sEH-independent 9-HODE:9-oxo-ODE ratio was unaffected in the Ephx2-null mice. The magnitude of the difference between sEH-dependent substrate: product ratios showed a strong correlation (p < 0.05, r > 0.81; Pearsons correlation) with the distance of the oxidized center from the carboxyl carbon (inset box). Significant differences are indicated with an asterisk (*, p < 0.05; 2-tailed t test).

View larger version (18K): [in this window] [in a new window]   FIGURE 4. Elimination of sEH protein expression reduces hypotensive effects of LPS challenge in mice. Genotype-specific effects on blood pressure and heart rate in response to LPS challenge. The mean systolic blood pressure (SBP) and heart rate (HR) responses were recorded via tail-cuff in the NIH colony before and periodically after administration of LPS (10 mg/kg, i.p). At 5 h post-LPS administration, the wild type blood pressure and heart rate were below the instrument detection limit (dashed line). Recovery from the acute hypotensive effect of LPS exposure was enhanced among the Ephx2-null mice compared with their wild type counterparts as demonstrated by the attenuated SBP response at both 24 and 48 h post-LPS (single factor ANOVA. *, p < 0.05; #, p < 0.1).

Whereas lowered DHETs and elevated EET production was observed in Ephx2-null kidney homogenates, the -hydroxylase metabolite, 20-HETE was enhanced 4-fold. Moreover, the lipoxygenase-dependent metabolites (mid-chain HETEs) and the cyclooxygenase-dependent prostaglandins PGF2, PGE₂, and 6-keto-PGF₁ were also increased 2–10-fold in the Ephx2-null kidney homogenates, suggesting up-regulation of these enzymes (Table 3).

Renal Feedback—Considerable evidence has accumulated indicating that expression of CYP enzymes and the production of EETs and 20-HETE in the kidney and peripheral vasculature are strong regulators of peripheral vascular tone, renal function, and blood pressure. Cellular expression of CYP 4A was measured in liver and kidney tissue homogenates. CYP 4A protein expression was 4-fold higher in whole kidney tissue homogenate from the Ephx2-null mice compared with wild type, and depressed in liver tissue homogenates of both genotypes (Fig. 5).

Urine oxylipin analysis from Ephx2-null or wild type male mice from the BI colony is presented in Fig. 6 and Fig. S1C. Whereas concentrations of metabolites among the pooled samples were high, the relative abundance of excreted metabolites showed significant differences between genotypes. Notably, the 12(13)-EpOME and 20-HETE were higher in the Ephx2-null urine, whereas the 12,13-DHOME, 14,15-DHET, and 5,6-DHET were all lower in this genotype. The concentrations of EETs were close to the detection limit in five of the six analyzed samples, likely precluding determination of changes in excretion of these metabolites.

	DISCUSSION

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Adaptation to defects in signaling, including genetic disruptions, are natural responses that allow organisms to maintain homeostatic control of critical phenotypic characteristics (36, 37, 38). An inability to compensate for such changes can lead to dire consequences (39). The initial description of the NIH-derived Ephx2-null mouse reported a reduction in male resting blood pressure (10). A number of studies have added additional support to the sEH-blood pressure regulatory link. Pharmacological inhibition of sEH is efficacious in lowering blood pressure in angiotensin-dependent hypertension in rodents (4, 21, 40, 41). Furthermore, several strains of spontaneously hypertensive rats show elevated sEH protein, and only these rats respond to sEH inhibitor therapy (21, 42). Pharmacological inhibition of sEH has also been shown to normalize blood pressure in septic shock induced by LPS in rodents (27). In a recent study it was found that genetic variations of the Ephx2 coding sequence are associated with the risk of coronary heart disease (34, 43). These results clearly suggest that sEH activity plays a role in blood pressure homeostasis.

View larger version (42K): [in this window] [in a new window]   FIGURE 5. Expression of CYP4A in kidney and liver homogenates of wild type and Ephx2-null mice from NIH colony. A, representative Western blot showing the expression of CYP4A protein detected with rabbit anti-rat CYP4A1–3 and -actin to confirm equivalent loading. B, densitometric values of CYP4A expression level in renal extracts from wild type and Ephx2-null mice (mean S.E. of n = 3; t test. *, p < 0.05).

View larger version (23K): [in this window] [in a new window]   FIGURE 6. Urinary oxylipin analyses showed changes in the relative abundance of excreted linoleate (A) and arachidonate (B) metabolites. A and B show the mean ± S.E. percentage of each analyte with respect to the quantified lipids of the same carbon number. Differences were determined by two-tailed t-tests and differences are indicated at the **, p < 0.05 and *, p < 0.1 levels.

To determine if a blood pressure phenotype could be revealed by a pro-hypotensive treatment, blood pressure and heart rate were recorded in a group of 4 mice from each genotype of the NIH colony after exposure to 10 mg/kg LPS (Fig. 4). Acute LPS administration produces a severe hypotension in mice which can be blunted by prophylactic inhibition of sEH (27). The Ephx2-null mice show a similar resistance (Fig. 4). The recovery was faster and survival was increased in the Ephx2-null mice as compared with wild types. Thus, it appears that an alteration of blood pressure regulation is retained in these mutants. In several hypertensive models, sEH inhibitors lower blood pressure toward normotensive levels, and in LPS-treated animals, sEH inhibitors buffered the fall in blood pressure toward normotensive levels (4, 27). These data indicate a role for epoxyeicosanoids in blood pressure homeostasis.

To further characterize the nature of the adaptive response in the Ephx2-null animals, oxylipin concentrations were measured in plasma and urine of healthy mice. Plasma profiles in sEH-gene disrupted mice revealed elevated epoxy fatty acids and decreases in their corresponding diols. The ratios of these epoxide/diol substrate-product pairs were elevated in the Ephx2-null mice in a structurally specific manner (Fig. 3), consistent with the known substrate specificity of the sEH. Thus, the 12,13-EpOME:DHOME and 14,15-EET:DHET ratios were the most sensitive indicators of sEH activity in these rodents. Interestingly, the epoxy fatty acid degradation was not totally abolished in the Ephx2-null mice (Ref. 10 and Table 2), suggesting an alternative route for their hydrolysis.

The CYP -hydroxylase metabolite, 20-HETE, plays a major role in vasoconstriction and renal natriuretic mechanisms (44). Recent reports further strengthen this concept and substantiate the link between CYP4A, 20-HETE, and hypertension (45–47). In the renal vasculature and glomerulus, 20-HETE is a vasoconstrictor that lowers glomerular filtration rate and raises blood pressure (44). In the peripheral microcirculation, 20-HETE also increases vascular tone and raises blood pressure (48). The increase in urine 20-HETE provided evidence for enhanced renal -hydroxylase activity in the Ephx2-null mouse. Thus, the elevated 20-HETE production and enhanced CYP4A protein expression in the kidney offers a mechanistic explanation for the stabilization of basal blood pressure and the blunted response to LPS challenge.

Finally, in this study we provide data supporting the hypothesis that the Ephx2-null genotype is associated with a phenotypic adaptive response in renal lipid metabolism. This change results in maintenance of normal basal blood pressure. One possible explanation for the discrepancy between the blood pressure observations made by Sinal et al. (10) and those of this study could be related to the genetic background of the Ephx2 null mice. For example, previous data from Sinal et al. were obtained on a different genetic background and after far fewer generations than either of the two strains reported here. In addition, the earlier observations reported only small changes in blood pressure, which could be missed because of pressure oscillations in the current work. These results support a self-regulating interaction between the epoxygenase and -hydroxylase pathways producing a fine-tuned control over blood pressure homeostasis in the mouse.

	FOOTNOTES

 
^* This work was supported in part by Grant R37 ES02710 from the NIEHS, National Institutes of Health, the NIEHS Superfund Basic Research Program P42 ES004699, NIEHS P30 ES05707, National Institutes of Health/NIEHS R01 ES013933, and the UCDMC Translational Technology Grant. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement"in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The on-line version of this article (available at http://www.jbc.org) contains supplemental data, Tables S1–S3, and Fig. S1.

¹ Both authors contributed equally to this work.

² To whom correspondence should be addressed: Dept. of Entomology, University of California Davis, CA 95616. Tel.: 530-752-7519; Fax: 530-752-1537; E-mail: bdhammock{at}ucdavis.edu.

³ The abbreviations used are: sEH, soluble epoxide hydrolase; BP, blood pressure; BPM, beeps per minute; CYP, cytochrome P450; DHETs, dihydroxyeicosatrienoic acids; DHOME, dihydroxyoctadecaenoic acid; EETs, epoxyeicosatrienoic acids; EpOMEs, epoxyoctadecenoic acids; HETE, hydroxyeicosatetraenoic acid; HODE, hydroxyoctadecadienoic acid; HR, heart rate; LPS, lipopolysaccharide; oxo-ODE, keto-octadeca(10Z, 11E)dienoic acid; PG, prostaglandin; SBP, systolic blood pressure; tDPPO, trans-1,3-diphenylpropene oxide; ANOVA, analysis of variance.

	ACKNOWLEDGMENTS

 
We thank C. Williams, D. Cooper, R. Sellati, Mary McFarland, and Lynn Pantages-Torok for technical assistance and Theresa Pedersen for critical review of the manuscript. National Institutes of Health Images is a public domain image processing and analysis program.

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