Lysophosphatidic acids are new substrates for the phosphatase domain of soluble epoxide hydrolase

Soluble epoxide hydrolase (sEH) is a bifunctional enzyme that has a C-terminus epoxide hydrolase domain and an N-terminus phosphatase domain. The endogenous substrates of epoxide hydrolase are known to be epoxyeicosatrienoic acids, but the endogenous substrates of the phosphatase activity are not well understood. In this study, to explore the substrates of sEH, we investigated the inhibition of the phosphatase activity of sEH toward 4-methylumbelliferyl phosphate by using lecithin and its hydrolyzed products. Although lecithin itself did not inhibit the phosphatase activity, the hydrolyzed lecithin significantly inhibited it, suggesting that lysophospholipid or fatty acid can inhibit it. Next, we investigated the inhibition of phosphatase activity by lysophosphatidyl choline, palmitoyl lysophosphatidic acid, monopalmitoyl glycerol, and palmitic acid. Palmitoyl lysophosphatidic acid and fatty acid efficiently inhibited phosphatase activity, suggesting that lysophosphatidic acids (LPAs) are substrates for the phosphatase activity of sEH. As expected, palmitoyl, stearoyl, oleoyl, and arachidonoyl LPAs were efficiently dephosphorylated by sEH (Km, 3-7 μM; Vmax, 150-193 nmol/min/mg). These results suggest that LPAs are substrates of sEH, which may regulate physiological functions of cells via their metabolism.     

Opposite regulation of cholesterol levels by the phosphatase and hydrolase domains of soluble epoxide hydrolase

Soluble epoxide hydrolase (sEH) is a bifunctional enzyme with two catalytic domains: a C-terminal epoxide hydrolase domain and an N-terminal phosphatase domain. Epidemiology and animal studies have attributed a variety of cardiovascular and anti-inflammatory effects to the C-terminal epoxide hydrolase domain. The recent association of sEH with cholesterol-related disorders, peroxisome proliferator-activated receptor activity, and the isoprenoid/cholesterol biosynthesis pathway additionally suggest a role of sEH in regulating cholesterol metabolism. Here we used sEH knock-out (sEH-KO) mice and transfected HepG2 cells to evaluate the phosphatase and hydrolase domains in regulating cholesterol levels. In sEH-KO male mice we found a approximately 25% decrease in plasma total cholesterol as compared with wild type (sEH-WT) male mice. Consistent with plasma cholesterol levels, liver expression of HMG-CoA reductase was found to be approximately 2-fold lower in sEH-KO male mice. Additionally, HepG2 cells stably expressing human sEH with phosphatase only or hydrolase only activity demonstrate independent and opposite roles of the two sEH domains. Whereas the phosphatase domain elevated cholesterol levels, the hydrolase domain lowered cholesterol levels. Hydrolase inhibitor treatment in sEH-WT male and female mice as well as HepG2 cells expressing human sEH resulted in higher cholesterol levels, thus mimicking the effect of expressing the phosphatase domain in HepG2 cells. In conclusion, we show that sEH regulates cholesterol levels in vivo and in vitro, and we propose the phosphatase domain as a potential therapeutic target in hypercholesterolemia-related disorders.     

An insect farnesyl phosphatase homologous to the N-terminal domain of soluble epoxide hydrolase

In insects, farnesyl pyrophosphate (FPP) is converted to juvenile hormone (JH) via a conserved pathway consisting of isoprenoid-derived metabolites. The first step of this pathway is presumed to be hydrolysis of FPP to farnesol in the ring gland. Based on alignment of putative phosphatases from Drosophila melanogaster with the phosphatase domain of soluble epoxide hydrolase, Phos2680 and Phos15739 with conserved phosphatase motifs were identified, cloned and purified. Both D. melanogaster phosphatases hydrolyzed para-nitrophenyl phosphate, however, Phos15739 also hydrolyzed FPP with a K_cat/K_m of 2.1 × 10⁵ M⁻¹ s⁻¹. RT-PCR analysis revealed that Phos15739 was expressed in the ring gland and its expression was correlated with JHIII titer during development of D. melanogaster. N-acetyl-S-geranylgeranyl-l-cysteine was found to be a potent inhibitor of Phos15739 with an IC₅₀ value of 4.4 μM. Thus, our data identify Phos15739 as a FPP phosphatase that likely catalyzes the hydrolysis of FPP to farnesol in D. melanogaster.     

Lipid sulfates and sulfonates are allosteric competitive inhibitors of the N-terminal phosphatase activity of the mammalian soluble epoxide hydrolase

The EPXH2 gene encodes for the soluble epoxide hydrolase (sEH), a homodimeric enzyme with each monomer containing two domains with distinct activities. The C-terminal domain, containing the epoxide hydrolase activity (Cterm-EH), is involved in the metabolism of arachidonic acid epoxides, endogenous chemical mediators that play important roles in blood pressure regulation, cell growth, and inflammation. We recently demonstrated that the N-terminal domain contains a Mg2+-dependent lipid phosphate phosphatase activity (Nterm-phos). However, the biological role of this activity is unknown. The inability of known phosphatase inhibitors to inhibit the Nterm-phos constitutes a significant barrier to the elucidation of its function. We describe herein sulfate, sulfonate, and phosphonate lipids as novel potent inhibitors of Nterm-phos. These compounds are allosteric competitive inhibitors with K(I) in the hundred nanomolar range. These inhibitors may provide a valuable tool to investigate the biological role of the Nterm-phos. We found that polyisoprenyl phosphates are substrates of Nterm-phos, suggesting a possible role in sterol synthesis or inflammation. Furthermore, some of these compounds inhibit the C-terminal sEH activity through a noncompetitive inhibition mechanism involving a new binding site on the C-terminal domain. This novel site may play a role in the natural in vivo regulation of epoxide hydrolysis by sEH.     

Fatty acid-binding proteins inhibit hydration of epoxyeicosatrienoic acids by soluble epoxide hydrolase

Epoxyeicosatrienoic acids (EETs) are potent regulators of vascular homeostasis and are bound by cytosolic fatty acid-binding proteins (FABPs) with K(d) values of approximately 0.4 microM. To determine whether FABP binding modulates EET metabolism, we examined the effect of FABPs on the soluble epoxide hydrolase (sEH)-mediated conversion of EETs to dihydroxyeicosatrienoic acids (DHETs). Kinetic analysis of sEH conversion of racemic [(3)H]11,12-EET yielded K(m) = 0.45 +/- 0.08 microM and V(max) = 9.2 +/- 1.4 micromol min(-1) mg(-)(1). Rat heart FABP (H-FABP) and rat liver FABP were potent inhibitors of 11,12-EET and 14,15-EET conversion to DHET. The resultant inhibition curves were best described by a substrate depletion model, with K(d) = 0.17 +/- 0.01 microM for H-FABP binding to 11,12-EET, suggesting that FABP acts by reducing EET availability to sEH. The EET depletion by FABP was antagonized by the co-addition of arachidonic acid, oleic acid, linoleic acid, or 20-hydroxyeicosatetraenoic acid, presumably due to competitive displacement of FABP-bound EET. Collectively, these findings imply that FABP might potentiate the actions of EETs by limiting their conversion to DHET. However, the effectiveness of this process may depend on metabolic conditions that regulate the levels of competing FABP ligands.     

Effect of soluble epoxide hydrolase inhibition on epoxyeicosatrienoic acid metabolism in human blood vessels

We investigated the effects of soluble epoxide hydrolase (sEH) inhibition on epoxyeicosatrienoic acid (EET) metabolism in intact human blood vessels, including the human saphenous vein (HSV), coronary artery (HCA), and aorta (HA). When HSV segments were perfused with 2 micromol/l 14,15-[3H]EET for 4 h, >60% of radioactivity in the perfusion medium was converted to 14,15-dihydroxyeicosatrienoic acid (DHET). Similar results were obtained with endothelium-denuded vessels. 14,15-DHET was released from both the luminal and adventitial surfaces of the HSV. When HSVs were incubated with 14,15-[3H]EET under static (no flow) conditions, formation of 14,15-DHET was detected within 15 min and was inhibited by the selective sEH inhibitors N,N'-dicyclohexyl urea and N-cyclohexyl-N'-dodecanoic acid urea (CUDA). Similarly, CUDA inhibited the conversion of 11,12-[3H]EET to 11,12-DHET by the HSV. sEH inhibition enhanced the uptake of 14,15-[3H]EET and facilitated the formation of 10,11-epoxy-16:2, a beta-oxidation product. The HCA and HA converted 14,15-[3H]EET to DHET, and this also was inhibited by CUDA. These findings in intact human blood vessels indicate that conversion to DHET is the predominant pathway for 11,12- and 14,15-EET metabolism and that sEH inhibition can modulate EET metabolism in vascular tissue.     

Adamantyl thioureas as soluble epoxide hydrolase inhibitors

A series of inhibitors of the soluble epoxide hydrolase (sEH) containing one or two thiourea groups has been developed. Inhibition potency of the described compounds ranges from 50?μM to 7.2?nM. 1,7-(Heptamethylene)bis[(adamant-1-yl)thiourea] (6f) was found to be the most potent sEH inhibitor, among the thioureas tested. The inhibitory activity of the thioureas against the human sEH is closer to the value of activity against rat sEH rather than murine sEH. While being less active, thioureas are up to 7-fold more soluble than ureas, which makes them more bioavailable and thus promising as sEH inhibitors.     

Symmetric adamantyl-diureas as soluble epoxide hydrolase inhibitors

A series of inhibitors of the soluble epoxide hydrolase (sEH) containing two urea groups has been developed. Inhibition potency of the described compounds ranges from 2.0 μM to 0.4 nM. 1,6-(Hexamethylene)bis[(adamant-1-yl)urea] (3b) was found to be a potent slow tight binding inhibitor (IC₅₀ = 0.5 nM) with a strong binding to sEH (K_i = 3.1 nM) and a moderately long residence time on the enzyme (k_off = 1.05 × 10⁻³ s⁻¹; t_1/2 = 11 min).     

Mammalian soluble epoxide hydrolase is identical to liver hepoxilin hydrolase

Hepoxilins are lipid signaling molecules derived from arachidonic acid through the 12-lipoxygenase pathway. These trans-epoxy hydroxy eicosanoids play a role in a variety of physiological processes, including inflammation, neurotransmission, and formation of skin barrier function. Mammalian hepoxilin hydrolase, partly purified from rat liver, has earlier been reported to degrade hepoxilins to trioxilins. Here, we report that hepoxilin hydrolysis in liver is mainly catalyzed by soluble epoxide hydrolase (sEH): i) purified mammalian sEH hydrolyses hepoxilin A₃ and B₃ with a V_max of 0.4–2.5 μmol/mg/min; ii) the highly selective sEH inhibitors N-adamantyl-N’-cyclohexyl urea and 12-(3-adamantan-1-yl-ureido) dodecanoic acid greatly reduced hepoxilin hydrolysis in mouse liver preparations; iii) hepoxilin hydrolase activity was abolished in liver preparations from sEH^−/− mice; and iv) liver homogenates of sEH^−/− mice show elevated basal levels of hepoxilins but lowered levels of trioxilins compared with wild-type animals. We conclude that sEH is identical to previously reported hepoxilin hydrolase. This is of particular physiological relevance because sEH is emerging as a novel drug target due to its major role in the hydrolysis of important lipid signaling molecules such as epoxyeicosatrienoic acids. sEH inhibitors might have undesired side effects on hepoxilin signaling.     

可溶性表氧化物水解酶与脂代谢

可溶性表氧化物水解酶(soluble epoxide hydrolase,sEH)在哺乳动物体内广泛存在。研究发现,sEH可以降解表氧二十碳三烯酸(epoxyeicosatrienoic acids,EETs)以及其他脂肪酸表氧化物。EETs具有广泛的心血管系统保护及抗炎作用,故sEH因其与心血管疾病的关系而受到关注。新近研究显示,sEH与脂质代谢密切相关,并与其C端水解酶区域和N端磷酸酶区域的不同活性有关。进一步深入探讨sEH的作用机制,将为研究脂质调节紊乱相关的代谢疾病提供一个新的治疗靶点。本文对sEH两端酶活性,及其与脂质代谢调节的研究进展予以综述。     

Nuclear metabolism. II. Further studies on epoxide hydrolase activity

Apparent K_m- and V_max-values of nuclear styrene 7,8-oxide hydrolase were determined at different protein concentrations. In the protein concentrations range used no significant differences in the apparent K_m-values were observed. The influence of the incubation with different modifiers (i.e. SKF-525A, metyrapone, 1,2-epoxy-3,3,3 trichloropropane, cyclohexene oxide) at two different concentrations on this enzyme activity was also determined. Cyclohexene oxide and 1,2-epoxy-3,3,3-trichloropropane, two well known inhibitors of the microsomal epoxide hydrolase(s) caused a marked inhibition, metyrapone had a strong activating effect whereas SKF-525A had no effect. In vivo pretreatment with phenobarbital significantly induced the nuclear epoxide hydrolase whereas β-naphthoflavone caused a lower degree of induction. This pattern is quantitatively different but qualitatively very similar to the microsomal one. Moreover a toxifying to detoxifying enzymatic activity balance is attempted for the metabolization of the alkenic double bond of styrene, taking into account the ratio between the styrene monooxygenase (toxifying enzyme) and the styrene 7,8-oxide hydrolase (detoxifying enzyme) after the above mentioned pretreatments, both in the microsomal and nuclear fractions.     

Optimization of piperidyl-ureas as inhibitors of soluble epoxide hydrolase

Inhibition of sEH is hypothesized to lead to an increase in epoxyeicosatrienoic acids resulting in the potentiation of their anti-inflammatory and vasodilatory effects. In an effort to explore sEH inhibition as an avenue for the development of vasodilatory and cardio- or renal-protective agents, a lead identified through high-throughput screening was optimized, guided by the determination of a solid state co-structure with sEH. Replacement of potential toxicophores was followed by optimization of cell-based potency and ADME properties to provide a new class of functionally potent sEH inhibitors with attractive in vitro metabolic profiles and high and sustained plasma exposures after oral administration in the rat.     

Discovery of potent non-urea inhibitors of soluble epoxide hydrolase

Soluble epoxide hydrolase (sEH) is a novel target for the treatment of hypertension and vascular inflammation. A new class of potent non-urea sEH inhibitors was identified via high throughput screening (HTS) and chemical modification. IC₅₀s of the most potent compounds range from micromolar to low nanomolar.     

Cloning and expression of soluble epoxide hydrolase from potato

Five cDNAs encoding a putative soluble epoxide hydrolase (sEH) from potato were isolated and characterized. The cDNAs contained open reading frames encoding 36 kDa polypeptides which were highly homologous to the carboxy terminal region of mammalian sEH. When one of the cDNAs was expressed in a baculovirus system a soluble 38 kDa protein with epoxide hydrolase activity was produced. The recombinant enzyme hydrolyzed a commonly used diagnostic substrate for the soluble form of mammalian EH. Inhibitor profiles of the recombinant potato and mammalian sEH were also similar. The expression of sEH in potato was found to be regulated by both developmental and environmental signals. Levels of mRNA for sEH were higher in meristematic tissue than in mature leaves. This mRNA was also observed to accumulate on wounding and application of exogenous methyl jasmonate.     

A novel activity of microsomal epoxide hydrolase: metabolism of the endocannabinoid 2-arachidonoylglycerol

Microsomal epoxide hydrolase (EPHX1, EC 3.3.2.9) is a highly abundant α/β-hydrolase enzyme that is known for its catalytical epoxide hydrolase activity. A wide range of EPHX1 functions have been demonstrated including xenobiotic metabolism; however, characterization of its endogenous substrates is limited. In this study, we present evidence that EPHX1 metabolizes the abundant endocannabinoid 2-arachidonoylglycerol (2-AG) to free arachidonic acid (AA) and glycerol. The EPHX1 metabolism of 2-AG was demonstrated using commercially available EPHX1 microsomes as well as PC-3 cells overexpressing EPHX1. Conversely, EPHX1 siRNA markedly reduced the EPHX1 expression and 2-AG metabolism in HepG2 cells and LNCaP cells. A selective EPHX1 inhibitor, 10-hydroxystearamide, inhibited 2-AG metabolism and hydrolysis of a well-known EPHX1 substrate, cis-stilbene oxide. Among the inhibitors studied, a serine hydrolase inhibitor, methoxy-arachidonyl fluorophosphate, was the most potent inhibitor of 2-AG metabolism by EPHX1 microsomes. These results demonstrate that 2-AG is an endogenous substrate for EPHX1, a potential role of EPHX1 in the endocannabinoid signaling and a new AA biosynthetic pathway.     

Inhibition of soluble epoxide hydrolase by fulvestrant and sulfoxides

The soluble epoxide hydrolase (sEH) is a key enzyme in the metabolism of epoxy-fatty acids, signaling molecules involved in numerous biologies. Toward finding novel inhibitors of sEH, a library of known drugs was tested for inhibition of sEH. We found that fulvestrant, an anticancer agent, is a potent (K_I = 26 nM) competitive inhibitor of sEH. From this observation, we found that alkyl-sulfoxides represent a new kind of pharmacophore for the inhibition of sEH.     

Non-urea functionality as the primary pharmacophore in soluble epoxide hydrolase inhibitors

Inhibition of soluble epoxide hydrolase has been proposed as a promising new pharmaceutical target for diseases involving hypertension and vascular inflammation. The most potent sEH inhibitors reported to date contain a urea or amide moiety as the central or ‘primary’ pharmacophore. We evaluated replacing the urea pharmacophore with other functional groups such as thiourea, sulfonamide, sulfonylurea, aminomethylene amide, hydroxyamide, and ketoamide to identify novel and potent inhibitors. The hydroxyamide moiety was identified as a novel pharmacophore affording potency comparable to urea.     

Solid-phase combinatorial approach for the optimization of soluble epoxide hydrolase inhibitors

A 192-member library of N,N'-disubstituted urea inhibitors was synthesized by a solid-phase method. The ureas were tested for their inhibitory activities against recombinant human soluble epoxide hydrolase. Simple carbocyclic or para/meta-substituted phenyl groups showed inhibition potencies that were equal to or greater than adamantane-based sEH inhibitors, while the presence of bulky or ionizable groups close to the urea group dramatically decreased their activities.     

Inhibition of soluble epoxide hydrolase activity by compounds isolated from the aerial parts of Glycosmis stenocarpa

The aim of this study is to search for soluble epoxide hydrolase (sEH) inhibitors from natural plants, bioassay-guided fractionation of lipophilic n-hexane and chloroform layers of an extract of the aerial parts of Glycosmis stenocarpa led to the isolation of 12 compounds (1–12) including murrayafoline-A (1), isomahanine (2), bisisomahanine (3), saropeptate (4), (24?S)-ergost-4-en-3,6-dione (5), stigmasta-4-en-3,6-dion (6), stigmast-4-en-3-one (7), β-sitosterol (8), 24-methylpollinastanol (9), trans-phytol (10), neosarmentol III (11) and (+)-epiloliolide (12). Their structures were elucidated on the basis of spectroscopic data. Among them, neosarmentol III (11) was isolated from nature for the first time. All the isolated compounds were evaluated for their inhibitory activity against sEH. Among isolated carbazole-type compounds, isomahanine (2) and bisisomahanine (3) were identified as a potent inhibitor of sEH, with IC₅₀ values of 22.5?±?1.7 and 7.7?±?1.2?µM, respectively. Moreover, the inhibitory action of 2 and 3 represented mixed-type enzyme inhibition.     

Brassica napus soluble epoxide hydrolase (BNSEH1).

Epoxide hydrolase (EC 3.3.2.3) in plants is involved in the metabolism of epoxy fatty acids and in mediating defence responses. We report the cloning of a full-length epoxide hydrolase cDNA (BNSEH1) from oilseed rape (Brassica napus) obtained by screening of a cDNA library prepared from methyl jasmonate induced leaf tissue, and the 5'-RACE technique. The cDNA encodes a soluble protein containing 318 amino acid residues. The identity on the protein level is 85% to an Arabidopsis soluble epoxide hydrolase (sEH) and 50-60% to sEHs cloned from other plants. A 5 x His tag was added to the N-terminus of the BNSEH1 and the construct was over-expressed in the yeast Pichia pastoris. The recombinant protein was recovered at high levels after Ni-agarose chromatography of lysed cell extracts, had a molecular mass of 37 kDa on SDS/PAGE and cross-reacted on Western blots with antibodies raised to a sEH from Arabidopsis thaliana. BNSEH1 was shown to be a monomer by gel filtration analysis. The activity was low towards cis-stilbene oxide but much higher using trans-stilbene oxide as substrate with Vmax of 0.47 micro mol.min.mg-1, Km of 11 micro m and kcat of 0.3 s-1. The optimum temperature of the recombinant enzyme was 55 degrees C and the optimum pH 6-7 for trans-stilbene oxide hydrolysis. The isolation of BNSEH1 will facilitate metabolic engineering of epoxy fatty acid metabolism for functional studies of resistance and seed oil modification in this important oilcrop.