Gamma-glutamyl hydrolase conjugase). Purification and properties of the bovine hepatic enzyme.

Bovine hepatic gamma-glutamyl hydrolase (conjugase) has been purified to homogeneity. A feature of the purification procedure was the use of high affinity macromolecular polyanion enzyme inhibitors which formed tight complexes with the enzyme altering its solubility, gel filtration, and ion exchange properties. The enzyme, which cleaves the gamma-glutamyl bonds of pteroylpolyglutamates, has a molecular weight of 108,000. It is a glycoprotein with an acid pH optimum, properties consistent with its lysosomal localization. Zinc is essential for enzyme stability. The presence of highly reactive sulfhydryl groups was evident from the extreme sensitivity to oxidizing agents and organomercurials. Very little thermal denaturation occurs below 65 degrees, but the enzyme is extremely sensitive to 0uffer anions, in keeping with the polyanionic nature of the substrate. In order to study the mechanism of action of the enzyme, a wide range of pteroylpolyglutamates, N-t-Boc polyglutamates and free polyglutamates were synthesized containing L-[U-14C]glutamic acid residues in different positions. Two pteroyltriglutamate derivatives were also synthesized in which an alpha bond replaced one of the two available gamma bonds. Time course studies of the products of the action of conjugase on these various substrates enabled us to draw the following conclusions about the enzyme: (a) peptide bond cleavage occurred only at gamma-glutamyl bonds and the presence of a COOH-terminal gamma bond was essential for enzyme action; (b) bond cleavage occurred with equal facility at internal points of the peptide chain and the enzyme should therefore be more appropriately classified as an acid hydrolase; (c) longer chain gamma-glutamyl peptides were preferentially attacked by the enzyme, the cleavage of diglutamyl peptides being extremely slow; and (d) cleavage of gamma bonds was independent of the NH2-terminal pteroyl moiety. Studies with polyanions such as the glycosaminoglycans and dextran sulfate supported the concept that the polyanion structure of the substrate was a major factor in substrate-active site interaction.     

Metabolic turnover of methotrexate polyglutamates in lysosomes derived from S180 cells. Definition of a two-step process limited by mediated lysosomal permeation of polyglutamates and activating reduced sulfhydryl compounds.

Transport and metabolic turnover of methotrexate (MTX) polyglutamates were examined in lysosomes derived from S180 cells. These studies extend prior work from this laboratory (Barrueco, J. R., and Sirotnak, F. M. (1991) J. Biol. Chem 266, 11732-11737) which described basic properties of a facilitative transport system in lysosomes capable of mediating intralysosomal accumulation of MTX polyglutamates. In the present report, we show that the rate of turnover of MTX polyglutamates in lysosomes, which releases MTX in the extralysosomal space, is limited by the extent of mediated intralysosomal accumulation of the polyglutamate and reduced sulfhydryls that activate the enzyme folylpolyglutamate hydrolase. Evidence is presented that cysteine functions as the naturally occurring reduced sulfhydryl compound in lysosomes being equipotent to 2-mercaptoethanol as an activator of folylpolyglutamate hydrolase. Folylpolyglutamate hydrolase in permeabilized lysosomes from S180 cells exhibited a low pH optimum characteristic of a lysosomal enzyme, was activated at concentrations of reduced sulfhydryl at 0.1 mM and above, and exhibited Km values in the range of 0.2-3 microM that decreased with increase in polyglutamate chain length. Values for Km for MTX polyglutamates of folylpolyglutamate hydrolase activity were 100-200-fold lower than values for Km or Ki for facilitated intralysosomal transport, whereas capacities for both processes were similar. This relationship between the kinetic properties of each process ensures efficient hydrolysis of MTX polyglutamates within the lysosome.     

A rapid colorimetric assay for gamma-glutamyl hydrolase (conjugase).

A simple procedure for the measurement of gamma-glutamyl hydrolase (conjugase) activity is described. Glutamic acid released from pteroylpenta-gamma-glutamate by hog kidney and chicken pancreas conjugases was quantitated using the dye 4,4'-bis(dimethylamino)benzophenone hydrazone. The procedure involves hydrolysis of the folylpoly-gamma-glutamate substrate by conjugase, conversion of glutamate to alpha-ketoglutarate by L-glutamate dehydrogenase and colorimetric measurement of the BDBH derivative of alpha-ketoglutarate. The release of as little as one nmol of glutamic acid from the substrate can be measured by this procedure, which is well suited for the assay of a variety of conjugase preparations. In addition, the method should provide a general assay for the enzymatic hydrolysis of various folate and antifolate polyglutamates.     

Nuclear localization of leukotriene A4 hydrolase in type II alveolar epithelial cells in normal and fibrotic lung

Leukotriene A4 (LTA4) hydrolase catalyzes the final step in leukotriene B4 (LTB4) synthesis. In addition to its role in LTB4 synthesis, the enzyme possesses aminopeptidase activity. In this study, we sought to define the subcellular distribution of LTA4 hydrolase in alveolar epithelial cells, which lack 5-lipoxygenase and do not synthesize LTA4. Immunohistochemical staining localized LTA4 hydrolase in the nucleus of type II but not type I alveolar epithelial cells of normal mouse, human, and rat lungs. Nuclear localization of LTA4 hydrolase was also demonstrated in proliferating type II-like A549 cells. The apparent redistribution of LTA4 hydrolase from the nucleus to the cytoplasm during type II-to-type I cell differentiation in vivo was recapitulated in vitro. Surprisingly, this change in localization of LTA4 hydrolase did not affect the capacity of isolated cells to convert LTA4 to LTB4. However, proliferation of A549 cells was inhibited by the aminopeptidase inhibitor bestatin. Nuclear accumulation of LTA4 hydrolase was also conspicuous in epithelial cells during alveolar repair following bleomycin-induced acute lung injury in mice, as well as in hyperplastic type II cells associated with fibrotic lung tissues from patients with idiopathic pulmonary fibrosis. These results show for the first time that LTA4 hydrolase can be accumulated in the nucleus of type II alveolar epithelial cells and that redistribution of the enzyme to the cytoplasm occurs with differentiation to the type I phenotype. Furthermore, the aminopeptidase activity of LTA4 hydrolase within the nucleus may play a role in promoting epithelial cell growth.     

The effect of methionine on methotrexate metabolism in rat hepatocytes in monolayer culture

The effect of methyl donors on the metabolism of methotrexate has been investigated in rat hepatocytes in monolayer culture. Pulse exposure to low concentrations of methotrexate (1 microM, 3h) in the absence of methionine results in the facile formation of the di- to pentaglutamates with the di- and triglutamate predominating. Further incubation after the removal of methotrexate (MTX) results in a shift to the tetra- and pentaglutamate at the expense of the shorter chain length derivatives. The same measurement in the presence of 1 mM methionine causes approx. an 80% inhibition in the formation of polyglutamates. This effect can be partially achieved when methionine is replaced by choline or betaine. No alteration in the formation of 7-hydroxymethotrexate could be detected by similar changes in methionine concentrations in the medium. The activity of the enzymes which synthesize and degrade methotrexate polyglutamates, folylpolyglutamate synthetase and gamma-glutamyl hydrolase, respectively, were the same in extracts of cells grown in the absence and in the presence of 1 mM methionine. Incubation of the hepatocytes with methionine causes a significant increase in 5,6,7,8-tetrahydrofolate (H4folate), 5,10-methylenehydrofolate and 10-formyltetrahydrofolate and a decrease in 5-methyltetrahydrofolate. These results suggest that the inhibition of glutamylation of methotrexate could be due in part to an elevation in reduced folates which can more effectively compete with methotrexate as a substrate for folylpolyglutamate synthetase. Inhibition in methotrexate glutamylation by methionine, betaine and choline in hepatocytes may contribute to the alleviation of hepatic toxicity by methyl donors.     

Combined effect of epinephrine and chalone extracted from Ehrlich ascites carcinoma administered during different time of day on cell division in the tumor

The biphasic circadian rhythm of mitotic activity has been demonstrated in a 5-day Ehrlich's ascites carcinoma (EAC) in mice. Adrenaline injected intraperitoneally in a dose of 1.5 micrograms/g bw produced an inhibitory effect on cell division that lasted over 4 hours and reached maximum at injection to mice during light time of the day. EAC extract in a dose of 1 ml also inhibited the mitosis during 4 hours, but the greatest fall in the mitotic activity was observed during the minimum mitotic activity in the control animals. Combined administration of adrenaline and the extract resulted in the phenomenon of prolonged inhibition of cell division, that persisted for maximum 6-8 hours, if the preparations were injected in the middle of the day light time. Of definite importance was the rhythm of changes in the sensitivity of proliferating tumor cells.     

Development and characteristics of a subline of Ehrlich ascites carcinoma cells persistently resistant to 5-fluoro-2'-deoxyuridine

A subline of Ehrlich ascites carcinoma (EAC) cells resistant to 5-fluoro-2'-deoxy-uridine (FdUrd) was developed by continuous exposure to progressively increasing concentrations of the drug (35-75 mg/kg per day) during 15 passages through mice. Since then, the EAC cells have been retransplanted more than 80 times through drug-untreated mice and continue to be resistant. After adaptation to growth in suspension culture the drug-adapted cells were 1000 times more resistant to FdUrd in comparison with parental ones, and remained near-tetraploid with doubling time longer than in parental line. The activity of thymidine kinase was deeply depressed (100-fold) whereas that of thymidylate synthetase several-fold increased in the resistant EAC cells, both grown in vivo and in vitro.     

Uncoupling the enzymatic and autoprocessing activities of Helicobacter pylori gamma-glutamyltranspeptidase

Gamma-glutamyltranspeptidase (gammaGT), a member of the N-terminal nucleophile hydrolase superfamily, initiates extracellular glutathione reclamation by cleaving the gamma-glutamyl amide bond of the tripeptide. This protein is translated as an inactive proenzyme that undergoes autoprocessing to become an active enzyme. The resultant N terminus of the cleaved proenzyme serves as a nucleophile in amide bond hydrolysis. Helicobacter pylori gamma-glutamyltranspeptidase (HpGT) was selected as a model system to study the mechanistic details of autoprocessing and amide bond hydrolysis. In contrast to previously reported gammaGT, large quantities of HpGT were expressed solubly in the inactive precursor form. The 60-kDa proenzyme was kinetically competent to form the mature 40- and 20-kDa subunits and exhibited maximal autoprocessing activity at neutral pH. The activated enzyme hydrolyzed the gamma-glutamyl amide bond of several substrates with comparable rates, but exhibited limited transpeptidase activity relative to mammalian gammaGT. As with autoprocessing, maximal enzymatic activity was observed at neutral pH, with hydrolysis of the acyl-enzyme intermediate as the rate-limiting step. Coexpression of the 20- and 40-kDa subunits of HpGT uncoupled autoprocessing from enzymatic activity and resulted in a fully active heterotetramer with kinetic constants similar to those of the wild-type enzyme. The specific contributions of a conserved threonine residue (Thr380) to autoprocessing and hydrolase activities were examined by mutagenesis using both the standard and coexpression systems. The results of these studies indicate that the gamma-methyl group of Thr380 orients the hydroxyl group of this conserved residue, which is required for both the processing and hydrolase reactions.     

Characterization of gamma-glutamyl hydrolase produced by Bacillus sp. isolated from Thai Thua-nao

Gamma-glutamyl hydrolase with a molecular mass of 28 kDa was purified from the culture broth of Bacillus sp. isolated from Thai Thua-nao, a natto-like fermented soybean food. The purified enzyme hydrolyzed chemically synthesized oligo-gamma-L-glutamates but not oligo-gamma-D-glutamates and degraded gamma-polyglutamic acid to a hydrolyzed product of only about 20 kDa (with D- and L-glutamic acid in a ratio of 70:30), suggesting that the enzyme is a gamma-glutamyl hydrolase that cleaves the gamma-glutamyl linkage between L- and L-glutamic acid of gamma-polyglutamic acid.     

Distribution of glucose-6-phosphatase activity in normal,hyperplastic, and preneoplastic rat liver

The significance of glucose-6-phosphatase (G6P) expression by bile duct-like cells proliferating during hepatocarcinogenesis in the histogenesis of hepatocellular carcinoma is not clear. To this end, we measured the histochemical and biochemical activity of G6P in normal rat liver, and in rat livers in which bile duct-like proliferation was induced by either hyperplastic (bile duct ligation for 14 days or feeding alpha-naphthylisothiocyanate for 28 days) or neoplastic (feeding a choline-devoid diet containing 0.1% ethionine for 60 days) regimens. In normal, hyperplastic, and preneoplastic livers, G6P histochemical activity was confined to the hepatocytes; proliferated bile duct-like cells, like normal bile ducts, did not display visible G6P staining. When the enzyme activity was determined biochemically, however, hydrolysis of glucose-6-phosphate was observed in both parenchymal and nonparenchymal liver cells isolated from all experimental animals. In elutriated nonparenchymal fractions, G6P activity was directly proportional to the number of cells positive for gamma-glutamyl transpeptidase and cytokeratin no. 19 (markers of bile duct cells) and inversely proportional to the number of cells positive for vimentin (marker of mesenchymal cells). These results indicate that, while by light microscopy hepatic G6P histochemical activity is detectable only in the hepatocytes, the biochemical activity is also expressed in proliferating bile duct-like cells. However, the nonparenchymal activity is observed during both neoplastic and hyperplastic liver growth, thus indicating that the presence of this enzyme in bile duct-like cells proliferating during hepatocarcinogenesis should not necessarily be construed as supporting their stem cell nature nor their neoplastic commitment.     

Distribution of glucose-6-phosphatase activity in normal, hyperplastic, and preneoplastic rat liver.

The significance of glucose-6-phosphatase (G6P) expression by bile duct-like cells proliferating during hepatocarcinogenesis in the histogenesis of hepatocellular carcinoma is not clear. To this end, we measured the histochemical and biochemical activity of G6P in normal rat liver, and in rat livers in which bile duct-like proliferation was induced by either hyperplastic (bile duct ligation for 14 days or feeding alpha-naphthylisothiocyanate for 28 days) or neoplastic (feeding a choline-devoid diet containing 0.1% ethionine for 60 days) regimens. In normal, hyperplastic, and preneoplastic livers, G6P histochemical activity was confined to the hepatocytes; proliferated bile duct-like cells, like normal bile ducts, did not display visible G6P staining. When the enzyme activity was determined biochemically, however, hydrolysis of glucose-6-phosphate was observed in both parenchymal and nonparenchymal liver cells isolated from all experimental animals. In elutriated nonparenchymal fractions, G6P activity was directly proportional to the number of cells positive for gamma-glutamyl transpeptidase and cytokeratin no. 19 (markers of bile duct cells) and inversely proportional to the number of cells positive for vimentin (marker of mesenchymal cells). These results indicate that, while by light microscopy hepatic G6P histochemical activity is detectable only in the hepatocytes, the biochemical activity is also expressed in proliferating bile duct-like cells. However, the nonparenchymal activity is observed during both neoplastic and hyperplastic liver growth, thus indicating that the presence of this enzyme in bile duct-like cells proliferating during hepatocarcinogenesis should not necessarily be construed as supporting their stem cell nature nor their neoplastic commitment.     

Epigenetic regulation of human gamma-glutamyl hydrolase activity in acute lymphoblastic leukemia cells

Gamma-glutamyl hydrolase (GGH) catalyzes degradation of the active polyglutamates of natural folates and the antifolate methotrexate (MTX). We found that GGH activity is directly related to GGH messenger RNA expression in acute lymphoblastic leukemia (ALL) cells of patients with a wild-type germline GGH genotype. We identified two CpG islands (CpG1 and CpG2) in the region extending from the GGH promoter through the first exon and into intron 1 and showed that methylation of both CpG islands in the GGH promoter (seen in leukemia cells from approximately 15% of patients with nonhyperdiploid B-lineage ALL) is associated with significantly reduced GGH mRNA expression and catalytic activity and with significantly higher accumulation of MTX polyglutamates (MTXPG(4-7)) in ALL cells. Furthermore, methylation of CpG1 was leukemia-cell specific and had a pronounced effect on GGH expression, whereas methylation of CpG2 was common in leukemia cells and normal leukocytes but did not significantly alter GGH expression. These findings indicate that GGH activity in human leukemia cells is regulated by epigenetic changes, in addition to previously recognized genetic polymorphisms and karyotypic abnormalities, which collectively determine interindividual differences in GGH activity and influence MTXPG accumulation in leukemia cells.     

Lactate dehydrogenase-elevating agent is responsible for interferon induction and enhancement of natural killer cell activity by inoculation of Ehrlich ascites carcinoma cells into mice

Inoculation of Ehrlich ascites carcinoma cells (EAC) into the peritoneal cavities of outbred ddY mice induced interferon (IFN) in the circulation. The maximum titer (1,280 U) was obtained at 24 hr after inoculation. This induced IFN had the characteristics of type I IFN, i.e., stability at pH2 and lability at 56 C. An increase in natural killer cell (NK) activity was also observed for the first 3 days after inoculation. In addition, plasma lactate dehydrogenase (LDH) activity was elevated in these mice. Inoculation of ascitic fluid or serum of EAC-bearing mice into normal mice increased plasma LDH activity six- to sevenfold over normal levels and elevated activities persisted throughout the life of the mice. These results suggest that the LDH-elevating agent was responsible for IFN induction and for enhancing NK activity. Because lactate dehydrogenase-elevating virus (LDV) can be eliminated from tumor cells by passage in vitro, we attempted to grow EAC in tissue culture for several months and re-examined whether the inoculation of such cells could elevate plasma LDH activity induce IFN and enhance NK activity. The results showed that inoculation of the passaged cells had no effect on these activities in normal mice. Therefore, we concluded that the IFN inducer was LDV which contaminated the EAC and then enhanced the NK activity. N-tropic murine leukemia virus also contaminated EAC, but this virus was not responsible because cultured cells of EAC still shed this virus.     

gamma-Glutamyl transpeptidase in rat liver during 3'-Me-DAB hepatocarcinogenesis: immunohistochemical and enzyme histochemical study

Immunohistochemical localization of gamma-glutamyl transpeptidase (gamma-GTP) in rat liver during 3'-methyl-4-dimethylaminoazobenzene (3'-Me-DAB) hepatocarcinogenesis was investigated and compared with sites of gamma-GTP activity. Immunohistochemically, gamma-GTP was stained in the apical border of proliferating oval cells during the early stages of azo-dye carcinogen feeding. After 7 weeks, multiple hyperplastic nodules appeared in which gamma-GTP was localized in the bile canaliculi. In hepatoma tissues, positive staining for gamma-GTP was observed in the bile canaliculi-like spaces, on the cell membrane, and sometimes in the cytoplasm of malignant cells. Enzyme histochemical staining showed gamma-GTP activity to be present in almost the same areas as the immunoreactive gamma-GTP. However, some areas adjacent to hepatoma tissue showed immunohistochemically reactive protein but no enzyme activity. Immunoreactive gamma-GTP was present in all locations at which enzyme activity was seen. The present data suggest that an altered form of gamma-GTP might be present in tissues during 3'-Me-DAB hepatocarcinogenesis.     

Three-dimensional structure of human gamma -glutamyl hydrolase. A class I glatamine amidotransferase adapted for a complex substate

gamma-Glutamyl hydrolase catalyzes the cleavage of the gamma-glutamyl chain of folylpoly-gamma-glutamyl substrates and is a central enzyme in folyl and antifolyl poly-gamma-glutamate metabolism. The crystal structure of human gamma-glutamyl hydrolase, determined at 1.6-A resolution, reveals that the protein is a homodimer. The overall structure of human gamma-glutamyl hydrolase contains 11 alpha-helices and 14 beta-strands, with a fold in which a central eight-stranded beta-sheet is sandwiched by three and five alpha-helices on each side. The topology is very similar to that of the class I glutamine amidotransferase domains, with the only major differences consisting of extensions in four loops and at the C terminus. These insertions are important for defining the substrate binding cleft and/or the dimer interface. Two sequence motifs are found in common between human gamma-glutamyl hydrolase and the class I glutamine amidotransferase family and include the catalytically essential residues, Cys-110 and His-220. These residues are located in the center of a large l-shaped cleft that is closed at one end and open at the other. Several conserved residues, including Glu-114, His-171, Gln-218, and Lys-223, may be important for substrate binding. Modeling of a methotrexate thioester intermediate, based on the corresponding complex of the glutamate thioester intermediate of Escherichia coli carbamoyl-phosphate synthetase, indicates that the substrate binds in an orientation with the pteroyl group toward the open end of the cleft.     

Cytosolic epoxide hydrolase

Epoxide hydrolase activity is recovered in the high-speed supernatant fraction from the liver of all mammals so far examined, including man. For some as yet unexplained reason, the rat has a very low level of this activity, so that cytosolic epoxide hydrolase is generally studied in mice. This enzyme selectively hydrolyzes trans epoxides, thereby complementing the activity of microsomal epoxide hydrolase, for which cis epoxides are better substrates. Cytosolic epoxide hydrolase has been purified to homogeneity from the livers of mice, rabbits and humans. Certain of the physicochemical and enzymatic properties of the mouse enzyme have been thoroughly characterized. Neither the primary amino acid, cDNA nor gene sequences for this protein are yet known, but such characterization is presently in progress. Unlike microsomal epoxide hydrolase and most other enzymes involved in xenobiotic metabolism, cytosolic epoxide hydrolase is not induced by treatment of rodents with substances such as phenobarbital, 2-acetylaminofluorene, trans-stilbene oxide, or butylated hydroxyanisole. The only xenobiotics presently known to induce cytosolic epoxide hydrolase are substances which also cause peroxisome proliferation, e.g., clofibrate, nafenopin and phthalate esters. These and other observations indicate that this enzyme may actually be localized in peroxisomes in vivo and is recovered in the high-speed supernatant because of fragmentation of these fragile organelles during homogenization, i.e., recovery of this enzyme in the cytosolic fraction is an artefact. The functional significance of cytosolic epoxide hydrolase is still largely unknown. In addition to deactivating xenobiotic epoxides to which the organism is exposed directly or which are produced during xenobiotic metabolism, primarily by the cytochrome P-450 system, this enzyme may be involved in cellular defenses against oxidative stress.     

Human kidney gamma-glutamyl transpeptidase. Catalytic properties, subunit structure, and localization of the gamma-glutamyl binding site on the light subunit.

Human kidney gamma-glutamyl transpeptidase has been purified by a procedure involving Lubrol extraction, acetone precipitation, treatment with bromelain, and column chromatography on DEAE-cellulose and Sephadex G-150. The final preparation is a glycoprotein (molecular weight of approximately 84,000) composed of two nonidentical glycopeptides (molecular weights of 62,000 and 22,000). The isozymic forms, separable by isoelectric focusing, have different contents of sialic acid. The utilization of L-glutamine (which is both a gamma-glutamyl donor and acceptor) is stimulated about 3-fold by maleate in contrast to 10-fold stimulation of glutamine utilization by the rat kidney enzyme. The gamma-glutamyl analogs, 6-diazo-5-oxo-L-norleucine (DON) and L-azaserine inactivate the human kidney enzyme with respect to its transpeptidase and hydrolase activities. Inactivation is prevented by gamma-glutamyl substrates (but not by acceptor substrates) and is accelerated by maleate. [14C]DON reacts covalently and stoichiometrically at the gamma-glutamyl site, which was localized to the light subunit of the enzyme. The light subunit of human transpeptidase closely resembles that of rat kidney enzyme in having the gamma-glutamyl binding site, and similar molecular weight and amino acid composition. The heavy subunits of the two enzymes are markedly different in both molecular weight and amino acid content; this may account for differences observed in acceptor amino acid specificity and in the magnitude of the maleate effect.     

Effects of Mg2+ and adenine nucleotides on thymidylate synthetase from different mouse tumors

Summary Magnesium ions variably influenced activity of highly purified thymidylate synthetase preparations from different mouse tumors, activating the enzyme from Ehrlich ascites carcinoma (EAC) cells and inhibiting the enzyme from L1210 and L5178Y cells and from 5-fluorodeoxyuridine (FdUrd)-resistant EAC cells. In the presence of Mg²⁺ in a concentration resulting in either maximum activation or inhibition (25–30 mM) the enzymes from both the sensitive and FdUrd-resistant EAC lines and L5178Y cells were activated by ATP. Under the same conditions of Mg²⁺ concentration ADP and AMP inhibited the enzyme from the parental but not from the FdUrd-resistant EAC cells.     

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.     

Characterization of the folate salvage enzyme p-aminobenzoylglutamate hydrolase in plants

Folates break down in vivo to give pterin and p-aminobenzoylglutamate (pABAGlu) fragments, the latter usually having a polyglutamyl tail. Pilot studies have shown that plants can hydrolyze pABAGlu and its polyglutamates to p-aminobenzoate, a folate biosynthesis precursor. The enzymatic basis of this hydrolysis was further investigated. pABAGlu hydrolase activity was found in all species and organs tested; activity levels implied that the proteins responsible are very rare. The activity was located in cytosol/vacuole and mitochondrial fractions of pea (Pisum sativum L.) leaves, and column chromatography of the activity from Arabidopsis tissues indicated at least three peaks. A major activity peak from Arabidopsis roots was purified 86-fold by a three-column procedure; activity loss during purification exceeded 95%. Size exclusion chromatography gave a molecular mass of approximately 200 kDa. Partially purified preparations showed a pH optimum near 7.5, a Km value for pABAGlu of 370 microM, and activity against folic acid. Activity was relatively insensitive to thiol and serine reagents, but was strongly inhibited by 8-hydroxyquinoline-5-sulfonic acid and stimulated by Mn2+, pointing to a metalloenzyme. The Arabidopsis genome was searched for proteins similar to Pseudomonas carboxypeptidase G, which contains zinc and is the only enzyme yet confirmed to attack pABAGlu. The sole significant matches were auxin conjugate hydrolase family members and the At4g17830 protein. None was found to have significant pABAGlu hydrolase activity, suggesting that this activity resides in hitherto unrecognized enzymes. The finding that Arabidopsis has folate-hydrolyzing activity points to an enzymatic component of folate degradation in plants.