The covalent structure of hepatic microsomal epoxide hydrolase. I. Isolation and characterization of the cyanogen bromide fragments

Microsomal epoxide hydrolase was purified to homogeneity from phenobarbital-induced rabbit liver for the purpose of determining the complete amino acid sequence. All of the expected 11 cyanogen bromide fragments of epoxide hydrolase were isolated by a combination of gel filtration and high pressure liquid chromatography. Each was characterized by its amino acid composition and NH2-terminal amino acid sequence. The complete amino acid sequences of the eight small fragments, from 5-29 residues, were determined.     

Complementary DNA and amino acid sequence of rat liver microsomal, xenobiotic epoxide hydrolase

The coding nucleotide sequence for rat liver microsomal, xenobiotic epoxide hydrolase was determined from two overlapping cDNA clones, which together contain 1750 nucleotides complementary to epoxide hydrolase mRNA. The single open reading frame of 1365 nucleotides codes for a 455 amino acid polypeptide with a molecular weight of 52,581. The deduced amino acid composition agrees well with those determined by direct amino acid analysis of the rat protein, and the amino acid sequence is 81% identical to that of rabbit epoxide hydrolase. Analysis of codon usage for epoxide hydrolase, and that of rabbit epoxide hydrolase. Analysis of codon usage for epoxide hydrolase, and comparison to codon usage for NADPH-cytochrome P-450 oxidoreductase and cytochromes P-450b, P-450d, and P-450PCN, suggest that epoxide hydrolase is more conserved than cytochromes P-450b and P-450PCN; comparison of the extent of sequence conservation for 12 homologous proteins between the rat and rabbit, including cytochrome P-450b, supports this hypothesis, and indicates that much of epoxide hydrolase is constrained to maintain its hydrophobic character, consistent with its intramembranous location. The predicted membrane topology of epoxide hydrolase delineates 6 membrane-spanning segments, less than the 8 or 10 predicted for two cytochrome P-450 isozymes; the lower number of membrane-spanning segments predicted for epoxide hydrolase correlates with its lesser dependence on the membrane for maintenance of its tertiary structure and catalytic activity.     

Human microsomal xenobiotic epoxide hydrolase. Complementary DNA sequence, complementary DNA-directed expression in COS-1 cells, and chromosomal localization

A lambda gt11 expression library constructed from human liver mRNA was screened with an antibody against human microsomal xenobiotic epoxide hydrolase. The clone pheh32 contains an insert of 1742 base pairs with an open reading frame coding for a protein of 455 amino acids with a calculated Mr of 52,956. The nucleotide sequence is 77% similar to the previously reported rat xenobiotic epoxide hydrolase cDNA sequence. The deduced amino acid sequence of the human epoxide hydrolase is 80% similar to the previously reported rabbit and 84% similar to the deduced rat protein sequence. The NH2-terminal amino acids deduced from the human xenobiotic epoxide hydrolase cDNA are identical to the published 19 NH2-terminal amino acids of the purified human xenobiotic epoxide hydrolase protein. Northern blot analysis revealed a single mRNA band of 1.8 kilobases. Southern blot analysis indicated that there is only one gene copy/haploid genome. The human xenobiotic epoxide hydrolase gene was assigned to the long arm of human chromosome 1. Several restriction fragment length polymorphisms were observed with the human epoxide hydrolase cDNA. pheh32 was expressed as enzymatically active protein in cultured monkey kidney cells (COS-1).     

Leukotriene A4 hydrolase in human leukocytes. Purification and properties

Leukotriene A4 hydrolase, a soluble enzyme catalyzing hydrolysis of the allylic epoxide leukotriene A4 to the dihydroxy acid leukotriene B4, was purified to apparent homogeneity from human leukocytes. The enzymatic reaction obeyed Michaelis-Menten saturation kinetics with respect to varying concentrations of leukotriene A4. An apparent KM value ranging between 20 and 30 microM was deduced from Eadie-Hofstee plots. Physical properties including molecular weight (68,000-70,000), amino acid composition, and aminoterminal sequence were determined. It was indicated that leukotriene A4 hydrolase is a monomeric protein, distinct from previously described epoxide hydrolases in liver.     

Guinea-pig liver leukotriene A4 hydrolase. Purification, characterization and structural properties

Leukotriene A4 hydrolase from perfused guinea-pig liver was purified 1200-fold to near homogeneity with a yield of about 20%. Apparent values of Km and Vmax at 37 degrees C (27 microM and 68 mumol x mg-1 x min-1), turnover number, and activation energy for the conversion of leukotriene A4 into leukotriene B4 were estimated from kinetic data obtained at -10 degrees C, 0 degree C and +10 degrees C (Arrhenius plots). Physical properties including Mr (67,000-71,000), pH optimum, isoelectric point and Stokes' radius were determined. The amino acid composition and N-terminal amino acid sequence were established after carboxymethylation of the enzyme. Unlike liver cytosolic epoxide hydrolase, the purified enzyme did not catalyze the conversion of leukotriene A4 into (5S,6R)-5,6-dihydroxy-7,9-trans-11,14-cis-icosatetraenoic acid.     

Cloning, expression, purification, and characterization of a novel epoxide hydrolase from Aspergillus niger SQ-6

A novel epoxide hydrolase from Aspergillus niger SQ-6 has now been cloned by inverse PCR. Its gene shows eight exons including a non-coding exon at its 5'-terminal (GenBank Accession No. AY966486). Phylogenetic analysis using deduced amino acid sequence (395 aa) confirms it as an epoxide hydrolase and shares 58.3% identity with that of A. niger LCP521 (GenBank Accession No. AF238460). The predicted catalytic triad is composed of Asp(191), His(369) and Glu(343). Active recombinant epoxide hydrolase has been successfully expressed in Escherichia coli as protein fusions with a poly-His tail. Scale-up fermentation can yield 2.5g/L of recombinant protein. The electrophoretic pure recombinant protein, which shows similar characterization as natural enzyme purified from A. niger SQ-6, can be easily purified by Ni(2+)-chelated affinity and gel-filtration chromatography. Optimal pH and temperature for purified enzyme are pH 7.5 and 37 degrees C, respectively. The K(m), k(cat) and maximal velocity (V(max)) for p-nitrostyrene oxide are determined to be 1.02mM, 172s(-1) and 231micromol min(-1)mg(-1), respectively. The enzyme can be inhibited by oxidant (H(2)O(2)), solvent (Tetrahydrofuran) and several metal ions including Hg(2+), Fe(2+) and Co(2+). This (R)-stereospecific epoxide hydrolase exhibits high enantioselectivity (enantiomeric excess value, 99%) for the less hindered carbon atom of epoxide. It may be an industrial biocatalyst for the preparation of enantiopure epoxides or vicinal diols.     

Cloning of an epoxide hydrolase-encoding gene from Aspergillus niger M200, overexpression in E. coli, and modification of activity and enantioselectivity of the enzyme by protein engineering

The gene encoding an epoxide hydrolase from Aspergillus niger M200 has been cloned and its sequence determined. The gene is interrupted by seven introns, one exon being only nine nucleotides long. The non-coding 5'- and 3'-regions of the mRNA are composed of 47 and 76 nucleotides, respectively. Overexpression of the fungal epoxide hydrolase in E. coli TOP10 has led to a 15-fold increase in specific activity (compared to the wild-type strain). Saturation mutagenesis at codon 217 resulted in the discovery of nine enzyme variants showing in several cases profound differences in activity and enantioselectivity towards various epoxides when compared to the data of the wild-type enzyme. The site 217 is located at the entrance of the tunnel that provides the substrate with access to the active site. The exchange of Ala at this position for Cys has led to a doubled enantioselectivity (E-value of 5.0) towards benzyl glycidyl ether. The same substitution resulted in a threefold-enhanced activity of the enzyme towards allyl glycidyl ether and styrene oxide without affecting enantioselectivity. The variant A217L showed an enhanced enantioselectivity towards tert-butyl glycidyl ether reaching an E-value of 100 (from 60 for the wild-type enzyme). Replacement of A217 by Val has led to higher activity towards allyl glycidyl ether by a factor of six. The substitutions Ala-->Glu and Ala-->Gln increased the enantioselectivity towards allyl glycidyl ether and styrene oxide by over 50% to E-values of 10 and 16, respectively. The study underlines that single amino acid exchanges in the substrate tunnel region can lead to significant improvements in enantioselectivity and activity of the epoxide hydrolase from A. niger M200.     

Enzymic conversion of 11,12-leukotriene A4 to 11,12-dihydroxy-5,14-cis-7,9-trans-eicosatetraenoic acid. Purification of an epoxide hydrolase from the guinea pig liver cytosol

(11S,12S)-Epoxy-5,14-cis-7,9-trans-eicosatetraenoic acid (11,12-leukotriene A4) was nonenzymically converted to seven compounds: two diastereomers of (12S)-hydroxyeicosatetraeno-delta-lactones (major products), two diastereomers of (5,12S)-dihydroxyeicosatetraenoic acid and three stereoisomers of (11,12S)-dihydroxyeicosatetraenoic acid. Among these compounds, (11R,12S)-dihydroxy-5,14-cis-7,9-trans-eicosatetraenoic acid proved to be the only enzymic product. This hydrolysis activity was present in the cytosol fractions of various tissues of guinea pig such as liver, adrenal gland, small intestine, and brain. We purified the epoxide hydrolase to an apparent homogeneity from the guinea pig liver. The enzyme had a molecular weight of 60,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and an isoelectric point of 7.3. The partial amino acid sequence was different from that of the microsomal enzyme. Km and Vmax values for 11,12-leukotriene A4 were 18 microM and 2.4 mumol/min/mg protein, respectively. These results indicate that 11,12-dihydroxyeicosatetraenoic acid is enzymically synthesized from 11,12-leukotriene A4 by the action of the cytosolic epoxide hydrolase in vitro.     

The complete amino acid sequence of diphtheria toxin fragment B. Correlation with its lipid-binding properties

The complete amino acid sequence of fragment B from diphtheria toxin has been determined. The polypeptide chain was split with cyanogen bromide, o-iodosobenzoic acid, clostripain and trypsin; all amino acid sequence analyses were made by automated Edman degradation. Fragment B, which corresponds to the carboxy terminus of the toxin molecule, contains 342 amino acids and has an Mr of 37240. The proposed amino acid sequence fully confirms the structure recently deduced from the nucleotide sequence of the structural gene. The complete sequence is analyzed in relationship with the role of fragment B in the transfer of diphtheria toxin fragment A from the extracellular medium into the cell cytoplasm.     

The amino acid sequence of Escherichia coli cyanase

The amino acid sequence of the enzyme cyanase (cyanate hydrolase) from Escherichia coli has been determined by automatic Edman degradation of the intact protein and of its component peptides. The primary peptides used in the sequencing were produced by cyanogen bromide cleavage at the methionine residues, yielding 4 peptides plus free homoserine from the NH2-terminal methionine, and by trypsin cleavage at the 7 arginine residues after acetylation of the lysines. Secondary peptides required for overlaps and COOH-terminal sequences were produced by chymotrypsin or clostripain cleavage of some of the larger peptides. The complete sequence of the cyanase subunit consists of 156 amino acid residues (Mr 16,350). Based on the observation that the cysteine-containing peptide is obtained as a disulfide-linked dimer, it is proposed that the covalent structure of cyanase is made up of two subunits linked by a disulfide bond between the single cystine residue in each subunit. The native enzyme (Mr 150,000) then appears to be a complex of four or five such subunit dimers.     

Isolation and characterization of the epoxide hydrolase-encoding gene from Xanthophyllomyces dendrorhous

The epoxide hydrolase (EH)-encoding gene (EPH1) from the basidiomycetous yeast Xanthophyllomyces dendrorhous was isolated. The genomic sequence has a 1,236-bp open reading frame which is interrupted by eight introns that encode a 411-amino-acid polypeptide with a calculated molecular mass of 46.2 kDa. The amino acid sequence is similar to that of microsomal EH and belongs to the alpha/beta hydrolase fold family. The EPH1 gene was not essential for growth of X. dendrorhous in rich medium under laboratory conditions. The Eph1-encoding cDNA was functionally expressed in Escherichia coli. A sixfold increase in specific activity was observed when we used resting cells rather than X. dendrorhous. The epoxides 1,2-epoxyhexane and 1-methylcyclohexene oxide were substrates for both native and recombinant Eph1. Isolation and characterization of the X. dendrorhous EH-encoding gene are essential steps in developing a yeast EH-based epoxide biotransformation system.     

Amino acid sequence studies on sheep liver fructose-bisphosphatase. II. The complete sequence

The cyanogen bromide fragments of S-carboxymethylated fructose-bisphosphatase were purified. The amino acid sequences of the small fragments were determined by the dansyl-Edman method. The large fragments were subjected to proteolytic digestion to give smaller peptides more amenable for purification and sequencing by similar methods. Enzyme digests of the S-carboxymethylated enzyme gave overlap peptides containing the methionine residues. In conjunction with the amino acid sequence of the 60-residue N-terminal fragment previously determined on the S-peptide released by limited proteolysis with subtilisin the complete sequence of 336 residues was deduced. The sequence has been compared with the 335 residue sequence of pig kidney fructose-bisphosphatase and some areas of sequence for rabbit liver enzyme. The strong homology previously noted for the S-peptide sequence is maintained for the complete enzyme with only 34 changes in 336 residues when comparing the pig and sheep enzymes.     

Structure and organization of the microsomal xenobiotic epoxide hydrolase gene

The gene for the microsomal xenobiotic rat liver epoxide hydrolase has been isolated and characterized. Clones were obtained from a Wistar Furth Charon 35 genomic library by hybridization with a full-length epoxide hydrolase cDNA. The gene for the xenobiotic epoxide hydrolase is approximately 16 kilobases in length and consists of 9 exons ranging in size from 109 to 420 base pairs and 8 intervening sequences, the largest of which is 3.2 kilobases. S1-nuclease mapping, primer extension studies, and sequence analysis were used to determine the 5' cap site and the size of the first exon (170 base pairs). Regulatory sequences analogous to TATA, CCAAT, and core enhancer sequences were noted in the 5'-flanking region of the gene. The cDNA and gene for epoxide hydrolase displayed nucleotide sequence identity although they were isolated from different rat strains. Also, Southern blot analysis of restricted liver DNA from inbred Fischer 344 and Wistar Furth rat strains, and outbred Sprague-Dawley rats indicated a high degree of structural similarity for the epoxide hydrolase gene within these three strains. Only a single functional epoxide hydrolase gene was identified and no evidence of hybridization to the genes for the microsomal cholesterol epoxide hydrolase or the cytosolic epoxide hydrolase was observed. However, a pseudogene for the microsomal xenobiotic epoxide hydrolase was isolated and characterized from the genomic library.     

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.     

保幼激素的代谢

保幼激素的代谢由保幼激素酯酶、保幼激素环氧水解酶和保幼激素二醇激酶等共同催化完成。在这些代谢酶的作用下,保幼激素代谢成保幼激素酸、保幼激素二醇、保幼激素酸二醇和保幼激素二醇磷酸。作者总结了保幼激素代谢的研究方法;按实验室和昆虫种类为线索,归纳和概括了每一种保幼激素代谢酶的研究进程;对保幼激素酯酶和保幼激素环氧水解酶作了序列分析;最后对保幼激素的代谢研究进行了展望。     

Nucleotide sequence and expression of clcD, a plasmid-borne dienelactone hydrolase gene from Pseudomonas sp. strain B13.

The clcD structural gene encodes dienelactone hydrolase (EC 3.1.1.45), an enzyme that catalyzes the conversion of dienelactones to maleylacetate. The gene is part of the clc gene cluster involved in the utilization of chlorocatechol and is carried on a 4.3-kilobase-pair BglII fragment subcloned from the Pseudomonas degradative plasmid pAC27. A 1.9-kilobase-pair PstI-EcoRI segment subcloned from the BglII fragment was shown to carry the clcD gene, which was expressed inducibly under the tac promoter at levels similar to those found in 3-chlorobenzoate-grown Pseudomonas cells carrying the plasmid pAC27. In this study, we present the complete nucleotide sequence of the clcD gene and the amino acid sequence of dienelactone hydrolase deduced from the DNA sequence. The NH2-terminal amino acid sequence encoded by the clcD gene from plasmid pAC27 corresponds to a 33-residue sequence established for dienelactone hydrolase encoded by the Pseudomonas sp. strain B13 plasmid pWR1. A possible relationship between the clcD gene and pcaD, a Pseudomonas putida chromosomal gene encoding enol-lactone hydrolase (EC 3.1.1.24) is suggested by the fact that the gene products contain an apparently conserved pentapeptide neighboring a cysteinyl side chain that presumably lies at or near the active sites; the cysteinyl residue occupies position 60 in the predicted amino acid sequence of dienelactone hydrolase.     

Amino acid sequence of S-adenosyl-L-homocysteine hydrolase from Dictyostelium discoideum as deduced from the cDNA sequence

S-Adenosyl-L-homocysteine hydrolase has been cloned from a lambda gt11 cDNA library prepared from Dictyostelium discoideum that had been starved for 3 hours. The sequence of the cloned cDNA was determined and the deduced amino acid sequence was compared to the amino acid sequence of rat AdoHcy hydrolase. When the sequences from the two species were aligned, 74% of the amino acids were in identical positions. If conservative changes were taken into account the homology was 84%. Because differences have been reported in the binding characteristics of NAD+ to the D. discoideum and rat AdoHcy hydrolases, changes in the amino acids of the putative NAD+-binding site were of particular interest. Six changes were observed in this region but the changes appeared to be in regions that are not critical to the three dimensional folding of the NAD+-binding site.     

Primary structure of human alpha1-protease inhibitor. The complete amino acid sequence of cyanogen bromide fragment II.

The complete amino acid sequence of a CNBr-fragment from human alpha1-protease inhibitor has been determined and is shown below. The peptide consists of 109 amino acid residues with 1 oligosaccharide unit. The 2 glutamic acid residues which have previously been shown to be substituted by lysine in the Z and by valine in the S mutant proteins are both located in this CNBr fragment. (formula: see text).     

Cloning and characterization of an epoxide hydrolase-encoding gene from Rhodotorula glutinis

We cloned and characterized the epoxide hydrolase gene, EPH1, from Rhodotorula glutinis. The EPH1 open reading frame of 1230 bp was interrupted by nine introns and encoded a polypeptide of 409 amino acids with a calculated molecular mass of 46.3 kDa. The amino acid sequence was similar to that of microsomal epoxide hydrolase, which suggests that the epoxide hydrolase of R. glutinis also belongs to the α/β hydrolase fold family. EPH1 cDNA was expressed in Escherichia coli and resting cells showed a specific activity of 200 nmol min⁻¹ (mg protein)⁻¹ towards 1,2-epoxyhexane. Received: 2 August 1999 / Received revision: 4 October 1999 / Accepted: 10 October 1999