Cytosolic hydrolase

Hydration of epoxides catalyzed by epoxide hydrolase is involved in both detoxication and intoxication reactions. With high concentrations of styrene oxide as a substrate, the relative activity of hepatic microsomal epoxide hydrolase in several animal species is rhesus monkey > human = guinea pig > rabbit > rat > mouse. With some substrates, such as epoxidized lipids, the cytosolic hydrolase may be much more important than the microsomal enzyme. 

Potential enzymes involved in anthocyanin metabolism — The lactase phlorizin hydrolase (LPH EC 3.2.1.108) present only in the small intestine on the outside of the brush border membrane and the cytosolic P-glucosidase (CBG EC 3.2.1.1) found in many tissues, particularly in liver, can catalyze the deglycosylation (or hydrolysis) of polyphenols. LPH may play a major role in polyphenol metabolism... 

EE Sterchi, JF Woodley. Peptide hydrolases of the human small intestinal mucosa Distribution of activities between brush border membranes and cytosol. Clin Chim... 

It should be noted that as early as 1993, Kurth and coworkers investigated the enzymatic transformation of bis-epoxides of type 8-51 using cytosolic epoxide hydrolase from rat liver. However, at that time the regio- and stereochemistry of the obtained THFs had not been investigated. 

Drugs may also undergo hydrolysis by intestinal esterases (hydrolases), more specifically carboxylesterases (EC 3.1.1.1) in the intestinal lumen and at the brush border membrane [58, 59]. It has been shown that intestinal hydrolase activity in humans was closer to that of the rat than the dog or Caco-2 cells [60]. In these studies, six propranolol ester prodrugs and p-nitrophenylacetate were used as substrates, and the hydrolase activity found was ranked in the order human > rat Caco-2 cells > dog for intestinal microsomes. The rank order in hydrolase activity for the intestinal cytosolic fraction was rat > Caco-2 cells = human > dog. The hydrolase activity towards p-nitrophenylacetate and tenofovir disoproxil has also been reported in various intestinal segments from rats, pigs and humans. The enzyme activity in intestinal homogenates was found to be both site-specific (duodenum > jejunum > ileum > colon) and species-dependent (rat > man > Pig)-... 

The overall metabolism of vitamin A in the body is regulated by esterases. Dietary retinyl esters are hydrolyzed enzymatically in the intestinal lumen, and free retinol enters the enterocyte, where it is re-esterified. The resulting esters are then packed into chylomicrons delivered via the lymphatic system to the liver, where they are again hydrolyzed and re-esterified for storage. Prior to mobilization from the liver, the retinyl esters are hydrolyzed, and free retinol is complexed with the retinol-binding protein for secretion from the liver [101]. Different esterases are involved in this sequence. Hydrolysis of dietary retinyl esters in the lumen is catalyzed by pancreatic sterol esterase (steryl-ester acylhydrolase, cholesterol esterase, EC 3.1.1.13) [102], A bile salt independent retinyl-palmitate esterase (EC 3.1.1.21) located in the liver cell plasma hydrolyzes retinyl esters delivered to the liver by chylomicrons. Another neutral retinyl ester hydrolase has been found in the nuclear and cytosolic fractions of liver homogenates. This enzyme is stimulated by bile salts and has properties nearly identical to those observed for... 

A variety of hydrolases catalyze the hydrolysis of acetylsalicylic acid. In humans, high activities have been seen with membrane-bound and cytosolic carboxylesterases (EC 3.1.1.1), plasma cholinesterase (EC 3.1.1.8), and red blood cell arylesterases (EC 3.1.1.2), whereas nonenzymatic hydrolysis appears to contribute to a small percentage of the total salicylic acid formed [76a] [82], A solution of serum albumin also displayed weak hydrolytic activity toward the drug, but, under the conditions of the study, binding to serum albumin decreased chemical hydrolysis at 37° and pH 7.4 from tm 12 1 h when unbound to 27 3 h for the fully bound drug [83], In contrast, binding to serum albumin increased by >50% the rate of carboxylesterase-catalyzed hydrolysis, as seen in buffers containing the hydrolase with or without albumin. It has been postulated that either bound acetylsalicylic acid is more susceptible to enzyme hydrolysis, or the protein directly activates the enzyme. 

According to biochemical separation, location, and substrate specificity, epoxide hydrolases (EH) have been divided into a number of groups. In mammals, the insoluble microsomal epoxide hydrolases and the soluble cytosolic epoxide hydrolases are enzymes of broad and complementary substrate specificity. 

The human cytosolic epoxide hydrolase (cytosolic EH, cEH, also known as soluble EH) has 554 amino acids (Mr 62.3 kDa) and is the product of the EPHX2 gene [49]. Its specific substrate is trans-stilbene oxide, and it appears... 

The cytosolic enzyme leukotriene A4 hydrolase (EC 3.3.2.6), which ster-eoselectively converts leukotriene A4 (LTA4) to leukotriene B4 [56], This enzyme catalyzes the hydrolytic cleavage of the 5,6-epoxide ring in LTA4, but, in contrast to what happens with other EHs, the product is not a vicinal diol but a 5,12-diol. As a zinc metalloenzyme, LTA4 hydrolase does not appear to be related to any other epoxide hydrolase. 

Amino acid sequence relationships have suggested a number of HYL families based on percent identity, enzymes with >40% identity belonging to the same family [48]. Families so identified include the mammalian microsomal EH (HYL1), the mammalian cytosolic EH (HYL2), the plant cytosolic EH (HYL3), and bacterial C-X bond hydrolases (haloacid dehydrogenases, HAD, and haloalkane dehalogenases, HLD). 

A critical input in unraveling the catalytic mechanism of epoxide hydrolases has come from the identification of essential residues by a variety of techniques such as analysis of amino acid sequence relationships with other hydrolases, functional studies of site-directed mutated enzymes, and X-ray protein crystallography (e.g., [48][53][68 - 74]). As schematized in Fig. 10.6, the reaction mechanism of microsomal EH and cytosolic EH involves a catalytic triad consisting of a nucleophile, a general base, and a charge relay acid, in close analogy to many other hydrolases (see Chapt. 3). 

Fig. 10.6. Simplified representation of the postulated catalytic cycle of microsomal and cytosolic epoxide hydrolases, showing the roles played by the catalytic triad (i.e., nucleophile, general base, and charge relay acid) and some other residues, a) Nucleophilic attack of the substrate to form a /3-hydroxyalkyl ester intermediate, b) Nucleophilic attack of the /Thydroxyal-kyl ester by an activated H20 molecule, c) Tetrahedral transition state in the hydrolysis of the /f-hydroxyalkyl ester, d) Product liberation, with the enzyme poised for a further catalytic... 

An unusual case of intramolecular competition (chemoselectivity, see Chapt. 1 in [la]) between ester and oxirane occurs in the detoxification of (oxiran-2-yl)methyl 2-ethyl-2,5-dimethylhexanoate (10.49), one of the most abundant isomers of an epoxy resin. The compound is chemically very stable, i.e., resistant to aqueous hydrolysis, but is rapidly hydrolyzed in cytosolic and microsomal preparations by epoxide hydrolase and carboxylesterase, which attack the epoxide and ester groups, respectively [129], The rate of overall enzymatic hydrolysis was species dependent, decreasing in the order mouse > rat > human, but was relatively fast in all tissues examined (lung and skin as portals of entry, and liver as a further barrier). In mouse and rat lung microsomes, ester hydrolysis was 3-4 times faster than epoxide hydration, whereas the opposite was true in human lung microsomes. 

G. M. Pacifici, A. Temellini, L. Giuliani, A. Rane, H. Thomas, F. Oesch, Cytosolic Epoxide Hydrolase in Humans Development and Tissue Distribution , Arch. Toxicol. 1988, 62, 254 - 257. 

L. Schladt, W. Worner, F. Setiabudi, F. Oesch, Distribution and Inducibility of Cytosolic Epoxide Hydrolase in Male Sprague-Dawley Rats , Biochem. Pharmacol. 1986, 35, 3309 - 3316. 

F. Waechter, P. Bentley, F. Bieri, S. Muakkassah-Kelly, W. Staubli, M. Villermain, Organ Distribution of Epoxide Hydrolases in Cytosolic and Microsomal Fractions of Normal and Nafenopin-Treated Male DBA/2 Mice , Biochem. Pharmacol. 1988, 37, 3897 -3903. 

E. C. Dietze, J. Stephens, J. Magdalou, D. M. Bender, M. Moyer, B. Fowler, B. D. Hammock, Inhibition of Human and Murine Cytosolic Epoxide Hydrolase by Group-Selective Reagents , Comp. Biochem. Physiol., B 1993, 104, 299 - 308. 

G. Bellucci, C. Chiappe, F. Marioni, M. Benetti, Regio- and Enantioselectivity of the Cytosolic Epoxide Hydrolase-Catalysed Hydrolysis of Racemic Monosubstituted Alkyloxiranes ,./. Chem. Soc., Perkin Trans. 1 1991, 361 - 363 G. Bellucci, C. Chiappe, L. Conti, F. Marioni, G. Pierini, Substrate Enantioselection in the Microsomal Epoxide Hydrolase Catalyzed Hydrolysis of Monosubstituted Oxiranes. Effects of Branching of Alkyl Chains ,./. Org. Chem. 1989, 54, 5978 - 5983. 

N. Chacos, J. Capdevilla, J. R. Falck, S. Manna, C. Martin-Wixtrom, S. S. Gill, B. D. Hammock, R. W. Estabrook, The Reaction of Arachidonic Acid Epoxides (Epoxyeico-satrienoic Acids) with a Cytosolic Epoxide Hydrolase , Arch. Biochem. Biophys. 1983, 223, 639 - 648. 

J. Meijer, J. W. DePierre, Properties of Cytosolic Epoxide Hydrolase Purified from the Liver of Untreated and Clofibrate-Treated Mice , Eur. J. Biochem. 1985, 150,1 - 16. 

J. Magdalou, B. D. Hammock, 1,2-Epoxycycloalkanes Substrates and Inhibiors of Microsomal and Cytosolic Epoxide Hydrolases in Mouse Liver , Biochem. Pharmacol. 1988, 37, 2717 - 2722. 

G. Bellucci, C. Chiappe, F. Marioni, Enantioselectivity of the Enzymatic Hydrolysis of Cyclohexene Oxide and ( )-l-Methylcyclohexene Oxide A Comparison between Microsomal and Cytosolic Epoxide Hydrolases , J. Chem. Soc., Perkin Trans. 1 1989, 2369 -2373. 

Alice et al studied the turnover kinetics of Listeria OTonocytogenex-secreted p60 protein (a murein hydrolase) by host cell cytosolic proteasomes. J774 cells, seeded in flasks and incubated overnight in culture medium, were infected with log-phase cultures of E. monocytogenes for 30 min, washed, and incubated in culture medium for 3 h, with gentamicin (50 tg/ml) added after the first 30 min to inhibit extracellular bacterial growth. Cells then were washed and placed in methionine-free medium with spectinomycin, gentamicin, the eukaryotic protein synthesis inhibitors [cycloheximide (50 tg/mL) and anisomycin (30 tg/ml),] and 25 dVI calpain inhibitor I. After 30 min, [ S]methionine was added, and the cells were pulse-labeled for periods of 20 to 60 min. Cells... 

Kawashima Y, Uy-Yu N, Kozuka H Sex-related difference in the inductions by perfluorooctanoic acid of peroxisomal fl-oxidation, microsomal 1-acylglycerophos-phocholine acyltransferase and cytosolic long-chain acyl-CoA hydrolase in rat liver. Biochem J 26 595-6Q0, 1989... 

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