Carboxylesterases (EC 3.1.1). Purification and titration of ox liver carboxylesterase

Bovine Carboxylesterases: Evidence for Two CES1 and Five Families of CES Genes on Chromosome 18

Predicted bovine carboxylesterase (CES) protein and gene sequences were derived from bovine (Bos taurus) genomic sequence data. Two bovine CES1 genes (CES1.1 and CES1.2) were located on chromosome 18 encoding amino acid sequences that were 81% identical. Two forms of CES1.2 were also observed apparently caused by an indel polymorphism encoded at the C-terminus end. Two CES gene clusters were observed on chromosome 18: CES5-CES1.1-CES1.2 and CES2-CES3-CES6. Bovine CES1, CES2, CES3, CES5 and CES6 shared 39-45% identity with each other, but showed 71-76% identity with each of the five corresponding human CES family members. Phylogeny studies indicated that bovine CES genes originated from five ancestral gene duplication events which predated the eutherian mammalian common ancestor. In addition, a subsequent CES1 gene duplication event is proposed during mammalian evolution prior to the appearance of the Bovidae common ancestor ~ 20 MY ago.

4-alkylidene oxazolones as substrates and inhibitors for sensitive assays of the normality of active sites and the catalytic properties of hydrolases

The suitability of eleven 4-alkylidene oxazolones for the determination of four hydrolases, alpha-chymotrypsin, trypsin, carboxylesterase and leucine aminopeptidase, was tested. The specific activities were in general low compared with those obtained with the classical substrates but the Kmapp values were also small. Hence, the kcat/Kmapp ratios of the oxazolones, the optimal indicator of activity, remained in the usual range. The high differential absorption coefficients of the oxazolones in the UV range render these substrates very suitable for the determination of active site normalities if the solubilities of the acyl enzymes and the magnitudes of the rapid bursts are sufficient. Since some of the oxazolones fluoresce, the sensitivity of the method may be increased up to 1000 x by fluorescence detection. The titrations may be carried out in organic solvents, e.g. dimethyl sulphoxide, which greatly stabilize the hydrolases. The high specificity of the oxazolones permits active site titrations in the presence of other hydrolases.

Physical and chemical characterization of a horse serum carboxylesterase

The serine carboxylesterase from horse serum was characterized by amino acid composition, peptide mapping, molecular and subunit weights, and sequencing of the amino acids around the essential serine residue at the active site. A protocol was developed for using reversed-phase high-performance liquid chromatography as the final step to obtain homogeneous preparations of horse serum carboxylesterase. Amounts sufficient for determining the amino acid composition and for peptide maps were obtained from a partially purified starting material which contained approximately 55% carboxylesterase. The amino acid composition, like the subunit weight (70,800 +/- 1400), was similar to the corresponding values reported for other serine carboxylesterases. However, the amino acid sequence of the tryptic digest fragment containing the essential nucleophilic seryl residue differed significantly from the corresponding sequences of other mammalian serine carboxylesterases.

Biochemical and genetic evidence for distinct membrane-bound and cytosolic sialic acid O-acetyl-esterases: serine-active-site enzymes

A cytosolic sialic acid-specific O-acetyl-esterase was previously described that can remove O-acetyl esters from the 9-position of sialic acids. We show that rat liver Golgi vesicles contain a distinct sialic acid-esterase located within the lumen of the same vesicles that add O-acetyl esters to sialic acids. Studies of a retinoblastoma cell line genetically deficient in the cytosolic enzyme also confirm the existence of distinct membrane-associated sialic acid esterase activity. We developed a sensitive, specific and facile assay, which measures release of [3H]acetyl groups from [3H-acetyl]9-O-acetyl-N-acetylneuraminic acid. Using this assay, we show that rat liver membranes may contain different sialic acid O-acetyl-esterases. The membrane-associated enzyme(s) bind to Concanavalin A Sepharose, whereas the cytosolic enzyme does not. Membrane-bound and cytosolic esterases are inactivated by di-isopropyl-fluorophosphate, showing they are serine-active-site enzymes.

Partial purification and characterization of a microsomal carboxylesterase specific for salicylate esters from guinea-pig liver

Studies on liver carboxylesterases have predominantly involved the use of uncharged ester and amide substrates to monitor activity. A microsomal carboxylesterase (EC 3.1.1.1) from guinea-pig liver microsomes has been identified which specifically hydrolyses aspirin (White, K.N. and Hope, D.B. (1981) Biochem. J. 197, 771-773), a substrate which is negatively charged at physiological pH, and this work describes its partial purification and characterization. The enzyme is monomeric, it has a molecular weight of approx. 55 000 and is very sensitive to inhibition by the carboxylesterase inhibitor bis(4-nitrophenyl)phosphate. Although it could not be completely separated from contaminating carboxylesterases, substrate specificity was investigated using the negatively charged esters of salicylic acid. The enzyme is not specific for the acetyl ester of salicylic acid, aspirin, but hydrolyses the longer chain esters more rapidly, with the highest Vmax for the n-octanoyl ester. The enzyme was subject to substrate inhibition which increased with increasing chain length of the fatty acid on the ester, and approached 100% inhibition at concentrations of substrate below critical micellar concentrations.

Characterization of an inducible amidase from Pseudomonas acidovorans AE1

The main molecular and catalytic properties of an acetanilide-hydrolyzing enzyme from Pseudomonas acidovorans AE 1, purified to a homogeneous state, were investigated. The molecular weight was 57 500 as determined by gel filtration and 55 300 as computed from the amino acid composition. By polyacrylamide gel electrophoresis in dodecylsulfate a polypeptide chain weight of 56 700 was obtained. Based on the reaction of the highly purufied enzyme with diethyl-4-nitrophenyl phosphate an equivalent weight of approximately 59 100 was found. From these results it was concluded that the enzyme consists of a single polypeptide chain and contains one active site per molecule. The enzyme hydrolyzed esters as well as certain aromatic amides. It also catalysed the transfer of acetyl groups to phenetidine yielding phenacetin. The activities towards aliphatic esters were much smaller. The enzyme was stable at pH values ranging from 7 to 9 and its pH-optimum was about 10. It was strongly inhibited by organophosphorous compounds, like diethyl-4-nitrophenyl phosphate or diisopropylphosphorofluoridate, as well as by physostigmine sulfate and -SH-blocking reagents, like HgCl-2 or 4-chloromercuribenzoic acid. o-Nitrophenol caused a competitive inhibition and phenetidine an uncompetitive inhibition.

Substrate stereochemistry of the enoyl-CoA hydratase reaction

1. A specimen of stereospecifically 2-tritiated 3-hydroxybutyric acid was prepared by hydroboration of ethyl crotonate. It was assumed that the hydroboration reaction took a syn course and hence that (2R,3S) plus (2S,3R)-3-hydroxy[2 minus 3H1]butyric acid was formed after oxidation and hydrolysis. 2. 3RS-3-Hydroxy[2 minus 3H2]butyric acid, symmetrically tritiated at C-2, was prepared by isotopic exchange of ethyl acetoacetate in tritiated water, followed by reduction and hydrolysis. 3. The 3R-enantiomers of the acids listed under paragraphs (1) and (2) were destroyed enzymically by use of 3R-specific 3-hydroxybutyrate dehydrogenase and the residual 3S-enantiomers were isolated. 4. The resulting specimens of 2R,3S-3-hydroxy[2 minus 3H1]butyric acid and 3S-3hydroxy[2 minus 3H2]-butyric acid were converted chemically to the acyl-CoA derivatives. These were incubated with enoyl-CoA hydratase. 5. In the presence of the enoyl-CoA hydratase symmetrically labelled 3S-3-hydroxy[2 minus 3H2]BUTYRYL-CoA lost nearly 50% of its tritium label; 2R,3S-3hydroxy [2-3-H1]butyryl-CoA lost about 78%. 6. It was concluded that the elimination of the elements of water from 3-hydroxybutyryl-CoA on the hydratase occurs stereospecifically with syn geometry.