Pig liver esterase. Reactions with alcohols, structure-reactivity correlations, and the acyl-enzyme intermediate

Ethynylphenyl carbonates and carbamates as dual-action acetylcholinesterase inhibitors and anti-inflammatory agents

Novel ethynylphenyl carbonates and carbamates containing carbon- and silicon-based choline mimics were synthesized from their respective phenol and aniline precursors and screened for anticholinesterase and anti-inflammatory activities. All molecules were micromolar inhibitors of acetylcholinesterase (AChE), with IC50s of 28-86 μM; the carbamates were two-fold more potent than the carbonates. Two of the most potent AChE inhibitors suppressed 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced inflammation by 40%. Furthermore, these molecules have physicochemical properties in the range of other CNS drugs. These molecules have the potential to treat inflammation; they could also dually target Alzheimer's disease through restoration of cholinergic balance and inflammation suppression.

Lipase-catalyzed ester exchange reactions in organic media with controlled humidity

Immobilized lipase activity is studied in organic solvent systems of controlled water content under the influence of a variety of reaction parameters, such as temperature, relative humidity, substrate concentrations, and type of fatty acid used. Control of the amount of water in the reaction system was found to be a valuable tool for the orientation of the reaction process and for the determination of the final reaction products. The properties of the immobilized lipase were studied using the interesterification of triolein and palmitic acid as the model system.

Analysis of enzymatic transacylase Brønsted studies with application to the ribosome

Preferential binding of an enzyme to the transition state relative to the ground state is a key strategy for enzyme catalysis. When there is a difference between the ground and transition state charge distributions, enzymes maximize electrostatic interactions to achieve this enhanced transition state binding. Although the transition state is difficult to observe directly by structural methods, the chemical details of this transient species can be characterized by studies of substituent effects (Brønsted, Hammett, Swain-Scott, etc.) and isotope effects. Brønsted analysis can provide an estimate of transition state charges for the nucleophile and leaving group of a reaction. This Account will discuss the theoretical basis of Brønsted analysis and describe its practical application to the study of transacylase enzyme systems including the peptidyl transferase reaction of the ribosome. The Brønsted coefficient is derived from the linear free energy relationship (LFER) that correlates the acidity (pK(a)) of a reactive atom to the log of its rate constant. The Brønsted coefficient establishes the change in atomic charge as the reaction proceeds from the ground state to the transition state. Bonding events alter the electrostatics of atoms and the extent of bonding can be extrapolated from transition state charges. Therefore, well-defined nucleophile and leaving group transition state charges limit the number of mechanisms that are consistent with a particular transition state. Brønsted results are most informative when interpreted in the context of other mechanistic data, especially for enzymatic studies where an active site may promote a transition state that differs significantly from a prediction based on uncatalyzed solution reactions. Here we review Brønsted analyses performed on transacylases to illustrate how these data enhanced the enzymatic mechanistic studies. Through a systematic comparison of five enzymes, we reveal a wide spectrum of Brønsted values that are possible for what otherwise appear to be similar chemical reactions. The variations in the Brønsted coefficients predict different transition states for the various enzymes. This Account explores an overriding theme in the enzymatic mechanisms that catalysis enhances commensurate bond formation and proton abstraction events. The extent of the two bonding events in relationship to each other can be inferred from the Brønsted coefficient. When viewed in the context of recent ribosomal studies, this interpretation provides mechanistic insights into peptide bond formation.

Carnosine protects against the inactivation of esterase induced by glycation and a steroid

Carnosine, an endogenous histidine-containing dipeptide, protects protein from oxidation and glycation, which may contribute to a potential treatment for some conformational diseases including cataract. Glycation, the non-enzymic reaction of sugars with proteins, promotes cross-linking and further aggregation. Prolonged use of glucocorticoids is a risk factor for cataract, as is diabetes. Esterase activity in the lens is decreased in senile cataract and diabetes. Previously, we reported that glycation and a steroid inactivate esterase. Here we tested the inactivation of esterase with fructose, fructose 6-phosphate (F6P) and ribose as model glycation reactions and prednisolone-21-hemisuccinate (P-21-H) as a model steroid and investigated the ability of carnosine to protect esterase against inactivation. The activity of esterase was measured by a spectrophotometric assay using p-nitrophenyl acetate as the substrate. The modified esterase was examined electrophoretically. The esterase was progressively inactivated by F6P, fructose, ribose and P-21-H. P-21-H was more effective than the sugars. Carnosine significantly inhibited the inactivation of esterase induced by all four compounds. Carnosine decreased the extent of the cross-linking. These results provide further evidence for carnosine's role as an anti-glycation compound. It is also proposed that carnosine may be an anti-steroid agent.

Estimation of inhibitory organophosphates with purified pig liver carboxylesterase

Organophosphates that inhibit acetylcholinesterase normally also inhibit pig liver carboxylesterase irreversibly. Since this liver esterase is well characterized and easily accessible in large amounts, we propose the use of this enzyme for the quantitation of low concentrations of such organophosphates. The principle of two estimation methods is described. Both methods involve the addition of an unknown amount of organophosphate to an assay mixture of purified esterase, buffer and a low affinity esterase substrate. In the first of these methods, the inhibitor concentration is calculated from the esterase activities before and after the addition of the inhibitor. In the second method, the amounts of inhibitor or of enzyme are changed in several assays, until equimolar conditions can be detected from the observed reaction kinetics. The theoretical background of these methods is discussed and practical examples for the estimation of paraoxon (order of 0.1 nmoles) are given.

Purification and partial characterization of a novel thermophilic carboxylesterase with high mesophilic specific activity

An esterase activity obtained from a strain of Bacillus stearothermophilus was purified 5,133-fold to electrophoretic homogeneity with 26% recovery. The purified esterase had a specific activity of 2,032 mumol min-1 mg-1 based on the hydrolysis of p-nitrophenyl caproate at pH 7.0 and 30 degrees C. The apparent molecular mass was 50,000 +/- 2,000 daltons from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and 45,000 +/- 3,000 daltons from gel filtration. Native polyacrylamide gels stained for esterase activity showed three bands. The isoelectric points were estimated to be 5.7, 5.8, and 6.0. Forty amino acid residues were sequenced at the N-terminus. The sequence showed no degeneracy, suggesting that the three esterases are functionally identical carboxylesterases differing by a limited number of amino acids. The enzyme showed maximum activity at pH 7.0 and was very stable at pH 6.0-8.9 with optimum stability at pH 6.0. At this pH and 60 degrees C the half-life was 170 h. Esterase activity was totally inhibited by phenylmethanesulfonyl fluoride, parahydroxymercuribenzoate, eserine, and tosyl-L-phenylalanine, but not by ethylendiaminetetra acetic acid. The esterase obeyed Michaelis-Menten kinetics in the hydrolysis of p-nitrophenyl esters, but both Vmax and KM were protein concentration-dependent. The esterase was able to hydrolyse a number of p-nitrophenyl derivatives (amino acid derivatives and aliphatic acids with different chain lengths).

Hydrolysis of carbonates, thiocarbonates, carbamates, and carboxylic esters of alpha-naphthol, beta-naphthol, and p-nitrophenol by human, rat, and mouse liver carboxylesterases

Thirty carbonates, thiocarbonates, carbamates, and carboxylic esters of alpha-naphthol, beta-naphthol, and p-nitrophenol were synthesized and tested as substrates for liver carboxylesterases from the crude microsomal fractions of human and mouse, and purified isozymes, hydrolases A and B, from rat liver microsomes. The carbonates, thiocarbonates, and carboxylic esters of alpha-naphthol were cleaved more rapidly than the corresponding beta-naphthol isomers by the mammalian liver esterases. alpha-Naphthyl esters of acetic, propionic, and butyric acids were among the best substrates tested for these enzymes. The majority of the substrates was consistently hydrolyzed at higher rates by hydrolase B compared with hydrolase A, although the Michaelis-Menten constant (Km) values of selected substrates differed widely with these two isozymes. Malathion was a 15-fold better substrate for hydrolase B than for hydrolase A. Compared with the corresponding carboxylates, the carbonate moiety of alpha- and beta-naphthol and p-nitrophenol lowered the specific activities of the enzymes by about fivefold but improved stability under basic conditions. The optimum pH of mouse liver esterase with the acetate, methyl-carbonate, and ethylthiocarbonate of alpha-naphthol was between pH 7.0 and pH 7.6. Human and mouse liver microsomal esterase activities were about five orders of magnitude lower than the esterase activities of purified rat liver hydrolase B. A relationship between the catalytic activity of the enzymes and the lipophilicity of the naphthyl substrates indicated that (i) in the alpha- and beta-naphthyl carbonate series, an inverse relationship between enzyme activity and lipophilicity of the substrates was observed, whereas (ii) in the alpha-naphthyl carboxylate series, an increase in enzyme activity with increasing lipophilicity of the substrates up to a logP value of about 4.0 was observed, after which the enzyme activity decreased.

Xenobiotic-metabolizing enzyme systems in test fish—IV. Comparative studies of liver microsomal and cytosolic hydrolases

1. The initial slopes of the substrate-activity curves of several hydrolases were determined in the microsomal and cytosolic fractions of the liver of several fish recommended by OECD for the regulatory testing of chemicals. 2. Inter-species differences ranged within a factor of 7-17 for the esterases and reached a factor of 60 for the amidase. Guppy and carp appeared endowed with hydrolase activities which, overall, are much higher than zebra fish, trout and golden orfe. 3. The comparison with the rat liver microsomal hydrolases strongly suggests that fish are endowed with similar or higher levels of A-esterase and with much less B-esterase/amidase activities.

N-Butyl-N-methyl-4-nitrophenyl carbamate as a specific active site titrator of bile-salt-dependent lipases

The effect of a series of synthetic carbamates on the human (milk or pancreatic) bile-salt-dependent lipase (cholesterol esterase) was examined. N-isopropyl-O-phenyl, N-methyl-O-phenyl, N-butyl-(4-nitrophenyl), N-phenyl-(4-nitrophenyl), N-butyl-N-methyl and N-pentyl-O-phenyl carbamates were inhibitors of the enzyme activity, while O-isopropyl-N-phenyl, O-methyl-N-phenyl, O-benzyl-N-isopropyl and O-cyclohexyl-N-phenyl carbamates were not even recognized by the enzyme. The N-alkyl chain length is essential for the enzyme inhibition and N-butyl-(4-nitrophenyl) or N-pentyl-O-phenyl carbamates are more potent inhibitors than N-methyl-O-phenyl or N-isopropyl carbamates. The inhibition by reactive carbamates fits the criteria for mechanism-based inhibition: the inhibition is first-order with time, shows saturation kinetics with increasing carbamate concentration and leads to an inactive stoichiometric enzyme-inhibitor complex; the enzyme activity can be protected by a competitive inhibitor. Evidence is shown that the enzymatic nucleophilic attack of carbamates is directed at the carbonyl carbon atom and not the nitrogen atom. The inhibition of bile-salt-dependent lipase does not occur consecutive to the formation of a reactive isocyanate derivative of carbamate but via a tetrahedral intermediate involving essential residues implicated in the enzyme catalytic site. This intermediate evolves by liberation of alcohol (or phenol) and formation of an inactive carbamyl enzyme. Among the carbamates tested, N-butyl-N-methyl-(4-nitrophenyl) carbamate specifically inhibits the bile-salt-dependent lipase; the release of 4-nitrophenol from this carbamate is directly proportional to the enzyme inhibition and it may be defined as a specific active-site titrator for bile-salt-dependent lipases.

Estradiol esters can replace 17 beta-estradiol in the stimulation of DNA and esterase synthesis by MCF-7 cells: a possible role for the estrogen-sensitive MCF-7 cell esterase

In this communication we extend our earlier observations on estrogen-sensitive carboxyl esterases in MCF-7 human breast cancer cells able to hydrolyze esters of estradiol. Using either estradiol acetate or p-nitrophenyl hexanoate as substrates, esterase activity was found to increase 2-3-fold in MCF-7 cells maintained in the presence of 10(-8) M estradiol. Following sucrose density centrifugation, over 85% of total esterase activity was found in the cytoplasmic fraction. No esterase activity was found in spent media from growing cells. By size exclusion chromatography, estradiol acetate esterase activity exhibited a mol. wt of 45-50 kDa. Attempts to demonstrate incorporation of [3H]estradiol into estradiol fatty acid esters by the above MCF-7 cell line (203P) were unsuccessful, although, such incorporation could be demonstrated in two other MCF-7 cell sublines. Incubation of the 203P cells with 10 nM [3H]estradiol in the presence of 0.5 mM radioinert estradiol acetate resulted in the incorporation of 35 +/- 12% of the label into the estradiol acetate in 10 min. In the absence of radioinert estradiol acetate, no incorporation was observed. When MCF-7 cells were incubated with [3H]estradiol in the presence of a large excess of radioinert estradiol valerate, label was found only in estradiol valerate. Similarly, when the incubation was carried out in the presence of a mixture of radioinert estradiol acetate and valerate, label was incorporated into both esters. We conclude that the apparent formation of radiolabeled estradiol esters by MCF-7 cells incubated under the above conditions, results at least in part, from an esterase-catalyzed exchange reaction. Under conditions where no ester hydrolysis could be detected in the absence of cells, valerate and stearate esters of estradiol were found to be as effective as unesterified estradiol in stimulating esterase synthesis and the incorporation of [3H]thymidine into DNA. These results are consistent with a model in which an intracellular esterase in MCF-7 cells can generate estradiol from an exogenous lipoidal steroid and elicit an estrogen response.

Aspirin hydrolyzing esterases from rat liver cytosol

Unlike most esterases, which are predominantly bound to the microsomal fraction, the enzymes hydrolyzing acetylsalicylic acid are present in an equal amount in the cytosol. Two soluble isozymes were purified to homogeneity from rat liver and characterized as serine esterases with a Mr of 35,000. Both had the wide substrate spectrum characteristic of enzymes active in detoxication. Both had a very low Km for acetylsalicylate. Three other cytoplasmic enzymes active with aspirin were observed but these differed in their high Mr (about 220,000) and their lack of reactivity with antibody to one of the homogeneous isozymes.

Further kinetic and molecular characterization of an extremely heat-stable carboxylesterase from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius

The carboxylesterase (serine esterase, EC 3.1.1.1) from Sulfolobus acidocaldarius was purified 940-fold to homogeneity by an improved purification procedure with a yield of 57%. In the presence of alcohols the enzyme catalyses the transfer of the substrate acyl group to alcohols in parallel to hydrolysis. The results show the existence of an alcohol-binding site and a competitive partitioning of the acyl-enzyme intermediate between water and alcohols. Aniline acts also as a nucleophilic acceptor for the acyl group. On the basis of titration with diethyl p-nitrophenyl phosphate, a number of four active centres is determined for the tetrameric carboxylesterase. The sequence of 20 amino acid residues at the esterase N-terminus and the amino acid composition are reported.

Dual-enzyme cascade--an amplified method for the detection of alkaline phosphatase

A method in which a two-enzyme cascade is used for rapid and sensitive detection of alkaline phosphatase is described. A masked inhibitor, 4-(3-oxo-4,4,4-trifluorobutyl)phenyl phosphate, is dephosphorylated by the action of alkaline phosphatase. The resulting compound, 1,1,1-trifluoro-4-(4-hydroxyphenyl)-butan-2-one, acts as a potent inhibitor of the second enzyme, a liver carboxylesterase. A determination of the residual esterase activity provides a highly sensitive indication of the original phosphatase concentration. The sensitivity of this dual-enzyme cascade is approximately 125-fold greater than that observed for the direct detection of phosphatase activity with p-nitrophenyl phosphate.

Human milk bile-salt stimulated lipase: further investigations on the amino-acids residues involved in the catalytic site

The bile-salt-stimulated lipase purified from human skim milk was modified with diisopropyl phosphofluoridate (DFP), N-ethyl-5-phenylisoxazolium-3'-sulfonate and ethoxyformic anhydride. These chemical modifications lead to the following results: (1) the inhibition of the enzyme by DFP is due to the phosphorylation of a single residue, probably a serine residue, which may represent the acylable group of the enzyme; (2) carbethoxylation of histidine residues leads to inhibition of the enzyme activity. Among the nine modified histidine residues, only one is essential for enzyme activity; (3) a free carboxyl group with a pKa of 5.4 is also involved in catalysis. These three essential residues are involved in the enzymatic hydrolysis of substrates whatever their physical state (soluble or emulsified). Upon treatment with DFP as well as with ethoxyformic anhydride, the enzyme remains able to bind to the model interface formed by siliconized glass-beads with almost the same efficiency (Kd between 4.1 and 7.4.10(-8) M) than the native bile-salt-stimulated lipase (Kd = 6.3.10(-8) M). Moreover, the modified and native enzymes occupy the same interfacial area (4000-4600 A2/molecule). By contrast, the enzyme modified by N-ethyl-5-phenylisoxazolium-3'-sulfonate reagent presents an interfacial area close to that of a denatured protein of size (approximately 18,300 A2/molecule) and a Kd more than 20-fold higher than that of the native enzyme. Solvent isotope effects measured on kcat/Km and kcat indicate that the catalytic mechanism of bile-salt-stimulated lipase involves transition states that are stabilized by hydrogen bonds as described in the two-step acylation-deacylation mechanism of serine enzymes.

Specificity of the sarcoplasmic reticulum calcium ATPase at the hydrolysis step

The coupling of Ca2+ transport to ATP hydrolysis by the SR ATPase requires that the enzyme operate with considerable specificity, which is different at different steps. The limits of specificity of the calcium-free phosphorylated enzyme for transfer of its phosphoryl group to water have been examined. The rate of transfer of the phosphoryl group to the simple nucleophile methanol was compared to its transfer to water by following the formation of methyl phosphate from inorganic phosphate. The reverse reaction, hydrolysis of methyl phosphate, was compared to phosphate-water oxygen exchange. The reactions involving methanol as nucleophile or leaving group are at least 2-3 orders of magnitude slower than those involving water. This result indicates that the transition state for this reaction involves strong and specific interactions of the H2O molecule with the enzyme. These interactions may also involve the bound Mg2+ ion. The results also suggest that the difference in specificity between Ca2+ free and Ca2+ bound states of the enzyme involves significant differences in the structure of the catalytic site.

Substrate specificity for formation of cholesterol ester conjugates from fenvalerate analogues and for granuloma formation

1. The substrate specificity of microsomal carboxyesterase(s) responsible for the formation of cholesteryl [2R]-2-(4-chlorophenyl) isovalerate from fenvalerate was investigated by incubating mouse kidney microsomes with 14C-cholesterol and the following substrates: fenvalerate isomers, fenvalerate analogues, other pyrethroids, methoprene and cycloprate analogues. Among the four isomers of fenvalerate, only the [2R, alpha S]-isomer yielded a cholesterol ester, being identical with the result obtained in the in vivo study. Some fenvalerate analogues produced cholesterol ester conjugates, but no other pyrethroids nor methoprene produced such conjugates. Some cycloprate analogues gave the corresponding cholesterol ester, the yields of which were dependent on their carbon-chain lengths. 2. Cholesterol ester formation in vitro from these fenvalerate analogues was well correlated with granuloma formation observed when the analogues were given to mice at 3000 ppm for a month. 3. Steroids other than cholesterol were also investigated as acceptors of the acid moiety of the [2R, alpha S]-isomer by incubating solubilized carboxyesterase(s) with the [2R, alpha S]-isomer in the presence of egg lecithin and several steroids. Dehydroisoandrosterone and pregnenolone were found to give the corresponding ester conjugates.

Stereoselective formation of a cholesterol ester conjugate from fenvalerate by mouse microsomal carboxyesterase(s)

In accordance with in vivo findings, of the four chiral isomers of fenvalerate (S-5602 Sumicidin, Pydrin, [RS]-alpha-cyano-3-phenoxybenzyl [RS]-2-(4-chlorophenyl)isovalerate), only the [2R, alpha S]-isomer (B-isomer) yielded cholesteryl [2R]-2-(4-chlorophenyl)isovalerate (CPIA-cholesterol ester) in the in vitro study using several tissue homogenates of mice, rats, dogs, and monkeys. There were species differences in the extent of CPIA-cholesterol-ester formation, with mouse tissues showing relatively higher activity than those of other animals. The kidney, brain, and spleen of mice showed relatively higher capacities to form this ester compared to other tissues, and the enzyme activity was mainly localized in microsomal fractions. The CPIA-cholesterol ester did not seem to be produced by three known biosynthetic pathways of endogenous cholesterol esters--acyl-CoA:cholesterol O-acyltransferase (ACAT), lecithin:cholesterol O-acyltransferase (LCAT), and cholesterol esterase. Carboxyesterase(s) of mouse kidney microsomes solubilized by digitonin hydrolyzed only the B alpha-isomer of fenvalerate, yielding CPIA, whereas they yielded the corresponding cholesterol ester in the presence of artificial liposomes containing cholesterol. Thus, it appears that the stereoselective formation of the CPIA-cholesterol ester results from the stereoselective formation of the CPIA-carboxyesterase complex only from the B alpha-isomer, which subsequently undergoes cleavage by cholesterol to yield the CPIA-cholesterol ester.

Specificity of two different purified acylcarnitine hydrolases from rat liver, their identity with other carboxylesterases, and their possible function

One of the previously described five purified monoglyceride-cleaving carboxylesterases from rat liver microsomes proved to be a carnitine ester hydrolase. This esterase, with an isoelectric point of 5.2, is most active with medium-chain acyl-L-carnitines (C12-C14). The esterase is also remarkably active with 1,3-diglycerides, especially 1,3-dioctanoylglycerol, that are hydrolyzed faster than the corresponding 1-monoglycerides and triglycerides. Only one of the other four purified carboxylesterases has moderate acylcarnitine-hydrolyzing activity. An altered procedure for the separation of the two microsomal acylcarnitine-cleaving enzymes is described. Both enzymes hydrolyze carnitine esters optimally at pH 8 and both are inactive with acetylcarnitine, palmitoyl-CoA, and butyrylthiocholine. The possible natural functions of the hydrolases are discussed. Besides their detoxifying action on natural membrane-lysing detergents (like carnitine esters and lysophospholipids), these enzymes could be involved in the transport of carnitine out of the liver.

Gluconeogenesis in rat hepatocytes from monomethyl succinate and other esters

Although little glucose is formed from succinate in rat hepatocytes, the rate of gluconeogenesis from monomethyl succinate approaches that from L-lactate. Dimethyl succinate is as good as monomethyl succinate at 5 mM, but not at 20 mM. Monoethyl fumarate and 4-methyl malate are only fair glucogenic substrates, but 1-methyl malate is another good substrate at high concentrations. The esters are apparently taken up either directly through the cell membrane, or by monocarboxylate transporters, and then hydrolyzed intracellularly by some esterase(s). This approach may permit the use of a wider range of substrates and inhibitors for the study of liver cell metabolism.

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.

Affinity of tixocortol pivalate (JO 1016), tixocortol, cortisol acetate and cortisol for dexamethasone receptors of mouse thymus cells and rat renomedullary interstitial cells in culture. Correlation with their biological activities

Affinity for the dexamethasone binding sites of tixocortol pivalate, (the ester of the 21 thiol derivatives of cortisol), a steroid with local anti-inflammatory activity similar to cortisol acetate and with no systemic activity, was investigated in comparison with other steroids: tixocortol (the thiol derivative yielded by esterase hydrolysis), cortisol acetate and cortisol. The rank order of relative affinity for dexamethasone receptor of mouse thymocytes (37 degrees C) was: dexamethasone (1), cortisol (0.20), tixocortol pivalate (0.16), tixocortol (0.065), cortisol acetate (0.05). The corresponding 21 oxygenated ester (cortisol pivalate) was found less potent (0.080). Using rat renomedullary interstitial cells in culture, tixocortol pivalate showed also a higher receptor affinity than tixocortol. Cortisol acetate was as potent as tixocortol pivalate. The biological activity of tixocortol pivalate measured by the inhibition of PGE2 secretion on the same model, was similar to cortisol acetate and cortisol (10(-6) M, 24 h incubation, 38-55% inhibition). Tixocortol was less active (26%). These results with tixocortol pivalate are in good agreement with previously reported in vivo studies and show a good correlation between its binding ability and biological effect.

Modification of the essential amino acids of human pancreatic carboxylic-ester hydrolase

Chemical modification of human pancreatic carboxylic-ester hydrolase (EC 3.1.1.1) were performed using organophosphorus compounds, ethoxyformic anhydride and Woodward's K reagent. It has been shown that: (1) the inhibition of the enzyme activity by organophosphorus compounds is due to the phosphorylation of only one alcohol residue, probably a serine residue which may represent the acylable group of the enzyme: (2) 35-36 free carboxyl groups are modified by Woodward's K reagent but only one is responsible for the loss of enzyme activity. This carboxyl group has a pKa of 5.2.: (3) carbethoxylation of histidine residues leads to the inhibition of the enzyme activity. All nine histidine residues are reactive but only one is essential for activity. Taking into account the probable formation of an acyl-enzyme intermediate (Lombardo, D. and Guy, O. (1981) Biochim. Biophys. Acta 657, 425-437) during substrate hydrolysis and the present data we discuss a possible mechanism for carboxylic-ester hydrolase catalysis, a mechanism similar to that described for chymotrypsin.

Influence of chain length on the in vitro hydrolysis of model ester prodrugs by ocular esterases

In designing ester prodrugs to improve corneal drug bioavailability, it is important to consider the influence of chain length on both corneal permeation and hydrolysis of the prodrug. However, the second factor has received relatively little attention. The purpose of this study was to evaluate whether the ocular hydrolysis of a homologous series of alpha- and beta-naphthyl esters was influenced by chain length. Solutions of each ester were incubated with selected ocular tissues and fluids of adult albino rabbits. For the alpha-series peak hydrolytic rate was reached at the caproate (C6) ester, coinciding with minimization in the value of the Michaelis-Menten constant (Km) and maximization in the value of maximum velocity (Vmax). For the beta-series peak hydrolytic rate was reached at the valerate (C5) ester. In contrast to the alpha-series this was primarily due to a large increase in value for Km. These findings indicate that the rate of ocular esterase-mediated hydrolysis varies within a homologous series of esters, and that this chain length dependency is influenced by the chemical nature of the parent compound.

Effects of alcohols on hydrolysis catalyzed by beta-D-glucosidase from Stachybotrys atra

The interaction of alcohols in the hydrolysis of aryl beta-D-glucopyranosides and aryl beta-D-xylopyranosides by beta-D-glucosidase (beta-D-glucoside glucohydrolase, EC 3.2.1.21) from Stachybotrys atra has been investigated. The results constitute support for the presence of a glycosyl-enzyme intermediate, formed during the first step (glycosylation) of the proposed two-step mechanism. Transfer of the glycosyl group to an alcohol, with the formation of an alkyl glycopyranoside, can take place in parallel to the transfer to a water molecule (second or deglycosylation step). The alcohol binds to the free enzyme and to the glycosyl-enzyme intermediate. The glycosyl-enzyme-alcohol complex undergoes hydrolysis in addition to the alcoholysis. For aryl beta-D-glucopyranosides the deglycosylation step is rate-limiting. For aryl beta-D-xylopyranosides two kinds of substrate behaviour can be observed. Depending on the substituent group on the phenyl ring, either both steps are rate-controlling or the first step is rate-limiting. Electron-withdrawing substituents increase the rate at which the substrate aglycon group is released.

Effect of alcohols on the hydrolysis catalyzed by human pancreatic carboxylic-ester hydrolase

Transfer reactions catalyzed by human pancreatic carboxylic-ester hydrolase (EC 3.1.1.1) were studied in the presence of methanol and butanol as nucleophiles. The addition of alcohols produced an increase in the total rate of 4-nitrophenyl acetate and n-propylthiol acetate disappearance and a concomitant slow decrease of the hydrolysis rate. These results indicate a competitive partitioning of an acyl-enzyme intermediate between water and nucleophile. Moreover, a strong inhibition of the rates of hydrolysis of methyl butyrate and triacetin by nucleophiles is in agreement with a rate-limiting acylation step. The kinetic data and a trans-ester characterization argue in favor of the formation of an acyl-enzyme intermediate and a two-step reaction mechanism, acylation and deacylation both being rate-limiting. The experiments performed with 4-nitrophenyl acetate show the existence of a nucleophile binding site.

Effect of organic solvents on the beef heart mitochondrial adenosine triphosphatase

The effect of organic solvents on the beef heart mitochondrial ATP-base-catalyzed ATP and ITP hydrolysis was examined. It was observed that numerous organic solvents stimulated ATP hydrolysis while ITP hydrolysis was inhibited. Methanol at 20% (v/v) was found to stimulate ATP hydrolysis by over 300%, while at the same methanol concentration ITP hydrolysis was inhibited approximately 50%. In the presence of 20% methanol, ATP hydrolysis exhibited linear plots of 1/[ATP] vs. 1/v, while in the absence of methanol negative cooperativity was observed. These data can be interpreted to imply that the catalytic and regulatory sites of the mitochondrial ATPase are being dissociated 20% methanol. The effect of methanol on the hydrolysis of ATP and ITP was examined as a function of pH. It was found that, at high pH in totally aqueous solutions, the hydrolysis of ATP and ITP was inhibited, while the presence of 20% methanol either caused the hydrolytic rate to peak and remain constant above pH 8 (with ATP as substrate) or caused the rate of hydrolysis to continue to increase above pH 8 (when ITP was the substrate). These data are interpreted to indicate that an acidic group in the active site may be ionizing, limiting the ATPase-catalyzed hydrolytic rate, and, with 20% methanol, this ionization was inhibited.

Kinetic mechanism of the aliphatic amidase from Pseudomonas aeruginosa

The kinetic constants for hydrolysis and transfer (with hydroxylamine as the alternate acceptor) of the aliphatic amidase (acylamide amidohydrolase, EC 3.5.1.4) from Pseudomonas aeruginosa were determined for a variety of acetyl and propionyl derivatives. The results obtained were consistent with a ping-pong or substitution mechanism. Product inhibition, which was pH dependent, implicated an acyl-enzyme compound as a compulsory intermediate and indicated that ammonia combined additionally with the free enzyme in a dead-end manner. The uncompetitive activation of acetamide hydrolysis by hydroxylamine and the observation that the partitioning of products between acetic acid and acetohydroxamate was linearly dependent on the hydroxylamine concentration substantiated these conclusions and indicated that deacylation was at least partially rate limiting. With propionamide as the acyl donor apparently anomalous results, which included inequalities in certain kinetic constants and a hyperbolic dependence of the partition ratio on the hydroxylamine concentration, could be explained by postulating a compulsory isomerisation of the acyl-enzyme intermediate prior to the transfer reaction.