Lipase-mediated stereoselective hydrolysis of stampidine and other phosphoramidate derivatives of stavudine

Enzymatic hydrolysis of stampidine and other aryl phosphate derivatives of stavudine were investigated using the Candida Antarctica Type B lipase. Modeling studies and comparison of the hydrolysis rate constants revealed a chiral preference of the lipase active site for the putative S-stereoisomer. The in vitro anti-HIV activity of these compounds correlated with their susceptibility to lipase- (but not esterase-) mediated hydrolysis. We propose that stampidine undergoes rapid enzymatic hydrolysis in the presence of lipase according to the following biochemical pathway: During the first step, hydrolysis of the ester group results in the formation of carboxylic acid. Subsequent step involves an intramolecular cyclization at the phosphorous center with simultaneous elimination of the phenoxy group to form a cyclic intermediate. In the presence of water, this intermediate is converted into the active metabolite Ala-d4T-MP. We postulate that the lipase hydrolyzes the methyl ester group of the l-alanine side chain to form the cyclic intermediate in a stereoselective fashion. This hypothesis was supported by experimental data showing that chloroethyl substituted derivatives of stampidine, which possess a chloroethyl linker unit instead of a methyl ester side chain, were resistant to lipase-mediated hydrolysis, which excludes the possibility of a direct hydrolysis of stampidine at the phosphorous center. Thus, our model implies that the lipase-mediated formation of the cyclic intermediate is a key step in metabolism of stampidine and relies on the initial configuration of the stereoisomers.     

Optical resolution of 2-(3-indolyl)propionic acid with Mucor javanicus and α-chymotrypsin

Resolution of 2-(3-indolyl)propionic acid was achieved via biocatalytic hydrolysis of its chloroethyl ester. Of the enzymes tested, Mucor javanicus lipase (R selectivity) and -chymotrypsin (S selectivity) had high reactivity and enantioselectivity (E value > 50). Neither enzyme showed enantioselectivity (E value = 1) for 2-phenylpropionic acid.     

cAMP stimulates cholesteryl ester clearance to high density lipoproteins in J7774 macrophages.

The regulation by cAMP of cholesteryl ester hydrolysis and net depletion of cellular cholesteryl ester (cholesteryl ester clearance) in J774 murine macrophages was explored. Using Sandoz 58035 to selectively inhibit acyl CoA:cholesterol acyltransferase, we showed that the absolute rate of cholesteryl ester hydrolysis was stimulated 2-fold in J774 cells by the cAMP analogues 8-(4-chlorophenylthio)adenosine 3':5'-cyclic monophosphate and dibutyryl-cAMP. The rate of hydrolysis was also stimulated by prostaglandin E1, by cholera toxin, and by a mixture of forskolin and isobutylmethylxanthine, but was not affected by epinephrine or dibutyryl-cGMP. These data demonstrate that cholesteryl ester hydrolysis in J774 cells can be stimulated by cAMP-dependent protein kinase. Cholesteryl ester clearance from J774 cells was achieved upon incubation with high density lipoproteins (HDL) plus CPT-cAMP but not with HDL alone. HDL-mediated cholesteryl ester clearance was dependent on the concentration of both HDL and CPT-cAMP. The data suggest that the defect responsible for the lack of HDL-mediated cholesteryl ester clearance in J774 cells involves a failure to modulate cAMP levels.     

The effect of calcium ions on the hydrolysis of benzoylarginine ethyl ester by porcine enteropeptidase.

Calcium ions are shown to have a marked pH-dependent effect on the kinetics of benzoyllarginine ethyl ester hydrolysis by porcine enteropeptidase (EC 3.4.21.9). Below pH 6.0, calcium ions stimulate benzoylarginine ethyl ester hydrolysis but inhibit this activity above pH 6.0. This effect is mainly on the Km for benzoylarginine ethyl ester. At pH 5.3, 2mM calcium ions reduce the Km for benzoylarginine ethyl ester from 0.31 mM to 0.26 mM while at pH 6.5 the Km increases four-fold from 0.035 mM to 0.12 mM in the presence of calcium ions. Enteropeptidase activity is not inhibited by ethylenediaminetetra-acetate indicating that calcium ions are a non-essential cofactor for benzoylarginine ethyl ester hydrolysis.     

Subtilisin-catalyzed transesterification in supercritical carbon dioxide

Summary Subtilisin Carlsberg was found to catalyze transesterification between N-acetyl-L-phenylalanine chloroethyl ester and ethanol in supercritical carbon dioxide. The effects of different temperatures and carbon dioxide/ethanol ratios on the reaction rate were investigated. A comparative study showed that enzymatic transesterification is faster in supercritical carbon dioxide than in anhydrous organic solvents.     

Phosphotriester formation by the haloethylnitrosoureas and repair of these lesions by E. coli BS21 extracts.

The alkylation of phosphates in DNA by therapeutically active haloethylnitrosoureas was studied by reacting N-chloroethyl-N-nitrosourea (CNU) with dTpdT, separating the products by HPLC, and identifying them by co-chromatography with authentic markers. Both hydroxyethyl and chloroethyl phosphotriesters of dTpdT were identified; a similar reaction between CNU and dTR yielded 3-hydroxyethyl and 3-chloroethyl dTR as the major products of ring alkylation. A DNA-like substrate for repair studies was synthesized by reacting 14C-labelled N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea (14C-CCNU) with poly dT and annealing the product to poly dA. An extract of E. coli strain BS21 selectively transferred a chloroethyl group from one of the chloroethyl phosphotriester isomers in this substrate to the bacterial protein; chemical instability of the hydroxyethyl phosphotriesters precluded definite conclusions about the repair of this product.     

Kinetic evaluation of a metalated diglycine conjugate as a functional mimetic of phosphate ester hydrolase.

The crucial role of phosphate ester hydrolysis in various biological processes has spurred vigorous research activities to understand mechanisms of phosphate ester hydrolysis and to develop model systems that assist the above-mentioned reaction in a catalytic fashion. In the present study, we describe a novel, metalated peptide conjugate 4 possessing phosphate ester hydrolyzing activity against a phosphate monoester, diester, and a RNA chemical model. The design of conjugate 4 is inspired by the ATCUN binding tripeptide motif of serum albumin and involves tethering of two diglycine units by a flexible 1,3-diaminopropane linker. Detailed kinetic investigations of phosphate ester hydrolysis using model substrates and efforts to decipher underlying mechanisms are presented.     

Synthesis and cytotoxic activity of a glucuronylated prodrug of nornitrogen mustard

A new glucuronylated prodrug of nornitrogen mustard, incorporating the same spacer group as the doxorubicin prodrug HMR 1826, has been prepared. Upon exposure to E. coli beta-glucuronidase, fast hydrolysis occurs but a lower cytotoxicity against LoVo cancer cells is observed compared to the nornitrogen mustard alone. This is explained by cyclization of the intermediate carbamic acid to the inactive chloroethyl oxazolidinone.     

Degradation of chylomicron remnant cholesteryl ester by rat hepatocyte monolayers. Inhibition by chloroquine and colchicine

Rat hepatocytes in monolayer cultures take up and degrade cholesteryl ester of isolated chylomicron remnants. The cholesteryl ester of native chylomicrons was metabolized at a slower rate. The uptake of cholesteryl ester was decreased by the presence of serum. The hydrolysis of cholesteryl ester but not the uptake or binding of chylomicron remnants by the cells was inhibited by chloroquine, which is known to inhibit the lysosomal degradation of protein and of low density lipoproteins by fibroblasts. Colchicine, which inhibits the hydrolysis of chylomicron cholesteryl ester after the uptake by the liver in vivo, had the same effect in hepatocyte monolayers.     

Chemoenzymatic synthesis of 3'-O-(carboxyalkyl)fluorescein labels.

A general and versatile method is described for the synthesis of fluorescent labels. Coupling of the 3'-phenol of fluorescein methyl ester with hydroxyalkyl benzyl esters, followed by benzyl ester hydrolysis, provided a series of fluorescein carboxyalkyl ethers. Use of the Mitsunobu reaction allowed for the introduction of linkers of different lengths onto the 3'-phenol of fluorescein. Chemoenzymatic benzyl ester hydrolysis was achieved with LPL-80 lipase, providing pH-independent labels useful for the preparation of fluorescent conjugates.     

Hydrolysis of chyle cholesterol esters with cell-free preparations of rat liver.

1. The effect of pH on the hydrolysis of chylomicron and chylomicron remnant cholesterol ester with rat liver homogenate was examined. The hydrolysis had three pH optima, at pH 4.5, at pH 6.0-6.5 and at pH 8.5. At the two upper pH optima extensive cholesterol ester hydrolysis occurred without simultaneous degradation of the triacylglycerol portion. 2. Similarly, microsomes (at pH 6.5-8.0) and 100 000 X g supernatant (at pH 7.5-8.5) efficiently hydrolyzed the cholesterol ester but not the triacylglycerol of chylomicron remnants. 3. With the same substrate no enrichment of neutral cholesterol esterase activity was seen in isolated plasma membranes. 4. At pH 4.5 lysosomes efficiently hydrolyzed both the cholesterol ester and the triacylglycerol portion of chylomicron remnants. 5. Three conclusions are drawn: (a) the study provides evidence against the existence of a plasma membrane-bound enzyme-hydrolyzing chylomicron cholesterol ester before or during its penetration into the cell; (b) enzymes of the cell sap and possibly of the endoplasmic reticulum can degrade cholesterol ester of chylomicron remnants without preceeding hydrolysis of the triacylglycerol core; and (c) lysosomal enzymes can degrade both the cholesterol ester and the triacylglycerol portion of chylomicron remnants if these are taken up as whole particles by endocytosis.     

Hydrolysis of cholesteryl ester in low density lipoprotein converts this lipoprotein to a liposome.

Previously, we isolated and characterized unique liposomal-like, cholesterol-rich lipid particles that accumulate in human atherosclerotic lesions. Human plasma low density lipoprotein (LDL) has a molar ratio of total cholesterol to phospholipid (3:1) similar to that of this lesion cholesterol-rich lipid particle. However, LDL is enriched in cholesteryl ester while the lesion lipid particle is enriched in unesterified cholesterol. To examine a possible precursor-product relationship between LDL and the lesion lipid particle, we hydrolyzed the cholesteryl ester core of LDL with cholesterol esterase. Cholesteryl ester hydrolysis occurred only after LDL was treated with trypsin. Trypsin pretreatment was not required for cholesteryl ester hydrolysis of LDL oxidized with copper, a treatment that also degrades apolipoprotein B, the major protein moiety in LDL. In contrast to greater than 90% hydrolysis of cholesteryl ester in trypsin-cholesterol esterase-treated or copper-oxidized LDL, there was only 18% hydrolysis of cholesteryl ester in similarly treated high density lipoprotein. With a limited 10-min hydrolysis of LDL cholesteryl ester, LDL-sized particles and newly formed larger flattened films or discs were present. With complete hydrolysis of LDL cholesteryl ester, LDL particles converted to complex multilamellar, liposomal-like, structures with sizes approximately five times larger than native LDL. These liposomal-like particles derived from LDL were chemically and structurally similar to unesterified cholesterol-rich lipid particles that accumulate in atherosclerotic lesions.     

Isosteric conversion of protein carboxyl groups into carboxamide groups. II. Application to lysozyme

For isosteric conversion of carboxyl groups of proteins into amide groups, ammonolysis of protein esters under mild conditions was attempted. Ammonolysis of methyl esters of lysozyme and bovine serum albumin proved to be incomplete. Highly reactive N-ethylsalicylamide esters of guanylated lysozyme were therefore prepared by subjecting the protein to reaction with N-ethylbenzisoxazolium ion at pH 4.2, 0 degree. Per molecule, 5-7 ester groups were introduced, with concomitant decrease of activity of 80-90%. Only 0.3 tyrosine was modified. On hydrolysis at pH 9.2 the activity was completely restored. At pH 7.9 three classes of ester groups could be distinguished: one group of high rate of hydrolysis (k1 = 1.5 min-1), three groups of intermediate rate (k2 = 0.13 min-1) and two groups of low rate (k3 = 0.018 min-1). The intermediate rate approximated the rate of hydrolysis of the model compound benzoylglycine N-ethylsalicylamide ester (k = 0.15 min-1). Ammonolysis at pH 9.2 in 2.0 M ammonia/ammonium acetate provided complete conversion of the ester groups into amide groups without restoration of activity, confirming the essentiality of certain carboxyl groups. In particular, rearrangement of the ester groups into relatively stable imide groups by O-N acyl migration was found to be completely absent. When native lysozyme was esterified with N-ethylbenzisoxazolium ion the activity did not completely return on hydrolysis.     

Cholate-independent retinyl ester hydrolysis. Stimulation by Apo-cellular retinol-binding protein

Apo-cellular retinol-binding protein (apoCRBP) activated the hydrolysis of endogenous retinyl esters in rat liver microsomes by a cholate independent retinyl ester hydrolase. A Michaelis-Menten relationship was observed between the apoCRBP concentration and the rate of retinol formation, with half-maximum stimulation at 2.6 +/- 0.6 microM (mean +/- S.D., n = 5). Two other retinol-binding proteins, bovine serum albumin and beta-lactoglobulin, acceptors for the rapid and spontaneous hydration of retinol from membranes, had no effect up to 90 microM. These data suggest activation of the hydrolase by apoCRBP directly, rather than by facilitating removal of retinol from membranes. The hydrolase responding was the cholate-independent/cholate-inhibited retinyl ester hydrolase as shown by: 60% inhibition of the apoCRBP effect by 3 mM cholate; apoCRBP enhancement of retinyl ester hydrolysis in liver microsomes that had no detectable cholate-enhanced activity; inhibition of cholate-dependent, but not apoCRBP-stimulated retinyl ester hydrolysis by rabbit anti-rat cholesteryl esterase. Compared to the rate (mean +/- S.D. of [n] different preparations) supported by 5 microM apoCRBP in liver microsomes of 6.7 +/- 3.7 pmol/min/mg protein [10], microsomes from rat lung, kidney, and testes had endogenous retinyl ester hydrolysis rates of 1.8 +/- 0.3 [5], 0.5 +/- 0.2 [3], and 0.3 +/- 0.2 [5] pmol/min/mg protein, respectively. N-Ethylmaleimide and N-tosyl-L-phenylalanine chloromethyl ketone were potent inhibitors of apoCRBP-stimulated hydrolysis with IC50 values of 0.25 and 0.15 mM, respectively, but phenylmethylsulfonyl fluoride and diisopropyl-fluorophosphate were less effective with IC50 values of 1 mM, indicating the importance of imidazole and sulfhydryl groups to the activity. These data provide evidence of a physiological role for the cholate-independent hydrolase in retinoid metabolism and suggest that apoCRBP is a signal for retinyl ester mobilization.     

Binding sites of cholinesterases. Alkylation by an aziridinium derivative

1. Alkylation of acetylcholinesterase and butyrylcholinesterase by 2-chloro-N-(chloroethyl)-N-methyl-2-phenylethylamine was observed. This alkylating agent was more potent than related compounds previously described, and less stable (half-life 8.5min. at 23 degrees ). 2. Alkylation had effects on hydrolysis of substrates varying from activation for indophenyl acetate to inhibition for acetylcholine, and intermediate effects with five other substrates. The effects were on V(max.) and not K(m). 3. Alkylation caused a variety of changes in sensitivity to inhibition by five carbamates, five organophosphates and four other inhibitors, varying from total protection against tetraethylammonium to mildly enhanced sensitivity to urea. 4. The findings suggested the existence of three binding sites, one of which was anionic and another hydrophobic, in addition to the esteratic site.     

A kinetic study of the hydrolysis of N-acetyl dehydroalanine methyl ester.

Hydrolysis rates of N-acetyl dehydroalanine methyl ester (methyl 2-acetamidoacrylate) and related model compounds were measured in aqueous, organic and mixed aqueous media. Adding dimethylsulfoxide (DMSO) to water, retarded hydrolysis of the ester by a factor of 2 to 500, depending on the pH of the medium and concentration of DMSO. Ethanol also slowed hydrolysis, but the effect was not so pronounced. Related studies show that the acetamido group C-N bond of sodium 2-acetamido-acrylate is hydrolyzed only about 1/130 as fast as the ester group C-O bond. Aqueous dimethyl sulfoxide should by a useful medium for synthesis of peptide, amino acid and protein derivatives of N-acetyl dehydroalanine methyl ester.     

The effect of high pressure on the rates of proteolytic hydrolysis,II. Trypsin

The interpretation of the volume change of activation for varying conditions of proteolytic hydrolysis is discussed.A volume change of activation of ?36 ml. was calculated from the acceleration of the rate of hydrolysis of β-lactoglobulin by crystalline trypsin.While the rates of hydrolysis of α-benzoyl-l-argininamide and α-benzoyl-l-arginine isopropyl ester were unaffected by pressures of 8000 lb./in.², the hydrolysis of l-arginine methyl ester was slightly accelerated, the volume change of activation being ?6 ml.At 54.5 °C. and pH 8.1 high pressures accelerate the hydrolysis of α-benzoyl-l-argininamide by crystalline trypsin indicating that heat inactivation is retarded at higher pressures.     

Effects of anti-microtubular agents and cycloheximide on the metabolism of chylomicron cholesteryl esters by hepatocyte suspensions.

1. Post-heparin plasma that promoted rapid hydrolysis of about 90% of the triacylglycerol markedly stimulated the uptake or binding of chylomicron cholesteryl ester by suspended hepatocytes. The net hydrolysis of chyle cholesteryl ester after the uptake by the cells was, however, slower than in vivo. 2. The cholesteryl ester uptake in the presence of post-heparin plasma was larger if the cells had been preincubated for 2h. It was inhibited by the presence of colchicine, vinblastine or cycloheximide during the preincubation, and by mild trypsin treatment of the preincubated cells. 3. The results suggested that the anti-microtubular agents, but not cycloheximide, also inhibited the hydrolysis of chyle cholesteryl ester after uptake or binding to the cells. 4. The uptake of isolated chylomicron remnant particles was more efficient than that of native chyle lipoproteins. It was, however, still stimulated by heparin alone and by post-heparin plasma. The heparin-stimulated uptake was markedly decreased if cycloheximide was present during the preincubation period.     

Methanolysis of cholesteryl esters: conditions for quantitative preparation of methyl esters.

We have investigated the conditions required to obtain a quantitative yield of methyl esters from cholesteryl esters by alkaline methanolysis. Methanolysis of the cholesteryl ester for 60 min at room temperature with 1 m methoxide reagent ensured complete reaction. Some ester hydrolysis always accompanied methanolysis and necessitated acid-catalyzed methylation of the resultant fatty acids after completion of the alcoholysis. Analysis of the composition of methyl ester product and remaining cholesteryl ester substrate before methanolysis had gone to completion showed selective hydrolysis of some fatty acid cholesteryl esters and illustrates the importance of obtaining a quantitative yield of methyl esters following methanolysis.     

Role of lysosomal acid lipase in the metabolism of plasma low density lipoprotein. Observations in cultured fibroblasts from a patient with cholesteryl ester storage disease.

The hydrolysis of cholesteryl esters contained in plasma low density lipoprotein was reduced in cultured fibroblasts derived from a patient with cholesteryl ester storage disease, an inborn error of metabolism in which lysosomal acid lipase activity is deficient. While these mutant cells showed a normal ability to bind low density lipoprotein at its high affinity cell surface receptor site, to take up the bound lipoprotein through endocytosis, and to hydrolyze the protein component of the lipoprotein in lysosomes, their defective lysosomal hydrolysis of the cholesteryl ester component of the lipoprotein led to the accumulation within the cell of unhydrolyzed cholesteryl esters, the fatty acid distribution of which resembled that of plasma lipoprotein. When the cholesteryl ester storage disease cells were incubated with low density lipoprotein, the reduced rate of liberation of free cholesterol by these mutant cells was associated with a delay in the occurrence of two lipoprotein-mediated regulatory events, suppression of 3-hydroxy-3-methylglutaryl coenzyme A reductase activity, and activation of endogenous cholesteryl ester formation. In contrast to their defective hydrolysis of exogenously derived lipoprotein-bound cholesteryl esters, the choleseryl ester storage disease cells showed a normal rate of hydrolysis of cholesteryl esters that had been synthesized within the cell. These data lend support to the concept that in cultured human fibroblasts cholesteryl esters entering the cell bound to low density lipoprotein are hydrolyzed within the lysosome and that one of the functions of this intracellular organelle is to supply the cell with free cholesterol.