Protease-catalyzed peptide synthesis using inverse substrates: the synthesis of Pro-Xaa-bonds by trypsin

Benzyloxycarbonyl-L-proline p-guanidinophenyl ester is an "inverse substrate" for trypsin; i.e., the cationic center is included in the leaving group instead of being in the acyl moiety. This substrate can be used in trypsin-catalyzed acyl-transfer reactions leading to the synthesis of Pro-Xaa peptide bonds. The reaction proceeds about 20 times slower than reaction with similar alanine-containing substrates, but the ratio between synthesis and hydrolysis is more favorable. The investigation of a series of nucleophiles led to information about the specificity of the process. Nucleophiles differing only in the P(1)'-position show an increasing acyl transfer efficiency in the order Phe < Gly < Ley < Ser < Ala < lle. C terminal elongation of the nucleophiles is of minor influence on their efficiency. The formation of an H bond between the acyl-enzyme and the nucleophile seems to play an important role in the aminolysis of the acyl-enzyme.     

Trypsin-catalyzed peptide synthesis withm-guanidinophenyl andm-(guanidinomethyl)phenyl esters as acyl donor component

Summary Two series of inverse substrates,m-guanidinophenyl andm-(guanidinomethyl)phenyl esters derived fromN-(tert-butyloxycarbonyl)amino acid, were prepared as an acyl donor component for trypsin-catalyzed peptide synthesis. The kinetic behavior of these esters toward tryptic hydrolysis was analyzed. They were found to couple with an acyl acceptor such asl-alaninep-nitroanilide to produce dipeptide in the presence of trypsin.Streptomyces griseus trypsin was a more efficient catalyst than the bovine trypsin. Within the enzymatic peptide coupling methods, this approach was shown to be advantageous, since the resulting peptides are resistant to the enzymatic hydrolysis.Abbreviations Boc tert-butyloxycarbonyl - Aib -aminoisobutyric acid - DMSO dimethylsulfoxide - Tris tris(hydroxymethyl)aminomethane - MOPS 3-morpholino-l-prop anesulfonate - G guanidinophenyl - GM (guanidinomethyl)phenyl - pNA p-nitroanilide     

Kinetics of trypsin-catalyzed hydrolysis of some arginine-containing peptide methyl esters

The kinetics of trypsin-catalyzed hydrolysis (at pH 8.5) of methyl esters of some synthetic dipeptides containing the residues of both arginine and L(D)-p-fluorophenylalanine or L(D)-tyrosine has been studied. The digestion of Tos-(pF)Phe-Arg-OMe was shown as unfollowing the Michaelis-Menten kinetic since in the reaction course the substrate activation is observed and while the reaction product is the enzymatic process inhibitor. In contrast to this, the hydrolysis of other substrates studied, follows the normal Michaelis-Menten kinetic.     

Comparison of the kinetics of the papain-catalyzed hydrolysis of glycine- and alanine-based esters and thiono esters

The kinetic constants for the papain-catalyzed hydrolysis of a series of substrates with glycine or alanine in the P1 position are discussed. The substrates have N-benzoyl, N-(p-nitrobenzoyl), N-(beta-phenylpropionyl), or N-(methyloxycarbonyl)phenylalanine attached to the P1 moiety, and kinetic constants are obtained for both esters and thiono esters. The results for the hydrolysis of esters can be readily interpreted in terms of the known specificity of papain. For any glycine ester the change in kcat/Km upon substituting C=S for C=O or upon substituting an alpha-CH3 group is minimal. However, upon making both these substitutions, i.e., going from a glycine ester to an alanine thiono ester substrate, larger changes are seen for this ratio. Data for N-benzoyl- and N-(beta-phenylpropionyl)glycine and -alanine methyl thiono esters show that k2 is the parameter most affected by the double C=S and alpha-CH3 substitution. A further conclusion is that the deacylation rate constants for any pair of glycine and alanine dithioacyl papains are similar; e.g., for the intermediates based on the "good" substrates PheAla and PheGly k3 differs by only 20%. This is a surprising finding in light of the very different conformations and interactions of the bound acyl groups revealed by resonance Raman spectroscopy and raises the possibility that specific stereochemical effects, such as the oxyanion hole and general base catalysis, are not operating in the hydrolysis of dithioacyl papains.     

Comparison of the kinetics and mechanism of the papain-catalyzed hydrolysis of esters and thiono esters

The kinetic constants for the papain-catalyzed hydrolysis of the methyl thiono esters of N-benzoylglycine and N-(beta-phenylpropionyl)glycine are compared with those for the corresponding methyl ester substrates. The k2/Ks values for the thiono esters are 2-3 times higher than those for the esters, and both show bell-shaped pH dependencies with similar pKa's (approximately 4 and 9). The k3 values for the thiono esters are 30-60 times less than those for the esters and do not exhibit a pH dependency. Solvent deuterium isotope effects on k2/Ks and k3 were measured for the ester and thiono ester substrates of both glycine derivatives. Each thiono ester substrate showed an isotope effect similar to that for the corresponding ester substrate. Moreover, use of the proton inventory technique indicated that, as for esters, one proton is transferred in the transition state for deacylation during reactions involving thiono esters and the degree of heavy atom reorganization in the transition state is very similar in both cases. The k3 values for the hydrolysis of a series of para-substituted N-benzoylglycine esters were found to correlate with the k3 values for the corresponding para-substituted thiono esters [Carey, P. R., Lee, H., Ozaki, Y., & Storer, A. C. (1984) J. Am. Chem. Soc. 106, 8258-8262], showing that the rate-determining step for the deacylation of both thiolacyl and dithioacyl enzymes probably involves the disruption of a contact between the substrate's glycinic nitrogen atom and the sulfur of cysteine-25. It is concluded that the hydrolysis of esters and thiono esters proceeds by essentially the same reaction pathway. Due to an oxygen-sulfur exchange process the product released in the case of the N-(beta-phenylpropionyl)glycine thiono ester substrate is the dioxygen acid; however, for the N-benzoylglycine thiono ester substrate, the thiol acid is the initial product. This thiol acid then acts as a substrate for papain and reacylates the enzyme to eventually give the dioxygen acid product. It is shown that thiol acids are excellent substrates for papain.     

Inhibitory effect of methyl esters of arginine-containing oligopeptides on thrombin and trypsin

Stereoisomeric oligopeptides were studied for their inhibitory effect on the hydrolysis of benzoyl-L-arginine methyl ester catalyzed by thrombin and trypsin, as well as on the thrombin-fibrinogen reaction. Comparison of the peptide structures, their conformational flexibility and inhibitory effects on thrombin and trypsin shows the availability of the essential differences in organization and functioning of the subsites S3, S2 and S'1 of these enzymes. In contrast to trypsin, thrombin is shown to be characterized by more pronounced secondary stereospecificity. This manifests in the more vigorous dropping of the catalytic constants of thrombin-catalyzed esterolysis than those of trypsin-catalyzed hydrolysis of the substrates, containing D-amino acids at the subsite P2. It is revealed that the peptide Tos-D-Val-D-Ala-D-Agr-D-Phe-OCH3 is the most powerful inhibitor among studied compounds. It is noteworthy that its antithrombin effect is almost an order of magnitude higher than its antitrypsin effect.     

Kinetic analysis of effector modulation of butyrylcholinesterase-catalysed hydrolysis of acetanilides and homologous esters

The effects of tyramine, serotonin and benzalkonium on the esterase and aryl acylamidase activities of wild-type human butyrylcholinesterase and its peripheral anionic site mutant, D70G, were investigated. The kinetic study was carried out under steady-state conditions with neutral and positively charged aryl acylamides [o-nitrophenylacetanilide, o-nitrotrifluorophenylacetanilide and m-(acetamido) N,N,N-trimethylanilinium] and homologous esters (o-nitrophenyl acetate and acetylthiocholine). Tyramine was an activator of hydrolysis for neutral substrates and an inhibitor of hydrolysis for positively charged substrates. The affinity of D70G for tyramine was lower than that of the wild-type enzyme. Tyramine activation of hydrolysis for neutral substrates by D70G was linear. Tyramine was found to be a pure competitive inhibitor of hydrolysis for positively charged substrates with both wild-type butyrylcholinesterase and D70G. Serotonin inhibited both esterase and aryl acylamidase activities for both positively charged and neutral substrates. Inhibition of wild-type butyrylcholinesterase was hyperbolic (i.e. partial) with neutral substrates and linear with positively charged substrates. Inhibition of D70G was linear with all substrates. A comparison of the effects of tyramine and serotonin on D70G versus the wild-type enzyme indicated that: (a) the peripheral anionic site is involved in the nonlinear activation and inhibition of the wild-type enzyme; and (b) in the presence of charged substrates, the ligand does not bind to the peripheral anionic site, so that ligand effects are linear, reflecting their sole interaction with the active site binding locus. Benzalkonium acted as an activator at low concentrations with neutral substrates. High concentrations of benzalkonium caused parabolic inhibition of the activity with neutral substrates for both wild-type butyrylcholinesterase and D70G, suggesting multiple binding sites. Benzalkonium caused linear, noncompetitive inhibition of the positively charged aryl acetanilide m-(acetamido) N,N,N-trimethylanilinium for D70G, and an unusual mixed-type inhibition/activation (alpha > beta > 1) for wild-type butyrylcholinesterase with this substrate. No fundamental difference was observed between the effects of ligands on the butyrylcholinesterase-catalysed hydrolysis of esters and amides. Thus, butyrylcholinesterase uses the same machinery, i.e. the catalytic triad S198/H448/E325, for the hydrolysis of both types of substrate. The differences in response to ligand binding depend on whether the substrates are neutral or positively charged, i.e. the differences depend on the function of the peripheral site in wild-type butyrylcholinesterase, or the absence of its function in the D70G mutant. The complex inhibition/activation effects of effectors, depending on the integrity of the peripheral anionic site, reflect the allosteric 'cross-talk' between the peripheral anionic site and the catalytic centre.     

Mechanism for the hydrolysis of organophosphates by the bacterial phosphotriesterase

Phosphotriesterase (PTE) from Pseudomonas diminuta is a zinc metalloenzyme that hydrolyzes a variety of organophosphorus compounds. The kinetic parameters of Zn/Zn PTE, Cd/Cd PTE, and a mixed-metal Zn/Cd hybrid PTE were obtained with a variety of substrates to determine the role of each metal ion in binding and catalysis. pH-rate profiles for the hydrolysis of diethyl p-nitrophenyl phosphate (I) and diethyl p-chlorophenyl phosphate (II) demonstrated that the ionization of a single group in the pH range of 5-10 was critical for substrate turnover. The pK(a) values determined from the kinetic assays were dependent on the identity of the metal ion that occupied the alpha site within the binuclear metal center. These results suggest that the hydrolytic nucleophile is activated as a hydroxide via the ionization of a water molecule attached to the alpha-metal ion. The kinetic constants for the hydrolysis of II and diethyl p-chlorophenyl thiophosphate (IV) were determined for the metal substituted forms of PTE. The kinetic constants for IV were greater than those for II. The inverse thio effect is consistent with the polarization of the phosphoryl oxygen/sulfur bond via a direct ligation to the metal center. The rate enhancement is greater when Cd(2+) occupies the beta-metal-ion position. A series of alanine and asparagine mutations were used to characterize the catalytic roles of Asp233, His254, and Asp301. Mutations to either Asp233 or His254 resulted in an enhanced rate of hydrolysis for the sluggish substrate, diethyl p-chlorophenyl phosphate, and a decrease in the kinetic constants for paraoxon (I). These results are consistent with the existence of a proton relay from Asp301 to His254 to Asp233 that is used to ferry protons away from the active site with substrates that do not require activation of the leaving group phenol. A mechanism for the hydrolysis of organophosphates by the bacterial PTE has been proposed.     

Thioamide substrate probes of metal-substrate interactions in carboxypeptidase A catalysis

Three thioamide peptides in which the oxygen atom of the scissile peptide bond is replaced by sulfur (denoted by (= S)) were synthesized and found to be good, convenient substrates for carboxypeptidase A. The thioamide bond absorbs strongly in the ultraviolet region, and enzymatic hydrolysis is monitored easily using a continuously recording spectrophotometric assay. The reaction follows Michaelis-Menten kinetics with kcat values of 68, 9.0, and 3.7 sec-1 and Km values of 0.83, 0.81, and 0.53 mM for Z-Glu-Phe(= S)-Phe, Z-Gly-Ala(= S)-Phe, and Z-Phe(= S)-Phe, respectively. Activities of the thioamides and their oxygen amide analogs were determined with a series of metal-substituted carboxypeptidases. The Cd(II), Mn(II), Co(II), and Ni(II) enzymes exhibit 30%-35%, 60%-85%, 150%-190%, and 40%-55% of the Zn(II) enzyme activity with the amide substrates; this compares with 240%-970%, 0%-15%, 340%-840%, and 30%-140% of the Zn(II) activity, respectively, with the thioamides. The activity of the Cu(II) and Hg(II) enzymes is less than 3% toward all substrates. Cadmium, a thiophilic metal, yields an enzyme which is exceedingly active with the thioamides; the kcat/Km values are 2.4-9.7-fold higher than with Zn(II) carboxypeptidase. In contrast, Mn(II), which has a relatively low affinity for sulfur, yields an enzyme with correspondingly low activity toward the thioamides. The results are consistent with a mechanism for peptide bond hydrolysis in which the metal atom interacts with the substrate carbonyl atom during catalysis.     

Interaction of carboxypeptidase A with carbamate and carbonate esters

The carbamate ester N-(phenoxycarbonyl)-L-phenylalanine binds well to carboxypeptidase A in the manner of peptide substrates. The ester exhibits linear competitive inhibition toward carboxypeptidase A catalyzed hydrolysis of the amide hippuryl-L-phenylalanine (Ki = 1.0 X 10(-3) M at pH 7.5) and linear noncompetitive inhibition toward hydrolysis of the specific ester substrate O-hippuryl-L-beta-phenyllactate (Ki = 1.4 X 10(-3) M at pH 7.5). Linear inhibition shows that only one molecule of inhibitor is bound per active site at pH 7.5. The hydrolysis of the carbamate ester is not affected by the presence of 10(-8)-10(-9) M enzyme (the concentrations employed in inhibition experiments), but at an enzyme concentration of 3 X 10(-6) M catalysis can be detected. The value of kcat at 30 degrees C, mu = 0.5 M, and pH 7.45 is 0.25 s-1, and Km is 1.5 X 10(-3) M. The near identity of Km and Ki shows that Km is a dissociation constant. Substrate inhibition can be detected at pH less than 7 but not at pH values above 7, which suggests that a conformational change is occurring near that pH. The analogous carbonate ester O-(phenoxycarbonyl)-L-beta-phenyllactic acid is also a substrate for the enzyme. The Km is pH independent from pH 6.5 to 9 and has the value of 7.6 X 10(-5) M in that pH region. The rate constant kcat is pH independent from pH 8 to 10 at 30 degrees C (mu = 0.5 M) with a limiting value of 1.60 s-1. Modification of the carboxyl group of glutamic acid-270 to the methoxyamide strongly inhibits the hydrolysis of O-(phenoxycarbonyl)-L-beta-phenyllactic acid. Binding of beta-phenyllactate esters and phenylalanine amides must occur in different subsites, but the ratios of kcat and kcat/Km for the structural change from hippuryl to phenoxy in each series are closely similar, which suggests that the rate-determining steps are mechanistically similar.     

Transition-state stabilization at the oxyanion binding sites of serine and thiol proteinases: hydrolyses of thiono and oxygen esters

X-ray diffraction studies suggested that the tetrahedral intermediate formed during the catalysis by serine and thiol proteinases can be stabilized by hydrogen bonds from the protein to the oxyanion of the intermediate [cf. Kraut, J. (1977) Annu. Rev. Biochem. 46, 331-358; Drenth, J., Kalk, K.H., & Swen, H.M. (1976) Biochemistry 15, 3731-3738]. To obtain evidence in favor or against this hypothesis, we synthesized thiono substrates (the derivatives of N-benzoyl-glycine methyl ester and N-acetylphenylalanine ethyl ester) containing a sulfur in place of the carbonyl oxygen atom of the scissile ester bond. We anticipated that this relatively subtle structural change specifically directed to the oxyanion binding site should produce serious catalytic consequences owing to the different properties of oxygen and sulfur if transition-state stabilization in the oxyanion hole is indeed important. In fact, while in alkaline hydrolysis the chemical reactivities of oxygen esters and corresponding thiono esters proved to be similar, neither chymotrypsin nor subtilisin hydrolyzed the thiono esters at a measurable rate. This result substantiates the crucial role of the oxyanion binding site in serine proteinase catalysis. On the basis of the similar values of the binding constants found for oxygen esters and their thiono counterparts, it can be concluded that the substitution of sulfur for oxygen significantly influences transition state stabilization but not substrate binding. The thiol proteinases papain and chymopapain react with the oxygen and thiono esters of N-benzoylglycine at similar rates. Apparently, in these reactions the above stabilizing mechanism is absent or not important, which is a major mechanistic difference between the catalyses by serine and thiol proteinases.     

A mechanistic view of enzyme inhibition and peptide hydrolysis in the active site of the SARS-CoV 3C-like peptidase

The 3C-like main peptidase 3CL(pro) is a viral polyprotein processing enzyme essential for the viability of the Severe Acute Respiratory Syndrome coronavirus (SARS-CoV). While it is generalized that 3CL(pro) and the structurally related 3C(pro) viral peptidases cleave their substrates via a mechanism similar to that underlying the peptide hydrolysis by chymotrypsin-like serine proteinases (CLSPs), some of the hypothesized key intermediates have not been structurally characterized. Here, we present three crystal structures of SARS 3CL(pro) in complex with each of two members of a new class of peptide-based phthalhydrazide inhibitors. Both inhibitors form an unusual thiiranium ring with the nucleophilic sulfur atom of Cys145, trapping the enzyme's catalytic residues in configurations similar to the intermediate states proposed to exist during the hydrolysis of native substrates. Most significantly, our crystallographic data are consistent with a scenario in which a water molecule, possibly via indirect coordination from the carbonyl oxygen of Thr26, has initiated nucleophilic attack on the enzyme-bound inhibitor. Our data suggest that this structure resembles that of the proposed tetrahedral intermediate during the deacylation step of normal peptidyl cleavage.     

Analysis of the relationship between the reactivity of synthetic substrates and thrombin inhibitors and their structure

Kinetics of thrombin- and trypsin-catalyzed hydrolysis of diphenylacetyl-L-arginine esters was studied at pH 8.5 and 25 degrees C, and the antithrombin activity of in vitro synthesized compounds was examined. The anticlotting activity of arylsulphonyl-L-arginine methyl esters appeared to be higher than that of the derivatives of diphenyl arginine. Relations were found connecting polar (delta) and steric (Es) characteristics of substituent (R) in R-C6H4-SO2-Arg-OCH3 esters with their antithrombin activity in vitro or with efficiency of their thrombin-catalyzed hydrolysis. This gives supplementary possibilities for synthesis of new substrates and more potent thrombin inhibitors.     

The substrate specificity of trypsin. The interrelationship between the structure and reactivity for quasi-substrates, derivatives of O-alkylmethylphosphonic acid and carboxylic acids

The kinetics of trypsin phosphorylation by thioesters of O-n-alkylmethylphosphonic acids, and reactivation of corresponding phosphoryl enzymes as well as kinetics of trypsin-catalyzed hydrolysis of p-nitrophenylcarboxylates have been studied. The rate constants for phosphorylation and dephosphorylation of trypsin depend on hydrophobicity of non-polar fragments in both substrate series in the same degree. On the other hand, the deacylation rate constants for a series of acyl trypsins do not change significantly while the apparent Michaelis constants change consistently with variations of non-polar acyl substituent. The study of substrate specificity of trypsin in terms of the transition state theory has allowed to elucidate the basis for low reactivity of trypsin towards the quasisubstrates.     

Kinetics of trypsin-catalyzed hydrolysis determined by isothermal titration calorimetry

Isothermal titration calorimetry (ITC) was applied to determine enzymatic activity and inhibition. We measured the Michaelis–Menten kinetics for trypsin-catalyzed hydrolysis of two substrates, casein (an insoluble macromolecule substrate) and Nα-benzoyl-dl-arginine β-naphthylamide (a small substrate), and estimated the thermodynamic parameters in the temperature range from 20 to 37 °C. The inhibitory activities of reversible (small molecule benzamidine) and irreversible (small molecule phenylmethanesulfonyl fluoride and macromolecule α1-antitrypsin) inhibitors of trypsin were also determined. We showed the usefulness of ITC for fast and direct measurement of inhibition constants and half-maximal inhibitory concentrations and for predictions of the mechanism of inhibition. ITC kinetic assays could be an easy and straightforward way to estimate Michaelis–Menten constants and the effectiveness of inhibitors as well as to predict the inhibition mechanism. ITC efficiency was found to be similar to that of classical spectrophotometric enzymatic assays.     

The structure-activity relationship of the papain hydrolysis of N-benzoylglycine esters

The relationship between structure and the Michaelis-Menten constants (Km) for the papain hydrolysis of a series of 37 N-benzoylglycine esters was investigated. The series studied comprises a wide range of aromatic and aliphatic esters with a 5000-fold variation in their Km constants and essentially constant kcat values. It was found that the variation in the Km constants could be rationalized by the following quantitative structure-activity relationship (QSAR): log 1/Km = 8.13F + 0.33Z + 1.27II3' + 1.95. In this equation F is the field inductive parameter, II3' is the hydrophobic constant for the more lipophilic of the two possible meta substituents and Z is the Van der Waals distance from oxygen through the end of the molecule, in the direction of the 4 position of the aromatic ester moiety.     

Identification of spirocyclic piperidine-azetidine inverse agonists of the ghrelin receptor

The discovery of spirocyclic piperidine-azetidine inverse agonists of the ghrelin receptor is described. The characterization and redressing of the issues associated with these compounds is detailed. An efficient three-step synthesis and a binding assay were relied upon as the primary means of rapidly improving potency and ADMET properties for this class of inverse agonist compounds. Compound 10 n bearing distributed polarity in the form of an imidazo-thiazole acetamide and a phenyl triazole is a unit lower in logP and has significantly improved binding affinity compared to the hit molecule 10a, providing support for further optimization of this series of compounds.     

Dynamical properties of model gene networks and implications for the inverse problem

We study the inverse problem, or the "reverse-engineering" problem, for two abstract models of gene expression dynamics, discrete-time Boolean networks and continuous-time switching networks. Formally, the inverse problem is similar for both types of networks. For each gene, its regulators and its Boolean dynamics function must be identified. However, differences in the dynamical properties of these two types of networks affect the amount of data that is necessary for solving the inverse problem. We derive estimates for the average amounts of time series data required to solve the inverse problem for randomly generated Boolean and continuous-time switching networks. We also derive a lower bound on the amount of data needed that holds for both types of networks. We find that the amount of data required is logarithmic in the number of genes for Boolean networks, matching the general lower bound and previous theory, but are superlinear in the number of genes for continuous-time switching networks. We also find that the amount of data needed scales as 2(K), where K is the number of regulators per gene, rather than 2(2K), as previous theory suggests.     

Mechanism of hydrolysis of dicholine esters with long polymethylene chain by human butyrylcholinesterase

Human butyrylcholinesterase hydrolyzes long chain dicholine esters more rapidly than short chain dicholine esters. The active site of butyrylcholinesterase is deeply buried within the enzyme molecule and there is limited space for binding of large compounds. Our goal was to understand how butyrylcholinesterase accommodates long chain dicholine esters to make them better substrates than short chain dicholine esters. For this purpose we studied the rate of hydrolysis of adipyldicholine (n=4) and sebacyldicholine (n=8) with mass spectrometry, a method that allowed monitoring the dicholine substrates, the monocholine intermediates, the dicarboxylic acid and choline products. It was shown that hydrolysis of adipyldicholine involves two consecutive steps, dicholine ester hydrolysis followed by relatively slow monocholine ester hydrolysis. However, sebacyldicholine was hydrolyzed at both choline ester sites, though hydrolysis of dicholine was faster than hydrolysis of monocholine. Sebacyldicholine was completely converted to sebacic acid and choline within 90 min, whereas only 15% of the adipyldicholine was converted to adipic acid in this time. Molecular modeling indicated that these dicholine esters can bind to butyrylcholinesterase in two energetically equivalent alternative conformations that may theoretically lead to hydrolysis. The long chain dicholine ester makes closer contact than the short chain ester between one of its carbonyl carbons and the catalytic Ser198, thus explaining why long-chain dicholine esters are hydrolyzed more rapidly by butyrylcholinesterase.     

Increase in the activity of Rhizopus delemar lipase on water-soluble esters by its binding with phosphatidylcholine

Rhizopus (Rh.) delemar (ATCC 34612) C-lipase was found to exhibit a slight activity towards water-soluble esters. The hydrolytic reaction of this lipase on alpha-naphthyl acetate was competitively inhibited by the presence of olive oil or Tween 80. This finding showed that both substrates, insoluble triglyceride and water-soluble ester, were hydrolyzed at the same site on the enzyme. The activities on water-soluble esters (alpha-naphthyl acetate, beta-naphthyl acetate, methyl acetylsalicylate and Tween 80) increased on binding of lipase with phosphatidylcholine (PC), although the activity on olive oil did not change. The increase in activity on water-soluble esters was due to the increase in the Vmax for its hydrolysis. It appears that local structural change of the catalytic site on lipase occurred on binding of PC to the lipase molecule and resulted in an increase in the activity on water-soluble esters. The temperature dependence of the hydrolysis of water-soluble esters demonstrated that the activation energy was lowered on binding of PC to the lipase molecule, and this resulted in an increase in the activity.