Comparative study of enzymatic activity of cholinesterases of different origin in thionaphthylacetate hydrolysis reactions

A comparative determination of kinetic parameters V and Km in the reaction of hydrolysis thionaphthylacetate and well known substrate acetylthiocholine by choline esterases from different sources was conducted. It is shown that butyrylcholine esterases hydrolyze thionaphthylacetate with velocity comparable with that of hydrolysis of acetylthiocholine, while acetylcholine esterases and propionylcholine esterases hydrolyze this substrate several times slower than acetylthiocholine. The values of Km in the reactions of hydrolysis of thionaphthylacetate for all studied cholinesterases is an order higher than for acetylthiocholine except cholinesterase of blood serum of fish. This value for the latter enzyme is practically equal.     

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.     

Hydrolysis of 4-nitrophenyl acetate catalyzed by carbonic anhydrase III from bovine skeletal muscle

We report three experiments which show that the hydrolysis of 4-nitrophenyl acetate catalyzed by carbonic anhydrase III from bovine skeletal muscle occurs at a site on the enzyme different than the active site for CO2 hydration. This is in contrast with isozymes I and II of carbonic anhydrase for which the sites of 4-nitrophenyl acetate hydrolysis and CO2 hydration are the same. The pH profile of kcat/Km for hydrolysis of 4-nitrophenyl acetate was roughly described by the ionization of a group with pKa 6.5, whereas kcat/Km for CO2 hydration catalyzed by isozyme III was independent of pH in the range of pH 6.0-8.5. The apoenzyme of carbonic anhydrase III, which is inactive in the catalytic hydration of CO2, was found to be as active in the hydrolysis of 4-nitrophenyl acetate as native isozyme III. Concentrations of N-3 and OCN- and the sulfonamides methazolamide and chlorzolamide which inhibited CO2 hydration did not affect catalytic hydrolysis of 4-nitrophenyl acetate by carbonic anhydrase III.     

The mode of binding of potential transition-state analogs to acetylcholinesterase.

Phenylacetone, 4-phenyl-2-butanone, and 4-oxopentyltrimethylammonium chloride were tested as potential transition state analogs for eel acetylcholinesterase (acetylcholine hydrolase, EC 3.1.1.7). Phenylacetone is a competitive inhibitor of the enzyme but not a transition state analog, since its binding constant is similar to that for the substrate phenyl acetate. 4-Phenyl-2-butanone binds 6-18 times more tightly than the inhibitors 4-phenyl-2-butanol and N-benzylacetamide and the substrate benzyl acetate and also blocks inactivation of the enzyme with methanesulfonyl fluoride. However, its binding is independent of pH in the range 5-7.5, whereas both V and V/Km for benzyl acetate hydrolysis decrease with decreasing pH in this range. These data indicate a specific but weak interaction between the ketone carbonyl and the enzyme, but probably do not justify considering this compound a transition state analog. 4-oxopentyltrimethylammonium iodide has previously been shown to bind about 125 times more strongly than the substrate acetylcholamine. It also binds about 375 times more strongly than the alcohol 4-hydroxypentyltrimethylammonium iodide. Furthermore, the ketone protects the enzyme from inactivation by methansulfony fluoride, while the corresponding quaternary ammonium alcohol accelerates this inactivation reaction. This additional information confirms that the ketone is a transition state analog.     

Kinetic investigation of soybean trypsin-like enzyme catalysis

Various esters and amides of benzoylarginine and of benzyloxycarbonylarginine were subjected to enzymic hydrolysis at pH 8.5 and 7.2 by soybean trypsin-like enzyme (STLE). The kcat values for the hydrolysis of esters and amides were essentially identical regardless of the kind of leaving group. These results suggest that the STLE-catalyzed hydrolysis of ester and amide substrates proceeds via an acylenzyme intermediate and that the deacylation step is rate-determining. Hydrolysis of various 4-methylcoumaryl-7-amides of varying chain length and amino acid sequence was carried out at pH 8.5. Analysis of kinetic parameters revealed that STLE does not exhibit any remarkable subsite requirement, but somewhat preferentially hydrolyzes shorter substrates. These observations are consistent with the fact that STLE does not hydrolyze protein substrates or oxidized insulin B chain but hydrolyzes oligopeptides (Nishikata, M. (1984) J. Biochem. 95, 1169-1177). It is possible that the active site of STLE is located at a deep position in the enzyme molecule. From the pH dependency of kcat/Km, the participation of a histidine residue in the catalytic process of STLE was suggested.     

Chemical synthesis and papain-catalysed hydrolysis of N-alpha-benzyloxycarbonyl-L-lysine p-nitroanilide.

The chemical synthesis of N-alpha-benzyloxycarbonyl-L-lysine p-nitroanilide (Z-Lys-pNA) is described in detail. The pH-dependence of the catalytic parameters kcat,' Km and kcat./Km for the papain-catalysed hydrolysis of Z-Lys-pNA are determined. kcat. and Km are pH-independent between pH 5 and pH 7.42, but the pH-dependence of kcat./Km is bell-shaped, decreasing at high and low pH values with pKa values of 7.97 and 4.40 respectively. The catalytic parameters and their pH-dependence are shown to be similar to those reported for other anilide substrates and it is concluded that the Km value of 0.01 mM previously reported [Angelides & Fink (1979) Biochemistry 18, 2355-2369] is incorrect. The possibility of accumulating a tetrahedral intermediate during the papain-catalysed hydrolysis of Z-Lys-pNA is discussed.     

Energetics of ribonuclease A catalysis. 1. pH, ionic strength, and solvent isotope dependence of the hydrolysis of cytidine cyclic 2',3'-phosphate

The pH, ionic strength, and solvent deuterium isotope dependence of the steady-state kinetics of the ribonuclease A catalyzed hydrolysis of cytidine cyclic 2',3'-phosphate has been investigated by using, primarily, the technique of flow microcalorimetry to monitor the kinetics. The pH dependence of the Michaelis-Menten parameters has been analyzed by assuming the participation of His-12 and -119 of the enzyme and a third ionizing group, postulated to be on the pyrimidine ring of the substrate, to determine the pH-independent rate constant kc, and Michaelis constant Km. The reported pH analysis, together with existing NMR data and chemical modification studies, allows an assignment of the functional roles of His-12 and -119 as being those of general acid and general base catalytic residues, respectively. At high pH, the apparent Km value is found to increase to unity. This drop in affinity between the enzyme and the substrate at high pH indicates that the substrate binds to the enzyme primarily through an electrostatic interaction with the active-site histidine residues, particularly His-12. The apparent absence of an interaction with the riboside portion of the substrate is suggested to be due to the fact that the substrate exists in a syn conformation about its glycosidic bond and thus cannot interact optimally with the enzyme's binding pocket. This will result in a relative destabilization of the enzyme-substrate complex, which can then be relieved upon the formation of the transition state. The ionic strength dependence of ribonuclease activity is shown to be primarily a result of its effect on the pKa of the histidine residues and a concomitant change in the value of Km.     

Dependence of the catalytic activity of papain on the ionization of two acidic groups.

The pH dependence of kcat/Km for the papain-catalyzed hydrolysis of ethyl hippurate, N-alpha-benzoyl-L-citrulline methyl ester, and the p-nitroanilide, amide, and ethyl ester derivatives of N-alpha-benzoyl-L-arginine was determined below pH 6.4. The value of kcat/Km was observed to be modulated by two acid ionizations rather than a single ionization as previously believed. For the five substrates studied, the average pK values for the two ionizations are 3.78 +/- 0.2 and 3.95 +/- 0.1 at T/2 0.3, 25 degrees C. The observation that similar pK values were obtained with different substrates was taken as evidence that the kinetically determined pK values are close in value to true macroscopic ionization constants for ionization of groups on the free enzyme.     

Purification and characterization of a pyridine nucleotide glycohydrolase from rabbit spleen

A particulate NMN glycohydrolase of rabbit spleen was solubilized with Triton X100 and purified approximately 100-fold. The enzyme was shown to have a pH maximum of 6.5, a Km of 0.25 mM, a Vmax of 5.3 mumol/min/mg protein, an activation energy of 7.9 kcal/mol, and a molecular weight of approximately 400,000. Both of the purified and the particulate enzymes exhibited identical catalytic properties with respect to substrate specificity, activation energy, pH profile and exchange reaction with nicotinic acid, except that the purified enzyme was highly activated with Triton X100 as compared with the particulate enzyme; it appears that the purified enzyme possesses the same catalytic properties as the enzyme present in the tissue and that solubilization does not significantly alter the native protein. In addition to catalytic activity with NMN, the rabbit spleen enzyme catalyzed an irreversible hydrolysis with NAD and NADP, exhibiting catalyzing activity ratios of NMN:NAD:NADP = 1.00:1.45:0.44 and Vmax/Km ratios of 1.00:1.7:2.3, respectively. These ratios of activity remained constant throughout purification of the enzyme and no separation of these activities was detected. Mutually competitive inhibition of the enzyme with Ki values similar to Km, and identical rates of thermal denaturation of the enzyme and activity-pH profiles with NMN or NAD indicated the hydrolysis of the C-N glycosidic linkage of the pyridine nucleotides to be catalyzed by the same enzyme. The enzyme was less specific for the purine structure of the substrate dinucleotides but was stereospecific for the glycosidic linkage cleaved. Nicotinamide riboside, the nicotinic acid analogs and the reduced forms were not hydrolyzed. A linear noncompetitive inhibition of NMN hydrolysis with nicotinamide indicated an ordered Uni-Bi mechanism in which nicotinamide was the first product released from the enzyme. A property that the rabbit spleen enzyme appears to share with other NAD glycohydrolases is the transglycosidation reaction. The ratio of transglycosidation reaction vs. hydrolysis catalyzed by the enzyme in the presence of NMN and nicotinic acid indicated that the enzyme could function as a primary transglycosidase rather than a hydrolytic enzyme in vivo.     

Characterization of the catalytic defect in the dysthrombin, Thrombin Quick

The dysthrombin, Thrombin Quick, is chromatographically separable into two components designated Thrombin Quick I and Thrombin Quick II. Thrombin Quick II lacks observable catalytic activity toward thrombin substrates. The steady-state kinetics of hydrolysis of benzoylarginine ethyl ester and Tos-Gly-Pro-Arg-p-nitroanilide by Thrombin Quick I are equivalent to those of thrombin. These results, in addition to binding studies with the active site titrant N2-(5-dimethylaminonaphthalene-1-sulfonyl)arginine N-(3-ethyl-1,5-pentanediyl)amide, indicate that binding interactions at the catalytic site of Thrombin Quick I are unaltered. Thrombin Quick I is inhibited by anti-thrombin III at the same rate as thrombin. Steady-state kinetic parameters for the release of fibrinopeptide A indicate defects in both kcat and Km for Thrombin Quick I with kcat/Km equal to 0.012 of the value for thrombin, corresponding to the relative fibrinogen clotting activity of 0.013. The results are interpreted as indicating a defect in Thrombin Quick I at a binding site, external to the catalytic site, which is essential for determining specificity toward fibrinogen. The defect in kcat may result secondarily from small perturbations in the steric relationship of the catalytic triad residues. The rate of hydrolysis by Thrombin Quick I of the protein substrates bovine prothrombin and bovine protein C (in the absence of cofactors) is about one-third of that observed for thrombin, indicating that hydrolysis of these substrates by thrombin involves different specificity determinants than does the hydrolysis of fibrinogen.     

Subsite structure of Saccharomycopsis alpha-amylase secreted from Saccharomyces cerevisiae

The kinetic parameters (kcat/Km) and the cleaved-bond distributions for the hydrolysis of linear maltooligosaccharides Gn (3 less than or equal to n less than or equal to 9) by Saccharomycopsis alpha-amylase (Sfamy) secreted from Saccharomyces cerevisiae were determined at pH 5.25 and 25 degrees C. The subsite affinities of Sfamy were also evaluated from these data. The subsite structure of Sfamy is characteristic of the active site of an endo-cleavage type enzyme, consisting of internal repulsive sites with the catalytic residues and external attractive sites. Moreover, the pKa values of the catalytic residues were calculated from the pH dependence plot of the kinetic parameter (kcat/Km). The amino acid residues which contribute to the subsite affinities and the catalytic activity of Sfamy are proposed and compared with those of Taka-amylase A.     

Catalytic properties of porcine pancreatic elastase: a steady-state and pre-steady-state study

Pre-steady-state and steady-state kinetics for the p.p. elastase-catalysed hydrolysis of ZAlaONp, one of the most favourable substrates for this serine protease, have been studied between pH 4.0 and 8.0. The results are consistent with the minimum three-step mechanism: (formula; see text) Under pre-steady-state conditions, where [E0] much greater than [S0], the values of the dissociation constant of the E X S complex (Ks = k-1/k+1) and of the individual rate constants for the catalytic steps (k+2 and k+3) have been determined over the whole pH range explored. Under steady-state conditions, where [S0] much greater than [E0], the values of kcat and Km have been obtained over the same pH range. The pH profiles of k+2, k+3, k+2/Ks, kcat, kcat/Km reflect the ionization of a group, probably His57, with a pKa value of 6.85 +/- 0.10. The values of Ks and Km are pH independent. The steady-state parameters for the p.p. elastase-catalysed hydrolysis of a number of p-nitrophenyl esters of N-alpha-carbobenzoxy-L-amino acids have been also determined between pH 4.0 and 8.0 and compared with those of b.beta-trypsin and b.alpha-chymotrypsin. For all the substrates examined the acylation step (k+2) is rate limiting in the p.p. elastase catalysis, between pH 4.0 and 8.0. The different catalytic behaviours of p.p. elastase, b.beta-trypsin and b.alpha-chymotrypsin are consistent with the known three-dimensional structures of these serine proteases.     

The catalytic activity of pig pepsin C towards small synthetic substrates.

A series of small peptides has been synthesized and used to investigate the activity of a minor pig pepsin, pepsin C (EC 3.4.23.3). The peptides had the general formula A-Leu-Val-His-B. B was either OMe, NH2 or OH. With B = NH2 hydrolysis (kcat./Km) at 37 degrees C and pH 2.07 increased as A was Ac-Ala, Ac-Tyr, Ac-Phe and Ac-Ala-Phe. The pH dependence of the hydrolysis of Ac-Phe-Leu-Val-His-NH2 indicated the apparent pKa values of two catalytically important groups on the enzyme as 1.42 and 4.88. Inhibition of the hydrolysis of the same peptide by Ac-Phe at pH 3.01 showed a form of mixed non-competitive inhibition. Hydrolysis of Ac-Tyr-Leu-Val-His-OMe and the corresponding amide showed non-classical kinetics, which are discussed in terms of a substrate-activating mechanism. The results are discussed with reference to observations made by other workers on pig pepsin A.     

The pH-dependence and group modification of beta-lactamase I.

The pH-dependence of the kinetic parameters for the hydrolysis of the beta-lactam ring by beta-lactamase I (penicillinase, EC 3.5.2.6) was studied. Benzylpenicillin and ampicillin (6-[D(-)-alpha-aminophenylacetamido]penicillanic acid) were used. Both kcat. and kcat./Km for both substrates gave bell-shaped plots of parameter versus pH. The pH-dependence of kcat./Km for the two substrates gave the same value (8.6) for the higher apparent pK, and so this value may characterize a group on the free enzyme; the lower apparent pK values were about 5(4.85 for benzylpenicillin, 5.4 for ampicillin). For benzylpenicillin both kcat. and kcat./Km depended on pH in exactly the same way. The value of Km for benzylpenicillin was thus independent of pH, suggesting that ionization of the enzyme's catalytically important groups does not affect binding of this substrate. The pH-dependence of kcat. for ampicillin differed, however, presumably because of the polar group in the side chain. The hypothesis that the pK5 group is a carboxyl group was tested. Three reagents that normally react preferentially with carboxyl groups inactivated the enzyme: the reagents were Woodward's reagent K, a water-soluble carbodi-imide, and triethyloxonium fluoroborate. These findings tend to support the idea that a carboxylate group plays a part in the action of beta-lactamase I.     

Interactions of derivatives of guanidinophenylalanine and guanidinophenylglycine with Streptomyces griseus trypsin

The rates of hydrolysis of the ester, amide and anilide substrates of p-guanidino-L-phenylalanine (GPA) by Streptomyces griseus trypsin (S. griseus trypsin) were compared with those of arginine (Arg) substrates. The specificity constant (kcat/km) for the hydrolysis of GPA substrates by the enzyme was 2-3-times lower than that for arginine substrates. The kcat and Km values for the hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalanine ethyl ester (Bz-GPA-OEt) by S. griseus trypsin are in the same order of magnitude as those of N alpha-benzoyl-L-arginine ethyl ester (Bz-Arg-OEt), although both values for the former when hydrolyzed by bovine trypsin are higher by one order of magnitude than those for the latter. The specificity constant for the hydrolysis of Bz-GPA-OEt by S. griseus trypsin is much higher than that for N alpha-benzoyl-p-guanidino-L-phenylglycine ethyl ester (Bz-GPG-OEt). As with the kinetic behavior of bovine trypsin, low values in Km and kcat were observed for the hydrolysis of amide and anilide substrates of GPA by S. griseus trypsin compared with those of arginine substrates. The rates of hydrolysis of GPA and arginine substrates by S. griseus trypsin are about 2- to 62-times higher than those obtained by bovine trypsin. Substrate activation was observed with S. griseus trypsin in the hydrolysis of Bz-GPA-OEt as well as Bz-Arg-OEt, whereas substrate inhibition was observed in three kinds of N alpha-protected anilide substrates of GPA and arginine. In contrast, no activation by the amide substrate of GPA could be detected with this enzyme.     

Effect of protons on the amidase activity of human alpha-thrombin. Analysis in terms of a general linkage scheme

The amidase activity of human alpha-thrombin has been studied in the pH range 5.5 to 10, and at four different chloride concentrations from 5 mM to 1 M. The Michaelis-Menten constant, Km, shows a bell-shaped dependence over the pH range studied, with a minimum around pH 8. The pH dependence of the catalytic constant, kcat, shows multiple inflection points especially at low (less than 0.1 M) chloride concentrations, thereby implicating the existence of multiple catalytic forms of the enzyme. A general linkage scheme is proposed for the analysis of the effect of protons on thrombin amidase activity, and experimental data have globally been analysed over the entire pH range in terms of such a scheme. Four proton-linked ionizable groups seem to be involved in the control of thrombin amidase activity. Two of these groups change their pK value upon substrate binding to the enzyme and account for the pH dependence of Km. All four groups control the catalytic activity of the enzyme which decreases with increasing protonation. Chloride has little effect on Km, while kcat changes significantly at pH less than 8. This effect is due to an increased enzymatic activity of the highly protonated intermediates at high chloride concentrations, as well as to the pK shift of two proton-linked ionizable groups.     

The sulphatase of ox liver. XXI: kinetic studies of the substrate-induced inactivation of sulphatase A.

The theoretical basis is given for methods of determining the apparent velocity constant, k*, for the substrate-induced inactivation of sulphatase A (aryl-sulphate sulphohydrolase, EC 3.1.6.1) and the initial velocity, vo, of the catalytic reaction. The expression is of the same form as the empirical relationships previously used but the significance of the various terms is clearly established. The method has been applied to the characterisation of the inactivation occurring during the hydrolysis of a number of substrates and it has been shown that k* varies with so in a hyperbolic relationship described by k, a velocity constant at infinite substrate concentrations and by K, a constant analogous to the Michaelis constant. Although K varies considerably for different substrates, and is consistently less than the corresponding Km, k is almost constant at 0.23 min-1. It is therefore suggested that the inactivation of the enzyme does not proceed through an enzyme . substrate complex but through the enzyme . SO2-4 complex produced during the catalytic reaction. The effects of several variables on these parameters are described.     

Catalytic role of the metal ion of carboxypeptidase A in ester hydrolysis.

The mechanism of action of bovine pancreatic carboxypeptidase. Aalpha (peptidyl-L-amino acid hydrolase; EC 3.4.12.2) has been investigated by application of cryoenzymologic methods. Kinetic studies of the hydrolysis of the specific ester substrate O-(trans-p-chlorocinnamoyl)-L-beta-phenyllactate have been carried out with both the native and the Co2+-substituted enzyme in the 25 to --45 degrees C temperature range. In the --25 to --45 degrees C temperature range with enzyme in excess, a biphasic reaction is observed for substrate hydrolysis characterized by rate constants for the fast (kf) and the slow (ks) processes. In Arrhenius plots, ks extrapolates to kcat at 25 degrees C for both enzymes in aqueous solution, indicating that the same catalytic rate-limiting step is observed. The slow process is analyzed for both metal enzymes, as previously reported (Makinen, M. W., Yamamura, K., and Kaiser, E. T. (1976) Proc Natl. Acad. Sci. U. S. A. 73, 3882-3886), to involve the deacylation of a mixed anhydride acyl-enzyme intermediate. Near --60 degrees C the acyl-enzyme intermediate of both metal enzymes can be stabilized for spectral characterization. The pH and temperature dependence of ks reveals a catalytic ionizing group with a metal ion-dependent shift in pKa and an enthalpy of ionization of 7.2 kcal/mol for the native enzyme and 6.2 kcal/mol for the Co2+ enzyme. These parameters identify the ionizing catalytic group as the metal-bound water molecule. Extrapolation of the pKa data to 25 degrees C indicates that this ionization coincides with that observed in the acidic limb of the pH profile of log(kcat/Km(app)) for substrate hydrolysis under steady state conditions. The results indicate that in the esterolytic reaction of carboxypeptidase. A deacylation of the mixed anhydride intermediate is catalyzed by a metal-bound hydroxide group.     

Kinetic study of carboxypeptidase P-catalyzed reaction. Pressure and temperature dependence of kinetic parameters

Detailed kinetic analyses of carboxypeptidase P-catalyzed reactions were carried out spectrophotometrically using 3-(2-furyl)acryloyl-acylated peptide substrates. The maximum kcat/Km was observed at around pH 3.5 for the synthetic peptide substrates. The kcat/Km value decreased with increasing pH, with an apparent pKa value of 4.43. However, the maximum kcat was observed at neutral pH (pH congruent to 6) and the pKa was 4.49. These apparently different pH profiles for kcat/Km and kcat of this enzyme were due to the decreasing Km value in the acid pH region. The pressure and temperature dependences of these kinetic parameters were also measured. N-Benzoylglycyl-L-phenyllactate (Bz-Gly-OPhLac) gave dependences similar to those of the peptide substrate, suggesting that there is no distinct difference in the catalytic mechanism between the peptide and the ester hydrolyses.     

Probing the Ser-Ser-Lys catalytic triad mechanism of peptide amidase: computational studies of the ground state, transition state, and intermediate

Peptide amidase (Pam), a hydrolytic enzyme that belongs to the amidase signature (AS) family, selectively catalyzes the hydrolysis of the C-terminal amide bond (CO-NH(2)) of peptides. The recent availability of the X-ray structures of Pam, fatty acid amide hydrolase, and malonamidase E2 has led to the proposal of a novel Ser-Ser-Lys catalytic triad mechanism for the amide hydrolysis by the AS enzymes. The molecular dynamics (MD) simulations using the CHARMM force field were performed to explore the catalytic mechanism of Pam. The 1.8 A X-ray crystal structure of Pam in complex with the amide analogue of chymostatin was chosen for the initial coordinates for the MD simulations. The five systems that were investigated are as follows: (i) enzyme.substrate with Lys123-NH(2), (ii) enzyme.substrate with Lys123-NH(3)(+), (iii) enzyme.substrate with Lys123-NH(3)(+) and Ser226-O(-), (iv) enzyme.transition state, and (v) enzyme.tetrahedral intermediate. Our data support the presence of the hydrogen bonding network among the catalytic triad residues, Ser226, Ser202, and Lys123, where Ser226 acts as the nucleophile and Ser202 bridges Ser226 and Lys123. The MD simulation supports the catalytic role of the crystallographic waters, Wat1 and Wat2. In all the systems that have been studied, the backbone amide nitrogens of Asp224 and Thr223 create an oxyanion hole by hydrogen bonding to the terminal amide oxygen of the substrate, and stabilize the oxyanion tetrahedral intermediate. The results from both our computational investigation and previously published experimental pH profile support two mechanisms. In a mechanism that is relevant at lower pH, the Lys123-NH(3)(+)-Ser202 dyad provides structural support to the catalytic residue Ser226, which in turn carries out a nucleophilic attack at the substrate amide carbonyl in concert with Wat1-mediated deprotonation and stabilization of the tetrahedral transition state by the oxyanion hole. In the mechanism operating at higher pH, the Lys123-NH(2)-Ser202 catalytic dyad acts as a general base to assist addition of Ser226 to the substrate amide carbonyl. The results from the MD simulation of the tetrahedral intermediate state show that both Ser202 and Lys123 are possible candidates for protonation of the leaving group, NH(2), to form the acyl-enzyme intermediate.