Kinetic solvent isotope effects on the deacylation of specific acyl-papains. Proton inventory studies on the papain-catalysed hydrolyses of specific ester substrates: analysis of possible transition state structures.

1. The hydrolyses of the p-nitrophenyl esters of N-benzyloxycarbonylglycine, alpha-N-benzyloxycarbonyl-L-lysine and N-methoxycarbonyl-L-phenylalanylglycine catalysed by papain (EC 3.4.22.2) have been studied in solvents having a variable composition of 2H2O and H2O. 2. kcat., which represents deacylation in the papain-catalysed hydrolysis of reactive esters, is some 2.3-fold less in 2H2O compared with H2O. The magnitude of kcat. has been determined as a function of the 2H atom fraction of the solvent. 3. Both linear and non-linear methods of least-square regression analysis have been applied to the data in order to obtain best-fit parameter values for several three-parameter models which express kcat. in terms of the 2H atom fraction of the solvent. These models represent some possible modes of restructuring of the active site protonic configuration consequent upon transition state formation. 4. The results of curve fitting reveal an essentially linear dependence of kcat. upon the 2H atom fraction, and it may therefore be concluded that the isotope effect originates from a single proton which is in the process of transfer in the transition state. 5. It is postulated on the basis of this and other evidence that the mobile proton is transferred from an attacking water molecule to the imidazole side chain of His-159 during tetrahedral intermediate formation. This has the effect of stabilizing the transition state and promoting catalysis. The role of His-159 in deacylation is therefore to provide general base catalysis. 6. Models that involve two or more protons, such as a two-proton relay system analogous to that proposed for the serine proteinases, or a multiproton 'medium' effect, are considered unlikely on the basis of the data reported in this paper. 7. A more detailed examination of possible transition state structures reveals that the only structure compatible with available experimental data and consistent with certain theoretical predictions is one in which the proton translocated in concern with reorganization of the heavy atom framework. In addition, the transition state vibrations of the mobile proton are strongly coupled to those of the heavy atoms. These properties of the transition state are also manifest in the transition state for the deacylation of serine proteinases.

Half-time analysis of the integrated Michaelis equation. Simulation and use of the half-time plot and its direct linear variant in the analysis of some alpha-chymotrypsin, papain- and fumarase-catalysed reactions.

Substitution of half-time parameters in the integrated form of the Michaelis-Menten equation for any enzyme-catalysed reaction yields an equation that gives a linear relationship between the half-time of the reaction and the substrate concentration at that point of the reaction. The logarithmic term of the integrated equation becomes a constant as a result of the substitution, which means that the use of the half-time plot of the equation requires calculation only of half-time and substrate-concentration values at various stages of the reaction. The half-time method is both simple and exact, being analogous to an [S(0)]/v(i) against [S(0)] plot. A direct linear form of the half-time plot has been devised that allows very simple estimation of Michaelis parameters and/or initial velocities from progress-curve data. This method involves no approximation and is statistically valid. Simulation studies have shown that linear-regression analysis of half-time plots provides unbiased estimates of the Michaelis parameters. Simulation of the effect of error in estimation of the product concentration at infinite time [P(infinity)] reveals that this is always a cause for concern, such errors being magnified approximately an order of magnitude in the estimate of the Michaelis constant. Both the half-time plot and the direct linear form have been applied to the analysis of a variety of experimental data. The method has been shown to produce excellent results provided certain simple rules are followed regarding criteria of experimental design. A set of rules has been formulated that, if followed, allows progress-curve data to be acquired and analysed in a reliable fashion. It is apparent that the use of modern spectrophotometers in carefully designed experiments allows the collection of data characterized by low noise and accurate [P(infinity)] estimates. [P(infinity)] values have been found, in the present work, to be precise to within +/-0.2% and noise levels have always been below 0.1% (signal-to-noise ratio approximately 1000). As a result of the considerations above, it is concluded that there is little to be feared with regard to the analysis of enzyme kinetics using complete progress curves, despite the generally lukewarm recommendations to be found in the literature. The saving in time, materials and experimental effort amply justify analysis of enzyme kinetics by progress-curve methods. Half-time plots linear to >/=90% of reaction have been obtained for some alpha-chymotrypsin-, papain- and fumarase-catalysed reactions.

Benzyloxycarbonylphenylalanylcitrulline p-nitroanilide as a substrate for papain and other plant cysteine proteinases.

After preliminary assays, with papain, bromelain and ficin, on a range of citrulline p-nitroanilides, values of Km and kcat. for the papain-catalysed hydrolysis of three derivatives, N alpha- benzyloxycarbonylcitrulline p-nitroanilide, benzyloxycarbonylphenylalanylcitrulline p-nitroanilide and benzyloxycarbonylglycylphenylalanylcitrulline p-nitroanilide, were obtained. It is concluded that benzyloxycarbonylphenylalanylcitrulline p-nitroanilide is a highly selective substrate for the sensitive detection and assay of the plant cysteine proteinases.

Consequences of molecular recognition in the S1-S2 intersubsite region of papain for catalytic-site chemistry. Change in pH-dependence characteristics and generation of an inverse solvent kinetic isotope effect by introduction of a P1-P2 amide bond into a two-protonic-state reactivity probe.

1. The pH-dependences of the second-order rate constant (k) for the reactions of papain (EC 3.4.22.2) with 2-(acetamido)ethyl 2'-pyridyl disulphide and with ethyl 2-pyridyl disulphide and of k for the reaction of benzimidazol-2-ylmethanethiol (as a minimal model of cysteine proteinase catalytic sites) with the former disulphide were determined in aqueous buffers at 25 degrees C at I 0.1. 2. Of these three pH-k profiles only that for the reaction of papain with 2-(acetamido)ethyl 2'-pyridyl disulphide has a rate maximum at pH approx. 6; the others each have a rate minimum in this pH region and a rate maximum at pH 4, which is characteristic of reactions of papain with other 2-pyridyl disulphides that do not contain a P1-P2 amide bond in the non-pyridyl part of the molecule. 3. The marked change in the form of the pH-k profile consequent upon introduction of a P1-P2 amide bond into the probe molecule for the reaction with papain but not for that with the minimal catalytic-site model is interpreted in terms of the induction by binding of the probe in the S1-S2 intersubsite region of the enzyme of a transition-state geometry in which nucleophilic attack by the -S- component of the catalytic site is assisted by association of the imidazolium ion component with the leaving group. 4. The greater definition of the rate maximum in the pH-k profile for the reaction of papain with an analogous 2-pyridyl disulphide reactivity probe containing both a P1-P2 amide bond and a potential occupant for the S2 subsite [2-(N'-acetyl-L-phenylalanylamino)ethyl 2'-pyridyl disulphide [Brocklehurst, Kowlessur, O'Driscoll, Patel, Quenby, Salih, Templeton, Thomas & Willenbrock (1987) Biochem. J. 244, 173-181]) suggests that a P2-S2 interaction substantially increases the population of transition states for the imidazolium ion-assisted reaction. 5. The overall kinetic solvent 2H-isotope effect at pL 6.0 was determined to be: for the reaction of papain with 2,2'-dipyridyl disulphide, 0.96 (i.e. no kinetic isotope effect), for its reaction with the probe containing only the P1-P2 amide bond, 0.75, for its reaction with the probe containing both the P1-P2 amide bond and the occupant for the S2 subsite, 0.61, and for kcat./Km for its catalysis of the hydrolysis of N-methoxycarbonylglycine 4-nitrophenyl ester, 0.67.(ABSTRACT TRUNCATED AT 400 WORDS)