Substrate and inhibitor specificity of glutamine cyclotransferase (QC).

This paper reports a systematic study of the substrate and inhibitor specificity of papaya latex glutamine cyclotransferase (QC). The results showed that the second amino acid residue in N-terminal glutaminyl peptides significantly accelerated papaya latex QC-catalyzed reactions while the third residue provided no further rate enhancement. Substrate binding was shown to be the main specificity-determining step. Fifteen proline derivatives and dipeptides containing an N-terminal proline were tested and found to inhibit papaya latex QC. This supports our previous molecular modeling study of the QC catalytic pathway which suggested a structure of the reaction intermediates similar to that of L-proline.

The second nucleophile molecule binds to the acyl-enzyme-nucleophile complex in alpha-chymotrypsin catalysis. Kinetic evidence for the interaction.

alpha-Chymotrypsin-catalyzed acyl transfer was studied using three acyl-group donors (Mal-L-Ala-L-Ala-L-PheOMe, Bz-L-TyrOEt and Ac-L-TrpOEt; Mal, maleyl; Bz, benzoyl; OMe, methyl ester; OEt, ethyl ester) and a series of amino-acid amides. Most of the reactions studied can be described by the simplest kinetic model without the nucleophile binding to the acyl-enzyme. The alpha-chymotrypsin-catalyzed transfer of the Mal-L-Ala-L-Ala-L-Phe group to the amides of L-Phe and L-Tyr showed a linear dependence of the partition constant, p, on the nucleophile concentration which can be interpreted by the hydrolysis of the acyl-enzyme-nucleophile complex. The alpha-chymotrypsin-catalyzed transfer of the Bz-L-Tyr and Ac-L-Trp groups to several amino-acid amides showed unusual behavior which can be interpreted by the kinetic model involving formation of a complex of the acyl-enzyme with two nucleophile molecules. These observations can explain the conflicting conclusions concerning the kinetics of alpha-chymotrypsin-catalyzed acyl transfer evident in previous studies.

How to predict product yield in kinetically controlled enzymatic peptide synthesis.

The published theory of kinetically controlled enzymatic peptide synthesis needed experimental verification. We carried out the measurement of the peptide yield and estimation of the key parameters alpha and beta for papain-catalyzed synthesis of Mal-L-Phe-L-Ala-LLeuNH(2) from Mal-L-Phe-L-AlaOMe and L-LeuNH(2). The experimental results demonstrate that this theory adequately describes the real process.

Acyl group transfer by proteases forming an acylenzyme intermediate: kinetic model analysis (including hydrolysis of acylenzyme- nucleophile complex).

The quantitative analysis of peptide synthesis via transfer of the acyl moiety from the activated donor (S) to the nucleophile (N), catalysed by proteases forming an acylenzyme intermediate, has been continued. The new kinetic model takes into account the hydrolysis of an acylenzyme-nucleophile complex (EAN). The intensity of the hydrolysis is characterized by parameter gamma equal to the ratio of the rate constant of EAN hydrolysis and the rate constant of peptide formation. The ability of the EAN complex to hydrolyse leads to a decrease in the apparent nucleophile reactivity (beta) of the aminocomponent. As a result, the maximal fractional conversions of S and N to the peptide decrease, and the apparent nucleophile reactivity becomes dependent on the nucleophile concentration. The pattern of parameter gamma influence on maximal fractional conversions depends on which component is in an excess. It is with the donor excess that hydrolysis of the EAN complex affects the peptide yield dramatically. Analytical expressions for the estimation of maximal product concentration were obtained and their accuracy evaluated.

Acyl group transfer by proteases forming acyl-enzyme intermediate: kinetic model analysis.

A kinetic model of peptide synthesis via transfer of the acyl moiety from activated derivatives of amino acids (S) to nucleophiles (N) catalyzed by proteases forming an acyl-enzyme intermediate has been analyzed. The kinetic model takes into account the subsequent enzymatic hydrolysis of synthesized peptide (P), and so the kinetic curve for this compound shows a maximum (denoted as p(max)). Particular stress is placed on analyzing the effects of initial concentrations and of kinetic constants on the value of p(max).The analysis has demonstrated that at a given ratio of initial S and N concentrations, p(max) is affected only by (i) the ratio of the second-order rate constants for enzymatic hydrolysis of S and P(alpha) and (ii) the ratio of rate constants for an attack of the acyl-enzyme intermediate by the nucleophile and water (beta). These conclusions apply regardless of the existence of linear inhibition by the components of the reaction mixture. Thus, the kinetically controlled maximum yield of peptide (p(max)) can be calculated a priori from values of alpha and beta that can be estimated experimentally or from reference data. Simple analytical expressions were obtained, allowing a fairly accurate prediction of p(max) for a broad spectrum of S and N initial concentrations.