Kinetic constraints and features imposed by the immobilization of enzymes onto solid matrices: a key to advanced biotransformation.

The kinetics of immobilized enzymes can not be analyzed by means of the simple Michaelis-Menten concept, which generally fails to describe the immobilized state due to both its probable barriers, and because the active concentration of the enzyme approaches, or even exceeds this of its substrate(s). In such cases, the various experimental data are usually treated by complex rate equations comprising too many parameters acquiring different natures and meanings, depending on both the properties of the immobilization state and the experimental conditions; thus, more likely, only apparent values of the Michaelis-Menten kinetic parameters can be estimated experimentally. Likewise, immobilization is often a key method in optimizing the operational performance of enzymes, in both laboratory and industrial scale, and affects considerably the kinetics in non-aqueous and non-conventional media due to several issues as the structural changes of the enzyme molecule, the heterogeneity of the system, and the partial or total absence of water. In this work a theoretical approach is described on the formulation of simplified rate equations, reflecting also the actual mass balances of the reactants, in the case where esterification synthetic reactions are catalyzed by immobilized lipases, in either a non-aqueous organic solvent or in a non-solvent system.

Purification and characterization of a novel extracellular protease from a halo-alkaliphilic Bacillus sp. 17N-1, active in polar organic solvents.

A novel enzyme of molecular mass about 29 kDa was purified from the strain halo-alkaliphilic Bacillus sp. 17N-1 and designated protease-B-17N-1. This enzyme is likely to be a cysteine protease; it was found active in media containing EDTAK2 and dithiothreitol, it maintained considerable activity at temperatures 14 degrees C to 33 degrees C and pH 6.50 to 8.50 with optimum k(cat)/Km and/or k(cat) values at pH 7.00 and 25 degrees C. The activity of protease-B-17N-1 was strongly affected by the specific irreversible inhibitor of cysteine proteases E-64, while it remained unaffected by the 3,4-dichloro-isocoumarine, an irreversible inhibitor specific for serine proteases. Protease-B-17N-1 retained full activity at 25 degrees C after 30 min incubation at 8 degrees C or at 33 degrees C; moreover, it was found to be stable and active in the polar organic solvents DMSO and acetonitrile. The enzyme hydrolyzed the substrate Cbz-FR-pNA via Michaelis-Menten kinetics, while it showed insignificant activity for the substrate Suc-AAA-pNA. Valuable pK(a)s, rate constants, activation energies and other important features were estimated from the profiles of parameters k(cat)/Km, k(cat) and Km, versus pH, temperature, and [NaCl]. In addition, interesting results were obtained from the effect of different metallic ions and polar organic solvents on the Michaelis-Menten parameters of protease-B-17N-1, showing that it performs catalysis via a (Cys)-S(-)/(His)-Im(+)H ion-pair, as well as its industrial and biotechnological potential, respectively.

Insight into catalytic mechanism of papain-like cysteine proteinases: the case of D158.

We studied the role of D158 in papain-like cysteine proteinases by using subtilisin Carlsberg, and its chemically modified analog thiolsubtilisin, by applying the proton inventory (PI) method and also by taking into account the pH profiles of the kcat/Km parameter. In the case of thiolsubtilisin, we estimated large inverse solvent isotope effects for kcat/Km, as in papain, whereas for subtilisin we found "dome-shaped" PI, suggesting a completely different mechanism. Finally, the kinetic behavior of thiolsubtilisin presented similarities as well as differences, compared to papain, suggesting a possible role for D158 as part of a catalytic triad in papain-like cysteine proteinases.

Insight into the catalysis of hydrolysis of four newly synthesized substrates by papain: a proton inventory study.

We synthesized the following four new peptide substrates, Suc-Phe-Leu-pNA, Suc-Phe-Leu-NMec, Suc-Phe-Leu-ONPh, and Pht-Phe-Leu-pNA, and we applied the proton inventory method to their hydrolysis by papain. Useful relationships between the rate constants of the catalytic reaction have been established and contributed to the elucidation of the hydrolytic mechanism of papain. For all amide substrates, the parameter K(S) and the rate constants k(1), k(-)(1), and k(2) were estimated. Moreover, it was found that k(cat)/K(m) = k(1) for all four substrates, while two exchangeable hydrogenic sites, one in the ground state and another in the transition state, generate an inverse isotope effect during the reaction governed by this parameter. The proton inventories of both k(2) and k(3) are essentially linear, whatever the acyl moiety and/or the leaving group of the substrate. The proton inventories of K(S) are also essentially linear for all amide substrates, while the observed large isotope effect of about 3 to 9 originates from a single hydrogenic site in the product state. This latter, in agreement to both the small transition state fractionation factors found for k(cat)/K(m) (or k(1)) and the unit ground-state fractionation factors found for k(2), argues for the formation of a tetrahedral adduct during the reaction governed by the k(1) parameter. Furthermore, papain acts as a one-proton catalyst during acylation or deacylation, both of which proceed through similar concerted reaction pathways, where a nucleophilic attack is accompanied by the movement of one proton.