The use of proton NMR as an alternative for the amino acid analysis as identity test for peptides.

Proton NMR was evaluated as an alternative to amino acid analysis as an identity test for peptides. Proton NMR can readily distinguish and identify all peptides currently described in the European Pharmacopoeia (Ph. Eur.). A comparison with amino acid analysis as an identity test is presented.

Solvent effect on lipase enantioselectivity. Evidence for the presence of two thermodynamic states.

The enantioselectivity of lipase-catalyzed kinetic resolutions has been measured at various temperatures in binary mixtures of solvents. Varying the solvent composition and temperature had a profound effect on the enantiomeric ratio. The values for delta delta H(R-S)(#) and delta delta S(R-S)(#), calculated from the E values measured at various temperatures, were estimated as a function of the solvent composition. By plotting delta delta H(R-S)(#) versus delta delta S(R-S)(#) as a function of the solvent composition, an extreme was observed. The resulting "hairpin-type" enthalpy-entropy compensation plots can be described by assuming the presence of two thermodynamically distinct physical states, displaying different enantioselectivities, that are in equilibrium with one another. Changing the solvent composition results in a change in the equilibrium constant K(eq) for the two states. The intriguing bell-shaped curves of the enantioselectivity versus solvent composition observed for lipase-catalyzed kinetic resolutions can be described assuming a linear correlation for the logarithm of K(eq) and the solvent composition. Thus, a simulation of the two-state model adequately describes the solvent effects found for lipase-catalyzed kinetic resolutions in binary mixtures of solvents and possibly in series of homologous organic solvents.

Optimization of Pseudomonas cepacia lipase preparations for catalysis in organic solvents.

The activity of different lipase (from Pseudomonas cepacia) forms, such as crude powder (crude PC), purified and lyophilized with PEG (PEG + PC), covalently linked to PEG (PEG-PC), cross-linked enzyme crystals (CLEC-PC), and immobilized in Sol-Gel-AK (Sol-Gel-AK-PC) was determined, at various water activities (aw), in carbon tetrachloride, benzene and 1,4-dioxane. The reaction of vinyl butyrate with 1-octanol was employed as a model and both transesterification (formation of 1-octyl butyrate) and hydrolysis (formation of butyric acid from vinyl butyrate) rates were determined. Both rates depended on the lipase form, solvent employed, and aw value. Hydrolysis rates always increased as a function of aw, while the optimum of aw for transesterification depended on the enzyme form and nature of the solvent. At proper aw, some lipase forms such as PEG + PC, PEG-PC, and Sol-Gel-AK-PC had a total activity in organic solvents (transesterification plus hydrolysis) which was close to (39 and 48%) or even higher than (130%) that displayed by the same amount of lipase protein in the hydrolysis of tributyrin-one of the substrates most commonly used as standard for the assay of lipase activity-in aqueous buffer. Instead, CLEC-PC and crude PC were much less active in organic solvents (2 and 12%) than in buffer. The results suggest that enzyme dispersion and/or proper enzyme conformation (favored by interaction with PEG or the hydrophobic Sol-Gel-AK matrix) are essential for the expression of high lipase activity in organic media.

Simple conformation space search protocols for the evaluation of enantioselectivity of lipases.

Two computational protocols have been evaluated regarding their ability to reproduce the enthalpic part of lipase enantioselectivity by forcefield potential energy differences (deltaV#R-S). Though the shortcomings of the approach are numerous, good qualitative results have been obtained here and elsewhere. The anticipated improvement of quantitative results by use of a second protocol, which did not impose any atom movement restrictions on the total system, was realized only in part. Seemingly, results depended not only on the design of the computational procedure but also on the enzyme-substrate combination modelled. With Candida antarctica lipase B, results diverged significantly more from an estimated deltadeltaH#R-S than with Rhizomucor miehei lipase and cutinase.