Synthesis of propyl gallate by transesterification of tannic acid in aqueous media catalysed by immobilised derivatives of tannase from Lactobacillus plantarum.

Immobilised derivatives of tannase from Lactobacillus plantarum were able to catalyse the transesterification of tannic acid by using moderate concentrations of 1-propanol in aqueous media. Transesterification of tannic acid was very similar to transesterification of methyl gallate. The synthetic yield depended on the pH and concentration of 1-propanol, although it did not vary much when using 30% or 50% 1-propanol. Synthetic yields of 45% were obtained with 30% of 1-propanol at pH 5.0. The product was chromatographically pure, and the reaction by-product was 55% pure gallic acid. On the other hand, immobilised tannase was fairly stable under optimal reaction conditions.

Improvement of enzyme properties with a two-step immobilizaton process on novel heterofunctional supports.

Novel heterofunctional glyoxyl-agarose supports were prepared. These supports contain a high concentration of groups (such as quaternary ammonium groups, carboxyl groups, and metal chelates) that are capable of adsorbing proteins, physically or chemically, at neutral pH as well as a high concentration of glyoxyl groups that are unable to immobilize covalently proteins at neutral pH. By using these supports, a two-step immobilization protocol was developed. In the first step, enzymes were adsorbed at pH 7.0 through adsorption of surface regions, which are complementary to the adsorbing groups on the support, and in the second step, the immobilized derivatives were incubated under alkaline conditions to promote an intramolecular multipoint covalent attachment between the glyoxyl groups on the support and the amino groups on the enzyme surface. These new derivatives were compared with those obtained on a monofunctional glyoxyl support at pH 10, in which the region with the greatest number of lysine residues participates in the first immobilization step. In some cases, multipoint immobilization on heterofunctional supports was much more efficient than what was achieved on the monofunctional support. For example, derivatives of tannase from Lactobacillus plantarum on an amino-glyoxyl heterofunctional support were 20-fold more stable than the best derivative on a monofunctional glyoxyl support. Derivatives of lipase from Geobacillus thermocatenulatus (BTL2) on the amino-glyoxyl supports were two times more active and four times more enantioselective than the corresponding monofunctional glyoxyl support derivative.