Rational design of biocatalysts based on covalent immobilization of acylase enzymes.

Acylases catalyze the hydrolysis of amide bonds. Penicillin G acylase (PGA) is used for the semi-synthesis of penicillins and cephalosporins. Although protein immobilization increases enzyme stability, the design of immobilized systems is difficult and usually it is empirically performed.

Rational design and synthesis of affinity matrices based on proteases immobilized onto cellulose membranes.

Discovery of new protease inhibitors may result in potential therapeutic agents or useful biotechnological tools. Obtainment of these molecules from natural sources requires simple, economic, and highly efficient purification protocols. The aim of this work was the obtainment of affinity matrices by the covalent immobilization of dipeptidyl peptidase IV (DPP-IV) and papain onto cellulose membranes, previously activated with formyl (FCM) or glyoxyl groups (GCM).

A thermostable exo-β-fructosidase immobilised through rational design.

Thermotoga maritima exo-β-fructosidase (BfrA) secreted by a recombinant Pichia pastoris strain was optimally immobilised on Glyoxyl-Sepharose CL 4B using the Rational Design of Immobilised Derivatives (RDID) strategy. Covalent attachment of the N-glycosylated BfrA onto the activated support at pH 10 allowed total recovery of the loaded enzyme and its activity. The immobilisation process caused no variation in the catalytic properties of the enzyme and allowed further enhancement of the thermal stability.

Rational design of immobilized lipases and phospholipases.

Immobilization of lipases and phospholipases on, mainly, water insoluble carriers, helps in their economic reuse and in the development of continuous bioprocesses. Design of efficient lipases and phospholipases-immobilized system is rather a difficult task. A lot of research work has been done in order to optimize immobilization techniques and procedures and to develop an efficient immobilized system.