Carrier-bound and carrier-free penicillin acylase biocatalysts for the thermodynamically controlled synthesis of ?-lactam compounds in organic medium

Wilson, L; Illanes A.; ROMERO, O; Vergara, J; Mateo, C

Keywords: phenyl, model, percolation, stability, acid, system, solvent, batch, thermodynamics, enzyme, no, polymerization, complexation, reduction, synthesis, binding, equilibrium, solvents, arsenic, protein, food, co, enzymes, reactors, beta, acylase, conversion, ethers, environments, drug, carrier, amines, penicillin, article, biocatalyst, organic, dynamic, chlorine, activity, cosolvents, reactor, additives, agarose, antibiotic, controlled, cleas, micro, positioning, study, 7, compounds, aggregates, derivative, amino, amidase, Reaction, nonhuman, G, Acetic, unclassified, medium, Sequential, (solid, state), phenylacetic, cephalosporin, Dioxane, Civil, lactam, enzymatic, Aviation, glyoxyl, Cross-linked, Diglyme, syntheses, Half-lives, Thermodynamically, deacetoxycephalosporanic, deacetoxycephalosporin

Abstract

Different carrier-free and carrier-bound penicillin acylases were evaluated in the thermodynamically controlled enzymatic synthesis in organic medium of deacetoxycephalosporin G (using phenylacetic acid and 7-amino-deacetoxycefalosporanic acid) used as a model reaction system. Stability of all biocatalysts was determined in a strong (dioxane) and a moderately weak cosolvent (diglyme) to select the best biocatalysts and reaction medium for performing synthesis. Diglyme was selected as cosolvent, while cross-linked enzyme aggregates with polymeric microenvironment (CLEAs-DP) and glyoxyl agarose immobilized penicillin acylase (GAPA) were selected as biocatalysts to perform the thermodynamically controlled synthesis of deacetoxycephalosporin G at different concentrations of cosolvent. Half-lives of CLEA-DP and GAPA were 666 h and 71 h, respectively, being their activities similar (242 and 254 IU/g, respectively). At the best conditions (70% diglyme), conversion yields were closer to 90%. Productivities of CLEA-DP and GAPA were 2.80 mM/h and 2.54 mM/h, respectively. Stability of both biocatalysts during synthesis was tested in sequential batch reactor operation being significantly higher for CLEA-DP where no reduction in equilibrium conversion was observed after four sequential batches. Higher stability also reflected in higher productivity. © 2008 Elsevier Inc. All rights reserved.

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Título de la Revista: ENZYME AND MICROBIAL TECHNOLOGY
Volumen: 43
Número: 6
Editorial: Elsevier Science Inc.
Fecha de publicación: 2008
Página de inicio: 442
Página final: 447
URL: http://www.scopus.com/inward/record.url?eid=2-s2.0-52949085077&partnerID=q2rCbXpz