Modificación química dirigida de lipasas en fase sólida
- Romero Ormazabal, Oscar
- J. M. Guisán Zuzendaria
- José Miguel Palomo Carmona Zuzendaria
Defentsa unibertsitatea: Universidad Autónoma de Madrid
Fecha de defensa: 2014(e)ko otsaila-(a)k 25
- Maria Encarnacion Lorenzo Abad Presidentea
- Mariola Tortosa Manzanares Idazkaria
- Andrés Rafael Alcántara Leon Kidea
- Vicente Gotor Fernández Kidea
- Antonio Ballesteros Olmo Kidea
Mota: Tesia
Laburpena
Enzymes are versatile biocatalysts finding an increasing application in many industrial fields including fine and organic chemistry, pharmacy, cosmetics or food industry. The enzymes unsurpassed chemo-, regioand enantioselectivity characteristics are making them interesting as fine chemistry biocatalysts since the preparation of pure intermediates is a key step for many industrially relevant processes. However, when using non-natural substrates enzyme specificity may not be as high as required for industrial purposes requesting the need of improvement of this enzyme property, possible through very different techniques, like screening, controlled immobilization, enzyme engineering, directed evolution and rational design approaches, chemical modification or combinations thereof. Strategies for the selective and efficient chemical modification of proteins have been implemented successfully for the study and modulation of enzyme specificity. However, despite the efforts made the past years the site-directed incorporation of different moieties, like carbohydrates, peptides, polymers, DNA, etc. specifically to the required position at the enzyme remains a challenging task. Applying conventional methods of chemical modification on a protein attached covalently or reversible to a surface or matrix can provide an important simplification of current protocols of modification. The main objective of this Doctoral Thesis has been the development and implementation of new strategies of site-directed chemical modifications of proteins on solid phase to improve their catalytic properties. Joining genetic and chemical modification approaches 5 strategies were developed using immobilized lipases as model enzymes: - Chemical glycosylation of lipases on solid phase - Promotion of the open conformation o lipase by two cysteine ligation - Development of semisynthetic lipases conjugates - Active center redesign with non-natural moieties - Development of hybrid catalysts: lipase active-site anchoring of organometallics These strategies were successfully applied, obtaining modified proteins with quantitative yields in almost all the cases. These new modified lipases showed improved activity, regioselectivity, enantioselectivity in several important biotransformations. The strategies developed during this thesis combine simplified and easy handling of the enzyme during all modification steps with highly selective chemical modification protocol. Methods are potentially extendable to other proteins and fields therefore offering general strategies for obtaining improved enzyme variants applying solid-phase chemical modification strategies