Oxidation of 1,2-Diols Using Alcohol Dehydrogenases : From Kinetic Characterization to Directed Evolution

Blikstad, Cecilia

January 2013

The use of enzymes as catalysts for chemical transformations has emerged as a “greener” alternative to traditional organic synthesis. An issue to solve though, is that enzymes are designed by nature to catalyze reactions in a living cell and therefore, in many cases, do not meet the requirements of a suitable biocatalyst. By mimicking Darwinian evolution these problems can be addressed in vitro by different types of directed evolution strategies. α-Hydroxy aldehydes and α-hydroxy ketones are important building blocks in the synthesis of natural products, fine chemicals and pharmaceuticals. In this thesis, two alcohol dehydrogenases, FucO and ADH-A, have been studied. Their potentials to serve as useful biocatalysts for the production of these classes of molecules have been investigated, and shown to be good. FucO for its strict regiospecificity towards primary alcohols and that it strongly prefers the S-enantiomer of diol substrates. ADH-A for its regiospecificity towards secondary alcohols, its enantioselectivity and that is has the ability to use a wide variety of bulky substrates. The kinetic mechanisms of these enzymes were investigated using pre-steady state kinetics, product inhibition, kinetic isotope effects and solvent viscosity effects, and in both cases, the rate limiting steps were pin-pointed to conformational changes occurring at the enzyme-nucleotide complex state. These characterizations provide an important foundation for further studies on these two enzymes.   FucO is specialized for activity with small aliphatic substrates but is virtually inactive with aryl-substituted compounds. By the use of iterative saturation mutagenesis, FucO was re-engineered and several enzyme variants active with S-3-phenylpropane-1,2-diol and phenylacetaldehyde were obtained. It was shown that these variants capability to act on larger substrates are mainly due to an enlargement of the active site cavity. Furthermore, several amino acids which are important for catalysis and specificity were identified. Phe254 interacts with aryl-substituted substrates through π-π stacking and may be essential for activity with these larger substrates. One mutation caused a loss in the interactions made between the enzyme and the nucleotide and thereby enhanced the turnover number for the preferred substrate

enzyme kinetics

alcohol dehydrogenase

directed evolution

enzyme engineering

diol

α-hydroxy aldehyde

Development of benign synthesis of some terminal α-hydroxy ketones and aldehydes

Vaismaa, M. (Matti)

11 August 2009

Abstract The synthesis of α-hydroxy aldehydes and hydroxymethyl ketones as well as their interconversion to each other are discussed in this thesis. The literature survey of the monograph reviews the synthetic methods for the preparation of 1,2-bifunctionalized hydroxy aldehydes and ketones. The keto-aldehyde isomerisation reaction catalyzed by Triosephosphate isomerase enzyme (TIM) and organic compounds that interact with the TIM are also introduced. In addition, the microwave heating techniques in organic syntheses are reviewed. The practical work consists of two entities: The synthesis of new substrate candidates and transition state analogues for a mutated monomeric TIM. These compounds are model compounds for the catalytic activity and the structural studies of the mutated monomeric TIM. The synthesis of the sulphonyl α-hydroxy ketone-based substrate candidates consists of four successive syntheses. The microwave-activation was utilized in the preparation of a carbon-sulphur bond and the synthesis of hydroxymethyl ketones. The improved synthesis of the terminal α-hydroxy ketone functionality with microwave activation is presented. The formation of charged compounds was utilized to improve the absorption of microwave energy of reaction mixtures. The design and the synthetic work were carried out in accordance to principles of green chemistry. The second part of the practical work is the development of an organocatalytic α-oxybenzoylation reaction of aldehydes with high enantiomeric selectivity. This novel method generated enantiomerically pure α-hydroxy aldehydes in the stable benzoate-protected form from achiral starting materials under mild conditions at the presence of air and moisture.

microwave-assisted synthesis

organocatalysis

triosephosphate isomerase

α-hydroxy aldehyde

α-hydroxy ketone