Protein engineering of alcohol dehydrogenases: effects of amino acid changes at positions 93 and 48 of yeast ADH1.

By protein engineering we have investigated changes to two amino acid residues (Trp93 and Ser48) in the substrate pocket of yeast alcohol dehydrogenase 1. Upon changing Thr48 to serine we produced an enzyme which has markedly greater activity towards aliphatic alcohols with chain length up to 8, together with a general increase in catalytic activity (V/K). Changes at position 93 were less pronounced, with the Phe enzyme being more active than the parent towards the range of alcohols but with the alanine enzyme showing very little difference from the wild-type. Enzymes with the double changes at 48 and 93 showed increased activity towards alcohols with 3-8 carbons but the increases were not additive over the single changes. The enzymes with changes at the two positions would metabolize both stereoisomers of 2-octanol whereas the parent ADH would attack only one of them. None of the engineered enzymes would attack cyclohexanol or aromatic alcohols. The results are in general agreement with the prediction that reducing the size of amino acids in the substrate pocket would enhance the ability to oxidize alcohols larger than ethanol.

Purification and preliminary characterization of alcohol dehydrogenase from Aspergillus nidulans.

Aspergillus alcohol dehydrogenase is produced in response to growth in the presence of a wide variety of inducers, of which the most effective are short-chain alcohols and ketones, e.g. butan-2-one and propan-2-ol. The enzyme can be readily extracted from fresh or freeze-dried cells and purified to homogeneity on Blue Sepharose in a single step by using specific elution with NAD+ and pyrazole. The pure enzyme has Mr 290 000 by electrophoresis or gel filtration; it is a homopolymer with subunit Mr 37 500 by electrophoresis in sodium dodecyl sulphate; its amino acid composition corresponds to Mr 37 900, and the native enzyme contains one zinc atom per subunit. The enzyme is NAD-specific and has a wide substrate activity in the forward and reverse reactions; its activity profile is not identical with those of other alcohol dehydrogenases.