Biocatalyst alcohol dehydrogenase

The reduction of several ketones, which were transformed by the wild-type lyophilized cells of Rhodococcus ruber DSM 44541 with moderate stereoselectivity, was reinvestigated employing lyophilized cells of Escherichia coli containing the overexpressed alcohol dehydrogenase (ADH- A ) from Rhodococcus ruber DSM 44541. The recombinant whole-cell biocatalyst significantly increased the activity and enantioselectivity [41]. For example, the enantiomeric excess of (R)-2-chloro-l-phenylethanol increased from 43 to >99%. This study clearly demonstrated the advantages of the recombinant whole cell biocatalysts over the wild-type whole cells. 

Hummel, W., Abokitse, K., Drauz, K. et al. (2003) Towards a large-scale asymmetric reduction process with isolated enzymes Expression of an (5)-alcohol dehydrogenase in E. coli and studies on the synthetic potential of this biocatalyst. Advanced Synthesis and Catalysis, 345 (1 + 2), 153-159. 

An isolated DNA molecule comprising DNA which encodes a group III alcohol dehydrogenase and DNA which encodes a BDS-active biocatalyst via nicotinamide adenosine dinucleotide-dependent manner. 

Biocatalysis is still an emerging field hence, some transformations are more established than others.Panke et alP have performed a survey of patent applications in the area of biocatalysis granted between the years 2000 and 2004. They found that although hydrolases, which perform hydrolyses and esterifications, still command widespread attention and remain the most utilized class of enzyme (Figure 1.5), significant focus has turned towards the use of biocatalysts with different activities and in particular alcohol dehydrogenases (ADHs) - also known as ketoreductases (KREDs) - used for asymmetric ketone reduction. 

Lactobacillus brevis whole-cell biotransformation When the reduction of diketo ester la was performed with whole cells of Lactobacillus brevis or L. kefir, formation of the 3,5-dihydroxy ester (3R,5S)-5a was observed [10, 22]. This was surprising since it is known that the prevailing alcohol dehydrogenase in I. brevis is the one described as LBADH [23] and since, moreover, this enzyme does not reduce P-keto 5-hydroxy ester 2a to the corresponding dihydroxy ester (Scheme 2.2.7.6). Under the conditions tested, further alcohol dehydrogenase activity is clearly present in I. brevis and I. kefir. Pfruender et al. optimized the production of L. kefir cells and used this biocatalyst for the one-pot synthesis of dihydroxy ester syn-(3R,5S)-5a using diketo ester la as starting material [24]. 

Since cinnamyl aldehyde is the main component of cassia oil (approximately 90%) and Sri Lanka cinnamon bark oil (approximately 75%) [49], it is industrially more important to generate cinnamyl alcohol, which is less abundantly available from nature but is important as cinnamon flavour, by biotransformation of natural cinnamyl aldehyde than vice versa. Recently, a whole-cell reduction of cinnamyl aldehyde with a conversion yield of 98% at very high precursor concentrations of up to 166 g L was described [136]. Escherichia coli DSM 14459 expressing a NADPH-dependent R alcohol dehydrogenase from Lactobacillus kefir and a glucose dehydrogenase from Thermoplasma acidophilum for intracellular cofactor regeneration was applied as the biocatalyst (Scheme 23.8). 

The chemoenzymatic synthesis of chiral alcohols is a field of major interest within biocatalytic asymmetric conversions. A convenient access to secondary highly enan-tiomerically enriched alcohols is the usage of alcohol dehydrogenases (ADHs) (ketoreductases) for the stereoselective reduction of prochiral ketones. Here, as in many other cases in asymmetric catalysis, enzymes are not always only an alternative to chemical possibilities, but are rather complementary. Albeit biocatalysts might sometimes seem to be more environmentally friendly, asymmetric ketone reduction... 

Screening kits/sets containing samples of the normal commercially available enzymes are also provided by other enzyme suppliers, such as Boehringer Mannheim/Roche (Chirazyme sets for lipases/esterases, aldol reaction kits), Altus Biologies (ChiroScreen Kits TE and EH (based on CLECs, see section 5) for the chiral resolution of alcohols, amines, and esters), Biocatalysts (kits with alcohol dehydrogenases), Enzymatix (lipase biotransformation research kit), and others. 

The utilization of biocatalysts other than hydrolytic enzymes has also been investigated. Alcohol dehydrogenase is used in the asymmetric reduction of ketones to yield optically active secondary alcohols (Scheme 51). " Although the productivity (substrate concentration) is low, high yields and excellent enantiomeric excess are obtained. On the other hand, carboxylation of pyrrole is efficient in SCCO2 (Scheme 52). The reaction under supercritical conditions is 12 times faster than that... 

---