A two-step biocatalytic cascade in micro-aqueous medium: using whole cells to obtain high concentrations of a vicinal diol

Abstract: Although single-and multi-step biocatalytic approaches show persuasive advantages for the synthesis of especially chiral compounds (e.g. high chemo-and stereoselectivity), their application often suffers from low substrate loads and hence low space-time-yields. We herein present a synthetic cascade approach in which lyophilised, recombinant whole cells are applied in micro-aqueous reaction systems yielding extremely high space-time-yields. As an example we investigated the two-step synthesis of 1-phenylpropane… Show more

“…Alternatively, water or buffer is added resulting in a micro-aqueous system, in which ideally no second phase is observed as the water is taken up by the solvent or the catalyst [27]. In 2011, Jakoblinnert et al applied lyophilized E. coli whole cells expressing Candida parapsilosis carbonyl reductase (CPCR) in a mixture of only acetophenone as main substrate and n-propanol as a cosubstrate for cofactor regeneration.…”

“…Nevertheless, substrate concentrations of 500 mM could be achieved in micro-aqueous MTBE in a 2-step reaction employing recombinant whole cell catalyst for carboligation and oxidoreduction, respectively. Even with highly inactivating acetaldehyde and benzaldehyde as substrates, space-time-yields and product concentration of the batch reactions were outstandingly high, with up to 327 g L À1 d À1 and 49 g L À1 for (1R,2R)-phenylpropane-1,2-diol production [27].…”

“…On the other hand, coexpression of multiple proteins may lead to a high metabolic burden during cell growth, which can result in poor overexpression and thus impaired catalytic performance [46]. Therefore, in some cases it can be beneficial to express each enzyme in single and later combine the cells into cascade reactions flexibly [27]. Anyhow, cascade biocatalysis becomes particularly sophisticated yet appealing when redox-neutral (see Section 'Cofactor regeneration') or recycling cascades [47] are designed.…”

Recent advances in whole cell biocatalysis techniques bridging from investigative to industrial scale

“…Alternatively, water or buffer is added resulting in a micro-aqueous system, in which ideally no second phase is observed as the water is taken up by the solvent or the catalyst [27]. In 2011, Jakoblinnert et al applied lyophilized E. coli whole cells expressing Candida parapsilosis carbonyl reductase (CPCR) in a mixture of only acetophenone as main substrate and n-propanol as a cosubstrate for cofactor regeneration.…”

“…Nevertheless, substrate concentrations of 500 mM could be achieved in micro-aqueous MTBE in a 2-step reaction employing recombinant whole cell catalyst for carboligation and oxidoreduction, respectively. Even with highly inactivating acetaldehyde and benzaldehyde as substrates, space-time-yields and product concentration of the batch reactions were outstandingly high, with up to 327 g L À1 d À1 and 49 g L À1 for (1R,2R)-phenylpropane-1,2-diol production [27].…”

“…On the other hand, coexpression of multiple proteins may lead to a high metabolic burden during cell growth, which can result in poor overexpression and thus impaired catalytic performance [46]. Therefore, in some cases it can be beneficial to express each enzyme in single and later combine the cells into cascade reactions flexibly [27]. Anyhow, cascade biocatalysis becomes particularly sophisticated yet appealing when redox-neutral (see Section 'Cofactor regeneration') or recycling cascades [47] are designed.…”

Recent advances in whole cell biocatalysis techniques bridging from investigative to industrial scale

“…Therefore, we decided to test E. coli /TeSADH WIC in an organic solvent, especially since both the wild‐type enzyme and the W110A have already been reported to be active in organic solvents . Inspired by the results of reactions catalyzed by lyophilized ADHs in micro‐aqueous systems (μAq), we decided to adapt similar reaction conditions and test whether the E. coli /TeSADH WIC would be active and still maintain low enantioselectivity. Oxidation of rac ‐ 1 b to 2 b under μAq conditions indicated E. coli /TeSADH WIC retains activity and low enantioselectivity in selected solvents, such as n ‐hexane, cyclohexane, toluene, diisopropyl ether (DIPE), methyl tert ‐butyl ether (MTBE), or ethyl acetate (Table , entries 1–6).…”

Biocatalytic Racemization Employing TeSADH: Substrate Scope and Organic Solvent Compatibility for Dynamic Kinetic Resolution

“…Using Escherichia coli cells coexpressing both carbonyl reductase and GDH has been proven to be a practical method for effective cofactor regeneration, even in unconventional media and multistep reaction systems . This method could decrease or avoid the external addition of cofactor and simplify the process.…”

Highly Efficient Synthesis of Optically Pure (S)‐1‐phenyl‐1,2‐ethanediol by a Self‐Sufficient Whole Cell Biocatalyst