Rapid Model-Based Optimization of a Two-Enzyme System for Continuous Reductive Amination in Flow

Abstract: Enzymes are increasingly combined into multienzyme systems for cost and productivity benefits. Further advantages can be gained through the use of immobilized enzymes, allowing continuous biotransformations in flow. However, the optimization of such multienzyme systems is challenging, particularly where immobilized enzymes are used. Here, we meet this challenge using both mechanistic and empirical modeling to optimize a reaction involving a reductive aminase and a glucose dehydrogenase for continuous biocataly… Show more

“…For the generation of secondary amines such as 3 from aldehyde 1 , RedAm and glucose dehydrogenase (GDH) combinations can be used and have also been demonstrated in flow systems previously. [ 14 , 31 , 32 ] Here, the reductive aminase from Ajellomyces dermatitidis ( Ad RedAm, 200 mg, 10 wt %) and the GDH from Bacillus megaterium ( Bs GDH, 10 mg, 10 wt %) were immobilized and both loaded into a packed bed reactor. Pleasingly, this also gave full conversion of the in situ generated hydrocinnamaldehyde 1 to the corresponding N ‐allyl amine 3 at steady state which was maintained for four hours (STY: 2.1 g L −1 h −1 ) (Table 1 ).…”

“…For the generation of secondary amines such as 3 from aldehyde 1 , RedAm and glucose dehydrogenase (GDH) combinations can be used and have also been demonstrated in flow systems previously [14, 31, 32] . Here, the reductive aminase from Ajellomyces dermatitidis ( Ad RedAm, 200 mg, 10 wt %) and the GDH from Bacillus megaterium ( Bs GDH, 10 mg, 10 wt %) were immobilized and both loaded into a packed bed reactor.…”

Development of Continuous Flow Systems to Access Secondary Amines Through Previously Incompatible Biocatalytic Cascades**

“…For the generation of secondary amines such as 3 from aldehyde 1 , RedAm and glucose dehydrogenase (GDH) combinations can be used and have also been demonstrated in flow systems previously. [ 14 , 31 , 32 ] Here, the reductive aminase from Ajellomyces dermatitidis ( Ad RedAm, 200 mg, 10 wt %) and the GDH from Bacillus megaterium ( Bs GDH, 10 mg, 10 wt %) were immobilized and both loaded into a packed bed reactor. Pleasingly, this also gave full conversion of the in situ generated hydrocinnamaldehyde 1 to the corresponding N ‐allyl amine 3 at steady state which was maintained for four hours (STY: 2.1 g L −1 h −1 ) (Table 1 ).…”

“…For the generation of secondary amines such as 3 from aldehyde 1 , RedAm and glucose dehydrogenase (GDH) combinations can be used and have also been demonstrated in flow systems previously [14, 31, 32] . Here, the reductive aminase from Ajellomyces dermatitidis ( Ad RedAm, 200 mg, 10 wt %) and the GDH from Bacillus megaterium ( Bs GDH, 10 mg, 10 wt %) were immobilized and both loaded into a packed bed reactor.…”

Development of Continuous Flow Systems to Access Secondary Amines Through Previously Incompatible Biocatalytic Cascades**

“…In the last years, the immobilization of engineered enzyme variants has allowed their application under industrially relevant conditions. 16,[33][34][35] To that aim, selective immobilization protocols that assure the activity and increase the stability of the enzymes upon the attachment to the solid carrier are pretended.…”

Selective oxidation of alkyl and aryl glyceryl monoethers catalysed by an engineered and immobilised glycerol dehydrogenase

“…Finnigan et al combined both mechanistic and empirical modeling to optimize a two-enzyme system for continuous reductive amination. 212 The multi-dimensional optimization shows a clear advantage compared to traditional time consuming one-factor at a time (OFAT) approaches. In addition, the availability of these models can be extended by modern public platforms such as github, and they can be operated with cloud-based Python notebooks.…”

The rise of continuous flow biocatalysis – fundamentals, very recent developments and future perspectives