Theo Peschke scite author profile

The establishment of microfluidic enzyme cascades is a topical field of research and development, which is currently hampered by the lack of methodologies for mild and efficient immobilization of isolated enzymes. We here describe the use of self-immobilizing fusion enzymes for the modular configuration of microfluidic packed-bed reactors. Specifically, three different enzymes, the (R)-selective alcohol dehydrogenase LbADH, the (S)-selective methylglyoxal reductase Gre2p and the NADP(H) regeneration enzyme glucose 1-dehydrogenase GDH, were genetically fused with streptavidin binding peptide, Spy and Halo-based tags, to enable their specific and directional immobilization on magnetic microbeads coated with complementary receptors. The enzyme-modified beads were loaded in four-channel microfluidic chips to create compartments that have the capability for either (R)- or (S)-selective reduction of the prochiral CS-symmetrical substrate 5-nitrononane-2,8-dione (NDK). Analysis of the isomeric hydroxyketone and diol products by chiral HPLC was used to quantitatively characterize the performance of reactors configured with different amounts of the enzymes. Long operating times of up to 14 days indicated stable enzyme immobilization and the general robustness of the reactor. Even more important, by fine-tuning of compartment size and loading, the overall product distribution could be controlled to selectively produce a single meso diol with nearly quantitative conversion (>95%) and excellent stereoselectivity (d.r. > 99:1) in a continuous flow process. We believe that our concept will be expandable to a variety of other biocatalytic or chemo-enzymatic cascade reactions.

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Self‐Assembling All‐Enzyme Hydrogels for Flow Biocatalysis

Peschke

Bitterwolf

Gallus

et al. 2018

Angew Chem Int Ed

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Continuous flowbiocatalysis is an emerging field of industrial biotechnology that uses enzymes immobilized in flowchannels for the production of value-added chemicals.We describe the construction of self-assembling all-enzyme hydrogels that are comprised of two tetrameric enzymes.T he stereoselective dehydrogenase LbADH and the cofactorregenerating glucose 1-dehydrogenase GDH were genetically fused with aS pyTago rS pyCatcher domain, respectively,t o generate two complementary homo-tetrameric building blocks that polymerizeu nder physiological conditions into porous hydrogels.M ounted in microfluidic reactors,t he gels show excellent stereoselectivity with near quantitative conversion in the reduction of prochiral ketones along with high robustness under process and storage conditions.T he gels function as compartment that retains intermediates thus enabling high total turnover numbers of the expensive cofactor NADP(H).

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Orthogonal Surface Tags for Whole‐Cell Biocatalysis

2017

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We herein describe the engineering of E. coli strains that display orthogonal tags for immobilization on their surface and overexpress a functional heterologous "protein content" in their cytosol at the same time. Using the outer membrane protein Lpp-ompA, cell-surface display of the streptavidin-binding peptide, the SpyTag/SpyCatcher system, or a HaloTag variant allowed us to generate bacterial strains that can selectively bind to solid substrates, as demonstrated with magnetic microbeads. The simultaneous cytosolic expression of functional content was demonstrated for fluorescent proteins or stereoselective ketoreductase enzymes. The latter strains gave high selectivities for specific immobilization onto complementary surfaces and also in the whole-cell stereospecific transformation of a prochiral C -symmetric nitrodiketone.

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Valency engineering of monomeric enzymes for self-assembling biocatalytic hydrogels

et al. 2019

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Surface Display of Complex Enzymes by in Situ SpyCatcher‐SpyTag Interaction

et al. 2020

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The display of complex proteins on the surface of cells is of great importance for protein engineering and other fields of biotechnology. Herein, we describe a modular approach, in which the membrane anchor protein Lpp‐OmpA and a protein of interest (passenger) are expressed independently as genetically fused SpyCatcher and SpyTag units and assembled in situ by post‐translational coupling. Using fluorescent proteins, we first demonstrate that this strategy allows the construct to be installed on the surface of E. coli cells. The scope of our approach was then demonstrated by using three different functional enzymes, the stereoselective ketoreductase Gre2p, the homotetrameric glucose 1‐dehydrogenase GDH, and the bulky heme‐ and diflavin‐containing cytochrome P450 BM3 (BM3). In all cases, the SpyCatcher‐SpyTag method enabled the generation of functional whole‐cell biocatalysts, even for the bulky BM3, which could not be displayed by conventional fusion with Lpp‐OmpA. Furthermore, by using a GDH variant carrying an internal SpyTag, the system could be used to display an enzyme with unmodified N‐ and C‐termini.

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Theo Peschke

Self-Immobilizing Fusion Enzymes for Compartmentalized Biocatalysis

Self‐Assembling All‐Enzyme Hydrogels for Flow Biocatalysis

Orthogonal Surface Tags for Whole‐Cell Biocatalysis

Valency engineering of monomeric enzymes for self-assembling biocatalytic hydrogels

Surface Display of Complex Enzymes by in Situ SpyCatcher‐SpyTag Interaction

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