Vector redesign and in‐droplet cell‐growth improves enrichment and recovery in live Escherichia coli

Directed evolution (DE) is a widely used method for improving the function of biomolecules via multiple rounds of mutation and selection. Microfluidic droplets have emerged as an important means to screen the large libraries needed for DE, but this approach was so far partially limited by the need t...

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Published in:Microbial biotechnology 2022-11, Vol.15 (11), p.2845-2853
Main Authors: Eenink, Bernard D. G., Kaminski, Tomasz S., Bornberg‐Bauer, Erich, Jose, Joachim, Hollfelder, Florian, Loo, Bert
Format: Article
Language:English
Subjects:
Antibiotics
Biofilms
Biomolecules
Brief Report
Brief Reports
Copy number
Directed evolution
Droplets
E coli
Enrichment
Enzymes
Evolution
Genotype & phenotype
Microfluidics
Mutation
Plasmids
Recovery
Redesign
Small libraries
Substrates
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cited_by cdi_FETCH-LOGICAL-c5114-88215fe8f726234e85573af5bd6bb55117faa36be9182aa4f461feca4ae696df3
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container_issue 11
container_start_page 2845
container_title Microbial biotechnology
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creator Eenink, Bernard D. G.
Kaminski, Tomasz S.
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Hollfelder, Florian
Loo, Bert
description Directed evolution (DE) is a widely used method for improving the function of biomolecules via multiple rounds of mutation and selection. Microfluidic droplets have emerged as an important means to screen the large libraries needed for DE, but this approach was so far partially limited by the need to lyse cells, recover DNA, and retransform into cells for the next round, necessitating the use of a high‐copy number plasmid or oversampling. The recently developed live cell recovery avoids some of these limitations by directly regrowing selected cells after sorting. However, repeated sorting cycles used to further enrich the most active variants ultimately resulted in unfavourable recovery of empty plasmid vector‐containing cells over those expressing the protein of interest. In this study, we found that engineering of the original expression vector solved the problem of false positives (i.e. plasmids lacking an insert) cells containing empty vectors. Five approaches to measure activity of cell‐displayed enzymes in microdroplets were compared. By comparing various cell treatment methods prior to droplet sorting two things were found. Substrate encapsulation from the start, that is prior to expression of enzyme, showed no disadvantage to post‐induction substrate addition by pico‐injection with respect to recovery of true positive variants. Furthermore in‐droplet cell growth prior to induction of enzyme production improves the total amount of cells retrieved (recovery) and proportion of true positive variants (enrichment) after droplet sorting. In this study five methods for to measure activity of cell‐displayed enzymes were compared. By comparing various cell treatment methods it was found that substrate encapsulation prior to enzyme expression in a one‐pot reaction showed no disadvantage in cell growth, and cell growth in‐droplet increased both the total amount of cells recovered, as well as the proportion of positives recovered.
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source Wiley Online Library Open Access; Publicly Available Content Database; PubMed Central
subjects Antibiotics
Biofilms
Biomolecules
Brief Report
Brief Reports
Copy number
Directed evolution
Droplets
E coli
Enrichment
Enzymes
Evolution
Genotype & phenotype
Microfluidics
Mutation
Plasmids
Recovery
Redesign
Small libraries
Substrates
title Vector redesign and in‐droplet cell‐growth improves enrichment and recovery in live Escherichia coli
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