Jaehwan Jeong scite author profile

Multiplex Automated Genome Engineering (MAGE) employs short oligonucleotides to scarlessly modify genomes. However, insertions of >10 bases are still inefficient, but can be improved substantially by selection of highly modified chromosomes. Here, we describe Co-Selection MAGE (CoS-MAGE) to optimize biosynthesis of aromatic amino acid derivatives by combinatorially inserting multiple T7 promoters simultaneously into 12 genomic operons. Promoter libraries can be quickly generated to study gain-of-function epistatic interactions in gene networks.

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Genome-scale genetic engineering in Escherichia coli

Jeong

Cho

Jung

et al. 2013

Biotechnology Advances

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Multiplex Generation, Tracking, and Functional Screening of Substitution Mutants Using a CRISPR/Retron System

et al. 2020

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We developed a clustered regularly interspaced short palindromic repeats (CRISPR)/retron system for multiplexed generation of substitution mutations by co-utilization of a retron system that continuously expresses donor DNA and a CRISPR/Cas9 cassette that induces cleavage at target genomic loci. Our system efficiently introduces substitution mutation in the Escherichia coli genome in a high-throughput manner. These substitution mutations can be tracked by analysis of retron plasmid sequences without laborious amplification of individual edited loci. We demonstrated that our CRISPR/retron system can introduce thousands of mutations in a single experiment and be used for screening phenotypes related to chemical responses or fitness changes. We expect that our system could facilitate genome-scale substitution screenings.

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Hierarchical gene synthesis using DNA microchip oligonucleotides

Kim

Jeong

Bang

2011

Journal of Biotechnology

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Repetitive genomic insertion of gene-sized dsDNAs by targeting the promoter region of a counter-selectable marker

Jeong

Seo

Jung

et al. 2015

Sci Rep

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Genome engineering can be used to produce bacterial strains with a wide range of desired phenotypes. However, the incorporation of gene-sized DNA fragments is often challenging due to the intricacy of the procedure, off-target effects, and low insertion efficiency. Here we report a genome engineering method enabling the continuous incorporation of gene-sized double-stranded DNAs (dsDNAs) into the Escherichia coli genome. DNA substrates are inserted without introducing additional marker genes, by synchronously turning an endogenous counter-selectable marker gene ON and OFF. To accomplish this, we utilized λ Red protein-mediated recombination to insert dsDNAs within the promoter region of a counter-selectable marker gene, tolC. By repeatedly switching the marker gene ON and OFF, a number of desired gene-sized dsDNAs can be inserted consecutively. With this method, we successfully inserted approximately 13 kb gene clusters to generate engineered E. coli strains producing 1,4-butanediol (1,4-BDO).

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Jaehwan Jeong

Genome-scale promoter engineering by coselection MAGE

Genome-scale genetic engineering in Escherichia coli

Multiplex Generation, Tracking, and Functional Screening of Substitution Mutants Using a CRISPR/Retron System

Hierarchical gene synthesis using DNA microchip oligonucleotides

Repetitive genomic insertion of gene-sized dsDNAs by targeting the promoter region of a counter-selectable marker

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