Toward a Generalized and High-throughput Enzyme Screening System Based on Artificial Genetic Circuits

Toward a Generalized and High-throughput Enzyme Screening System Based on Artificial Genetic Circuits

Large-scale screening of enzyme libraries is essential for the development of cost-effective biological processes, which will be indispensable for the production of sustainable biobased chemicals. Here, we introduce a genetic circuit termed the Genetic Enzyme Screening System that is highly useful f...

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Veröffentlicht in:ACS synthetic biology 2014-03, Vol.3 (3), p.163-171
Hauptverfasser: Choi, Su-Lim, Rha, Eugene, Lee, Sang Jun, Kim, Haseong, Kwon, Kilkoang, Jeong, Young-Su, Rhee, Young Ha, Song, Jae Jun, Kim, Hak-Sung, Lee, Seung-Goo
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Bacterial Proteins - analysis
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
Enzymes - analysis
Enzymes - genetics
Enzymes - metabolism
Genes, Reporter - genetics
High-Throughput Screening Assays - methods
Metagenome
Single-Cell Analysis
Synthetic Biology - methods
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container_end_page 171
container_issue 3
container_start_page 163
container_title ACS synthetic biology
container_volume 3
creator Choi, Su-Lim
Rha, Eugene
Lee, Sang Jun
Kim, Haseong
Kwon, Kilkoang
Jeong, Young-Su
Rhee, Young Ha
Song, Jae Jun
Kim, Hak-Sung
Lee, Seung-Goo
description Large-scale screening of enzyme libraries is essential for the development of cost-effective biological processes, which will be indispensable for the production of sustainable biobased chemicals. Here, we introduce a genetic circuit termed the Genetic Enzyme Screening System that is highly useful for high-throughput enzyme screening from diverse microbial metagenomes. The circuit consists of two AND logics. The first AND logic, the two inputs of which are the target enzyme and its substrate, is responsible for the accumulation of a phenol compound in cell. Then, the phenol compound and its inducible transcription factor, whose activation turns on the expression of a reporter gene, interact in the other logic gate. We confirmed that an individual cell harboring this genetic circuit can present approximately a 100-fold higher cellular fluorescence than the negative control and can be easily quantified by flow cytometry depending on the amounts of phenolic derivatives. The high sensitivity of the genetic circuit enables the rapid discovery of novel enzymes from metagenomic libraries, even for genes that show marginal activities in a host system. The crucial feature of this approach is that this single system can be used to screen a variety of enzymes that produce a phenol compound from respective synthetic phenyl-substrates, including cellulase, lipase, alkaline phosphatase, tyrosine phenol-lyase, and methyl parathion hydrolase. Consequently, the highly sensitive and quantitative nature of this genetic circuit along with flow cytometry techniques could provide a widely applicable toolkit for discovering and engineering novel enzymes at a single cell level.
doi_str_mv 10.1021/sb400112u
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subjects Bacterial Proteins - analysis
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
Enzymes - analysis
Enzymes - genetics
Enzymes - metabolism
Genes, Reporter - genetics
High-Throughput Screening Assays - methods
Metagenome
Single-Cell Analysis
Synthetic Biology - methods
title Toward a Generalized and High-throughput Enzyme Screening System Based on Artificial Genetic Circuits
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