Clonal Amplification-Enhanced Gene Expression in Synthetic Vesicles

Zhanar Abil; Ana Maria Restrepo Sierra; Christophe Danelon

doi:10.1021/acssynbio.2c00668

Clonal Amplification-Enhanced Gene Expression in Synthetic Vesicles

Zhanar Abil, Ana Maria Restrepo Sierra, Christophe Danelon^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

1 Citation (Scopus)

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Abstract

In cell-free gene expression, low input DNA concentration severely limits the phenotypic output, which may impair in vitro protein evolution efforts. We address this challenge by developing CADGE, a strategy that is based on clonal isothermal amplification of a linear gene-encoding dsDNA template by the minimal Φ29 replication machinery and in situ transcription-translation. We demonstrate the utility of CADGE in bulk and in clonal liposome microcompartments to boost up the phenotypic output of soluble and membrane-associated proteins, as well as to facilitate the recovery of encapsulated DNA. Moreover, we report that CADGE enables the enrichment of a DNA variant from a mock gene library via either a positive feedback loop-based selection or high-throughput screening. This new biological tool can be implemented for cell-free protein engineering and the construction of a synthetic cell.

Original language	English
Pages (from-to)	1187-1203
Journal	ACS Synthetic Biology
Volume	12
Issue number	4
DOIs	https://doi.org/10.1021/acssynbio.2c00668
Publication status	Published - 2023

Keywords

cell-free gene expression
directed evolution
DNA amplification
synthetic cell

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acssynbio.2c00668Final published version, 10.6 MBLicence: CC BY

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title = "Clonal Amplification-Enhanced Gene Expression in Synthetic Vesicles",

abstract = "In cell-free gene expression, low input DNA concentration severely limits the phenotypic output, which may impair in vitro protein evolution efforts. We address this challenge by developing CADGE, a strategy that is based on clonal isothermal amplification of a linear gene-encoding dsDNA template by the minimal Φ29 replication machinery and in situ transcription-translation. We demonstrate the utility of CADGE in bulk and in clonal liposome microcompartments to boost up the phenotypic output of soluble and membrane-associated proteins, as well as to facilitate the recovery of encapsulated DNA. Moreover, we report that CADGE enables the enrichment of a DNA variant from a mock gene library via either a positive feedback loop-based selection or high-throughput screening. This new biological tool can be implemented for cell-free protein engineering and the construction of a synthetic cell.",

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AU - Abil, Zhanar

AU - Restrepo Sierra, Ana Maria

AU - Danelon, Christophe

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AB - In cell-free gene expression, low input DNA concentration severely limits the phenotypic output, which may impair in vitro protein evolution efforts. We address this challenge by developing CADGE, a strategy that is based on clonal isothermal amplification of a linear gene-encoding dsDNA template by the minimal Φ29 replication machinery and in situ transcription-translation. We demonstrate the utility of CADGE in bulk and in clonal liposome microcompartments to boost up the phenotypic output of soluble and membrane-associated proteins, as well as to facilitate the recovery of encapsulated DNA. Moreover, we report that CADGE enables the enrichment of a DNA variant from a mock gene library via either a positive feedback loop-based selection or high-throughput screening. This new biological tool can be implemented for cell-free protein engineering and the construction of a synthetic cell.

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Clonal Amplification-Enhanced Gene Expression in Synthetic Vesicles

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Engineering Synthetic Cells through Module Integration and Evolution

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