The evolving art of creating genetic diversity: from directed evolution to synthetic biology

Andrew Currin; Steven Parker; Christopher Robinson; Eriko Takano; Nigel Scrutton; Rainer Breitling

The evolving art of creating genetic diversity: from directed evolution to synthetic biology

Andrew Currin, Steven Parker, Christopher Robinson, Eriko Takano, Nigel Scrutton, Rainer Breitling

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

Abstract

The ability to engineer biological systems, whether to introduce novel functionality or improved performance, is a cornerstone of biotechnology and synthetic biology. Typically, this requires the generation of genetic diversity to explore variations in phenotype, a process that can be performed at many levels, from single molecule targets (i.e., in directed evolution of enzymes) to whole organisms (e.g., in chassis engineering). Recent advances in DNA synthesis technology and automation have enhanced our ability to create variant libraries with greater control and throughput. This review highlights the latest developments in approaches to create such a hierarchy of diversity from the enzyme level to entire pathways in vitro, with a focus on the creation of combinatorial libraries that are required to navigate a target’s vast design space successfully to uncover significant improvements in function.

Original language	English
Journal	Biotechnology Advances
Publication status	Accepted/In press - 26 Apr 2021

Research Beacons, Institutes and Platforms

Manchester Institute of Biotechnology

Manchester Synthetic Biology Research Centre for Fine and Speciality Chemicals
Scrutton, N., Azapagic, A., Balmer, A., Barran, P., Breitling, R., Delneri, D., Dixon, N., Faulon, J., Flitsch, S., Goble, C., Goodacre, R., Hay, S., Kell, D., Leys, D., Lloyd, J., Lockyer, N., Martin, P., Micklefield, J., Munro, A., Pedrosa Mendes, P., Randles, S., Salehi Yazdi, F., Shapira, P., Takano, E., Turner, N. & Winterburn, J.
14/11/14 → 13/05/20
Project: Research

Cite this

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title = "The evolving art of creating genetic diversity: from directed evolution to synthetic biology",

abstract = "The ability to engineer biological systems, whether to introduce novel functionality or improved performance, is a cornerstone of biotechnology and synthetic biology. Typically, this requires the generation of genetic diversity to explore variations in phenotype, a process that can be performed at many levels, from single molecule targets (i.e., in directed evolution of enzymes) to whole organisms (e.g., in chassis engineering). Recent advances in DNA synthesis technology and automation have enhanced our ability to create variant libraries with greater control and throughput. This review highlights the latest developments in approaches to create such a hierarchy of diversity from the enzyme level to entire pathways in vitro, with a focus on the creation of combinatorial libraries that are required to navigate a target{\textquoteright}s vast design space successfully to uncover significant improvements in function.",

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AU - Parker, Steven

AU - Robinson, Christopher

AU - Takano, Eriko

AU - Scrutton, Nigel

AU - Breitling, Rainer

PY - 2021/4/26

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AB - The ability to engineer biological systems, whether to introduce novel functionality or improved performance, is a cornerstone of biotechnology and synthetic biology. Typically, this requires the generation of genetic diversity to explore variations in phenotype, a process that can be performed at many levels, from single molecule targets (i.e., in directed evolution of enzymes) to whole organisms (e.g., in chassis engineering). Recent advances in DNA synthesis technology and automation have enhanced our ability to create variant libraries with greater control and throughput. This review highlights the latest developments in approaches to create such a hierarchy of diversity from the enzyme level to entire pathways in vitro, with a focus on the creation of combinatorial libraries that are required to navigate a target’s vast design space successfully to uncover significant improvements in function.

M3 - Article

SN - 0734-9750

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ER -

The evolving art of creating genetic diversity: from directed evolution to synthetic biology

Abstract

Research Beacons, Institutes and Platforms

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Projects

Manchester Synthetic Biology Research Centre for Fine and Speciality Chemicals

Cite this