Emerging trends in genome integration tools for precision engineering of diverse bacterial species

Riesa K W Rohmat; Thea C T Irvine; Shivang Hina-Nilesh Joshi; Andrew M Bailey; Christopher Jenkins; David Ulaeto; Pierre Buscaill; Thomas E Gorochowski

doi:10.1093/synbio/ysaf019

Emerging trends in genome integration tools for precision engineering of diverse bacterial species

Riesa K W Rohmat, Thea C T Irvine, Shivang Hina-Nilesh Joshi, Andrew M Bailey, Christopher Jenkins, David Ulaeto, Pierre Buscaill^*, Thomas E Gorochowski^*

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

The ability to precisely insert DNA payloads into a genome enables the comprehensive engineering of cellular phenotypes and the creation of new biotechnologies. To achieve such modifications, the most widely used techniques rely on a host cell’s native DNA repair mechanisms like homologous recombination, which hampers their broader use in organisms lacking these capabilities. Here, we explore the current landscape of genome integration systems with a particular focus on those that function in bacteria and which are precise, self-contained and portable, placing minimal requirements on the host cell. Through a historical analysis, we observe long-term use of recombineering technologies, a recent rise in the use of CRISPR-guided systems that consist of associated integrase machinery, and growing efforts to modify non-model organisms. Looking forward, we highlight some of the remaining challenges and how synthetic genomics may offer a way to create bacterial strains optimised for extensive long-term modification. As the field of synthetic biology sets its sights on real-world impact, the effective engineering of genomes will be critical in shaping the robust phenotypes that applications demand.

[See paper for graphical abstract]

Original language	English
Article number	ysaf019
Number of pages	15
Journal	Synthetic Biology
Volume	10
Issue number	1
Early online date	11 Dec 2025
DOIs	https://doi.org/10.1093/synbio/ysaf019
Publication status	Published - 4 Jan 2026

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© The Author(s) 2025. Published by Oxford University Press.

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title = "Emerging trends in genome integration tools for precision engineering of diverse bacterial species",

abstract = "The ability to precisely insert DNA payloads into a genome enables the comprehensive engineering of cellular phenotypes and the creation of new biotechnologies. To achieve such modifications, the most widely used techniques rely on a host cell{\textquoteright}s native DNA repair mechanisms like homologous recombination, which hampers their broader use in organisms lacking these capabilities. Here, we explore the current landscape of genome integration systems with a particular focus on those that function in bacteria and which are precise, self-contained and portable, placing minimal requirements on the host cell. Through a historical analysis, we observe long-term use of recombineering technologies, a recent rise in the use of CRISPR-guided systems that consist of associated integrase machinery, and growing efforts to modify non-model organisms. Looking forward, we highlight some of the remaining challenges and how synthetic genomics may offer a way to create bacterial strains optimised for extensive long-term modification. As the field of synthetic biology sets its sights on real-world impact, the effective engineering of genomes will be critical in shaping the robust phenotypes that applications demand. [See paper for graphical abstract]",

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T1 - Emerging trends in genome integration tools for precision engineering of diverse bacterial species

AU - Rohmat, Riesa K W

AU - Irvine, Thea C T

AU - Hina-Nilesh Joshi, Shivang

AU - Bailey, Andrew M

AU - Jenkins, Christopher

AU - Ulaeto, David

AU - Buscaill, Pierre

AU - Gorochowski, Thomas E

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N2 - The ability to precisely insert DNA payloads into a genome enables the comprehensive engineering of cellular phenotypes and the creation of new biotechnologies. To achieve such modifications, the most widely used techniques rely on a host cell’s native DNA repair mechanisms like homologous recombination, which hampers their broader use in organisms lacking these capabilities. Here, we explore the current landscape of genome integration systems with a particular focus on those that function in bacteria and which are precise, self-contained and portable, placing minimal requirements on the host cell. Through a historical analysis, we observe long-term use of recombineering technologies, a recent rise in the use of CRISPR-guided systems that consist of associated integrase machinery, and growing efforts to modify non-model organisms. Looking forward, we highlight some of the remaining challenges and how synthetic genomics may offer a way to create bacterial strains optimised for extensive long-term modification. As the field of synthetic biology sets its sights on real-world impact, the effective engineering of genomes will be critical in shaping the robust phenotypes that applications demand. [See paper for graphical abstract]

AB - The ability to precisely insert DNA payloads into a genome enables the comprehensive engineering of cellular phenotypes and the creation of new biotechnologies. To achieve such modifications, the most widely used techniques rely on a host cell’s native DNA repair mechanisms like homologous recombination, which hampers their broader use in organisms lacking these capabilities. Here, we explore the current landscape of genome integration systems with a particular focus on those that function in bacteria and which are precise, self-contained and portable, placing minimal requirements on the host cell. Through a historical analysis, we observe long-term use of recombineering technologies, a recent rise in the use of CRISPR-guided systems that consist of associated integrase machinery, and growing efforts to modify non-model organisms. Looking forward, we highlight some of the remaining challenges and how synthetic genomics may offer a way to create bacterial strains optimised for extensive long-term modification. As the field of synthetic biology sets its sights on real-world impact, the effective engineering of genomes will be critical in shaping the robust phenotypes that applications demand. [See paper for graphical abstract]

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Emerging trends in genome integration tools for precision engineering of diverse bacterial species

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