Half a century after their discovery: Structural insights into exonuclease and annealase proteins catalyzing recombineering

Fitschen, LJ; Newing, TP; Johnston, NP; Bell, CE; Tolun, G

Half a century after their discovery: Structural insights into exonuclease and annealase proteins catalyzing recombineering

Fitschen, LJ Newing, TP Johnston, NP Bell, CE Tolun, G

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Publisher:: Elsevier
Publication Type:: Journal Article
Citation:: Engineering Microbiology, 2024, 4, (1), pp. 100120
Issue Date:: 2024-03-01

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Field	Value	Language
dc.contributor.author	Fitschen, LJ
dc.contributor.author	Newing, TP
dc.contributor.author	Johnston, NP
dc.contributor.author	Bell, CE
dc.contributor.author	Tolun, G
dc.date.accessioned	2024-01-30T06:12:07Z
dc.date.available	2024-01-30T06:12:07Z
dc.date.issued	2024-03-01
dc.identifier.citation	Engineering Microbiology, 2024, 4, (1), pp. 100120
dc.identifier.issn	2667-3703
dc.identifier.uri	http://hdl.handle.net/10453/175090
dc.description.abstract	Recombineering is an essential tool for molecular biologists, allowing for the facile and efficient manipulation of bacterial genomes directly in cells without the need for costly and laborious in vitro manipulations involving restriction enzymes. The main workhorses behind recombineering are bacteriophage proteins that promote the single-strand annealing (SSA) homologous recombination pathway to repair double-stranded DNA breaks. While there have been several reviews examining recombineering methods and applications, comparatively few have focused on the mechanisms of the proteins that are the key players in the SSA pathway: a 5′→3′ exonuclease and a single-strand annealing protein (SSAP or “annealase”). This review dives into the structures and functions of the two SSA recombination systems that were the first to be developed for recombineering in E. coli: the RecET system from E. coli Rac prophage and the λRed system from bacteriophage λ. By comparing the structures of the RecT and Redβ annealases, and the RecE and λExo exonucleases, we provide new insights into how the structures of these proteins dictate their function. Examining the sequence conservation of the λExo and RecE exonucleases gives more profound insights into their critical functional features. Ultimately, as recombineering accelerates and evolves in the laboratory, a better understanding of the mechanisms of the proteins behind this powerful technique will drive the development of improved and expanded capabilities in the future.
dc.language	en
dc.publisher	Elsevier
dc.relation.ispartof	Engineering Microbiology
dc.relation.isbasedon	10.1016/j.engmic.2023.100120
dc.rights	info:eu-repo/semantics/openAccess
dc.title	Half a century after their discovery: Structural insights into exonuclease and annealase proteins catalyzing recombineering
dc.type	Journal Article
utslib.citation.volume	4
pubs.organisational-group	University of Technology Sydney
pubs.organisational-group	University of Technology Sydney/Faculty of Science
pubs.organisational-group	University of Technology Sydney/Faculty of Science/School of Life Sciences
utslib.copyright.status	open_access	*
dc.date.updated	2024-01-30T06:12:05Z
pubs.issue	1
pubs.publication-status	Accepted
pubs.volume	4
utslib.citation.issue	1

Abstract:

Recombineering is an essential tool for molecular biologists, allowing for the facile and efficient manipulation of bacterial genomes directly in cells without the need for costly and laborious in vitro manipulations involving restriction enzymes. The main workhorses behind recombineering are bacteriophage proteins that promote the single-strand annealing (SSA) homologous recombination pathway to repair double-stranded DNA breaks. While there have been several reviews examining recombineering methods and applications, comparatively few have focused on the mechanisms of the proteins that are the key players in the SSA pathway: a 5′→3′ exonuclease and a single-strand annealing protein (SSAP or “annealase”). This review dives into the structures and functions of the two SSA recombination systems that were the first to be developed for recombineering in E. coli: the RecET system from E. coli Rac prophage and the λRed system from bacteriophage λ. By comparing the structures of the RecT and Redβ annealases, and the RecE and λExo exonucleases, we provide new insights into how the structures of these proteins dictate their function. Examining the sequence conservation of the λExo and RecE exonucleases gives more profound insights into their critical functional features. Ultimately, as recombineering accelerates and evolves in the laboratory, a better understanding of the mechanisms of the proteins behind this powerful technique will drive the development of improved and expanded capabilities in the future.

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http://hdl.handle.net/10453/175090