Versatile and robust genome editing with <i>Streptococcus thermophilus</i> CRISPR1-Cas9

Daniel Agudelo; Sophie Carter; Minja Velimirovic; Alexis Duringer; Jean-François Rivest; Sébastien Levesque; Jérémy Loehr; Mathilde Mouchiroud; Denis Cyr; Paula J. Waters; Mathieu Laplante; Sylvain Moineau; Adeline Goulet; Yannick Doyon

doi:10.1101/gr.255414.119

Versatile and robust genome editing with <i>Streptococcus thermophilus</i> CRISPR1-Cas9

Daniel Agudelo(Centre hospitalier universitaire de Québec), Sophie Carter(Centre hospitalier universitaire de Québec), Minja Velimirovic(Centre hospitalier universitaire de Québec), Alexis Duringer(Centre hospitalier universitaire de Québec), Jean-François Rivest(Centre hospitalier universitaire de Québec), Sébastien Levesque(Centre hospitalier universitaire de Québec), Jérémy Loehr(Centre hospitalier universitaire de Québec), Mathilde Mouchiroud(Institut universitaire de cardiologie et de pneumologie de Québec), Denis Cyr(Centre Hospitalier Universitaire de Sherbrooke), Paula J. Waters(Centre Hospitalier Universitaire de Sherbrooke), Mathieu Laplante(Institut universitaire de cardiologie et de pneumologie de Québec), Sylvain Moineau(Université Laval), Adeline Goulet(Centre National de la Recherche Scientifique), Yannick Doyon(Centre hospitalier universitaire de Québec)

Genome Research

January 1, 2020

10.1101/gr.255414.119

Cited by 80Open Access

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Abstract

Targeting definite genomic locations using CRISPR-Cas systems requires a set of enzymes with unique protospacer adjacent motif (PAM) compatibilities. To expand this repertoire, we engineered nucleases, cytosine base editors, and adenine base editors from the archetypal Streptococcus thermophilus CRISPR1-Cas9 (St1Cas9) system. We found that St1Cas9 strain variants enable targeting to five distinct A-rich PAMs and provide a structural basis for their specificities. The small size of this ortholog enables expression of the holoenzyme from a single adeno-associated viral vector for in vivo editing applications. Delivery of St1Cas9 to the neonatal liver efficiently rewired metabolic pathways, leading to phenotypic rescue in a mouse model of hereditary tyrosinemia. These robust enzymes expand and complement current editing platforms available for tailoring mammalian genomes.

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