Authors
Nathalie Laforge, Magali Calabre, Matthieu Jules, Anne-Gaëlle Planson
Published in
ACS synthetic biology. Jul 29, 2025. Epub Jul 29, 2025.
Abstract
With the advent of MAD7, a Cpf1-like nuclease, there has been a renewed focus on the development of CRISPR-based genome engineering tools in recent years. To improve genome engineering methodologies in B. subtilis, we revisited the potential of MAD7 for gene modification and expression interference. A key challenge in these endeavors is the limited transformation efficiency. To overcome this, we developed an efficient transformation protocol using strains overexpressing competence genes. Our results showed that although MAD7 together with a B. subtilis chromosome-targeting gRNA is lethal, enabling robust counterselection, we successfully engineered a strain carrying the MAD7-gRNA machinery in a reversibly inactivated state, marking a significant advance in the field. We demonstrated that both MAD7 and its catalytically inactive variant (dMAD7) can be conditionally regulated by inactivation at elevated temperatures. In addition, the MAD7-gRNA complex is effective for multiplex genome editing, allowing for the simultaneous deletion, mutation, or insertion of up to four loci, and enabling the combination of gene deletion, gene insertion, and point mutations. Furthermore, we established a strategy that achieves the simultaneous removal of MAD7 and the gRNA along with the desired genome edits. Altogether, this comprehensive study underscores the versatility of MAD7 for complex, scarless genome engineering and lays a strong foundation for further advancing genetic manipulation in B. subtilis.
PMID:
40729556
Bibliographic data and abstract were imported from PubMed on 30 Jul 2025.
Read full publication at:
Please sign in
to see all details.
Advertisement
Stats
- Recommendations n/a n/a positive of 0 vote(s)
- Views 54
- Comments 0