Efficient transformation and genome editing in a nondomesticated, biocontrol strain, Bacillus subtilis GLB191

Efficient transformation and genome editing in a nondomesticated, biocontrol strain, Bacillus subtilis GLB191

Abstract Bacillus subtilis has been widely used as a biological control agent in agricultural production. Environmental strains of B. subtilis are an important source of biological control agents. However, due to its low genetic transformation efficiency, the genetic manipulation of the environmenta...

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Main Authors: Yu Zhao, Zhenshuo Wang, Qian Wang, Bing Wang, Xiaoning Bian, Qingchao Zeng, Daowan Lai, Qi Wang, Yan Li
Format: Article
Language:English
Published: BMC 2024-12-01
Series:Phytopathology Research
Subjects:
Bacillus subtilis
Electroporation
Response surface methodology
Genome editing
Online Access:https://doi.org/10.1186/s42483-024-00287-0
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Summary:Abstract Bacillus subtilis has been widely used as a biological control agent in agricultural production. Environmental strains of B. subtilis are an important source of biological control agents. However, due to its low genetic transformation efficiency, the genetic manipulation of the environmental and nondomesticated strains is challenging. In this study, the impact of competent cell preparation, pulse electroporation, and recovery culture on the electroporation efficiency of B. subtilis GLB191 was assessed utilizing response surface methodology. Results indicated that the concentration of glycine, DL-threonine, and Tween 80 used in a cell wall weakening solution during competent cell preparation, and the voltage applied during pulse electroporation were the primary factors affecting electroporation efficiency. Optimization of these factors led to nearly a three-fold increase (reaching 74.00 ± 5.10 CFU/µg DNA) in electroporation efficiency. The elimination of dam and dcm modifications to mitigate the influence of host restriction-modification systems was integrated to further increase the electroporation efficacy. An electroporation efficiency for replicative plasmids of 1.96 ± 0.05 × 106 CFU/µg DNA was achieved using the optimized strategy. Utilizing this improved methodology, the temperature-sensitive plasmid pJOE8899 was efficiently transformed into B. subtilis GLB191, resulting in a markerless knockout of pdeH. The optimized transformation strategy significantly enhances the efficiency of markerless genome editing of nondomesticated B. subtilis, offering the potential for future interpretation of their modes of action, which is critical for the development of the nondomesticated B. subtilis strains.
ISSN:2524-4167

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