4.7 Article

The construction of a PAM-less base editing toolbox in Bacillus subtilis and its application in metabolic engineering

Journal

CHEMICAL ENGINEERING JOURNAL
Volume 469, Issue -, Pages -

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2023.143865

Keywords

PAM-less; Base editor; Gene editing; SpRY; Multiplex; Bacillus subtilis

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SpRY overcomes the PAM recognition barrier in Bacillus subtilis and enables the development of a highly efficient PAM-less base editing toolbox. This toolbox allows for multiplexed gene editing and has been successfully applied in gene knockout and translation control. It shows great potential in metabolic engineering and codon expansion.
The necessity of a specific protospacer adjacent motif (PAM) greatly limited the editing scope and the application range of Cas9-dependent base editors. Here, we showed that SpRY breaks the PAM recognition barrier in Bacillus subtilis with a preference toward NRN than NYN while the PAM specificity is slightly distinct from other or-ganisms. We developed a highly efficient PAM-less base editing toolbox for B. subtilis based on a variant of Cas9 nickase, nSpRY, yielding PAM-less adenine and/or cytosine base editors (PLABE/PLCBE/PLACBE) for A-to-G and/or C-to-T conversions. The conversion efficiency was optimized to 100% at high-activity sites and the editing window was refined to 1-2 nucleotides at pre-selected sites. Multiplexed editing for double, triple, and quadruple genes was validated simply by one cycle of editing. As a proof of concept, PLCBE was utilized to introduce premature stop codons for yielding gene knockouts and PLABE was applied to change start codons from ATG to GTG for realizing translation control. A website was designed to accelerate the inactivation of any genes of interest in B. subtilis by incorporating PAM specificity information for identifying the high-efficiency sites. Facilitated by multiplexed PAM-less editing, we successfully obtained a diversified library of strain vari-ants for chemical production with multi-level regulations in central and competing metabolism pathways. We recruited this library to modulate metabolic fluxes in B. subtilis, achieving up to a 26.3% increase in acetoin production with a final titer of 20.8 g/L in shake-flask fermentation. By enabling in situ base editing of nearly all As and Cs in the Bacillus genome, this toolbox shows great potential in applications of metabolic engineering and codon expansion.

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