Mol Microbiol. 2025 Sep 13. doi: 10.1111/mmi.70022. Online ahead of print.
ABSTRACT
Streptococcus agalactiae (group B Streptococcus; GBS) is a leading cause of neonatal sepsis and meningitis. Despite advances in molecular microbiology, GBS genome engineering remains laborious due to inefficient mutagenesis protocols. Here, we report a versatile and rapid Cas12a-based toolkit for GBS genetic manipulation. We developed two shuttle plasmids-pGBSedit for genome editing and pGBScrispri for inducible CRISPR interference-derived from an Enterococcus faecium system and optimized for GBS. Using these tools, we achieved targeted gene insertions, markerless deletions, and efficient, template-free mutagenesis via alternative end-joining repair. Furthermore, a catalytically inactive dCas12a variant enabled inducible gene silencing, with strand-specific targeting effects. The system demonstrated broad applicability across multiple GBS strains and minimal off-target activity, as confirmed by whole-genome sequencing. In benchmarking, template-less Cas12a mutagenesis yielded sequence-confirmed mutants in ~7 days and homology-directed edits in ~7-14 days; aTC-resistant colonies arose at ~10-4 of uninduced CFU, and 27%-65% of resistant clones carried the intended homology-directed edit depending on locus and homology arm length (e.g., ~27% markerless deletion; ~35% insertion; 65% with 1 kb arms). These workflows provide a rapid alternative to temperature-sensitive plasmid mutagenesis protocols that typically require ≥ 4 weeks. This Cas12a-based platform offers an efficient, flexible, and scalable approach to genetic studies in GBS, facilitating functional genomics and accelerating pathogenesis research.
PMID:40944362 | DOI:10.1111/mmi.70022
