Abstract
Streptococcus pneumoniae is a human pathogen that has become increasingly resistant to the synthetic fluoroquinolone antibiotics that target bacterial topoisomerases. To identify pathways that are essential under fluoroquinolone stress and thus might represent novel targets to revitalize the use of this class of antibiotics, we performed genome-wide CRISPRi-seq screens to determine antibiotic-gene essentiality signatures. As expected, genes involved in DNA recombination and repair become more important under fluoroquinolone-induced DNA damage, such as recA, recJ, recF, recO, rexAB and ruvAB. Surprisingly, we also found that specific downregulation of the gene encoding the histidine kinase LiaS caused fluoroquinolone hypersensitivity. LiaS is part of the LiaFSR (VraTSR) three-component regulatory system involved in cell envelope homeostasis. We show that LiaS keeps the response regulator LiaR inactive, and that deletion of liaS causes hyperphosphorylation of LiaR and subsequent upregulation of the LiaR regulon. RNA-seq was used to refine the LiaR regulon, highlighting the role of the heat-shock response and the pleiotropic regulator SpxA2 in fluoroquinolone sensitivity. Activating the LiaR-regulon by the cell envelope-targeting antibiotic bacitracin synergized with ciprofloxacin and levofloxacin. This synergistic antibiotic combination restored sensitivity in fluoroquinolone-resistant strains in vitro. Importantly, bacitracin/levofloxacin combination therapy was also effective in vivo and improved the treatment of fluoroquinolone-resistant S. pneumoniae infection in a zebrafish meningitis model. Together, the approaches and findings presented here provides a starting point for identification and validation of potent combination therapies that could be used in the clinic to treat antibiotic-resistant pneumococcal infections.
Competing Interest Statement
The authors have declared no competing interest.