Profiling cell envelope-antibiotic interactions reveals vulnerabilities to β-lactams in a multidrug-resistant bacterium

Abstract

AbstractThe cell envelope of the Gram-negativeBurkholderia cepaciacomplex (Bcc) presents unique restrictions to antibiotic penetration. As a consequence, Bcc species are notorious for causing recalcitrant multidrug-resistant infections in immunocompromised individuals, such as those living with cystic fibrosis. To systematically identify cell envelope-associated resistance and susceptibility determinants at the genome level, we constructed a high-density, randomly-barcoded transposon mutant library in the clinical isolateB. cenocepaciaK56-2 and exposed it to a panel of more than twenty cell envelope-targeting antibiotics. By quantifying relative mutant fitness with BarSeq, followed by validation with CRISPR-interference, we profiled over a hundred new functional associations and identified novel mediators of antibiotic susceptibility in the Bcc cell envelope. We revealed new connections between β-lactam susceptibility, peptidoglycan synthesis, and blockages in undecaprenyl phosphate metabolism, which highlight a vulnerability in sharing this lipid intermediate. We then show that the clinically relevant synergy of the β-lactam/β-lactamase inhibitor combination ceftazidime/avibactam is primarily mediated by inhibition of the PenB carbapenemase. Importantly, we found that avibactam more strongly potentiates the activity of aztreonam and meropenem than ceftazidime in a panel of Bcc clinical isolates. Finally, we characterize for first time in the Bcc the iron and receptor-dependent activity of the novel siderophore-cephalosporin antibiotic, cefiderocol. Overall, our work has implications for antibiotic target prioritization, and for using additional combinations of β-lactam/β-lactamase inhibitors that can extend the utility of our current clinical arsenal of antibacterial therapies.Author SummaryWhile the Gram-negative cell envelope is a major barrier to antibiotic action, we have an incomplete picture of how each component contributes to antibiotic resistance. To answer this question from a genome-wide perspective in a model of antibiotic-resistant bacteria, we constructed a library of randomly-barcoded transposon mutants inBurkholderia cenocepaciaand exposed it to a panel of diverse cell envelope-targeting antibiotics. We identified individual genes and whole pathways associated with antibiotic resistance, including several novel players. Focusing on clinically relevant antibiotics, our strategy dissected how the synergy of the important β-lactam/β-lactamase inhibitor combination ceftazidime/avibactam primarily depends upon inhibition of a single β-lactamase. Additionally, we are the first to characterise the molecular basis of the antibiotic mechanism of cefiderocol inBurkholderia, a new and very potent siderophore-cephalosporin conjugate drug. Encouragingly, we found that cefiderocol susceptibility was greatest at physiological iron concentrations. Overall, we highlight several avenues that can be taken to enhance or develop new therapeutic strategies againstBurkholderiainfection.