Combining Signal Peptidase and Lipoprotein Processing Inhibitors Overcomes Ayr Resistance in Staphylococcus aureus.

Antibiotic resistance in bacterial pathogens is an ongoing public health concern. The arylomycins are a class of natural product antibiotics that target the type I signal peptidase, which carries out the terminal step in protein secretion. Here, we used transposon sequencing (Tn-Seq) to profile the effects of the optimized arylomycin derivative G0775 in Staphylococcus aureus. Our transposon libraries include both upregulation and inactivation mutants, allowing us to identify resistance mechanisms and targets for synergism. We identified several cell envelope pathways that, when inactivated, sensitize S. aureus to the arylomycin G0775. These pathways include the lipoprotein processing pathway, and we have shown that inhibitors of this pathway synergize with G0775 even though lipoprotein processing is nonessential in S. aureus. Moreover, we found that blocking this pathway completely reverses Ayr resistance, which is a major resistance mechanism to arylomycins, including G0775. Our Tn-Seq data also showed that upregulation of mprF and several other genes is protective against G0775. Because a subset of these genes was previously found in a Tn-Seq profile of the clinically important antibiotic daptomycin, we tested a set of daptomycin-nonsusceptible clinical isolates with gain-of-function mutations in mprF for susceptibility to arylomycin G0775. Despite structural and mechanistic differences between these antibiotics, we observed similar decreases in susceptibility. Taken together, our results highlight how Tn-Seq profiles that include both gene inactivation and upregulation can identify targets, antibiotic resistance mechanisms, and strategies to overcome resistance.

Multi-strain Tn-Seq reveals common daptomycin resistance determinants in Staphylococcus aureus.

Antibiotic-resistant Staphylococcus aureus remains a leading cause of antibiotic resistance-associated mortality in the United States. Given the reality of multi-drug resistant infections, it is imperative that we establish and maintain a pipeline of new compounds to replace or supplement our current antibiotics. A first step towards this goal is to prioritize targets by identifying the genes most consistently required for survival across the S. aureus phylogeny. Here we report the first direct comparison of multiple strains of S. aureus via transposon sequencing. We show that mutant fitness varies by strain in key pathways, underscoring the importance of using more than one strain to differentiate between core and strain-dependent essential genes. We treated the libraries with daptomycin to assess whether the strain-dependent differences impact pathways important for survival. Despite baseline differences in gene importance, several pathways, including the lipoteichoic acid pathway, consistently promote survival under daptomycin exposure, suggesting core vulnerabilities that can be exploited to resensitize daptomycin-nonsusceptible isolates. We also demonstrate the merit of using transposons with outward-facing promoters capable of overexpressing nearby genes for identifying clinically-relevant gain-of-function resistance mechanisms. Together, the daptomycin vulnerabilities and resistance mechanisms support a mode of action with wide-ranging effects on the cell envelope and cell division. This work adds to a growing body of literature demonstrating the nuanced insights gained by comparing Tn-Seq results across multiple bacterial strains.