TY - JOUR T1 - Nasty Prophages and the Dynamics of Antibiotic-Tolerant Persister Cells JF - bioRxiv DO - 10.1101/200477 SP - 200477 AU - Alexander Harms AU - Cinzia Fino AU - Michael A. Sørensen AU - Szabolcs Semsey AU - Kenn Gerdes Y1 - 2017/01/01 UR - http://biorxiv.org/content/early/2017/10/09/200477.1.abstract N2 - Bacterial persisters are phenotypic variants that survive antibiotic treatment in a dormant state and can be formed by multiple pathways. We recently proposed that the second messenger (p)ppGpp drives Escherichia coli persister formation through protease Lon and the activation of toxin-antitoxin (TA) modules. This model found support in the field, but also generated controversy as part of recent heated debates on the validity of significant parts of the literature. In this study, we therefore used our previous work as a model to critically examine common experimental procedures in order to understand and overcome the inconsistencies often observed between results of different laboratories. Our results show that seemingly simple antibiotic killing assays are very sensitive to variation of culture conditions and bacterial growth phase. Additionally, we found that some assay conditions cause the killing of antibiotic-tolerant persisters via induction of cryptic prophages. Similarly, the inadvertent infection of mutant strains with bacteriophage φ80, a notorious laboratory contaminant, has apparently caused several phenotypes that we reported in our previous studies. We therefore reconstructed all infected mutants and probed the validity of our model of persister formation in a refined assay setup that uses robust culture conditions and unravels the dynamics of persister cells through all bacterial growth stages. Our results confirm the importance of (p)ppGpp and Lon, but do not anymore support a role of TA modules in E. coli persister formation. We anticipate that the results and approaches reported in our study will lay the ground for future work in the field.Importance The recalcitrance of antibiotic-tolerant persister cells is thought to cause relapsing infections and antibiotic treatment failure in various clinical setups. Previous studies have identified multiple genetic pathways involved in persister formation, but also revealed reproducibility problems that sparked controversies about adequate tools to study persister cells. In this study we unraveled how typical antibiotic killing assays often fail to capture the biology of persisters and instead give widely different results based on ill-controlled experimental parameters and artifacts caused by cryptic as well as contaminant prophages. We therefore established a new, robust assay that enabled us to follow the dynamics of persister cells through all growth stages of bacterial cultures without distortions by bacteriophages. This system also favored adequate comparisons of mutant strains with aberrant growth phenotypes. We anticipate that our results will contribute to a robust, common basis of future studies on the formation and eradication of antibiotic-tolerant persisters. ER -