par Oms, Thierry 
;Schlechtweg, Tatjana ;Cayron, Julien ;Van Melderen, Laurence
Référence Journal of Visualized Experiments, 193
Publication Publié, 2023-03
;Schlechtweg, Tatjana ;Cayron, Julien ;Van Melderen, Laurence Référence Journal of Visualized Experiments, 193
Publication Publié, 2023-03
Article révisé par les pairs
| Résumé : | Antibiotic persistence refers to the capacity of small bacterial subpopulations to transiently tolerate high doses of bactericidal antibiotics. Upon bactericidal antibiotic treatment, the bulk of the bacterial population is rapidly killed. This first rapid phase of killing is followed by a substantial decrease in the rate of killing as the persister cells remain viable. Classically, persistence is determined at the population level by time/kill assays performed with high doses of antibiotics and for defined exposure times. While this method provides information about the level of persister cells and the killing kinetics, it fails to reflect the intrinsic cell-to-cell heterogeneity underlying the persistence phenomenon. The protocol described here combines classical time/kill assays with single-cell analysis using real-time fluorescence microscopy. By using appropriate fluorescent reporters, the microscopy imaging of live cells can provide information regarding the effects of the antibiotic on cellular processes, such as chromosome replication and segregation, cell elongation, and cell division. Combining population and single-cell analysis allows for the molecular and cellular characterization of the persistence phenotype. |
