DESCIRIBE REQUIREMENT, PROCEDURE AND RESULT DISCUSSION: Isolation of Antibiotic Resistant Mutants.
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Isolation of bacterial mutants hypersusceptible to antibiotics can reveal novel targets for antibiotic potentiators. However, identification of such mutants is a difficult task which normally requires laborious replica plating of thousands of colonies. The technique proposed here allows for the positive selection of genetic knockout mutants leading to hypersusceptibility. This technique, designated SDR (selection for DNA release), involves introduction of random insertions of a marker gene into the chromosome of a highly transformable bacterial species, followed by treatment of the obtained library with an antibiotic at subinhibitory concentrations. DNA released by lysing bacteria is collected and used to transform fresh bacteria, selecting for insertion of the marker gene. These selection cycles are repeated until variants with a hypersusceptibility phenotype caused by insertion of the marker begin to dominate in the library. This approach allowed for isolation of a number of mutants of the gram-negative opportunistic pathogen Acinetobacter sp. susceptible to 4- to 16-times-lower concentrations of ampicillin than wild-type bacteria. The mutations affected proteins involved in peptidoglycan turnover and, surprisingly, proteins involved in exopolysaccharide production. A further modification of the SDR technique is described which allows for selecting mutants hypersensitive to agents that affect bacterial physiology but do not cause cell lysis, e.g., inhibitors of translation. This application of SDR is illustrated here by identification of several mutants of Acinetobacter sp. with increased susceptibility (two- to fivefold decrease in the MIC) to erythromycin. The same technique can be used to identify prospective targets for potentiators of many other antibacterial agents.
Gene knockout mutations leading to hypersusceptibility to antibiotics can help identify novel targets of antibiotic potentiators. Indeed, if bacteria become hypersensitive to a particular antibiotic upon disruption of a certain gene, an inhibitor of the protein product of this gene is likely to have the same effect and promote antibiotic action. Apart from genetic knockouts of known antibiotic resistance genes, only a limited number of hypersusceptibility mutations have been described to date, mostly due to the laboriousness of their isolation.