TetR Regulated in vivo Repression Technology to Identify Conditional Gene Silencing in Genetically Engineerable Bacteria Using Vibrio cholerae Murine Infections as Model System.

Investigation of bacterial gene regulation upon environmental changes is still a challenging task. For example, Vibrio cholerae, a pathogen of the human gastrointestinal tract, faces diverse transient conditions in different compartments upon oral ingestion. Genetic reporter systems have been demonstrated to be extremely powerful tools to unravel gene regulation events in complex conditions, but so far focused mainly on gene induction. Herein, we describe the TetR-controlled recombination-based in vivo expression technology TRIVET, which allows detection of gene silencing events. TRIVET resembles a modified variant of the in vivo expression technology (IVET) as well as recombination-based in vivo expression technology (RIVET), which were used to identify conditional gene induction in several bacteria during host colonization. Like its predecessors, TRIVET is a single cell based reporter system, which allows the analysis of bacterial gene repression in a spatiotemporal manner via phenotypical changes in the resistance profile. Briefly, a promoterless tetR (encoding the transcriptional repressor TetR) can be integrated randomly into the bacterial genome via transposon mutagenesis or site-specific downstream of a promoter of interest via homologous recombination. Reduction of transcriptional expression of TetR results in a de-repression of the TetR-controlled resolvase TnpR, which in turn leads to excision of an antibiotic resistance cassette (also known as res-cassette) and altered resistance profile observable via streaking on ampicillin and kanamycin plates. This alteration can then be quantified as the ratio between resistant and non-resistant isolates. Furthermore, the newly introduced second reporter gene, a promoterless phoA (encoding the alkaline phosphatase PhoA) offers an additional validation step of the results via an independent colorimetric assay to measure enzyme activity. The protocol presented herein also offers an approach to identify the gene locus in case of the random screen for gene repression as well as a quantification of the conditional repression of a gene of interest. Although the current protocol is established for gene repression during host colonization, it can likely be adapted to study gene silencing under various conditions faced by a bacterium.