A Small RNA Derived From the 5' End of the IS200 tnpA Transcript Regulates Multiple Virulence Regulons in Salmonella typhimurium.

Abstract

The insertion sequence IS200 is widely distributed in Eubacteria. Despite its prevalence, IS200 does not appear to be mobile and as such is considered an ancestral component of bacterial genomes. Previous work in Salmonella enterica revealed that the IS200 tnpA transcript is processed to form a small, highly structured RNA (5'tnpA) that participates in the posttranscriptional control of invF expression, encoding a key transcription factor in this enteropathogen's invasion regulon. To further examine the scope of 5'tnpA transcript integration into Salmonella gene expression networks, we performed comparative RNA-seq, revealing the differential expression of over 200 genes in a Salmonella SL1344 5'tnpA disruption strain. This includes the genes for the master regulators of both invasion and flagellar regulons (HilD and FlhDC, respectively), plus genes involved in cysteine biosynthesis and an operon (phsABC) encoding a thiosulfate reductase complex. These expression changes were accompanied by an 80-fold increase in Salmonella invasion of HeLa cells. Follow-up experimentation suggested an additional direct target of 5'tnpA to be the small RNA PinT, which has previously been shown to be a negative regulator of invasion genes through its inhibitory action on key transcription factors governing the Salmonella pathogenicity island 1 regulon. This study provides a powerful new example of bacterial transposon domestication that is based not on the production/use of a regulatory protein or regulatory DNA sequences, but on the function of a transposon-derived small RNA.