The transcription factor IscR promotes Yersinia type III secretion system activity by antagonizing the repressive H-NS-YmoA histone-like protein complex

Abstract

AbstractThe type III secretion system (T3SS) is a appendage used by many bacterial pathogens, such as pathogenic Yersinia, to subvert host defenses. However, because the T3SS is energetically costly and immunogenic, it must be tightly regulated in response to environmental cues to enable survival in the host. Here we show that expression of the Yersinia Ysc T3SS master regulator, LcrF, is orchestrated by the opposing activities of the repressive YmoA/H-NS histone-like protein complex and induction by the iron and oxygen-regulated IscR transcription factor. Although IscR has been shown to bind the lcrF promoter and is required for in vivo expression of lcrF, in this study we show IscR alone fails to enhance lcrF transcription in vitro. Rather, we find that in a ymoA mutant, IscR is no longer required for LcrF expression or T3SS activity. Additionally, a mutation in YmoA that prevents H-NS binding (ymoAD43N) rescues the T3SS defect of a ΔiscR mutant, suggesting that a YmoA/H-NS complex is needed for this repressive activity. Furthermore, chromatin immunoprecipitation analysis revealed that H-NS is enriched at the lcrF promoter at environmental temperatures, while IscR is enriched at this promoter at mammalian body temperature under aerobic conditions. Importantly, CRISPRi knockdown of H-NS leads to increased lcrF transcription. Collectively, our data suggest that as IscR levels rise with iron limitation and oxidative stress, conditions Yersinia experiences during extraintestinal infection, IscR antagonizes YmoA/H-NS-mediated repression of lcrF transcription to drive T3SS activity and manipulate host defense mechanisms.Author SummaryFacultative pathogens must silence virulence gene expression during growth in the environment, while retaining the ability to upregulate these genes upon infection of a host. H-NS is an architectural DNA binding protein proposed to silence horizontally acquired genes, regulating virulence genes in a number of pathogens. Indeed, H-NS was predicted to regulate plasmid-encoded virulence genes in pathogenic Yersinia. However, Yersinia H-NS is reported to be essential, complicating testing of this model. We used chromatin immunoprecipitation and inducible CRISPRi knockdown to show that H-NS binds to the promoter of a critical plasmid-encoded virulence gene, silencing its expression. Importantly, under conditions that mimic Yersinia infection of a mammalian host, the transcriptional regulator IscR displaces H-NS to drive virulence factor expression.