Two enhancer binding proteins activate σ54-dependent transcription of a quorum regulatory RNA in a bacterial symbiont

To colonize a host, bacteria depend on an ensemble of signaling systems to convert information about the various environments encountered within the host into specific cellular activities. How these signaling systems coordinate transitions between cellular states in vivo remains poorly understood. T...

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Bibliographic Details
Published in:eLife 2023-05, Vol.12
Main Authors: Surrett, Ericka D, Guckes, Kirsten R, Cousins, Shyan, Ruskoski, Terry B, Cecere, Andrew G, Ludvik, Denise A, Okafor, C Denise, Mandel, Mark J, Miyashiro, Tim I
Format: Article
Language:English
Subjects:
Bacteria
Bioluminescence
Colonization
Euprymna scolopes
gene regulation
Kinases
Light
Microbiology and Infectious Disease
Phosphorylation
RNA polymerase
Sigma factor
Signal transduction
symbiosis
Transcription activation
Transcription factors
Vibrio fischeri
Vibrionaceae
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Summary:To colonize a host, bacteria depend on an ensemble of signaling systems to convert information about the various environments encountered within the host into specific cellular activities. How these signaling systems coordinate transitions between cellular states in vivo remains poorly understood. To address this knowledge gap, we investigated how the bacterial symbiont Vibrio fischeri initially colonizes the light organ of the Hawaiian bobtail squid Euprymna scolopes . Previous work has shown that the small RNA Qrr1, which is a regulatory component of the quorum-sensing system in V. fischeri , promotes host colonization. Here, we report that transcriptional activation of Qrr1 is inhibited by the sensor kinase BinK, which suppresses cellular aggregation by V. fischeri prior to light organ entry. We show that Qrr1 expression depends on the alternative sigma factor σ 54 and the transcription factors LuxO and SypG, which function similar to an OR logic gate, thereby ensuring Qrr1 is expressed during colonization. Finally, we provide evidence that this regulatory mechanism is widespread throughout the Vibrionaceae family. Together, our work reveals how coordination between the signaling pathways underlying aggregation and quorum-sensing promotes host colonization, which provides insight into how integration among signaling systems facilitates complex processes in bacteria.
ISSN:2050-084X
2050-084X
DOI:10.7554/eLife.78544