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Quorum sensing (QS) is a chemical communication process that bacteria use to track population density and orchestrate collective behaviors. QS relies on the production, accumulation, and group-wide detection of extracellular signal molecules called autoinducers. Vibriophage 882 (phage VP882), a bacterial virus, encodes a homolog of theVibrioQS receptor-transcription factor, called VqmA, that monitors theVibrioQS autoinducer DPO. Phage VqmA binds DPO at high host-cell density and activates transcription of the phage geneqtip. Qtip, an antirepressor, launches the phage lysis program. Phage-encoded VqmA when bound to DPO also manipulates host QS by activating transcription of the host genevqmR. VqmR is a small RNA that controls downstream QS target genes. Here, we sequenceVibrio parahaemolyticusstrain O3:K6 882, the strain from which phage VP882 was initially isolated. The chromosomal region normally encodingvqmRandvqmAharbors a deletion encompassingvqmRand a portion of thevqmApromoter, inactivating that QS system. We discover thatV.parahaemolyticusstrain O3:K6 882 is also defective in its other QS systems, due to a mutation inluxO, encoding the central QS transcriptional regulator LuxO. Both thevqmR-vqmAandluxOmutations lockV.parahaemolyticusstrain O3:K6 882 into the low-cell density QS state. Reparation of the QS defects inV.parahaemolyticusstrain O3:K6 882 promotes activation of phage VP882 lytic gene expression and LuxO is primarily responsible for this effect. Phage VP882-infected QS-competentV.parahaemolyticusstrain O3:K6 882 cells lyse more rapidly and produce more viral particles than the QS-deficient parent strain. We propose that, inV.parahaemolyticusstrain O3:K6 882, constitutive maintenance of the low-cell density QS state suppresses the launch of the phage VP882 lytic cascade, thereby protecting the bacterial host from phage-mediated lysis.

 

Most bacteria in the biosphere are predicted to be polylysogens harbouring multiple prophages^1–5. In studied systems, prophage induction from lysogeny to lysis is near-universally driven by DNA-damaging agents⁶. Thus, how co-residing prophages compete for cell resources if they respond to an identical trigger is unknown. Here we discover regulatory modules that control prophage induction independently of the DNA-damage cue. The modules bear little resemblance at the sequence level but share a regulatory logic by having a transcription factor that activates the expression of a neighbouring gene that encodes a small protein. The small protein inactivates the master repressor of lysis, which leads to induction. Polylysogens that harbour two prophages exposed to DNA damage release mixed populations of phages. Single-cell analyses reveal that this blend is a consequence of discrete subsets of cells producing one, the other or both phages. By contrast, induction through the DNA-damage-independent module results in cells producing only the phage sensitive to that specific cue. Thus, in the polylysogens tested, the stimulus used to induce lysis determines phage productivity. Considering the lack of potent DNA-damaging agents in natural habitats, additional phage-encoded sensory pathways to lysis likely have fundamental roles in phage–host biology and inter-prophage competition.

 

Viruses that infect bacteria, called phages, shape the composition of bacterial communities and are important drivers of bacterial evolution. We recently showed that temperate phages, when residing in bacteria (i.e., prophages), are capable of manipulating the bacterial cell-to-cell communication process called quorum sensing (QS). QS relies on the production, release, and population-wide detection of signaling molecules called autoinducers (AI). Gram-negative bacteria commonly employ N -acyl homoserine lactones (HSL) as AIs that are detected by LuxR-type QS receptors. Phage ARM81ld is a prophage of the aquatic bacterium Aeromonas sp. ARM81, and it encodes a homolog of a bacterial LuxR, called LuxR ARM81ld . LuxR ARM81ld detects host Aeromonas -produced C4-HSL, and in response, activates the phage lytic program, triggering death of its host and release of viral particles. Here, we show that phage LuxR ARM81ld activity is modulated by noncognate HSL ligands and by a synthetic small molecule inhibitor. We determine that HSLs with acyl chain lengths equal to or longer than C8 antagonize LuxR ARM81ld . For example, the C8-HSL AI produced by Vibrio fischeri that coexists with Aeromonads in aquatic environments, binds to and inhibits LuxR ARM81ld , and consequently, protects the host from lysis. Coculture of V. fischeri with the Aeromonas sp. ARM81 lysogen suppresses phage ARM81ld virion production. We propose that the cell density and species composition of the bacterial community could determine outcomes in bacterial-phage partnerships. 

Quorum sensing is a chemical communication process that bacteria use to coordinate group behaviors. In the global pathogen Vibrio cholerae , one quorum-sensing receptor and transcription factor, called VqmA (VqmA Vc ), activates expression of the vqmR gene encoding the small regulatory RNA VqmR, which represses genes involved in virulence and biofilm formation. Vibriophage VP882 encodes a VqmA homolog called VqmA Phage that activates transcription of the phage gene qtip , and Qtip launches the phage lytic program. Curiously, VqmA Phage can activate vqmR expression but VqmA Vc cannot activate expression of qtip . Here, we investigate the mechanism underlying this asymmetry. We find that promoter selectivity is driven by each VqmA DNA-binding domain and key DNA sequences in the vqmR and qtip promoters are required to maintain specificity. A protein sequence-guided mutagenesis approach revealed that the residue E194 of VqmA Phage and A192, the equivalent residue in VqmA Vc , in the helix-turn-helix motifs contribute to promoter-binding specificity. A genetic screen to identify VqmA Phage mutants that are incapable of binding the qtip promoter but maintain binding to the vqmR promoter delivered additional VqmA Phage residues located immediately C-terminal to the helix-turn-helix motif as required for binding the qtip promoter. Surprisingly, these residues are conserved between VqmA Phage and VqmA Vc . A second, targeted genetic screen revealed a region located in the VqmA Vc DNA-binding domain that is necessary to prevent VqmA Vc from binding the qtip promoter, thus restricting DNA binding to the vqmR promoter. We propose that the VqmA Vc helix-turn-helix motif and the C-terminal flanking residues function together to prohibit VqmA Vc from binding the qtip promoter. 

Quorum sensing is a bacterial communication process whereby bacteria produce, release, and detect extracellular signaling molecules called autoinducers to coordinate collective behaviors. In the pathogen Vibrio cholerae, the quorum-sensing autoinducer 3,5-dimethyl-pyrazin-2-ol (DPO) binds the receptor and transcription factor VqmA. The DPO-VqmA complex activates transcription of vqmR, encoding the VqmR small RNA, which represses genes required for biofilm formation and virulence factor production. Here, we show that VqmA is soluble and properly folded, and activates basal-level transcription of its target vqmR in the absence of DPO. VqmA transcriptional activity is increased in response to increasing concentrations of DPO, allowing VqmA to drive the V. cholerae quorum-sensing transition at high cell densities. We solved the DPO-VqmA crystal structure to 2.0 Å resolution and compared it to existing structures to understand the conformational changes VqmA undergoes upon DNA binding. Analysis of DPO analogs showed that a hydroxyl or carbonyl group at the 2’ position is critical for binding to VqmA. The proposed DPO precursor, a linear molecule, N-alanyl-aminoacetone or Ala-AA, also bound and activated VqmA. Results from site-directed mutagenesis and competitive ligand-binding analyses revealed that DPO and Ala-AA occupy the same binding site. In summary, our structure–function analysis identifies key features required for VqmA activation and DNA binding and establishes that, while VqmA binds two different ligands, VqmA does not require a bound ligand for folding or basal transcriptional activity. However, bound ligand is required for maximal activity.