Vibrio cholerae Outer Membrane Vesicles Inhibit Bacteriophage Infection

Reyes‐Robles, Tamara; Dillard, Rebecca S.; Cairns, Lynne S.; Silva-Valenzuela, Cecilia A.; Housman, Max; Ali, Afsar; Wright, Elizabeth; Camilli, Andrew

doi:10.1128/jb.00792-17

Cited by 140 publications

(114 citation statements)

References 39 publications

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“…This long-range stress response complements the short-range kin lysis stress system previously reported in P. aeruginosa (54). PQS activates heightened stress responses in P. aeruginosa, including the formation of outer membrane vesicles, which interfere with cytokine production and deliver toxins to target host cells (55)(56)(57). Through activation of the PqsR receptor, PQS also induces pqsE expression, which synthesizes a QS molecule that activates RhlR and is thereby responsible for regulation of key virulence factors that kill plants and animals, including hydrogen cyanide and elastase (41,58,59).…”

Section: Discussionsupporting

confidence: 68%

“…In natural environments, the stress response could mitigate the spread of phage infection throughout a population and thereby serve as a bacterial defense mechanism against phage to complement other defenses, including the CRISPR-Cas system (60). In particular, membrane vesicles function as phage decoys, and their production is upregulated in response to PQS in P. aeruginosa (56,57,61). Thus, the production of PQS and membrane vesicles in response to phage infection could function as a mechanism to increase transient immunity to phage.…”

Section: Discussionmentioning

confidence: 99%

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PQS Produced by the Pseudomonas aeruginosa Stress Response Repels Swarms Away from Bacteriophage and Antibiotics

et al. 2019

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We investigate the effect of bacteriophage infection and antibiotic treatment on the coordination of swarming, a collective form of flagellum-and pilus-mediated motility in bacteria. We show that phage infection of the opportunistic bacterial pathogen Pseudomonas aeruginosa abolishes swarming motility in the infected subpopulation and induces the release of the Pseudomonas quinolone signaling molecule PQS, which repulses uninfected subpopulations from approaching the infected area. These mechanisms have the overall effect of limiting the infection to a subpopulation, which promotes the survival of the overall population. Antibiotic treatment of P. aeruginosa elicits the same response, abolishing swarming motility and repulsing approaching swarms away from the antibiotic-treated area through a PQS-dependent mechanism. Swarms are entirely repelled from the zone of antibiotic-treated P. aeruginosa, consistent with a form of antibiotic evasion, and are not repelled by antibiotics alone. PQS has multiple functions, including serving as a quorum-sensing molecule, activating an oxidative stress response, and regulating the release of virulence and host-modifying factors. We show that PQS serves additionally as a stress warning signal that causes the greater population to physically avoid cell stress. The stress response at the collective level observed here in P. aeruginosa is consistent with a mechanism that promotes the survival of bacterial populations. IMPORTANCE We uncover a phage-and antibiotic-induced stress response in the clinically important opportunistic pathogen Pseudomonas aeruginosa. Phage-infected P. aeruginosa subpopulations are isolated from uninfected subpopulations by the production of a stress-induced signal. Activation of the stress response by antibiotics causes P. aeruginosa to physically be repelled from the area containing antibiotics altogether, consistent with a mechanism of antibiotic evasion. The stress response observed here could increase P. aeruginosa resilience against antibiotic treatment and phage therapy in health care settings, as well as provide a simple evolutionary strategy to avoid areas containing stress.

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Section: Discussionsupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

PQS Produced by the Pseudomonas aeruginosa Stress Response Repels Swarms Away from Bacteriophage and Antibiotics

et al. 2019

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“…We show that ICP3 is able to attach to V. cholerae but is incapable of replicating in fresh or estuary water, and the majority becomes inactive after a short period of time. ICP3 when bound to outer membrane vesicles cannot inject its DNA and 90% of bound ICP3 shows a full capsid (30). T7 DNA ejection needs active transport into the bacterial host that is mediated by the host RNA polymerase (31).…”

Section: Discussionmentioning

confidence: 99%

“…V. cholerae HC1037, a O1 El Tor clinical isolate (30) was grown in LB Miller broth or LB Miller agar plates at 37°C. Fresh water was collected from Massapoag Lake in MA, USA.…”

Section: Methodsmentioning

confidence: 99%

Niche adaptation limits bacteriophage predation of Vibrio cholerae in a nutrient-poor aquatic environment

Camilli

Silva-Valenzuela

2018

Preprint

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20Vibrio cholerae, the causative agent of cholera, has reservoirs in fresh and brackish 21 water where it interacts with virulent bacteriophages. Phages are the most abundant 22 certain niches or stages of the host bacterial life cycle. Unveiling the phage/bacterial 44 interactions in their natural setting is important to the understanding of cholera outbreaks 45 and could be ultimately used to help develop a method for outbreak prediction and/or 46 control. 47 48 \body 49

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“…In the bacterial domain, they have multifaceted roles including the delivery of autolysins, cytotoxins and virulence factors, as well as nucleic acids (34, 35). In our membrane vesicle sample, DNA sequencing leads us to formulate several suppositions: i) since half of vesicle reads map to contigs classified as potential phages, it may be that Epoisses membrane vesicles serve as decoys and trap phages, as recently reported in Vibrio cholerae (36). The interaction between phage tail fibers and membrane vesicles harboring proper phage receptors could contribute to the emptying, and thereby inactivating of phage virions, after DNA injection.…”

Section: Discussionmentioning

confidence: 89%

Viral metagenomic analysis of the cheese surface: a comparative study of rapid procedures for extracting virus-like particles

Dugat-Bony

Lossouarn

Paepe

et al. 2018

Preprint

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12Running Head: Viral extraction procedure for cheese virome analysis 13 14 #Address correspondence to Eric Dugat-Bony, eric.dugat-bony@inra.fr 15 16 KEYWORDS 17 Cheese rind, viral metagenomic, VLPs extraction procedure 18 2 ABSTRACT 19The structure and functioning of microbial communities from fermented foods, including 20 cheese, have been extensively studied during the past decade. However, there is still a lack of 21 information about both the occurrence and the role of viruses in modulating the function of 22 this type of spatially structured and solid ecosystems. Viral metagenomics was recently 23 applied to a wide variety of environmental samples and standardized procedures for 24 recovering virus-like particles from different type of materials has emerged. In this study, we 25 adapted a procedure originally developed to extract viruses from fecal samples, in order to 26 enable efficient virome analysis of cheese surface. We tested and validated the positive 27 impact of both addition of a filtration step prior to virus concentration and substitution of 28 purification by density gradient ultracentrifugation by a simple chloroform treatment to 29 eliminate membrane vesicles. Viral DNA extracted from the several procedures, as well as a 30 vesicle sample, were sequenced using Illumina paired-end MiSeq technology and the 31 subsequent clusters assembled from the virome were analyzed to assess those belonging to 32 putative phages, plasmid-derived DNA, or even from bacterial chromosomal DNA. The best 33 procedure was then chosen, and used to describe the Epoisses cheese virome. This study 34 provides the basis of future investigations regarding the ecological importance of viruses in 35 cheese microbial ecosystems.36 37 IMPORTANCE 38Whether bacterial viruses (phages) are necessary or not to maintain food ecosystem function 39 is not clear. They could play a negative role by killing cornerstone species that are necessary 40 for fermentation. But they might also be positive players, by preventing the overgrowth of 41 unwanted species (e.g. food spoilers). To assess phages contribution to food ecosystem 42 functioning, it is essential to set up efficient procedures for extracting viral particles in solid 43 3 food matrix, then selectively sequence their DNA without being contaminated by bacterial 44 DNA, and finally to find strategies to assemble their genome out of metagenomic sequences.45 This study, using cheese rind surface as a model, describes a comparative analysis of 46 procedures for selectively extracting viral DNA from cheese and to efficiently characterize 47 49The cheese surface hosts dense and diverse microbial communities composed of bacteria, 50 yeasts and filamentous fungi. Composition of these communities has been studied for decades 51 (see (1) and (2) for reviews). With the help of high throughput sequencing techniques, we 52 now have detailed pictures of the communities present in a large panel of cheese varieties, and 53 from all over the world (3-6). However, like many other microbia...

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Vibrio cholerae Outer Membrane Vesicles Inhibit Bacteriophage Infection

Cited by 140 publications

References 39 publications

PQS Produced by the Pseudomonas aeruginosa Stress Response Repels Swarms Away from Bacteriophage and Antibiotics

PQS Produced by the Pseudomonas aeruginosa Stress Response Repels Swarms Away from Bacteriophage and Antibiotics

Niche adaptation limits bacteriophage predation of Vibrio cholerae in a nutrient-poor aquatic environment

Viral metagenomic analysis of the cheese surface: a comparative study of rapid procedures for extracting virus-like particles

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