Global discovery of colonization determinants in the squid symbiont<i>Vibrio fischeri</i>

Brooks, John F.; Gyllborg, Mattias C.; Cronin, David; Quillin, Sarah J.; Mallama, Celeste A.; Foxall, Randi L; Whistler, Cheryl A.; Goodman, Andrew L.; Mandel, Mark J.

doi:10.1073/pnas.1415957111

Cited by 105 publications

(128 citation statements)

References 35 publications

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“…For each trial, the mean CFU competitive index value (test CFU/control CFU) was not significantly different from the hypothetical mean of 1.0 (Table 1), which is similar to previous reports of competitions between isogenic test and control strains (18,31). By examining the corresponding sets of light organ images, we counted the number of crypts colonized with the control strain, the test strain, or both strains.…”

Section: Resultssupporting

confidence: 84%

Niche-Specific Impact of a Symbiotic Function on the Persistence of Microbial Symbionts within a Natural Host

Verma

Miyashiro

2016

Appl Environ Microbiol

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How the function of microbial symbionts is affected by their population/consortium structure within a host remains poorly understood. The symbiosis established between Euprymna scolopes and Vibrio fischeri is a well-characterized host-microbe association in which the function and structure of V. fischeri populations within the host are known: V. fischeri populations produce bioluminescence from distinct crypt spaces within a dedicated host structure called the light organ. Previous studies have revealed that luminescence is required for V. fischeri populations to persist within the light organ and that deletion of the lux gene locus, which is responsible for luminescence in V. fischeri, leads to a persistence defect. In this study, we investigated the impact of bioluminescence on V. fischeri population structure within the light organ. We report that the persistence defect is specific to crypt I, which is the most developmentally mature crypt space within the nascent light organ. This result provides insight into the structure/function relationship that will be useful for future mechanistic studies of squid-Vibrio symbiosis. In addition, our report highlights the potential impact of the host developmental program on the spatiotemporal dynamics of host-microbe interactions. IMPORTANCEMetazoan development and physiology depend on microbes. The relationship between the symbiotic function of microbes and their spatial structure within the host environment remains poorly understood. Here we demonstrate, using a binary symbiosis, that the host requirement for the symbiotic function of the microbial symbiont is restricted to a specific host environment. Our results also suggest a link between microbial function and host development that may be a fundamental aspect of the more complex host-microbe interactions. Microbes are a dominant form of life on Earth, and their associations with humans and other animals directly impact host development, physiology, and evolution (1-3). In many cases, the acquisition of microbes from the environment represents a key moment in the life history of the host. Studies of mammalian gut microbiota have suggested that the spatial distribution of these microbes within the host, i.e., their biogeography, is an important factor in the assemblage and maintenance of such associations (see reference 4 for a recent review). For instance, when microbial communities isolated from diverse habitats are transplanted into gnotobiotic mice, the resulting composition closely resembles that normally found in the mouse cecum (5). Body part-specific microbiota have also been observed in nonmammalian systems, such as that of the jellyfish Aurelia aurita, which shows significant differences in microbial composition between the gastric cavity and exumbrellar mucus (6). These studies suggest that hosts select certain biogeographical landscapes for their associated microbiota. However, examining how biogeography impacts the symbiotic function of microbes remains challenging for most associations, due in ...

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Section: Resultssupporting

confidence: 84%

Niche-Specific Impact of a Symbiotic Function on the Persistence of Microbial Symbionts within a Natural Host

Verma

Miyashiro

2016

Appl Environ Microbiol

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“…Some critical mechanisms for S. alvi colonization of the bee gut, including LPS modifications, membrane integrity components, the stringent response, proteases, and DNA break repair, are also important for infection by human pathogens (41)(42)(43). Similarly, colonization of light-producing organs by the squid symbiont Vibrio fisheri depends on genes dictating biofilm formation and cellular stress responses (44). In aquatic Vibrio colonizing zebra fish intestines, genes underlying cell envelope, chemosensory and motility functions seem crucial (45).…”

Section: Discussionmentioning

confidence: 99%

Genome-wide screen identifies host colonization determinants in a bacterial gut symbiont

Powell

Leonard

Kwong

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

139

152

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Animal guts are often colonized by host-specialized bacterial species to the exclusion of other transient microorganisms, but the genetic basis of colonization ability is largely unknown. The bacterium Snodgrassella alvi is a dominant gut symbiont in honey bees, specialized in colonizing the hindgut epithelium. We developed methods for transposon-based mutagenesis in S. alvi and, using high-throughput DNA sequencing, screened genome-wide transposon insertion (Tnseq) and transcriptome (RNA-seq) libraries to characterize both the essential genome and the genes facilitating host colonization. Comparison of Tn-seq results from laboratory cultures and from monoinoculated worker bees reveal that 519 of 2,226 protein-coding genes in S. alvi are essential in culture, whereas 399 are not essential but are beneficial for gut colonization. Genes facilitating colonization fall into three broad functional categories: extracellular interactions, metabolism, and stress responses. Extracellular components with strong fitness benefits in vivo include trimeric autotransporter adhesins, O antigens, and type IV pili (T4P). Experiments with T4P mutants establish that T4P in S. alvi likely function in attachment and biofilm formation, with knockouts experiencing a competitive disadvantage in vivo. Metabolic processes promoting colonization include essential amino acid biosynthesis and iron acquisition pathways, implying nutrient scarcity within the hindgut environment. Mechanisms to deal with various stressors, such as for the repair of double-stranded DNA breaks and protein quality control, are also critical in vivo. This genome-wide study identifies numerous genetic networks underlying colonization by a gut commensal in its native host environment, including some known from more targeted studies in other hostmicrobe symbioses.type IV pilus | transposon mutagenesis | microbiota | symbiosis | Neisseriaceae

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“…For that purpose, we constructed a mariner transposition vector, termed pMarVF1, that transposes efficiently to generate single stable insertions in V. fischeri ES114 and other V. fischeri strains. We generated a library of over 40,000 unique erythromycin-resistant insertions (Tnerm) in strain ES114 (28), and this served as the donor library in the mapping.…”

Section: Resultsmentioning

confidence: 99%

TfoX-Based Genetic Mapping Identifies Vibrio fischeri Strain-Level Differences and Reveals a Common Lineage of Laboratory Strains

et al. 2015

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Bacterial strain variation exists in natural populations of bacteria and can be generated experimentally through directed or random mutation. The advent of rapid and cost-efficient whole-genome sequencing has facilitated strain-level genotyping. Even with modern tools, however, it often remains a challenge to map specific traits to individual genetic loci, especially for traits that cannot be selected under culture conditions (e.g., colonization level or pathogenicity). Using a combination of classical and modern approaches, we analyzed strain-level variation in Vibrio fischeri and identified the basis by which some strains lack the ability to utilize glycerol as a carbon source. We proceeded to reconstruct the lineage of the commonly used V. fischeri laboratory strains. Compared to the wild-type ES114 strain, we identify in ES114-L a 9.9-kb deletion with endpoints in tadB2 and glpF; restoration of the missing portion of glpF restores the wild-type phenotype. The widely used strains ESR1, JRM100, and JRM200 contain the same deletion, and ES114-L is likely a previously unrecognized intermediate strain in the construction of many ES114 derivatives. ES114-L does not exhibit a defect in competitive squid colonization but ESR1 does, demonstrating that glycerol utilization is not required for early squid colonization. Our genetic mapping approach capitalizes on the recently discovered chitin-based transformation pathway, which is conserved in the Vibrionaceae; therefore, the specific approach used is likely to be useful for mapping genetic traits in other Vibrio species.I dentifying relevant differences in bacterial strains is fundamental to determining the genetic basis of microbial phenotypes. In many cases, the number of polymorphisms between strains is so high that elucidating which locus or loci contribute to specific phenotypes cannot be achieved simply by determining the genome sequence of the isolates. This challenge is especially pronounced in identifying loci that contribute to colonization and/or pathogenicity phenotypes. The study of genomic islands has made it clear that the acquisition of large regions of DNA can profoundly influence a bacterium's ability to engage with a eukaryotic host (1, 2). Recently, it has become increasingly apparent that defined genetic changes in bacteria at individual loci, single genes, or even nucleotide changes have led to dramatic effects in the evolution of colonizing bacteria. As some examples, the acquisition of the nil locus in Xenorhabdus nematophila contributed to the species-specific association with the worm host Steinernema carpocapsae, inactivation of the RscA biofilm regulator was critical in the evolution of Yersinia pestis from Yersinia pseudotuberculosis, and acquisition of the biofilm regulation of RscS facilitated colonization of north Pacific squid by Vibrio fischeri (3-8).In most cases, identification of factors that contribute to host colonization specificity has relied first on identifying the factor as being necessary for host colonization by standard g...

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Global discovery of colonization determinants in the squid symbiontVibrio fischeri

Cited by 105 publications

References 35 publications

Niche-Specific Impact of a Symbiotic Function on the Persistence of Microbial Symbionts within a Natural Host

Niche-Specific Impact of a Symbiotic Function on the Persistence of Microbial Symbionts within a Natural Host

Genome-wide screen identifies host colonization determinants in a bacterial gut symbiont

TfoX-Based Genetic Mapping Identifies Vibrio fischeri Strain-Level Differences and Reveals a Common Lineage of Laboratory Strains

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