The Host as the Driver of the Microbiota in the Gut and External Environment of Drosophila melanogaster

Wong, Adam C. N.; Luo, Yuan; Jing, Xin; Franzenburg, Soeren; Bost, Alyssa; Douglas, Angela E.

doi:10.1128/aem.01442-15

Cited by 118 publications

(130 citation statements)

References 48 publications

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“…2); importantly, despite limitations associated with a CFU-based approach, we observed broad overlap between the dominant bacterial species that we cultured and those identified using sequence-based approaches (e.g., Providencia, Morganella, Vagococcus, Proteus, Koukoulia, and Serratia) (33). However, with full care treatment alone, it cannot be determined if larvae require constant replenishment of the parental species for these to be maintained in the larval gut, given other research showing that gut bacteria may be transient without continuous parental provisions (24,38,39). One possibility, for example, is that the dominant bacteria from the carcass may outcompete endogenous beetle bacteria within the larval gut; this may be driven actively if the bacteria on the Nicrophorus Microbiota throughout Development Applied and Environmental Microbiology carcass are particularly good colonizers or passively since larval exposure to carcass bacteria is continuous.…”

Section: Discussionmentioning

confidence: 63%

Gut Microbiota Colonization and Transmission in the Burying Beetle Nicrophorus vespilloides throughout Development

Wang

Rozen

2017

Appl Environ Microbiol

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Carrion beetles in the genus Nicrophorus rear their offspring on decomposing carcasses where larvae are exposed to a diverse community of decomposer bacteria. Parents coat the carcass with antimicrobial secretions prior to egg hatch (defined as prehatch care) and also feed regurgitated food, and potentially bacteria, to larvae throughout development (defined as full care). Here, we partition the roles of prehatch and posthatch parental care in the transmission and persistence of culturable symbiotic bacteria to larvae. Using three treatment groups (full care, prehatch care only, and no care), we found that larvae receiving full care are predominantly colonized by bacteria resident in the maternal gut while larvae receiving no care are colonized with bacteria from the carcass. More importantly, larvae receiving only prehatch care were also predominantly colonized by maternal bacteria; this result indicates that parental treatment of the carcass, including application of bacteria to the carcass surface, is sufficient to ensure symbiont transfer even in the absence of direct larval feeding. Later in development, we found striking evidence that pupae undergo an aposymbiotic stage, after which they are recolonized at eclosion with bacteria similar to those found on the molted larval cuticle and on the wall of the pupal chamber. Our results clarify the importance of prehatch parental care for symbiont transmission in Nicrophorus vespilloides and suggest that these bacteria successfully outcompete decomposer bacteria during larval and pupal gut colonization.IMPORTANCE Here, we examine the origin and persistence of the culturable gut microbiota of larvae in the burying beetle Nicrophorus vespilloides. This insect is particularly interesting for this study because larvae are reared on decomposing vertebrate carcasses, where they are exposed to high densities of carrion-decomposing microbes. Larvae also receive extensive parental care in the form of carcass preservation and direct larval feeding. We find that parents transmit their gut bacteria to larvae both directly, through regurgitation, and indirectly via their effects on the carcass. In addition, we find that larvae become aposymbiotic during pupation but are recolonized apparently from bacteria shed onto the insect cuticle before adult eclosion. Our results highlight the diverse interactions between insect behavior and development on microbiota composition. They further suggest that competitive interactions mediate the bacterial composition of Nicrophorus larvae together with or apart from the influence of beetle immunity, suggesting that the bacterial communities of these insects may be highly coevolved with those of their host species.KEYWORDS Nicrophorus, parental care, symbiosis, microbiota, transmission A nimals are colonized by a diverse community of bacterial symbionts that play crucial roles in their ecology and evolution (1-3). This has been especially well studied in insects, whose bacterial symbionts can influence traits ranging from mate

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Section: Discussionmentioning

confidence: 63%

Gut Microbiota Colonization and Transmission in the Burying Beetle Nicrophorus vespilloides throughout Development

Wang

Rozen

2017

Appl Environ Microbiol

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“…The Acetobacteraceae, which are obligately aerobic bacteria that exploit sugar‐rich habitats (Crotti et al., ), are strongly represented in most laboratory and field Drosophila (including this study). Interestingly, Lactobacillus (Lactobacillales) that dominate some laboratory cultures of Drosophila are at low abundance in wild Drosophila , which mostly contain Lactobacilli of the genera Weisella, Leoconostoc and Enterococcus (Chandler et al., ; Storelli et al., ; Wong et al., ; this study). Presumably, some Lactobacillus species, especially L. brevis and L. plantarum , have greater tolerance of the laboratory environment than the Lactobacillales associated with wild Drosophila , but the mechanisms underlying this difference remain to be established.…”

Section: Discussionmentioning

confidence: 68%

How gut transcriptional function of Drosophila melanogaster varies with the presence and composition of the gut microbiota

et al. 2017

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Despite evidence from laboratory experiments that perturbation of the gut microbiota affects many traits of the animal host, our understanding of the effect of variation in microbiota composition on animals in natural populations is very limited. The core purpose of this study on the fruit fly Drosophila melanogaster was to identify the impact of natural variation in the taxonomic composition of gut bacterial communities on host traits, with the gut transcriptome as a molecular index of microbiota-responsive host traits. Use of the gut transcriptome was validated by demonstrating significant transcriptional differences between the guts of laboratory flies colonized with bacteria and maintained under axenic conditions. Wild Drosophila from six field collections made over two years had gut bacterial communities of diverse composition, dominated to varying extents by Acetobacteraceae and Enterobacteriaceae. The gut transcriptomes also varied among collections and differed markedly from those of laboratory flies. However, no overall relationship between variation in the wild fly transcriptome and taxonomic composition of the gut microbiota was evident at all taxonomic scales of bacteria tested for both individual fly genes and functional categories in Gene Ontology. We conclude that the interaction between microbiota composition and host functional traits may be confounded by uncontrolled variation in both ecological circumstance and host traits (e.g., genotype, age physiological condition) under natural conditions, and that microbiota effects on host traits identified in the laboratory should, therefore, be extrapolated to field population with great caution.

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“…Approaches: Use population genetic methods of tracking lineages, experimentally “tag” microbes to track their dispersal and division, or examine the effect of introducing a host with microbiota into a sterile environment. Relevant examples : …”

Section: Communities Within Communitiesmentioning

confidence: 99%

“…Approaches: Evaluate how composition of both non‐host‐associated and host‐associated microbial communities changes with alterations in the environment. Relevant examples : …”

Section: Communities Within Communitiesmentioning

confidence: 99%

Rethinking “mutualism” in diverse host‐symbiont communities

Mushegian

Ebert

2015

BioEssays

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While examples of bacteria benefiting eukaryotes are increasingly documented, studies examining effects of eukaryote hosts on microbial fitness are rare. Beneficial bacteria are often called "mutualistic" even if mutual reciprocity of benefits has not been demonstrated and despite the plausibility of other explanations for these microbes' beneficial effects on host fitness. Furthermore, beneficial bacteria often occur in diverse communities, making mutualism both empirically and conceptually difficult to demonstrate. We suggest reserving the terms "mutualism" and "parasitism" for pairwise interactions where the relationship is largely independent of other species and can be verified by measuring the fitness effect experienced by both partners. In hosts with diverse microbial communities, we propose re-formulating some of the essential questions of symbiosis research - e.g. concerning specificity, transmission mode, and common evolutionary fates - as questions of community ecology and ecosystem function, allowing important biological interactions to be investigated without making assumptions about reciprocity. Understanding the fitness of host-associated bacteria is a crucial component of investigations into the role of microbes in eukaryote evolution.

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The Host as the Driver of the Microbiota in the Gut and External Environment of Drosophila melanogaster

Cited by 118 publications

References 48 publications

Gut Microbiota Colonization and Transmission in the Burying Beetle Nicrophorus vespilloides throughout Development

Gut Microbiota Colonization and Transmission in the Burying Beetle Nicrophorus vespilloides throughout Development

How gut transcriptional function of Drosophila melanogaster varies with the presence and composition of the gut microbiota

Rethinking “mutualism” in diverse host‐symbiont communities

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