Bacterial community composition and diversity in an ancestral ant fungus symbiosis

Kellner, Katrin; Ishak, Heather D.; Linksvayer, Timothy A.; Mueller, Ulrich G.

doi:10.1093/femsec/fiv073

Cited by 54 publications

(83 citation statements)

References 80 publications

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“…[11,39]) and microbiome convergence has also been noted in some, but not all, leaf-cutter ant symbioses (e.g. [40,41]). Pratte et al [31] recently demonstrated changes in microbiome composition between anemone-hosting and non-hosting A. clarkii clownfish in a laboratory setting, implying either direct microbial transfer from anemone to clownfish or a shift in microbial diversity in response to the interaction.…”

Section: Resultsmentioning

confidence: 96%

Host identity and symbiotic association affects the taxonomic and functional diversity of the clownfish-hosting sea anemone microbiome

et al. 2020

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All eukaryotic life engages in symbioses with a diverse community of bacteria that are essential for performing basic life functions. In many cases, eukaryotic organisms form additional symbioses with other macroscopic eukaryotes. The tightly linked physical interactions that characterize many macroscopic symbioses create opportunities for microbial transfer, which likely affects the diversity and function of individual microbiomes, and may ultimately lead to microbiome convergence between distantly related taxa. Here, we sequence the microbiomes of five species of clownfish-hosting sea anemones that co-occur on coral reefs in the Maldives. We test the importance of evolutionary history, clownfish symbiont association, and habitat on the taxonomic and predicted functional diversity of the microbiome, and explore signals of microbiome convergence in anemone taxa that have evolved symbioses with clownfishes independently. Our data indicate that host identity and clownfish association shapes the majority of the taxonomic diversity of the clownfish-hosting sea anemone microbiome, and predicted functional microbial diversity analyses demonstrate a convergence among host anemone microbiomes, which reflect increased functional diversity over individuals that do not host clownfishes. Further, we identify upregulated predicted microbial functions that are likely affected by clownfish presence. Taken together our study potentially reveals an even deeper metabolic coupling between clownfishes and their host anemones, and what could be a previously unknown mutualistic benefit to anemones that are symbiotic with clownfishes.

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Section: Resultsmentioning

confidence: 96%

Host identity and symbiotic association affects the taxonomic and functional diversity of the clownfish-hosting sea anemone microbiome

et al. 2020

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“…Members of γ-Proteobacteria were found in the attine ant abdomens but only in traces and then primarily in the rectum (Figure 2). This finding is of interest because representatives of γ-Proteobacteria have repeatedly been reported as being abundant in the fungus gardens of attine ants (Aylward et al, 2014(Aylward et al, , 2012Kellner, Ishak, Linksvayer, & Mueller, 2015;Pinto-Tomás et al, 2009), although it remains unclear whether these were the same OTUs or not. These previously reported γ-Proteobacteria are mostly Enterobacteriaceae with abilities to fix nitrogen in laboratory fungus gardens of Atta leaf-cutting ants (Pinto-Tomás et al, 2009).…”

Section: Myr Ednaella Workers (Supporting Informationmentioning

confidence: 85%

The evolution of abdominal microbiomes in fungus‐growing ants

et al. 2018

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The attine ants are a monophyletic lineage that switched to fungus farming ca. 55–60 MYA. They have become a model for the study of complex symbioses after additional fungal and bacterial symbionts were discovered, but their abdominal endosymbiotic bacteria remain largely unknown. Here, we present a comparative microbiome analysis of endosymbiotic bacteria spanning the entire phylogenetic tree. We show that, across 17 representative sympatric species from eight genera sampled in Panama, abdominal microbiomes are dominated by Mollicutes, α‐ and γ‐Proteobacteria, and Actinobacteria. Bacterial abundances increase from basal to crown branches in the phylogeny reflecting a shift towards putative specialized and abundant abdominal microbiota after the ants domesticated gongylidia‐bearing cultivars, but before the origin of industrial‐scale farming based on leaf‐cutting herbivory. This transition coincided with the ancestral single colonization event of Central/North America ca. 20 MYA, documented in a recent phylogenomic study showing that almost the entire crown group of the higher attine ants, including the leaf‐cutting ants, evolved there and not in South America. Several bacterial species are located in gut tissues or abdominal organs of the evolutionarily derived, but not the basal attine ants. The composition of abdominal microbiomes appears to be affected by the presence/absence of defensive antibiotic‐producing actinobacterial biofilms on the worker ants' cuticle, but the significance of this association remains unclear. The patterns of diversity, abundance and sensitivity of the abdominal microbiomes that we obtained explore novel territory in the comparative analysis of attine fungus farming symbioses and raise new questions for further in‐depth research.

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“…Several studies used next-generation sequencing approaches to characterize microbiomes from fungus gardens of leafcutter ants (Suen et al, 2010;Aylward et al, 2012;Aylward et al, 2014) and non-leafcutter attine species (Sen et al, 2009;Ishak et al, 2011;Liberti et al, 2015;Kellner et al, 2015). These studies documented the presence of a great bacterial diversity in attine gardens (e.g., Enterobacter, Pseudomonas, Klebsiella, Pantoea and others), and Aylward et al (2012) investigated the potential functions of bacteria in Atta gardens using meta-proteomic analyses.…”

Section: Introductionmentioning

confidence: 99%

Bacterial microbiomes from vertically transmitted fungal inocula of the leaf‐cutting ant Atta texana

Meirelles

McFrederick

Rodrigues

et al. 2016

Environ Microbiol Rep

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2 Originality-Significance Statement: An ongoing debate is whether beneficial microbiomes can be inherited from parent to offspring generations. We survey bacterial microbiomes present in the fungal cultivar inocula of leaf-cutting ants, which are vertically transmitted and could potentially lead to co-propagation of beneficial fungus-bacteria consortia to improve health and growth of incipient gardens. SummaryMicrobiome surveys provide clues for the functional roles of symbiotic microbial communities and their hosts. In this study, we elucidated bacterial microbiomes associated with the vertically-transmitted fungal inocula (pellets) used by foundress queens of the leafcutting ant Atta texana as starter-cultures for new gardens. As reference microbiomes, we also surveyed bacterial microbiomes of foundress queens, gardens, and brood of incipient nests. Pseudomonas, Acinetobacter, Propionibacterium, and Corynebacterium were consistently present in high abundance in microbiomes. Some pellet and ant samples contained abundant bacteria from an Entomoplasmatales-clade, and a separate PCR-based survey of Entomoplasmatales bacteria in eight attine ant-genera from Brazil placed these bacteria in a monophyletic clade within the bacterial genus Mesoplasma. The attine antMesoplasma association parallels a similar association between a closely-related, monophyletic Entomoplasmatales-clade and army ants. Of thirteen A. texana nests surveyed, three nests with exceptionally high Mesoplasma abundance died, whereas the other nests survived. It is unclear whether Mesoplasma was the primary cause of mortality, or Mesoplasma became abundant in moribund nests for non-pathogenic reasons. However, the consistent and geographically widespread presence of Mesoplasma suggests an important functional role in the association with attine ants.

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Bacterial community composition and diversity in an ancestral ant fungus symbiosis

Cited by 54 publications

References 80 publications

Host identity and symbiotic association affects the taxonomic and functional diversity of the clownfish-hosting sea anemone microbiome

Host identity and symbiotic association affects the taxonomic and functional diversity of the clownfish-hosting sea anemone microbiome

The evolution of abdominal microbiomes in fungus‐growing ants

Bacterial microbiomes from vertically transmitted fungal inocula of the leaf‐cutting ant Atta texana

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