Genome streamlining and chemical defense in a coral reef symbiosis

Kwan, Jason C.; Donia, Mohamed S.; Han, Andrew; Hirose, Euichi; Haygood, Margo G.; Schmidt, Eric W.

doi:10.1073/pnas.1213820109

Cited by 141 publications

(209 citation statements)

References 45 publications

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“…The detection of this candidate genus from a GBR ascidian expands the known geographic range of this symbiont taxon and further supports its specificity to the host genus Ecteinascidia. In addition, this symbiont lineage is particularly notable for its putative role in secondary metabolite synthesis within the animal cell, including the production of the anticancer agent ET-743 (Rath et al, 2011), which may constitute a key functional aspect of ascidian-bacterial symbioses (Kwan et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…As a basal lineage in the phylum Chordata, ascidians occupy a key stage in deuterostome evolution (Delsuc et al, 2006). Ascidians are also a prolific source of novel marine natural products (Erwin et al, 2010) and the involvement of microbial symbionts in bioactive compound production (Schmidt and Donia, 2010) has prompted recent studies of the ascidian microbiota (Donia et al, 2011;Kwan et al, 2012). Historically, most studies of microbial symbionts in ascidians have focused on cyanobacteria, in particular the genera Prochloron and Synechocystis.…”

Section: Introductionmentioning

confidence: 99%

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Down under the tunic: bacterial biodiversity hotspots and widespread ammonia-oxidizing archaea in coral reef ascidians

et al. 2013

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Ascidians are ecologically important components of marine ecosystems yet the ascidian microbiota remains largely unexplored beyond a few model species. We used 16S rRNA gene tag pyrosequencing to provide a comprehensive characterization of microbial symbionts in the tunic of 42 Great Barrier Reef ascidian samples representing 25 species. Results revealed high bacterial biodiversity (3 217 unique operational taxonomic units (OTU 0.03 ) from 19 described and 14 candidate phyla) and the widespread occurrence of ammonia-oxidizing Thaumarchaeota in coral reef ascidians (24 of 25 host species). The ascidian microbiota was clearly differentiated from seawater microbial communities and included symbiont lineages shared with other invertebrate hosts as well as unique, ascidian-specific phylotypes. Several rare seawater microbes were markedly enriched (200-700 fold) in the ascidian tunic, suggesting that the rare biosphere of seawater may act as a conduit for horizontal symbiont transfer. However, most OTUs (71%) were rare and specific to single hosts and a significant correlation between host relatedness and symbiont community similarity was detected, indicating a high degree of host-specificity and potential role of vertical transmission in structuring these communities. We hypothesize that the complex ascidian microbiota revealed herein is maintained by the dynamic microenvironments within the ascidian tunic, offering optimal conditions for different metabolic pathways such as ample chemical substrate (ammonia-rich host waste) and physical habitat (high oxygen, low irradiance) for nitrification. Thus, ascidian hosts provide unique and fertile niches for diverse microorganisms and may represent an important and previously unrecognized habitat for nitrite/nitrate regeneration in coral reef ecosystems.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Down under the tunic: bacterial biodiversity hotspots and widespread ammonia-oxidizing archaea in coral reef ascidians

et al. 2013

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“…Indeed, there are several examples in which a defensive role has been experimentally assigned to individual secondary metabolites (Paul et al, 1990;Joullie et al, 2003). Strikingly, there are now several examples in which it has been shown that symbiotic bacteria produce potentially defensive metabolites, while the host animals do not (Supplementary Table S8) (Schmidt et al, 2005;Donia et al, 2006Donia et al, , 2008Rath et al, 2011;Donia et al, 2011bDonia et al, , 2011cKwan et al, 2012). Beyond defense, symbiotic metabolites in ascidians are also known to have other roles.…”

Section: Introductionmentioning

confidence: 99%

“…By contrast, certain groups of highly toxic polyketides are synthesized by genome-reduced, obligate intracellular alpha-proteobacteria, Candidatus Endolissoclinum faulkneri (Kwan et al, 2012). This interaction has resulted in vertical transmission and co-speciation that has been ongoing for approximately 6-35 million years (Kwan et al, 2012;Kwan and Schmidt, 2013). During that period, the production of toxic secondary metabolism has been maintained while the remainder of the symbiont's genome has degraded.…”

Section: Introductionmentioning

confidence: 99%

“…Nonetheless, isolated Prochloron chemistry is strongly ascidian species specific, implicating a chemical driver in the interaction (Donia et al, 2011b). By contrast, certain groups of highly toxic polyketides are synthesized by genome-reduced, obligate intracellular alpha-proteobacteria, Candidatus Endolissoclinum faulkneri (Kwan et al, 2012). This interaction has resulted in vertical transmission and co-speciation that has been ongoing for approximately 6-35 million years (Kwan et al, 2012;Kwan and Schmidt, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Species specificity of symbiosis and secondary metabolism in ascidians

et al. 2014

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Ascidians contain abundant, diverse secondary metabolites, which are thought to serve a defensive role and which have been applied to drug discovery. It is known that bacteria in symbiosis with ascidians produce several of these metabolites, but very little is known about factors governing these 'chemical symbioses'. To examine this phenomenon across a wide geographical and species scale, we performed bacterial and chemical analyses of 32 different ascidians, mostly from the didemnid family from Florida, Southern California and a broad expanse of the tropical Pacific Ocean. Bacterial diversity analysis showed that ascidian microbiomes are highly diverse, and this diversity does not correlate with geographical location or latitude. Within a subset of species, ascidian microbiomes are also stable over time (R ¼ À 0.037, P-value ¼ 0.499). Ascidian microbiomes and metabolomes contain species-specific and location-specific components. Location-specific bacteria are found in low abundance in the ascidians and mostly represent strains that are widespread. Location-specific metabolites consist largely of lipids, which may reflect differences in water temperature. By contrast, species-specific bacteria are mostly abundant sequenced components of the microbiomes and include secondary metabolite producers as major components. Species-specific chemicals are dominated by secondary metabolites. Together with previous analyses that focused on single ascidian species or symbiont type, these results reveal fundamental properties of secondary metabolic symbiosis. Different ascidian species have established associations with many different bacterial symbionts, including those known to produce toxic chemicals. This implies a strong selection for this property and the independent origin of secondary metabolite-based associations in different ascidian species. The analysis here streamlines the connection of secondary metabolite to producing bacterium, enabling further biological and biotechnological studies.

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