Abstract

ABSTRACTMicrobial relationships are critical to coral health, and changes in microbiomes are often exhibited following environmental disturbance. However, the dynamics of coral-microbial composition and external factors that govern coral microbiome assembly and response to disturbance remain largely uncharacterized. Here, we investigated how antibiotic-induced disturbance affects the coral mucus microbiota in the facultatively symbiotic temperate coral Astrangia poculata, which occurs naturally with high (symbiotic) or low (aposymbiotic) densities of the endosymbiotic dinoflagellate Breviolum psygmophilum. We also explored how differences in the mucus microbiome of natural and disturbed A. poculata colonies affected levels of extracellular superoxide, a reactive oxygen species thought to have both beneficial and detrimental effects on coral health. Using a bacterial and archaeal small-subunit (SSU) rRNA gene sequencing approach, we found that antibiotic exposure significantly altered the composition of the mucus microbiota but that it did not influence superoxide levels, suggesting that superoxide production in A. poculata is not influenced by the mucus microbiota. In antibiotic-treated A. poculata exposed to ambient seawater, mucus microbiota recovered to its initial state within 2 weeks following exposure, and six bacterial taxa played a prominent role in this reassembly. Microbial composition among symbiotic colonies was more similar throughout the 2-week recovery period than that among aposymbiotic colonies, whose microbiota exhibited significantly more interindividual variability after antibiotic treatment and during recovery. This work suggests that the A. poculata mucus microbiome can rapidly reestablish itself and that the presence of B. psygmophilum, perhaps by supplying nutrients, photosynthate, or other signaling molecules, exerts influence on this process.IMPORTANCE Corals are animals whose health is often maintained by symbiotic microalgae and other microorganisms, yet they are highly susceptible to environmental-related disturbances. Here, we used a known disruptor, antibiotics, to understand how the coral mucus microbial community reassembles itself following disturbance. We show that the Astrangia poculata microbiome can recover from this disturbance and that individuals with algal symbionts reestablish their microbiomes in a more consistent manner compared to corals lacking symbionts. This work is important because it suggests that this coral may be able to recover its mucus microbiome following disturbance, it identifies specific microbes that may be important to reassembly, and it demonstrates that algal symbionts may play a previously undocumented role in microbial recovery and resilience to environmental change.

Highlights

  • Microbial relationships are critical to coral health, and changes in microbiomes are often exhibited following environmental disturbance

  • Mucus and seawater were sampled for analysis of associated bacterial and archaeal communities by sequencing the V4 region of the smallsubunit rRNA (SSU rRNA) gene, with mucus collected from all colonies immediately before antibiotic treatment, immediately following antibiotic treatment (0 h), and 96 h, 1 week, and 2 weeks after treatment (Table 2)

  • Following a 2-week period of exposure to natural seawater microorganisms, the surface mucus microbiome of antibiotics-exposed A. poculata colonies resembled that of untreated control A. poculata colonies

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Summary

Introduction

Microbial relationships are critical to coral health, and changes in microbiomes are often exhibited following environmental disturbance. This work is important because it suggests that this coral may be able to recover its mucus microbiome following disturbance, it identifies specific microbes that may be important to reassembly, and it demonstrates that algal symbionts may play a previously undocumented role in microbial recovery and resilience to environmental change. Most corals maintain beneficial relationships with microalgae in the family Symbiodiniaceae [1], which support their ability to deposit aragonite skeletons and form reefs [2] Environmental disturbances, such as elevated seawater temperatures and. An emerging hypothesis is that extracellular production of reactive oxygen species (ROS) by coral and/or associated microorganisms may play a beneficial role in the physiology and health of the coral host [22, 23], as previously observed for other eukaryotes [24, 25]. Due to the multiple production and degradation processes and sources, deciphering the biological source of extracellular superoxide production in corals is challenging, and simplified experimental systems examining microbial colonization could shed light on the importance of bacterial-derived superoxide production

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