School of BioSciences - Research Publications
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ItemExploring microbiome engineering as a strategy for improved thermal tolerance in Exaiptasia diaphana(OXFORD UNIV PRESS, 2022-04)AIMS: Fourteen percent of all living coral, equivalent to more than all the coral on the Great Barrier Reef, has died in the past decade as a result of climate change-driven bleaching. Inspired by the 'oxidative stress theory of coral bleaching', we investigated whether a bacterial consortium designed to scavenge free radicals could integrate into the host microbiome and improve thermal tolerance of the coral model, Exaiptasia diaphana. METHODS AND RESULTS: E. diaphana anemones were inoculated with a consortium of high free radical scavenging (FRS) bacteria, a consortium of congeneric low FRS bacteria, or sterile seawater as a control, then exposed to elevated temperature. Increases in the relative abundance of Labrenzia during the first 2 weeks following the last inoculation provided evidence for temporary inoculum integration into the E. diaphana microbiome. Initial uptake of other consortium members was inconsistent, and these bacteria did not persist either in E. diaphana's microbiome over time. Given their non-integration into the host microbiome, the ability of the FRS consortium to mitigate thermal stress could not be assessed. Importantly, there were no physiological impacts (negative or positive) of the bacterial inoculations on the holobiont. CONCLUSIONS: The introduced bacteria were not maintained in the anemone microbiome over time, thus, their protective effect is unknown. Achieving long-term integration of bacteria into cnidarian microbiomes remains a research priority. SIGNIFICANCE AND IMPACT OF THE STUDY: Microbiome engineering strategies to mitigate coral bleaching may assist coral reefs in their persistence until climate change has been curbed. This study provides insights that will inform microbiome manipulation approaches in coral bleaching mitigation research.
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ItemExaiptasia diaphana from the great barrier reef: a valuable resource for coral symbiosis research(SPRINGER, 2020-02-06)The sea anemone, Exaiptasia diaphana, previously known as Exaiptasia pallida or Aiptasia pallida, has become increasingly popular as a model for cnidarian-microbiome symbiosis studies due to its relatively rapid growth, ability to reproduce sexually and asexually, and symbiosis with diverse prokaryotes and the same microalgal symbionts (family Symbiodiniaceae) as its coral relatives. Clonal E. diaphana strains from Hawaii, the Atlantic Ocean, and Red Sea are now established for use in research. Here, we introduce Great Barrier Reef (GBR)-sourced E. diaphana strains as additions to the model repertoire. Sequencing of the 18S rRNA gene confirmed the anemones to be E. diaphana while genome-wide single nucleotide polymorphism analysis revealed four distinct genotypes. Based on Exaiptasia-specific inter-simple sequence repeat (ISSR)-derived sequence characterized amplified region (SCAR) marker and gene loci data, these four E. diaphana genotypes are distributed across several divergent phylogenetic clades with no clear phylogeographical pattern. The GBR E. diaphana genotypes comprised three females and one male, which all host Breviolum minutum as their homologous Symbiodiniaceae endosymbiont. When acclimating to an increase in light levels from 12 to 28 μmol photons m−2 s−1, the genotypes exhibited significant variation in maximum quantum yield of Symbiodiniaceae photosystem II and Symbiodiniaceae cell density. The comparatively high levels of physiological and genetic variability among GBR anemone genotypes make these animals representative of global E. diaphana diversity and thus excellent model organisms. The addition of these GBR strains to the worldwide E. diaphana collection will contribute to cnidarian symbiosis research, particularly in relation to the climate resilience of coral reefs.