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Dichotomy between Regulation of Coral Bacterial Communities and Calcification Physiology under Ocean Acidification Conditions

Shore, A ; Day, R D ; Stewart, J A ; Burge, C A Stabb, Eric V ; Stabb, Eric V.

Applied and environmental microbiology, 2021-02, Vol.87 (6) [Periódico revisado por pares]

United States: American Society for Microbiology

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  • Título:
    Dichotomy between Regulation of Coral Bacterial Communities and Calcification Physiology under Ocean Acidification Conditions
  • Autor: Shore, A ; Day, R D ; Stewart, J A ; Burge, C A
  • Stabb, Eric V ; Stabb, Eric V.
  • Assuntos: Abundance ; Acidification ; Animals ; Anthozoa - microbiology ; Anthozoa - physiology ; Bacteria ; Bacteria - classification ; Bacteria - isolation & purification ; Boron ; Boron isotopes ; Calcification ; Calcification, Physiologic ; Carbon dioxide ; Chemical analysis ; Coral reef ecosystems ; Coral reefs ; Destabilization ; Dispersion ; Endozoicomonas ; Environmental changes ; Gene sequencing ; Hydrogen-Ion Concentration ; Invertebrate Microbiology ; Isotopes ; Marine ecosystems ; Microbiomes ; Ocean acidification ; Oceans and Seas ; pH effects ; Physiology ; Porites rus ; rRNA 16S ; Seawater ; Seawater - chemistry ; Water analysis
  • É parte de: Applied and environmental microbiology, 2021-02, Vol.87 (6)
  • Notas: Citation Shore A, Day RD, Stewart JA, Burge CA. 2021. Dichotomy between regulation of coral bacterial communities and calcification physiology under ocean acidification conditions. Appl Environ Microbiol 87:e02189-20. https://doi.org/10.1128/AEM.02189-20.
  • Descrição: Ocean acidification (OA) threatens the growth and function of coral reef ecosystems. A key component to coral health is the microbiome, but little is known about the impact of OA on coral microbiomes. A submarine CO vent at Maug Island in the Northern Mariana Islands provides a natural pH gradient to investigate coral responses to long-term OA conditions. Three coral species ( , , and ) were sampled from three sites where the mean seawater pH is 8.04, 7.98, and 7.94. We characterized coral bacterial communities (using 16S rRNA gene sequencing) and determined pH of the extracellular calcifying fluid (ECF) (using skeletal boron isotopes) across the seawater pH gradient. Bacterial communities of both species stabilized (decreases in community dispersion) with decreased seawater pH, coupled with large increases in the abundance of , an endosymbiont. experienced a significant decrease in ECF pH near the vent, whereas experienced a trending decrease in ECF pH near the vent. In contrast, exhibited bacterial community destabilization (increases in community dispersion), with significant decreases in abundance, while its ECF pH remained unchanged across the pH gradient. Our study shows that OA has multiple consequences on abundance and suggests that abundance may be an indicator of coral response to OA. We reveal an interesting dichotomy between two facets of coral physiology (regulation of bacterial communities and regulation of calcification), highlighting the importance of multidisciplinary approaches to understanding coral health and function in a changing ocean. Ocean acidification (OA) is a consequence of anthropogenic CO emissions that is negatively impacting marine ecosystems such as coral reefs. OA affects many aspects of coral physiology, including growth (i.e., calcification) and disrupting associated bacterial communities. Coral-associated bacteria are important for host health, but it remains unclear how coral-associated bacterial communities will respond to future OA conditions. We document changes in coral-associated bacterial communities and changes to calcification physiology with long-term exposure to decreases in seawater pH that are environmentally relevant under midrange IPCC emission scenarios (0.1 pH units). We also find species-specific responses that may reflect different responses to long-term OA. In , calcification physiology was highly regulated despite changing seawater conditions. In spp., changes in bacterial communities do not reflect a breakdown of coral-bacterial symbiosis. Insights into calcification and host-microbe interactions are critical to predicting the health and function of different coral taxa to future OA conditions.
  • Editor: United States: American Society for Microbiology
  • Idioma: Inglês
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