Influence of ocean warming and acidification on habitat-forming coralline algae and their associated molluscan assemblages

When ocean warming and acidification impact habitat-forming species, substantial alterations to the supported ecological communities and associated ecosystems are likely to follow. Here, we used experimental manipulations to test the hypotheses that ocean warming and acidification would negatively a...

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Bibliographic Details
Published in:Global Ecology and Conservation
Main Authors: Brendan P. Kelaher, Lea T. Mamo, Euan Provost, Sebastian G. Litchfield, Anna Giles, Peter Butcherine
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2022
Subjects:
Ocean climate change
Epifauna
Amphiroa
Seaweed
Mesocosm
Calcifying
Ecology
QH540-549.5
Ocean acidification
Online Access:https://doi.org/10.1016/j.gecco.2022.e02081
https://doaj.org/article/b660e0a9d5aa49bebabd8e9a3fce8542
Description
Summary:When ocean warming and acidification impact habitat-forming species, substantial alterations to the supported ecological communities and associated ecosystems are likely to follow. Here, we used experimental manipulations to test the hypotheses that ocean warming and acidification would negatively affect habitat-forming coralline algal turfs and the diverse molluscan assemblages they support. Boulders covered in a turf of Amphiroa anceps with intact faunal assemblages were subjected to an orthogonal combination of current (~ 23 °C) and future (~ 26 °C) ocean temperatures, and current (~ 430 µatm) and future (~ 880 µatm) seawater pCO2. Ocean warming negatively impacted the cover and photosynthetic efficiency of Amphiroa fronds, whereas ocean acidification caused the biomass per unit area and the frond density of Amphiroa turf to be 56% and 59% less than current ocean conditions, respectively. Ocean acidification also caused a significant change in the structure of molluscan assemblages associated with Amphiroa turf, which included a 43% and a 61% reduction in the species richness and overall abundance of molluscs, respectively. The results demonstrate that coralline algal turfs are particularly vulnerable to ocean climate change, which has implications for the biodiversity and ecosystem functions supported by these globally distributed foundation species.

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