Macroalgal presence decreases coral calcification rates more than ocean acidification

IF 2.7 2区生物学 Q1 MARINE & FRESHWATER BIOLOGY

Coral Reefs Pub Date : 2024-06-04 DOI:10.1007/s00338-024-02515-7

Ashtyn L. Isaak, Maureen Ho, Max S. Dhillon, Maggie D. Johnson, Hildegard Westphal, Steve S. Doo

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Abstract

Global coral reef degradation has precipitated phase shifts toward macroalgal-dominated communities. Despite the negative repercussions for reefscapes, higher abundances of primary producers have the potential to positively impact the physicochemical environment and mitigate negative impacts of ocean acidification (OA). In this study, we investigated the influence of macroalgal (cf. Sargassum vulgare) density on coral (Acropora millepora and A. hemprichii) calcification rates under current and future OA conditions. Corals were resistant to OA up to ~ 1100 µatm, with no changes in calcification rates. However, the presence of (low and high density) algae reduced calcification rates by ~ 41.8%, suggesting either a chemical defense response due to algal metabolites or potential physical impacts from shading or abrasion. Documented beneficial buffering effects of macroalgae in OA may also elicit negative impacts on coral calcification, suggesting further work is needed to elucidate how species interactions influence responses to projected climate change.

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巨藻的存在比海洋酸化更能降低珊瑚的钙化率

全球珊瑚礁的退化导致了以大型藻类为主的群落的阶段性转变。尽管这对珊瑚礁景观造成了负面影响，但初级生产者丰度的提高有可能对物理化学环境产生积极影响，并减轻海洋酸化（OA）的负面影响。在这项研究中，我们调查了在当前和未来 OA 条件下，大型藻类（马尾藻）密度对珊瑚（Acropora millepora 和 A. hemprichii）钙化率的影响。珊瑚对大约 1100 µatm 以下的 OA 具有抵抗力，钙化率没有变化。然而，（低密度和高密度）藻类的存在使钙化率降低了约 41.8%，这表明藻类代谢产物产生了化学防御反应，或遮光或磨损产生了潜在的物理影响。记录的大型藻类在 OA 中的有益缓冲作用也可能对珊瑚钙化产生负面影响，这表明需要进一步研究物种相互作用如何影响对预测气候变化的响应。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Coral Reefs 生物-海洋与淡水生物学

CiteScore

6.80

自引率

11.40%

发文量

111

审稿时长

4-8 weeks

期刊介绍： Coral Reefs, the Journal of the International Coral Reef Society, presents multidisciplinary literature across the broad fields of reef studies, publishing analytical and theoretical papers on both modern and ancient reefs. These encourage the search for theories about reef structure and dynamics, and the use of experimentation, modeling, quantification and the applied sciences. Coverage includes such subject areas as population dynamics; community ecology of reef organisms; energy and nutrient flows; biogeochemical cycles; physiology of calcification; reef responses to natural and anthropogenic influences; stress markers in reef organisms; behavioural ecology; sedimentology; diagenesis; reef structure and morphology; evolutionary ecology of the reef biota; palaeoceanography of coral reefs and coral islands; reef management and its underlying disciplines; molecular biology and genetics of coral; aetiology of disease in reef-related organisms; reef responses to global change, and more.