Effects of Ocean Acidification on Resident and Active Microbial Communities of Stylophora pistillata.

Didier Zoccola,Maren Ziegler,Chakkiath Paul Antony,Christian R Voolstra,Alexander Venn,Manuel Aranda,Marcelle Muniz Barreto,Eric Tambutté,Sylvie Tambutté,Denis Allemand

doi:10.3389/fmicb.2021.707674

Abstract

Ocean warming and ocean acidification (OA) are direct consequences of climate change and affect coral reefs worldwide. While the effect of ocean warming manifests itself in increased frequency and severity of coral bleaching, the effects of ocean acidification on corals are less clear. In particular, long-term effects of OA on the bacterial communities associated with corals are largely unknown. In this study, we investigated the effects of ocean acidification on the resident and active microbiome of long-term aquaria-maintained Stylophora pistillata colonies by assessing 16S rRNA gene diversity on the DNA (resident community) and RNA level (active community). Coral colony fragments of S. pistillata were kept in aquaria for 2 years at four different pCO2 levels ranging from current pH conditions to increased acidification scenarios (i.e., pH 7.2, 7.4, 7.8, and 8). We identified 154 bacterial families encompassing 2,047 taxa (OTUs) in the resident and 89 bacterial families including 1,659 OTUs in the active communities. Resident communities were dominated by members of Alteromonadaceae, Flavobacteriaceae, and Colwelliaceae, while active communities were dominated by families Cyclobacteriacea and Amoebophilaceae. Besides the overall differences between resident and active community composition, significant differences were seen between the control (pH 8) and the two lower pH treatments (7.2 and 7.4) in the active community, but only between pH 8 and 7.2 in the resident community. Our analyses revealed profound differences between the resident and active microbial communities, and we found that OA exerted stronger effects on the active community. Further, our results suggest that rDNA- and rRNA-based sequencing should be considered complementary tools to investigate the effects of environmental change on microbial assemblage structure and activity.

Highlights

Coral reefs are among the most biodiverse and productive ecosystems in the world
Illumina MiSeq sequencing of bacterial 16S rDNA and rRNA amplicons generated a total of 4,157,907 sequences from 24 samples [average 173,247 ± 100,095 (SD)], being 1,482,981 for resident (DNA) and active (RNA) samples and 2,674,938 for DNA samples (Supplementary Table 1)
We show that ocean acidification (OA) can significantly impact the resident coral microbiome, a stronger effect was observed on the active microbial community, which suggests that the microbial community responded primarily to the environmental change through modified activity patterns

Summary

Introduction

Coral reefs are among the most biodiverse and productive ecosystems in the world. The framework of reefs is built by scleractinian corals. They are referred to as holobionts, obligate symbiotic organisms that live in close association with microorganisms such as endosymbiotic photosynthetic algae, bacteria, archaea, viruses and fungi (Rohwer et al, 2002; Rosenberg et al, 2007). The coral microbiome has a range of functional roles, including nitrogen fixation (Lesser et al, 2004; Lema et al, 2012; Pogoreutz et al, 2017a,b), sulfur cycling (Raina et al, 2009), antibacterial activities (Ritchie, 2006) and overall holobiont health (Rosenberg et al, 2007; Robbins et al, 2019; Voolstra and Ziegler, 2020). As high throughput sequencing of microbial DNA becomes more accessible, studies based on analysis of phylogenetic markers such as the 16S rRNA gene become increasingly available

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Discussion

Conclusion