Abstract
The association between corals and photosynthetic dinoflagellates (Symbiodinium spp.) is the key to the success of reef ecosystems in highly oligotrophic environments, but it is also their Achilles‘ heel due to its vulnerability to local stressors and the effects of climate change. Research during the last two decades has shaped a view that coral host–Symbiodinium pairings are diverse, but largely exclusive. Deep sequencing has now revealed the existence of a rare diversity of cryptic Symbiodinium assemblages within the coral holobiont, in addition to one or a few abundant algal members. While the contribution of the most abundant resident Symbiodinium species to coral physiology is widely recognized, the significance of the rare and low abundant background Symbiodinium remains a matter of debate. In this study, we assessed how coral–Symbiodinium communities assemble and how rare and abundant components together constitute the Symbiodinium community by analyzing 892 coral samples comprising >110 000 unique Symbiodinium ITS2 marker gene sequences. Using network modeling, we show that host–Symbiodinium communities assemble in non-random ‘clusters‘ of abundant and rare symbionts. Symbiodinium community structure follows the same principles as bacterial communities, for which the functional significance of rare members (the ‘rare bacterial biosphere’) has long been recognized. Importantly, the inclusion of rare Symbiodinium taxa in robustness analyses revealed a significant contribution to the stability of the host–symbiont community overall. As such, it highlights the potential functions rare symbionts may provide to environmental resilience of the coral holobiont.
Highlights
Corals and coral reef ecosystems are immediately threatened by global climate change and local anthropogenic impacts (Hoegh-Guldberg et al, 2007)
The bleaching response and stress tolerance of the coral host are affected by the associated Symbiodinium type (Berkelmans and van Oppen, 2006; Abrego et al, 2008), where a type is defined based on ribosomal ITS2 DNA sequences, which, in combination with other genetic markers, is used to distinguish Symbiodinium species (LaJeunesse et al, 2012, 2014)
Symbiodinium community distribution reveals high number of rare species We explored community patterns of host–Symbiodinium assemblages using ITS2 next-generation sequencing (NGS) data of Symbiodinium communities form discrete clusters of co-occurrence We examined the patterns of co-occurrence of Symbiodinium Operational Taxonomic Units (OTUs) at the individual sample and at the host genus level
Summary
Corals and coral reef ecosystems are immediately threatened by global climate change and local anthropogenic impacts (Hoegh-Guldberg et al, 2007) This is because the obligate association of corals with dinoflagellate endosymbionts of the genus Symbiodinium represents both the success and the Achilles’ heel of these ecosystems. The bleaching response and stress tolerance of the coral host are affected by the associated Symbiodinium type (Berkelmans and van Oppen, 2006; Abrego et al, 2008), where a type is defined based on ribosomal ITS2 DNA sequences, which, in combination with other genetic markers, is used to distinguish Symbiodinium species (LaJeunesse et al, 2012, 2014) These host–symbiont associations are not static and may change as a mechanism to increase the size of the ecological niche (Ziegler et al, 2015) or in response capabilities (Whitacre and Bender, 2010) and (2)
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