Phylogenetic signature of light and thermal stress for the endosymbiotic dinoflagellates of corals (Family Symbiodiniaceae)

Lesser, Michael P.

doi:10.1002/lno.11155

Cited by 26 publications

(24 citation statements)

References 86 publications

(166 reference statements)

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“…Indeed, we observed a significantly higher abundance of variants associated with Symbiodinium (clade A), Cladocopium (clade C), and Durusdinium (clade D) taxa in anemones that were preexposed to 32°C, but also in heat stressed individuals (that is, Aiptasia reared at 25°C and subsequently subjected to 32°C). Symbiodinium species are known to be more resilient, with lower reactive oxygen species levels and slower deterioration of photosystem (PS) II compared to Breviolum, for example [41,[59][60][61][62]. Surprisingly, despite S. linucheae (A4) being supposedly the most thermally tolerant species tested here (according to [32]), it was barely observed at 32°C; only in few individuals from 25°C and for which it was already present in their initial ITS2 composition.…”

Section: Discussionmentioning

confidence: 73%

Temperature transcends partner specificity in the symbiosis establishment of a cnidarian

et al. 2020

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Coral reef research has predominantly focused on the effect of temperature on the breakdown of coral-dinoflagellate symbioses. However, less is known about how increasing temperature affects the establishment of new coral-dinoflagellate associations. Inter-partner specificity and environment-dependent colonization are two constraints proposed to limit the acquisition of more heat tolerant symbionts. Here, we investigated the symbiotic dynamics of various photosymbionts in different host genotypes under “optimal” and elevated temperature conditions. To do this, we inoculated symbiont-free polyps of the sea anemone Exaiptasia pallida originating from Hawaii (H2), North Carolina (CC7), and the Red Sea (RS) with the same mixture of native symbiont strains (Breviolum minutum, Symbiodinium linucheae, S. microadriaticum, and a Breviolum type from the Red Sea) at 25 and 32 °C, and assessed their ITS2 composition, colonization rates, and PSII photochemical efficiency (Fv/Fm). Symbiont communities across thermal conditions differed significantly for all hosts, suggesting that temperature rather than partner specificity had a stronger effect on symbiosis establishment. Overall, we detected higher abundances of more heat resistant Symbiodiniaceae types in the 32 °C treatments. Our data further showed that PSII photophysiology under elevated temperature improved with thermal pre-exposure (i.e., higher Fv/Fm), yet, this effect depended on host genotype and was influenced by active feeding as photochemical efficiency dropped in response to food deprivation. These findings highlight the role of temperature and partner fidelity in the establishment and performance of symbiosis and demonstrate the importance of heterotrophy for symbiotic cnidarians to endure and recover from stress.

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Section: Discussionmentioning

confidence: 73%

Temperature transcends partner specificity in the symbiosis establishment of a cnidarian

et al. 2020

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“…Studies that have examined the resistance of corals to predicted changes in OW and OA have resulted in variable results reflecting the interand intraspecific phenotypic plasticity of corals and their Symbiodiniaceae symbionts (Hoadley et al, 2015;Bahr et al, 2016; Castillo et al, 2018;Cole et al, 2018;Davies et al, 2018). For Symbiodiniaceae, the diversity in phenotypic characters related to the stress response is significant (Díaz-Almeyda et al, 2018;Lesser, 2019), and recent studies, including those on M. cavernosa, have shown that "symbiont shuffling" to stresstolerant Symbiodiniaceae (i.e., Durusdinium trenchi [Phylotype D1a]) can occur after exposure to thermal stress (Silverstein et al, 2015(Silverstein et al, , 2017Cunning et al, 2018). The change to, or addition of, D. trenchi symbionts to the Symbiodiniaceae community potentially adds resistance to future thermal perturbation (Silverstein et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

“…The change to, or addition of, D. trenchi symbionts to the Symbiodiniaceae community potentially adds resistance to future thermal perturbation (Silverstein et al, 2015). While some studies incorporating both long and short-exposures of corals to combined OW and OA conditions have revealed little effect of OA on gene expression or the functional diversity of their Symbiodiniaceae (Baghdasarian et al, 2017;Davies et al, 2018), other studies on the functional responses of corals in response to OW and OA have shown significant effects where OA lowers the thermal response threshold of the coral (e.g., Anthony et al, 2008) when using ecologically relevant irradiances (sensu Lesser, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Nonetheless, the production of ROS is inevitable, even in the absence of thermal stress, as it is directly related to pO 2 (Jamieson et al, 1986). As a result, the endosymbiotic Symbiodiniaceae contribute significant amounts of photogenerated O 2 − and H 2 O 2 (Lesser, 1996(Lesser, , 2019Suggett et al, 2008;Saragosti et al, 2010;McGinty et al, 2012), and both host cells (Perez and Weis, 2006) and Symbiodiniaceae also produce nitric oxide (NO • ) (Bouchard and Yamasaki, 2008). Nitric oxide synthase (NOS) activity in corals and sea anemones (Morrall et al, 2000;Trapido-Rosenthal et al, 2005) suggest that NO • production, and subsequently reactive RNS, including the highly reactive peroxynitrite radical (ONOO − ), are produced and are considered important contributors to redox stress and initiation of coral bleaching (Weis, 2008).…”

Section: Discussionmentioning

confidence: 99%

“…Most severe bleaching occurs in the first 15 m depth on a coral reef (e.g., Baird et al, 2018) where irradiances are high (e.g., Lesser, 2000) and experimental evidence has supported a significant, and interactive, role for solar radiation in the bleaching phenomenon (Lesser et al, 1990;Brown et al, 2002;Bhagooli and Hidaka, 2004;Lesser and Farrell, 2004;Lesser, 2010Lesser, , 2011a. Both the host and dinoflagellate symbionts respond by differential expression of stress genes that include heat shock proteins, enzymatic antioxidants, fluorescent proteins and regulators of apoptosis, autophagy or necrosis (Lesser and Farrell, 2004;Baird et al, 2009;Lesser, 2011a,b), or by switching to symbionts with increased organismal functionality (i.e., temperature compensated photophysiology) under environmental stress (Suggett et al, 2017;Lesser, 2019). One way to identify coral phenotypes resistant to environmental stress is to use molecular markers known to respond to multiple environmental stressors (Downs et al, 2000;Tchernov et al, 2004;Kenkel et al, 2011Kenkel et al, , 2014Jin et al, 2016;Louis et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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A New “Business as Usual” Climate Scenario and the Stress Response of the Caribbean Coral Montastraea cavernosa

et al. 2020

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The climate change related decline of shallow (<30 m) coral reef ecosystems has been driven by the mortality of scleractinian corals caused primarily by the phenomenon known as "coral bleaching." But despite pervasive phase shifts and macroalgal dominance on many coral reefs, some coral species have persisted. One of those species is Montastraea cavernosa which has been categorized as resilient to a range of biotic and abiotic stressors. In order to understand the mechanism(s) of resistance in this coral, we present the results of a thermal stress and ocean acidification (OA) experiment on M. cavernosa, both its brown and orange color morphs, representing conditions predicted by the Representative Concentration Pathway (RCP) 6.0 scenario in the year 2100. We assessed the community response of the prokaryotic microbiome, the photophysiological response of the endosymbiotic Symbiodiniaceae and the molecular responses of critical pathways in the host by quantifying transcript abundances of genes encoding fluorescent proteins, heat shock proteins, antioxidant enzymes and regulators of apoptosis. After a 12 d acclimatization experiment, no visible bleaching was observed in any treatment, and the excitation pressure on photosystem II of the symbiotic Symbiodiniaceae showed no effects of the independent or interactive effects of thermal stress and OA, while only minor, but significant, changes in the prokaryotic microbiome were observed when exposed to RCP 6.0 predicted OA conditions. At the end of the experiment, the host heat shock protein 90 showed an increase in transcript abundance under the combined effects of thermal stress and OA compared to high temperatures alone, but these treatment groups were not significantly different from treatments under normal temperatures. While Bax, an activator of apoptosis, was significantly higher under thermal stress alone compared to control samples. Taken together, M. cavernosa, exhibits ecological stability over time and this may be based on its physiological persistence, resistance and resilience when experimentally exposed to the ecologically realistic RCP 6.0 climate model predictions.

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Thermal plasticity of coral reef symbionts is linked to major alterations in their lipidome composition

Botana

Chaves‐Filho

Inague

et al. 2022

Limnology & Oceanography

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Coral bleaching caused by ocean warming is leading to worldwide coral decline. The physiological processes underlying this ecological event are still incompletely understood, although previous research has suggested oxidative stress as major player in the impairment of symbiont thylakoid membranes and in symbiosis breakdown. Lipids are interesting targets of investigation, given their susceptibility to thermal and oxidative stresses. Here, an untargeted lipidomic approach was employed to examine changes in lipidome and pigments of three coral reef symbionts (Symbiodiniaceae) after a heat shock in in vitro experiments. The acute thermal stress induced species-specific changes in lipidome and pigments compositions of both heat sensitive and tolerant symbionts. Heat sensitivity was characterized by a steep and steady decline in cell densities over time (4 and 240 h after heat shock). At the membrane level, heat sensitive symbiont displayed a quantitative decrease in glycolipids linked to polyunsaturated fatty acids, followed by enrichment in oxidized lipids and sphingolipids. Despite showing distinct adaptations, the two heat tolerant symbionts were characterized by the preservation of membrane lipids after heat shock, particularly glycolipids. This finding suggests the action of powerful antioxidant systems, preventing the escalation of oxidized lipids concentration in thylakoid membranes under thermal stress. Although limited by the examination of free-living symbionts, our study provides a solid baseline for the investigation of lipidome and pigments alterations of Symbiodiniaceae in response to heat stress. Novel potential lipid biomarkers linked to thermal stress are suggested. In particular, oxidized lipids-which are implicated in coral symbiosis establishment and breakdown-appear as attractive targets for further research.

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Phylogenetic signature of light and thermal stress for the endosymbiotic dinoflagellates of corals (Family Symbiodiniaceae)

Cited by 26 publications

References 86 publications

Temperature transcends partner specificity in the symbiosis establishment of a cnidarian

Temperature transcends partner specificity in the symbiosis establishment of a cnidarian

A New “Business as Usual” Climate Scenario and the Stress Response of the Caribbean Coral Montastraea cavernosa

Thermal plasticity of coral reef symbionts is linked to major alterations in their lipidome composition

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