Mapping carbon fate during bleaching in a model cnidarian symbiosis: the application of <sup>13</sup>C metabolomics

Hillyer, Katie E.; Dias, Daniel A.; Lutz, Adrian; Roessner, Ute; Davy, Simon K.

doi:10.1111/nph.14515

Cited by 62 publications

(72 citation statements)

References 73 publications

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“…Such direct measurements of coral metabolism could help improve understanding of the potential effects of high light on carbon fixation and translocation. Furthermore, there is also evidence to suggest that studies of in vitro Symbiodiniaceae may overestimate the importance of glycerol, and glucose is in fact the major photosynthate translocated from in hospite symbionts to hosts (Ishikura et al, 1999;Hillyer et al, 2017b;Matthews et al, 2017). Glucose concentration was not found to vary between LL to HL and LL to LL control corals in the present study.…”

Section: Discussioncontrasting

confidence: 46%

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Lohr

Camp

Kuzhiumparambil

et al. 2019

Journal of Experimental Biology

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Corals continuously adjust to short-term variation in light availability on shallow reefs. Long-term light alterations can also occur as a result of natural and anthropogenic stressors, as well as management interventions such as coral transplantation. Although short-term photophysiological responses are relatively well understood in corals, little information is available regarding photoacclimation dynamics over weeks of altered light availability. We coupled photophysiology and metabolomic profiling to explore changes that accompany longer-term photoacclimation in a key Great Barrier Reef coral species, Acropora muricata. High light (HL)-and low light (LL)acclimated corals were collected from the reef and reciprocally exposed to high and low light ex situ. Rapid light curves using pulseamplitude modulation (PAM) fluorometry revealed photophysiological acclimation of LL corals to HL and HL corals to LL within 21 days. A subset of colonies sampled at 7 and 21 days for untargeted LC-MS and GC-MS metabolomic profiling revealed metabolic reorganization before acclimation was detected using PAM fluorometry. Metabolomic shifts were more pronounced for LL to HL corals than for their HL to LL counterparts. Compounds driving metabolomic separation between HL-exposed and LL control colonies included amino acids, organic acids, fatty acids and sterols. Reduced glycerol and campesterol suggest decreased translocation of photosynthetic products from symbiont to host in LL to HL corals, with concurrent increases in fatty acid abundance indicating reliance on stored lipids for energy. We discuss how these data provide novel insight into environmental regulation of metabolism and implications for management strategies that drive rapid changes in light availability.

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Section: Discussioncontrasting

confidence: 46%

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Lohr

Camp

Kuzhiumparambil

et al. 2019

Journal of Experimental Biology

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“…The consistency of our results with the literature [13,36,45] strongly supports the hypothesis that glucose is a major chemical form in the translocation of reduced carbon in the symbiosis of E. pallida. The possibility of glucose being synthesized from glycerol seems unlikely, being an energyconsuming path.…”

Section: Discussionsupporting

confidence: 81%

“…In contrast, thermally induced bleaching seems to have a minor effect on glucose metabolism for this anemone, as has been shown by Hillyer et al [36].…”

Section: Symbiont-dependent Metabolism In Exaiptasiamentioning

confidence: 58%

Experimentally Induced Bleaching in the Sea Anemone Exaiptasia Supports Glucose as a Main Metabolite Associated with Its Symbiosis

Molina

Castillo-Medina²,

Thomé³

2017

Journal of Marine Biology

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Our current understanding of carbon exchange between partners in the Symbiodinium-cnidarian symbioses is still limited, even though studies employing carbon isotopes have made us aware of the metabolic complexity of this exchange. We examined glycerol and glucose metabolism to better understand how photosynthates are exchanged between host and symbiont. The levels of these metabolites were compared between symbiotic and bleached Exaiptasia pallida anemones, assaying enzymes directly involved in their metabolism. We measured a significant decrease of glucose levels in bleached animals but a significant increase in glycerol and G3P pools, suggesting that bleached animals degrade lipids to compensate for the loss of symbionts and seem to rely on symbiotic glucose. The lower glycerol 3-phosphate dehydrogenase but higher glucose 6-phosphate dehydrogenase specific activities measured in bleached animals agree with a metabolic deficit mainly due to the loss of glucose from the ruptured symbiosis. These results corroborate previous observations on carbon translocation from symbiont to host in the sea anemone Exaiptasia, where glucose was proposed as a main translocated metabolite. To better understand photosynthate translocation and its regulation, additional research with other symbiotic cnidarians is needed, in particular, those with calcium carbonate skeletons.

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“…Glucose is thought to be the major photosynthetic product translocated from the algal symbiont to its cnidarian host (Burriesci et al, 2012; Hillyer et al, 2017). Results presented here suggest that, whereas in free-living Symbiodiniaceae fixed carbon in excess of immediate requirements likely accumulates in glycogen and/or starch, in symbiosis the balance shifts to glycogen / starch breakdown; limit dextrinase is upregulated to enable glucose mobilization, glycogen synthase is downregulated and the carbohydrate transporter R144.6 is activated.…”

Section: Discussionmentioning

confidence: 99%

Transcriptomic insights into the establishment of coral-algal symbioses from the symbiont perspective

Mohamed

Andrade

Moya

et al. 2019

Preprint

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Despite the ecological significance of the mutualistic relationship between Symbiodiniaceae and reef-building corals, the molecular machinery underpinning the establishment of this relationship is not well understood. This is especially true of the symbiont side, as previous attempts to understand the interaction between coral larvae and Symbiodiniaceae have focused nearly exclusively on the host. In the current study, Acropora tenuis planula larvae were exposed to a compatible strain of Symbiodiniaceae (Cladocopium) and the transcriptomic landscape of the symbiont profiled at 3, 12, 48 and 72 h post-exposure using RNA-Seq. The transcriptomic response of Cladocopium to the symbiotic state was complex, the most obvious feature being an extensive and generalised downregulation of gene expression. Included in this “symbiosis-derived transcriptional repression” were a range of stress response and immune-related genes. In contrast, genes implicated in metabolism were upregulated in the symbiotic state. Consistent with previous ecological studies, this transcriptomic response of Cladocopium implied that active translocation of metabolites to the host occurred, and thus that the mutualistic relationship can be established at the larval stage. This study provides novel insights into the transcriptomic remodelling that occurs in Symbiodiniaceae, with important implications for understanding the establishment of symbiosis between corals and their dinoflagellate partners.

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Mapping carbon fate during bleaching in a model cnidarian symbiosis: the application of ¹³C metabolomics

Cited by 62 publications

References 73 publications

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Experimentally Induced Bleaching in the Sea Anemone Exaiptasia Supports Glucose as a Main Metabolite Associated with Its Symbiosis

Transcriptomic insights into the establishment of coral-algal symbioses from the symbiont perspective

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Mapping carbon fate during bleaching in a model cnidarian symbiosis: the application of 13C metabolomics

Cited by 62 publications

References 73 publications

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Resolving coral photoacclimation dynamics through coupled photophysiological and metabolomic profiling

Experimentally Induced Bleaching in the Sea Anemone Exaiptasia Supports Glucose as a Main Metabolite Associated with Its Symbiosis

Transcriptomic insights into the establishment of coral-algal symbioses from the symbiont perspective

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Mapping carbon fate during bleaching in a model cnidarian symbiosis: the application of ¹³C metabolomics