Abstract
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.
Highlights
IntroductionTropical symbiotic cnidarians are characterized by the metabolic exchange of organic carbon and nutrients with their symbiotic dinoflagellate partners, allowing them to prosper in oligotrophic waters [1, 2]
We measured a significant decrease of glucose levels in bleached animals but a significant increase in glycerol and Glycerol 3-phospate (G3P) pools, suggesting that bleached animals degrade lipids to compensate for the loss of symbionts and seem to rely on symbiotic glucose
Tropical symbiotic cnidarians are characterized by the metabolic exchange of organic carbon and nutrients with their symbiotic dinoflagellate partners, allowing them to prosper in oligotrophic waters [1, 2]
Summary
Tropical symbiotic cnidarians are characterized by the metabolic exchange of organic carbon and nutrients with their symbiotic dinoflagellate partners, allowing them to prosper in oligotrophic waters [1, 2]. The chemical identity of the organic carbon that is translocated from symbiont to host seems to be different depending on the organism. Excess carbon fixed by the symbionts cannot be used to their own advantage (i.e., increase in cell numbers), mainly due to the limitation of nitrogen and phosphorous of the symbiotic animals [15,16,17,18,19], a result of the nutrient-poor waters where they live.
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