Abstract
The endosymbiosis between cnidarians and dinoflagellates of the genus Symbiodinium is key to the high productivity of tropical coral reefs. In this endosymbiosis, Symbiodinium translocate most of their photosynthates to their animal host in exchange for inorganic nutrients. Among these, carbon dioxide (CO2) derived from host respiration helps to meet the carbon requirements to sustain photosynthesis of the dinoflagellates. Nonetheless, recent studies suggest that productivity in symbiotic cnidarians such as corals is CO2-limited. Here we show that glucose enrichment stimulates respiration and gross photosynthesis rates by 80 and 140 %, respectively, in the symbiotic upside-down jellyfish Cassiopeia sp. from the Central Red Sea. Our findings show that glucose was rapidly consumed and respired within the Cassiopeia sp. holobiont. The resulting increase of CO2 availability in hospite in turn likely stimulated photosynthesis in Symbiodinium. Hence, the increase of photosynthesis under these conditions suggests that CO2 limitation of Symbiodinium is a common feature of stable cnidarian holobionts and that the stimulation of holobiont metabolism may attenuate this CO2 limitation.
Highlights
Despite being surrounded by highly nutrient-poor waters, tropical coral reefs are among the most productive marine ecosystems (Hatcher, 1988)
Symbiodinium translocate most of their photosynthates to the cnidarian host that in turn provides inorganic nutrients derived from its metabolism (Muscatine et al, 1989)
Glucose-stimulated Photosynthesis in Symbiodinium is controlled by two major processes: (1) CO2 is produced during holobiont respiration (Muscatine et al, 1989)
Summary
Despite being surrounded by highly nutrient-poor (oligotrophic) waters, tropical coral reefs are among the most productive marine ecosystems (Hatcher, 1988). Glucose-stimulated Photosynthesis in Symbiodinium is controlled by two major processes: (1) CO2 is produced during holobiont respiration (Muscatine et al, 1989). Several studies suggest that productivity in Symbiodinium may be carbon-limited even in stable symbiotic systems (Muscatine et al, 1989; Herfort et al, 2008; Klein et al, 2017).
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