Seawater carbonate chemistry and photosynthetic potential, cell density, lipid content of Symbiodinium

Dinoflagellates from the Symbiodiniaceae family and corals have an ecologically important endosymbiotic relationship. Scleractinian corals cannot survive for long periods without their symbionts. These algae, also known as zooxanthellae, on the other hand, thrives outside the coral cells. The free-l...

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Bibliographic Details
Main Authors: Hill, Lilian J, Paradas, Wladimir C, Willemes, Maria Julia, Pereira, Miria G, Salomon, Paulo S, Mariath, Rodrigo, Moura, Rodrigo L, Atella, Georgia C, Farina, Marcos, Amado-Filho, Gilberto M, Salgado, Leonardo T
Format: Dataset
Language:English
Published: PANGAEA 2019
Subjects:
pH
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.914234
https://doi.org/10.1594/PANGAEA.914234
Description
Summary:Dinoflagellates from the Symbiodiniaceae family and corals have an ecologically important endosymbiotic relationship. Scleractinian corals cannot survive for long periods without their symbionts. These algae, also known as zooxanthellae, on the other hand, thrives outside the coral cells. The free-living populations of zooxanthellae are essential for the resilience of the coral to environmental stressors such as temperature anomalies and ocean acidification. Yet, little is known about how ocean acidification may affect the free-living zooxanthellae. In this study we aimed to test morphological, physiological and biochemical responses of zooxanthellae from the Symbiodinium genus isolated from the coral Mussismilia braziliensis, endemic to the Brazilian coast, to acidification led by increased atmospheric CO2. We tested whether photosynthetic yield, cell ultrastructure, cell density and lipid profile would change after up to 16 days of exposure to pH 7.5 in an atmospheric pCO2 of 1633 μatm. Photosynthetic yield and cell density were negatively affected and chloroplasts showed vesiculated thylakoids, indicating morphological damage. Moreover, Symbiodinium fatty acid profile drastically changed in acidified condition, showing lower polyunsaturated fatty acids and higher saturated fatty acids contents, when compared to the control, non-acidified condition. These results show that seawater acidification as an only stressor causes significant changes in the physiology, biochemistry and ultrastructure of free-living Symbiodinium.