Functional significance of genetically different symbiotic algae Symbiodinium in a coral reef symbiosis

The giant sea anemone Condylactis gigantea associates with members of two clades of the dinoflagellate alga Symbiodinium, either singly or in mixed infection, as revealed by clade‐specific quantitative polymerase chain reaction of large subunit ribosomal DNA. To explore the functional significance o...

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Bibliographic Details
Published in:Molecular ecology 2007-11, Vol.16 (22), p.4849-4857
Main Authors: LORAM, J. E., TRAPIDO-ROSENTHAL, H. G., DOUGLAS, A. E.
Format: Article
Language:English
Subjects:
Algae
Anemone - physiology
Animals
Carbon
Carbon - metabolism
Carbon Radioisotopes
Condylactis
Condylactis gigantea
coral
Coral reefs
Deoxyribonucleic acid
Dinoflagellida - genetics
Dinoflagellida - physiology
DNA
Flowers & plants
Genetics
Hot Temperature
Lipids
Marine
molecular diversity
photosynthate release
Photosynthesis
Symbiodinium
Symbiosis
Temperature
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Summary:The giant sea anemone Condylactis gigantea associates with members of two clades of the dinoflagellate alga Symbiodinium, either singly or in mixed infection, as revealed by clade‐specific quantitative polymerase chain reaction of large subunit ribosomal DNA. To explore the functional significance of this molecular variation, the fate of photosynthetically fixed carbon was investigated by 14C radiotracer experiments. Symbioses with algae of clades A and B released ca. 30–40% of fixed carbon to the animal tissues. Incorporation into the lipid fraction and the low molecular weight fraction dominated by amino acids was significantly higher in symbioses with algae of clade A than of clade B, suggesting that the genetically different algae in C. gigantea are not functionally equivalent. Symbioses with mixed infections yielded intermediate values, such that this functional trait of the symbiosis can be predicted from the traits of the contributing algae. Coral and sea anemone symbioses with Symbiodinium break down at elevated temperature, a process known as ‘coral bleaching’. The functional response of the C. gigantea symbiosis to heat stress varied between the algae of clades A and B, with particularly depressed incorporation of photosynthetic carbon into lipid of the clade B algae, which are more susceptible to high temperature than the algae of clade A. This study provides a first exploration of how the core symbiotic function of photosynthate transfer to the host varies with the genotype of Symbiodinium, an algal symbiont which underpins corals and, hence, coral reef ecosystems.
ISSN:0962-1083
1365-294X
DOI:10.1111/j.1365-294X.2007.03491.x