Characterisation of a Novel Retrovirus and a dsDNA Virus Infecting the Coral Algal Endosymbiont, Symbiodinium sp.

Karen Dawn Weynberg1, Matthew J Neave2, Peta L Clode3, Christian R Voolstra4, Christopher Brownlee5, Patrick Laffy1, Nicole Webster1, Rachel Levin6, Elisha Wood-Charlson7 and Madeleine JH van Oppen1, (1)Australian Institute for Marine Science, Townsville, Australia, (2)King Abdullah University of Science & Technology, Jeddah, Saudi Arabia, (3)University of Western Australia, CMCA, Perth, Australia, (4)King Abdullah University of Science and Technology, BESE/RSRC, Thuwal, Saudi Arabia, (5)University of New South Wales, BRIL, Sydney, Australia, (6)University of New South Wales, Sydney, Australia, (7)University of Hawaii at Manoa, Oceanography, Honolulu, HI, United States
Abstract:
Research into viruses associated with coral reefs is a newly emerging field. Corals form an important symbiotic relationship with the dinoflagellate species Symbiodinium, which the coral relies heavily upon for nutrients and calcification. Coral bleaching is the result of disruption of this symbiosis when the algae and/or its photosynthetic pigments are lost from the coral tissues. Environmental stressors, including elevated sea surface temperatures and increased UV light exposure, have been implicated in coral bleaching. We set out to test the hypothesis that Symbiodinium in culture plays host to a latent virus that switches to a lytic infection under stress, such as UV exposure or elevated temperature. Analysis of Symbiodinium cultures (isolated from corals on the Great Barrier Reef) using flow cytometry and transmission electron microscopy (TEM), revealed an active viral infection was ongoing, regardless of experimental conditions. Morphological analysis using TEM revealed filamentous and icosahedral virus-like particles associated with Symbiodinium cultures. We present genomic data of the virus assemblages isolated from cultured Symbiodinium cells that indicate this dinoflagellate is targeted by both a dsDNA virus, related to members of the Nucleo-Cytoplasmic Large dsDNA Virus family (NCLDV), and a novel ssRNA virus related to the Orthoretrovirinae. Further investigations are underway to detect viruses in freshly isolated Symbiodinium from reef corals and to compare these with viruses observed in laboratory cultures of this symbiotic alga. We aim to develop molecular diagnostic probes to detect viruses in field samples to help monitor and assess the impact of viruses in coral bleaching and other climate change-related events, which have huge implications for the health of coral reefs to future global climate scenarios.