Host starvation and in hospite degradation of algal symbionts shape the heat stress response of the Cassiopea-Symbiodiniaceae symbiosis

Détails

Ressource 1Télécharger: Toullec et al_2024_Host starvation and in hospite degradartion.pdf (2412.16 [Ko])
Etat: Public
Version: Final published version
Licence: CC BY 4.0
ID Serval
serval:BIB_B39FB92537EC
Type
Autre: (aucun autre type ne convient)
Collection
Publications
Institution
Titre
Host starvation and in hospite degradation of algal symbionts shape the heat stress response of the Cassiopea-Symbiodiniaceae symbiosis
Auteur⸱e⸱s
Toullec G., Rädecker N., Pogoreutz C., Banc-Prandi G., Escrig S., Genoud C., Olmos C. M., Spangenberg J., Meibom A.
ISSN
2049-2618
Date de publication
29/02/2024
Langue
anglais
Résumé
Background
Global warming is causing large-scale disruption of cnidarian-Symbiodiniaceae symbioses fundamental to major marine ecosystems, such as coral reefs. However, the mechanisms by which heat stress perturbs these symbiotic partnerships remain poorly understood. In this context, the upside-down jellyfish Cassiopea has emerged as a powerful experimental model system.
Results
We combined a controlled heat stress experiment with isotope labeling and correlative SEM-NanoSIMS imaging to show that host starvation is a central component in the chain of events that ultimately leads to the collapse of the Cassiopea holobiont. Heat stress caused an increase in catabolic activity and a depletion of carbon reserves in the unfed host, concurrent with a reduction in the supply of photosynthates from its algal symbionts. This state of host starvation was accompanied by pronounced in hospite degradation of algal symbionts, which may be a distinct feature of the heat stress response of Cassiopea. Interestingly, this loss of symbionts by degradation was concealed by body shrinkage of the starving animals, resulting in what could be referred to as “invisible” bleaching.
Conclusions
Overall, our study highlights the importance of the nutritional status in the heat stress response of the Cassiopea holobiont. Compared with other symbiotic cnidarians, the large mesoglea of Cassiopea, with its structural sugar and protein content, may constitute an energy reservoir capable of delaying starvation. It seems plausible that this anatomical feature at least partly contributes to the relatively high stress tolerance of these animals in rapidly warming oceans.
Mots-clé
Climate change, Photosymbiosis, Cnidaria, Symbiodiniaceae, Bleaching, Metabolism, NanoSIMS
Pubmed
Open Access
Oui
Financement(s)
Fonds national suisse / 200021_179092
Fonds national suisse / 200021_179092
Fonds national suisse / 212614
Fonds national suisse / 200021_179092
Création de la notice
23/11/2023 9:37
Dernière modification de la notice
06/03/2024 7:16
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