1. Hypoxia as a physiological cue and pathological stress for coral larvae
- Author
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Peter Harrison, David J. Suggett, Christian R. Voolstra, Katie Chartrand, David J. Hughes, Rachel Alderdice, Mathieu Pernice, Anny Cárdenas, Nadine M Boulotte, and Michael Kühl
- Subjects
0106 biological sciences ,Ocean deoxygenation ,Coral ,Biology ,010603 evolutionary biology ,01 natural sciences ,03 medical and health sciences ,Stress, Physiological ,ddc:570 ,Gene expression ,Genetics ,medicine ,gene expression profiling ,Animals ,14. Life underwater ,Epigenetics ,RNA-Seq ,Hypoxia ,Deoxygenation ,coral ,development ,Ecology, Evolution, Behavior and Systematics ,030304 developmental biology ,coral, development, gene expression profiling, hypoxia, RNA-Seq ,0303 health sciences ,hypoxia ,Coral Reefs ,fungi ,Hypoxia (medical) ,Anthozoa ,Phenotype ,Cell biology ,Gene expression profiling ,Larva ,medicine.symptom ,Cues - Abstract
Ocean deoxygenation events are intensifying worldwide and can rapidly drive adult corals into a state of metabolic crisis and bleaching-induced mortality, but whether coral larvae are subject to similar stress remains untested. We experimentally exposed apo-symbiotic coral larvae of Acropora selago to deoxygenation stress with subsequent reoxygenation aligned to their night-day light cycle, and followed their gene expression using RNA-Seq. After 12 h of deoxygenation stress (~2 mg O2 /L), coral planulae demonstrated a low expression of HIF-targeted hypoxia response genes concomitant with a significantly high expression of PHD2 (a promoter of HIFα proteasomal degradation), similar to corresponding adult corals. Despite exhibiting a consistent swimming phenotype compared to control samples, the differential gene expression observed in planulae exposed to deoxygenation-reoxygenation suggests a disruption of pathways involved in developmental regulation, mitochondrial activity, lipid metabolism, and O2 -sensitive epigenetic regulators. Importantly, we found that treated larvae exhibited a disruption in the expression of conserved HIF-targeted developmental regulators, for example, Homeobox (HOX) genes, corroborating how changes in external oxygen levels can affect animal development. We discuss how the observed deoxygenation responses may be indicative of a possible acclimation response or alternatively may imply negative latent impacts for coral larval fitness. published
- Published
- 2021
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