Ocean acidification induces distinct transcriptomic responses across life history stages of the sea urchin Heliocidaris erythrogramma
Autor: | Gregory A. Wray, Dione J. Deaker, Kathryn E. Smith, Hannah R Devens, Phillip L Davidson, Maria Byrne |
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Rok vydání: | 2020 |
Předmět: |
0106 biological sciences
0301 basic medicine Oceans and Seas Biology 010603 evolutionary biology 01 natural sciences Article Transcriptome 03 medical and health sciences biology.animal Genetic variation Genetics Animals Juvenile Anthocidaris Seawater 14. Life underwater Sea urchin Gene Ecology Evolution Behavior and Systematics Life Cycle Stages Marine larval ecology Ocean acidification Marine invertebrates Carbon Dioxide Hydrogen-Ion Concentration 030104 developmental biology 13. Climate action Evolutionary biology Sea Urchins |
Zdroj: | Mol Ecol |
ISSN: | 1365-294X 0962-1083 |
Popis: | Ocean acidification (OA) from seawater uptake of rising carbon dioxide emissions impairs development in marine invertebrates, particularly in calcifying species. Plasticity in gene expression is thought to mediate many of these physiological effects, but how these responses change across life history stages remains unclear. The abbreviated lecithotrophic development of the sea urchin Heliocidaris erythrogramma provides a valuable opportunity to analyse gene expression responses across a wide range of life history stages, including the benthic, post-metamorphic juvenile. We measured the transcriptional response to OA in H. erythrogramma at three stages of the life cycle (embryo, larva, and juvenile) in a controlled breeding design. The results reveal a broad range of strikingly stage-specific impacts of OA on transcription, including changes in the number and identity of affected genes; the magnitude, sign, and variance of their expression response; and the developmental trajectory of expression. The impact of OA on transcription was notably modest in relation to gene expression changes during unperturbed development and much smaller than genetic contributions from parentage. The latter result suggests that natural populations may provide an extensive genetic reservoir of resilience to OA. Taken together, these results highlight the complexity of the molecular response to OA, its substantial life history stage specificity, and the importance of contextualizing the transcriptional response to pH stress in light of normal development and standing genetic variation to better understand the capacity for marine invertebrates to adapt to OA. |
Databáze: | OpenAIRE |
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