Acclimatory gene expression of primed clams enhances robustness to elevated p CO 2

• Published in: Molecular ecology Vol. 31; no. 19; pp. 5005 - 5023
• Main Authors: Gurr, Samuel J., Trigg, Shelly A., Vadopalas, Brent, Roberts, Steven B., Putnam, Hollie M.
• Format: Journal Article
• Language: English
• Published: 01.10.2022
• ISSN: 0962-1083; 1365-294X
• DOI: 10.1111/mec.16644

Abstract Sublethal exposure to environmental challenges may enhance ability to cope with chronic or repeated change, a process known as priming. In a previous study, pre‐exposure to seawater enriched with p CO 2 improved growth and reduced antioxidant capacity of juvenile Pacific geoduck Panopea generosa clams, suggesting that transcriptional shifts may drive phenotypic modifications post‐priming. To this end, juvenile clams were sampled and TagSeq gene expression data were analysed after (i) a 110‐day acclimation under ambient (921 μatm, naïve) and moderately elevated p CO 2 (2870 μatm, pre‐exposed); then following (ii) a second 7‐day exposure to three p CO 2 treatments (ambient: 754 μatm; moderately elevated: 2750 μatm; severely elevated: 4940 μatm), a 7‐day return to ambient p CO 2 and a third 7‐day exposure to two p CO 2 treatments (ambient: 967 μatm; moderately elevated: 3030 μatm). Pre‐exposed geoducks frontloaded genes for stress and apoptosis/innate immune response, homeostatic processes, protein degradation and transcriptional modifiers. Pre‐exposed geoducks were also responsive to subsequent encounters, with gene sets enriched for mitochondrial recycling and immune defence under elevated p CO 2 and energy metabolism and biosynthesis under ambient recovery. In contrast, gene sets with higher expression in naïve clams were enriched for fatty‐acid degradation and glutathione components, suggesting naïve clams could be depleting endogenous fuels, with unsustainable energetic requirements if changes in carbonate chemistry persist. Collectively, our transcriptomic data indicate that p CO 2 priming during post‐larval periods could, via gene expression regulation, enhance robustness in bivalves to environmental change. Such priming approaches may be beneficial for aquaculture, as seafood demand intensifies concurrent with increasing climate change in marine systems.