Image_3_Examining the impacts of elevated, variable pCO2 on larval Pacific razor clams (Siliqua patula) in Alaska.pdf

An increase in anthropogenic carbon dioxide is driving oceanic chemical shifts resulting in a long-term global decrease in ocean pH, colloquially termed ocean acidification (OA). Previous studies have demonstrated that OA can have negative physiological consequences for calcifying organisms, especia...

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Bibliographic Details
Main Authors: Marina W. Alcantar, Jeff Hetrick, Jacqueline Ramsay, Amanda L. Kelley
Format: Still Image
Language:unknown
Published: 2024
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
ocean acidification
vaterite
biomineralogy
Siliqua patula
variability
larval response
amorphous calcium carbonate (ACC)
Pacific
Ocean acidification
Online Access:https://doi.org/10.3389/fmars.2024.1253702.s003
https://figshare.com/articles/figure/Image_3_Examining_the_impacts_of_elevated_variable_pCO2_on_larval_Pacific_razor_clams_Siliqua_patula_in_Alaska_pdf/25052114
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Summary:An increase in anthropogenic carbon dioxide is driving oceanic chemical shifts resulting in a long-term global decrease in ocean pH, colloquially termed ocean acidification (OA). Previous studies have demonstrated that OA can have negative physiological consequences for calcifying organisms, especially during early life-history stages. However, much of the previous research has focused on static exposure to future OA conditions, rather than variable exposure to elevated pCO 2 , which is more ecologically relevant for nearshore species. This study examines the effects of OA on embryonic and larval Pacific razor clams (Siliqua patula), a bivalve that produces a concretion during early shell development. Larvae were spawned and cultured over 28 days under three pCO 2 treatments: a static high pCO 2 of 867 μatm, a variable, diel pCO 2 of 357 to 867 μatm, and an ambient pCO 2 of 357 μatm. Our results indicate that the calcium carbonate polymorphism of the concretion phase of S. patula was amorphous calcium carbonate which transitioned to vaterite during the advanced D-veliger stage, with a final polymorphic shift to aragonite in adults, suggesting an increased vulnerability to dissolution under OA. However, exposure to elevated pCO 2 appeared to accelerate the transition of larval S. patula from the concretion stage of shell development to complete calcification. There was no significant impact of OA exposure to elevated or variable pCO 2 conditions on S. patula growth or HSP70 and calmodulin gene expression. This is the first experimental study examining the response of a concretion producing bivalve to future predicted OA conditions and has important implications for experimentation on larval mollusks and bivalve management.

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