Journal
ECOLOGY AND EVOLUTION
Volume 5, Issue 21, Pages 4875-4884Publisher
WILEY
DOI: 10.1002/ece3.1756
Keywords
Biomineralization; CO; (2); mussels; ocean acidification; shell shape; shell thickness; temperature
Categories
Funding
- Leverhulme Trust [RPG-042]
- BBSRC [BB/E025110/1] Funding Source: UKRI
- Biotechnology and Biological Sciences Research Council [BB/E025110/1] Funding Source: researchfish
- Division Of Mathematical Sciences
- Direct For Mathematical & Physical Scien [1107046] Funding Source: National Science Foundation
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Ocean acidification threatens organisms that produce calcium carbonate shells by potentially generating an under-saturated carbonate environment. Resultant reduced calcification and growth, and subsequent dissolution of exoskeletons, would raise concerns over the ability of the shell to provide protection for the marine organism under ocean acidification and increased temperatures. We examined the impact of combined ocean acidification and temperature increase on shell formation of the economically important edible mussel Mytilus edulis. Shell growth and thickness along with a shell thickness index and shape analysis were determined. The ability of M.edulis to produce a functional protective shell after 9months of experimental culture under ocean acidification and increasing temperatures (380, 550, 750, 1000atm pCO(2), and 750, 1000atm pCO(2)+2 degrees C) was assessed. Mussel shells grown under ocean acidification conditions displayed significant reductions in shell aragonite thickness, shell thickness index, and changes to shell shape (750, 1000atm pCO(2)) compared to those shells grown under ambient conditions (380atm pCO(2)). Ocean acidification resulted in rounder, flatter mussel shells with thinner aragonite layers likely to be more vulnerable to fracture under changing environments and predation. The changes in shape presented here could present a compensatory mechanism to enhance protection against predators and changing environments under ocean acidification when mussels are unable to grow thicker shells. Here, we present the first assessment of mussel shell shape to determine implications for functional protection under ocean acidification.
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