Coastal acidification impacts on shell mineral structure of bivalve mollusks

Fitzer, S. C. , Torres Gabarda, S., Daly, L., Hughes, B., Dove, M., O'Connor, W., Potts, J., Scanes, P. and Byrne, M. (2018) Coastal acidification impacts on shell mineral structure of bivalve mollusks. Ecology and Evolution, 8(17), pp. 8973-8984. (doi: 10.1002/ece3.4416) (PMID:30271559) (PMCID:PMC6157695)

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Abstract

Ocean acidification is occurring globally through increasing CO2 absorption into the oceans creating particular concern for calcifying species. In addition to ocean acidification, near shore marine habitats are exposed to the deleterious effects of runoff from acid sulfate soils which also decreases environmental pH. This coastal acidification is being exacerbated by climate change‐driven sea‐level rise and catchment‐driven flooding. In response to reduction in habitat pH by ocean and coastal acidification, mollusks are predicted to produce thinner shells of lower structural integrity and reduced mechanical properties threatening mollusk aquaculture. Here, we present the first study to examine oyster biomineralization under acid sulfate soil acidification in a region where growth of commercial bivalve species has declined in recent decades. Examination of the crystallography of the shells of the Sydney rock oyster, Saccostrea glomerata, by electron back scatter diffraction analyses revealed that the signal of environmental acidification is evident in the structure of the biomineral. Saccostrea glomerata, shows phenotypic plasticity, as evident in the disruption of crystallographic control over biomineralization in populations living in coastal acidification sites. Our results indicate that reduced sizes of these oysters for commercial sale may be due to the limited capacity of oysters to biomineralize under acidification conditions. As the impact of this catchment source acidification will continue to be exacerbated by climate change with likely effects on coastal aquaculture in many places across the globe, management strategies will be required to maintain the sustainable culture of these key resources.

Item Type:Articles
Additional Information:Centre of Excellence for Environmental Decisions, Australian Research Council, Grant/Award Number: DP 1500102771; Natural Environment Research Council, Grant/Award Number: NE/N01409X/1
Status:Published
Refereed:Yes
Glasgow Author(s) Enlighten ID:Daly, Dr Luke and Fitzer, Dr Susan
Authors: Fitzer, S. C., Torres Gabarda, S., Daly, L., Hughes, B., Dove, M., O'Connor, W., Potts, J., Scanes, P., and Byrne, M.
College/School:College of Science and Engineering > School of Geographical and Earth Sciences
College of Science and Engineering > School of Geographical and Earth Sciences > Earth Sciences
Journal Name:Ecology and Evolution
Publisher:Wiley
ISSN:2045-7758
ISSN (Online):2045-7758
Published Online:14 August 2018
Copyright Holders:Copyright © 2018 The Authors
First Published:First published in Ecology and Evolution 8(17): 8973-8984
Publisher Policy:Reproduced under a Creative Commons License

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Project CodeAward NoProject NamePrincipal InvestigatorFunder's NameFunder RefLead Dept
716661An understanding of biomineralisation pathways is key to predict climate change impact on aquacultureSusan FitzerNatural Environment Research Council (NERC)NE/N01409X/1SCHOOL OF GEOGRAPHICAL & EARTH SCIENCES