Directional fabrication and dissolution of larval and juvenile oyster shells under ocean acidification

Biomineralization is one of the key biochemical processes in calcifying bivalve species such as oysters that is affected by ocean acidification (OA). Larval life stages of oysters are made of aragonite crystals whereas the adults are made of calcite and/or aragonite. Though both calcite and aragonit...

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Published in:Proceedings of the Royal Society. B, Biological sciences Biological sciences, 2023-01, Vol.290 (1991), p.20221216
Main Authors: Chandra Rajan, Kanmani, Li, Yang, Dang, Xin, Lim, Yong Kian, Suzuki, Michio, Lee, Seung Woo, Vengatesen, Thiyagarajan
Format: Article
Language:English
Subjects:
Animal Shells - chemistry
Animals
Calcium Carbonate - analysis
Carbon Dioxide - analysis
Crassostrea
Global Change and Conservation
Hydrogen-Ion Concentration
Larva
Ocean Acidification
Seawater - chemistry
Solubility
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Summary:Biomineralization is one of the key biochemical processes in calcifying bivalve species such as oysters that is affected by ocean acidification (OA). Larval life stages of oysters are made of aragonite crystals whereas the adults are made of calcite and/or aragonite. Though both calcite and aragonite are crystal polymorphs of calcium carbonate, they have different mechanical properties and hence it is important to study the micro and nano structure of different life stages of oyster shells under OA to understand the mechanisms by which OA affects biomineralization ontogeny. Here, we have studied the larval and juvenile life stages of an economically and ecologically important estuarine oyster species, , under OA with focus over shell fabrication under OA (pH 7.4). We also look at the effect of parental exposure to OA on larvae and juvenile microstructure. The micro and nanostructure characterization reveals directional fabrication of oyster shells, with more organized structure as biomineralization progresses. Under OA, both the larval and juvenile stages show directional dissolution, i.e. the earlier formed shell layers undergo dissolution at first, owing to longer exposure time. Despite dissolution, the micro and nanostructure of the shell remains unaffected under OA, irrespective of parental exposure history.
ISSN:0962-8452
1471-2954
DOI:10.1098/rspb.2022.1216