In Situ Geochemical Analysis of Organics in Growth Lines of Antarctic Scallop Shells: Implications for Sclerochronology

Bivalve shells are extensively used as bioarchives for paleoclimate and paleoenvironmental reconstructions. Proxy calibrations in recent shells are the basis for sclerochronology and the applications of geochemistry data to fossils. Shell geochemical information, however, could be altered with the d...

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Bibliographic Details
Published in:Minerals
Main Authors: Alberto Pérez-Huerta, Sally E. Walker, Chiara Cappelli
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2020
Subjects:
atom probe tomography (APT)
biomineralization
proteoglycans
carboxylic acid
Adamussium colbecki
Antarctica
Mineralogy
QE351-399.2
Antarctic
The Antarctic
Antarc*
Online Access:https://doi.org/10.3390/min10060529
https://doaj.org/article/af8653ecf8d1450ebbcaa2f202572ce1
Description
Summary:Bivalve shells are extensively used as bioarchives for paleoclimate and paleoenvironmental reconstructions. Proxy calibrations in recent shells are the basis for sclerochronology and the applications of geochemistry data to fossils. Shell geochemical information, however, could be altered with the disappearance of intercrystalline organic matrix components, including those linked to shell growth increments, during early diagenesis. Thus, an evaluation of the chemistry of such organics is needed for the correct use of sclerochronological records in fossil shells. Here, we use atom probe tomography (APT) for in situ geochemical characterization of the insoluble organic matrix in shell growth increments in the Antarctic scallop, Adamussium colbecki . We confirm the presence of carboxylated S-rich proteoglycans, possibly involved in calcite nucleation and growth in these scallops, with significant concentrations of magnesium and calcium. Diagenetic modification of these organic components could impact proxy data based on Mg/Ca ratios, but more importantly the use of the δ 15 N proxy, since most of the shell nitrogen is likely bound to the amide groups of proteins. Overall, our findings reinforce the idea that shell organics need to be accounted for in the understanding of geochemical proxies.

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