Crystal growth kinetics as an architectural constraint on the evolution of molluscan shells

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

Abstract

Molluscan shells are a classic model system to study formation–structure–function relationships in biological materials and the process of biomineralized tissue morphogenesis. Typically, each shell consists of a number of highly mineralized ultrastructures, each characterized by a specific 3D mineral–organic architecture. Surprisingly, in some cases, despite the lack of a mutual biochemical toolkit for biomineralization or evidence of homology, shells from different independently evolved species contain similar ultrastructural motifs. In the present study, using a recently developed physical framework, which is based on an analogy to the process of directional solidification and simulated by phase-field modeling, we compare the process of ultrastructural morphogenesis of shells from 3 major molluscan classes: A bivalve Unio pictorum, a cephalopod Nautilus pompilius, and a gastropod Haliotis asinina. We demonstrate that the fabrication of these tissues is guided by the organisms by regulating the chemical and physical boundary conditions that control the growth kinetics of the mineral phase. This biomineralization concept is postulated to act as an architectural constraint on the evolution of molluscan shells by defining a morphospace of possible shell ultrastructures that is bounded by the thermodynamics and kinetics of crystal growth.

Details

Original languageEnglish
Pages (from-to)20388-20397
Number of pages10
JournalProceedings of the National Academy of Sciences of the United States of America : PNAS
Volume116
Issue number41
Publication statusPublished - 2019
Peer-reviewedYes

External IDs

Scopus 85073064629

Keywords

Library keywords