Plasticity in organic composition maintains biomechanical performance in shells of juvenile scallops exposed to altered temperature and pH conditions
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Nature
Date
2021-12-17Referencia bibliográfica
Lagos, N.A... [et al.]. Plasticity in organic composition maintains biomechanical performance in shells of juvenile scallops exposed to altered temperature and pH conditions. Sci Rep 11, 24201 (2021). [https://doi.org/10.1038/s41598-021-03532-0]
Sponsorship
PIA ANID ACT 172037; Comision Nacional de Investigacion Cientifica y Tecnologica (CONICYT) CONICYT FONDECYT 1190444 1210171; ANID - Millennium Science Initiative Program ICN2019_015; ANID doctoral scholarhip 21210012; ANID PFCHA / Doctorados Becas Chile Chile/2019-CEL00011051Abstract
The exposure to environmental variations in pH and temperature has proven impacts on benthic
ectotherms calcifiers, as evidenced by tradeoffs between physiological processes. However, how
these stressors affect structure and functionality of mollusk shells has received less attention. Episodic
events of upwelling of deep cold and low pH waters are well documented in eastern boundary systems
and may be stressful to mollusks, impairing both physiological and biomechanical performance.
These events are projected to become more intense, and extensive in time with ongoing global
warming. In this study, we evaluate the independent and interactive effects of temperature and pH
on the biomineral and biomechanical properties of Argopecten purpuratus scallop shells. Total organic
matter in the shell mineral increased under reduced pH (~ 7.7) and control conditions (pH ~ 8.0). The
periostracum layer coating the outer shell surface showed increased protein content under low pH
conditions but decreasing sulfate and polysaccharides content. Reduced pH negatively impacts shell
density and increases the disorder in the orientation of calcite crystals. At elevated temperatures
(18 °C), shell microhardness increased. Other biomechanical properties were not affected by pH/
temperature treatments. Thus, under a reduction of 0.3 pH units and low temperature, the response
of A. purpuratus was a tradeoff among organic compounds (biopolymer plasticity), density, and
crystal organization (mineral plasticity) to maintain shell biomechanical performance, while increased
temperature ameliorated the impacts on shell hardness. Biopolymer plasticity was associated with
ecophysiological performance, indicating that, under the influence of natural fluctuations in pH and
temperature, energetic constraints might be critical in modulating the long-term sustainability of this
compensatory mechanism.