Abstract
The teeth of all vertebrates predominantly comprise the same materials, but their lifespans vary widely: in stark contrast to mammals, shark teeth are functional only for weeks, rather than decades, making lifelong durability largely irrelevant. However, their diets are diverse and often mechanically demanding, and as such, their teeth should maintain a functional morphology, even in the face of extremely high and potentially damaging contact stresses. Here, we reconcile the dilemma between the need for an operative tooth geometry and the unavoidable damage inherent to feeding on hard foods, demonstrating that the tooth cusps of Port Jackson sharks, hard-shelled prey specialists, possess unusual microarchitecture that controls tooth erosion in a way that maintains functional cusp shape. The graded architecture in the enameloid provokes a location-specific damage response, combining chipping of outer enameloid and smooth wear of inner enameloid to preserve an efficient shape for grasping hard prey. Our discovery provides experimental support for the dominant theory that multi-layered tooth enameloid facilitated evolutionary diversification of shark ecologies.
Highlights
The teeth of all vertebrates predominantly comprise the same materials, but their lifespans vary widely: in stark contrast to mammals, shark teeth are functional only for weeks, rather than decades, making lifelong durability largely irrelevant
Many durophagous animals have molariform teeth for crushing, but the anterior pointed teeth of heterodontids are peculiar, since they are surely prone to extreme contact stresses, and mechanical erosion from grasping and feeding on hardshelled foods, and from the grit associated with feeding in sandy and coralline environments
We provide an in-depth analysis of the chemical, microscale and nanoscale structural composition, mechanical behavior, and damage mechanisms of the tooth enameloid of Port Jackson shark, providing an empirical performance test of enameloid tissue architectures thought to have been vital to shark dietary evolution
Summary
Micro-anatomical description of Port Jackson shark tooth enameloid. During their development, shark tooth “files”. In Port Jackson shark teeth, in addition to the expected drop in X-ray attenuation levels and mineral density between enameloid and dentin, we demonstrate a distinct gradient in X-ray attenuation within the enameloid layer, decreasing from the tooth surface toward the enameloid–dentin junction (Fig. 1d). This through-enameloid electron density gradient persisted even when teeth were scanned from different orientations (i.e., it was not a scanning artifact, such as from beam-hardening). In chitons (Cryptochiton stelleri)[31] or bloodworms (Glycera dibranchiata)[32], for example, metals (zinc, iron) are a
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