First paleoproteome study of fossil fish otoliths and the pristine preservation of the biomineral crystal host

Otoliths are calcium carbonate components of the stato-acoustical organ responsible for hearing and maintenance of the body balance in teleost fish. During their formation, control over, e.g., morphology and carbonate polymorph is influenced by complex insoluble collagen-like protein and soluble non...

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Published in:Scientific reports 2023-03, Vol.13 (1), p.3822-3822, Article 3822
Main Authors: Stolarski, Jarosław, Drake, Jeana, Coronado, Ismael, Vieira, Ana R., Radwańska, Urszula, Heath-Heckman, Elizabeth A. C., Mazur, Maciej, Guo, Jinming, Meibom, Anders
Format: Article
Language:English
Subjects:
631/181/414
704/2151/414
Acoustics
Animals
Calcium Carbonate
Collagen
Contamination
Crystal structure
Fish Proteins
Fishes
Fossils
Humanities and Social Sciences
Inner ear
Isoforms
Mineralization
Miocene
multidisciplinary
Otolithic Membrane
Otoliths
Preservation
Proteins
Science
Science (multidisciplinary)
Sensory epithelium
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Summary:Otoliths are calcium carbonate components of the stato-acoustical organ responsible for hearing and maintenance of the body balance in teleost fish. During their formation, control over, e.g., morphology and carbonate polymorph is influenced by complex insoluble collagen-like protein and soluble non-collagenous protein assemblages; many of these proteins are incorporated into their aragonite crystal structure. However, in the fossil record these proteins are considered lost through diagenetic processes, hampering studies of past biomineralization mechanisms. Here we report the presence of 11 fish-specific proteins (and several isoforms) in Miocene (ca. 14.8–14.6 Ma) phycid hake otoliths. These fossil otoliths were preserved in water-impermeable clays and exhibit microscopic and crystallographic features indistinguishable from modern representatives, consistent with an exceptionally pristine state of preservation. Indeed, these fossil otoliths retain ca. 10% of the proteins sequenced from modern counterparts, including proteins specific to inner ear development, such as otolin-1-like proteins involved in the arrangement of the otoliths into the sensory epithelium and otogelin/otogelin-like proteins that are located in the acellular membranes of the inner ear in modern fish. The specificity of these proteins excludes the possibility of external contamination. Identification of a fraction of identical proteins in modern and fossil phycid hake otoliths implies a highly conserved inner ear biomineralization process through time.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-023-30537-8