Abstract
Carbonate concretions are known to contain well-preserved fossils and soft tissues. Recently, biomolecules (e.g. cholesterol) and molecular fossils (biomarkers) were also discovered in a 380 million-year-old concretion, revealing their importance in exceptional preservation of biosignatures. Here, we used a range of microanalytical techniques, biomarkers and compound specific isotope analyses to report the presence of red and white blood cell-like structures as well as platelet-like structures, collagen and cholesterol in an ichthyosaur bone encapsulated in a carbonate concretion from the Early Jurassic (~182.7 Ma). The red blood cell-like structures are four to five times smaller than those identified in modern organisms. Transmission electron microscopy (TEM) analysis revealed that the red blood cell-like structures are organic in composition. We propose that the small size of the blood cell-like structures results from an evolutionary adaptation to the prolonged low oxygen atmospheric levels prevailing during the 70 Ma when ichthyosaurs thrived. The δ13C of the ichthyosaur bone cholesterol indicates that it largely derives from a higher level in the food chain and is consistent with a fish and cephalopod diet. The combined findings above demonstrate that carbonate concretions create isolated environments that promote exceptional preservation of fragile tissues and biomolecules.
Highlights
Dinosaur fossils, even with the most beautifully preserved anatomy, generally lack soft tissues such as fibrous or cellular remains as well as biomolecules or molecular fossils
The latter finding was remarkable considering the fact that the bone fragments were not well preserved, which is in agreement with models suggesting that preservation of biomolecules and soft tissues in the fossil record is more common than previously thought[8,9,10,11]
Early post mortem encapsulation led to preservation of the bone tissue in the concretion
Summary
Even with the most beautifully preserved anatomy, generally lack soft tissues such as fibrous or cellular remains as well as biomolecules or molecular fossils. Red blood cell (RBC)-like structures, along with amino acids associated with collagen-like fibres, were found in 75 million-year-old dinosaur bones[8] The latter finding was remarkable considering the fact that the bone fragments were not well preserved, which is in agreement with models suggesting that preservation of biomolecules and soft tissues in the fossil record is more common than previously thought[8,9,10,11]. Excellent for tissues and biomolecules due to water column stratification and strong euxinic conditions in the bottom waters[15,16] Under these euxinic conditions, organic matter-rich mudstones were deposited and the diagenetic formation of carbonate concretions was common[17]. Such carbonate concretions often contain fossils[18,19] or, in some exceptional cases, even biomolecules[20,21]
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