Geochemical Fingerprints of Ginkgoales Across the Triassic-Jurassic Boundary of Greenland

Premise of research. Geochemical fingerprinting of fossil plants is a relatively new research field complementing morphological analyses and providing information for paleoenvironmental interpretations. Ginkgoales contains a single extant species but was diverse through the Mesozoic and is an excell...

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Bibliographic Details
Published in:International Journal of Plant Sciences
Main Authors: Vajda, Vivi, Pucetaite, Milda, Steinthorsdottir, Margret
Format: Article in Journal/Newspaper
Language:English
Published: Naturhistoriska riksmuseet, Enheten för paleobiologi 2021
Subjects:
paleobotany
Ginkgo
chemotaxonomy
proteins
CO2
climate
Biochemistry and Molecular Biology
Biokemi och molekylärbiologi
Geosciences
Multidisciplinary
Multidisciplinär geovetenskap
Biophysics
Biofysik
Botany
Botanik
Other Earth and Related Environmental Sciences
Annan geovetenskap och miljövetenskap
Greenland
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:nrm:diva-4336
https://doi.org/10.1086/715506
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Summary:Premise of research. Geochemical fingerprinting of fossil plants is a relatively new research field complementing morphological analyses and providing information for paleoenvironmental interpretations. Ginkgoales contains a single extant species but was diverse through the Mesozoic and is an excellent target for biochemical analyses. Methodology. Cuticles derived from fresh and fallen autumn leaves of extant Ginkgo biloba and seven fossil gink- goalean leaf taxa, one seed fern taxon, and two taxa with bennettitalean affinity were analyzed by infrared (IR) microspec- troscopy at the D7 beamline in the MAX IV synchrotron laboratory, Sweden. The fossil material derives from Triassic and Jurassic successions of Greenland. Spectral data sets were compared and evaluated by hierarchical cluster analysis (HCA) and principal component analysis performed on vector-normalized, first-derivative IR absorption spectra. Pivotal results. The IR absorption spectra of the fossil leaves all reveal signatures that clearly indicate the pres- ence of organic compounds. Spectra of the extant G. biloba leaves reveal the presence of aliphatic chains, aromatic and ester carbonyl functional groups from polymer cutin and other waxy compounds, and polysaccharides. Inter- estingly, both the extant autumn leaves and the fossil specimens reveal the presence of carboxyl/ketone molecules, suggesting that chemical alterations during the initial stages of decomposition are preserved through fossilization. Two major subclusters were identified through HCA of the fossil spectra. Conclusions. Consistent chemical IR signatures, specific for each fossil taxon are present in cuticles, and suf- ficient molecular content is preserved in key regions to reflect the plants’ original chemical signatures. The alter- ations of the organic compounds are initiated as soon as the leaves are shed, with loss of proteins and increased ester and carboxyl/ketone compound production in the fallen leaves. We further show that the groupings of taxa reflect a combination of phylogeny and environmental conditions related to the end-Triassic event. Also funded by a Utrecht NetworkYoung Researchers grant to M. Pucetaite

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