Diskagma
Diskagma ("disc-like fragment") is a genus of problematic fossil from a Paleoproterozoic (2200 million years old) paleosol from South Africa, and significant as the oldest likely eukaryote and earliest evidence for megascopic life on land.[1]
Diskagma Temporal range: 2200 Ma | |
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Diskagma buttonii holotype, in thin section of 2200 million year old Waterval Onder paleosol, South Africa | |
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Genus: | Diskagma Retallack (2013) |
Type species | |
Diskagma buttonii Retallack (2013) |
Description
Diskagma buttonii is a small fossil less than 1mm in length found within the surface horizon of a Vertisol paleosol above the Hekpoort Basalt dated to 2200 million years old. The opacity of the matrix and the size of the fossil meant that its three dimensional structure required imaging by computer-assisted x-ray tomography using a cyclotron source[1] The fossils are shaped like an urn with an apical cup, which is filled with filamentous structures whose exact nature is uncertain due to recrystallization of the matrix under greenschist facies metamorphism. The base of these hollow urns is a system of hollow tubes running over the paleosol and connecting the urns into groups. The walls of Diskagma have scattered spiny or tubular extensions.
Biological affinities
Diskagma buttonii is a problematic fossil that has been named before its biological affinities have been understood. Its size and complexity suggest that it had the degree of cytoskeletal complexity found in eukaryotes, but it predates the other fossil candidate for the oldest eukaryote Grypania, now known to be 1800 million years old,[2] and at 2200 million years old is much older than molecular clock estimates for eukaryotes of 1600 million years.[3] Another similar fossil is Horodyskia. The size and hollow shape of Diskagma are similar to the living fungus Geosiphon, which is endosymbiotic with the cyanobacterium Nostoc. However, the apical cup and filaments are not seen in modern Geosiphon.
Paleoenvironmental significance
Diskagma buttonii dates to the Paleoproterozoic Great Oxygenation Event, a time of marked increase in atmospheric oxygenation compared with that of the Archean.[4] If, like the living Geosiphon, the central cavity of Diskagma housed a photosymbiont, it may have contributed to atmospheric oxygenation.
Although Precambrian landscapes are customarily regarded as barren as the surface of Mars, Diskagma is evidence for very early life on land. Furthermore, at 2200 million years old, Diskagma was larger than coeval marine microbes of the Gunflint Chert, and more complex than stromatolites.
References
- Retallack, G.J.; Krull, E.S.; Thackray, G.D.; Parkinson, D. (2013). "Problematic urn-shaped fossils from a Paleoproterozoic (2.2 Ga) paleosol in South Africa". Precambrian Research. 235: 71–87. Bibcode:2013PreR..235...71R. doi:10.1016/j.precamres.2013.05.015.
- Schneider, D.A.; Bickford, M.E.; Cannon, W.F.; Schulz, K.J.; Hamilton, M.A. (2002). "Age of volcanic rocks and syndepositional iron formations, Marquette Range Supergroup: implications for the tectonic setting of Paleoproterozoic iron formations of the Lake Superior region". Canadian Journal of Earth Sciences. 39 (6): 999–1012. Bibcode:2002CaJES..39..999S. doi:10.1139/e02-016.
- Hedges, S.B.; Kumar, S. (2009). The time tree of life. Oxford University Press, New York.
- Murakami, T.; Sreenivas, B.; Sharma, S.D.; and Sugimori, H. (2011). "Quantification of atmospheric oxygen levels during the Paleoproterozoic using paleosol compositions and iron oxidation kinetics". Geochimica et Cosmochimica Acta. 75 (14): 3982–4004. Bibcode:2011GeCoA..75.3982M. doi:10.1016/j.gca.2011.04.023.