A billion years of environmental stability and the emergence of eukaryotes: New data from northern Australia

doi:10.1130/0091-7613(1998)026<0555:ABYOES>2.3.CO;2

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A billion years of environmental stability and the emergence of eukaryotes: New data from northern Australia

M. D. Brasier¹ and J. F. Lindsay²

¹ Department of Earth Sciences, Oxford University, Parks Road, Oxford, United Kingdom
² Australian Geological Survey Organization, GPO Box 378, Canberra, ACT, Australia

Carbon isotopes through 6 km of fully cored drill holes in 1.7to 1.5 Ga carbonates of the Mount Isa and McArthur basins, Australia(which host the earliest known eukaryote biomarkers) providethe most comprehensive and best-dated ${delta}$ ¹³C stratigraphy yet obtainedfrom such ancient rocks. Both basins reveal remarkably stabletemporal ${delta}$ ¹³C trends (mean of –0.6 ${per thousand}$ ± 2 ${per thousand}$ PDB [Peedeebelemnite]) and confirm the impression of ${delta}$ ¹³C stasis between2.0 and 1.0 Ga, which, together with other evidence, suggesta prolonged period of stability in crustal dynamics, redox stateof surface environments, and planetary climate. This ${delta}$ ¹³C stasisis consistent with great stability in the carbon cycle controlled,we suggest, by P limitation of primary productivity. Recentevidence shows that P depletion is a major factor in obligateassociations between photosymbionts and host cells. We arguethat a billion years of stability in the carbon and nutrientcycles may have been the driving force that propelled prokaryotestoward photosymbiosis and the emergence of the autotrophic eukaryotecell.

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