Possible evolution of mobile animals in association with microbial mats

Gingras, Murray K.; Hagadorn, James W.; Seilacher, Adolf; Lalonde, Stefan V.; Peçoits, Ernesto; Petrash, Daniel A.; Konhauser, Kurt O.

doi:10.1038/ngeo1142

Cited by 124 publications

(95 citation statements)

References 23 publications

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“…This is reflected by a switch from the absence to presence of carbonate-bound iodine (Hardisty et al, 2014). Such a record indicates the potential for habitable marine environments, at least in terms of minimum O 2 thresholds, hundreds of millions of years before the first evidence for animal life or eukaryotic diversification (Gingras et al, 2011;Knoll, 2014).…”

Section: Iodinementioning

confidence: 99%

Trace elements at the intersection of marine biological and geochemical evolution

Robbins

Lalonde

Planavsky

et al. 2016

Earth-Science Reviews

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158

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Life requires a wide variety of bioessential trace elements to act as structural components and reactive centers in metalloenzymes. These requirements differ between organisms and have evolved over geological time, likely guided in some part by environmental conditions. Until recently, most of what was understood regarding trace element concentrations in the Precambrian oceans was inferred by extrapolation, geochemical modeling, and/or genomic studies. However, in the past decade, the increasing availability of trace element and isotopic data for sedimentary rocks of all ages have yielded new, and potentially more direct, insights into secular changes in seawater composition -and ultimately the evolution of the marine biosphere. Compiled records of many bioessential trace elements (including Ni, Mo, P, Zn, Co, Cr, Se, and I) provide new insight into how trace element abundance in Earth's ancient oceans may have been linked to biological evolution. Several of these trace elements display redox-sensitive behavior, while others are redox-sensitive but not bioessential (e.g., Cr, U). Their temporal trends in sedimentary archives provide useful constraints on changes in atmosphere-ocean redox conditions that are linked to biological evolution, for example, the activity of oxygen-producing, photosynthetic cyanobacteria. In this review, we summarize available Precambrian trace element proxy data, and discuss how temporal trends in the seawater concentrations of specific trace elements may be linked to the evolution of both simple and complex life. We also examine several biologically relevant and/or redox-sensitive trace elements that have yet to be fully examined in the A C C E P T E D M A N U S C R I P T ACCEPTED MANUSCRIPT3 sedimentary rock record (e.g., Cu, Cd, W) and suggest several directions for future studies.

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Section: Iodinementioning

confidence: 99%

Trace elements at the intersection of marine biological and geochemical evolution

Robbins

Lalonde

Planavsky

et al. 2016

Earth-Science Reviews

Self Cite

158

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“…Under such a scenario, oxygen produced by the benthic microbial community would be consumed proximal to the mat, much as is observed in some modern mat systems (e.g., Gingras et al, 2011;Sumner et al, 2015).…”

Section: Iron Formations Primary Productivity and Atmospheric Oxygementioning

confidence: 99%

Iron formations: A global record of Neoarchaean to Palaeoproterozoic environmental history

Konhauser

Planavsky

Hardisty

et al. 2017

Earth-Science Reviews

364

257

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“…Moreover, they note that the aggressively oxidizing environments generated diurnally by cyanobacterial oxygen production within mats (e.g., Gingras et al 2011) would have destroyed lipids sourced from the overlying water column. In consequence, the lack of steranes in most Proterozoic shales may simply reflect preservational circumstances common before the Ediacaran Period, when evolving animals dramatically restricted the distribution of benthic mat communities.…”

Section: Paleobiology Of Early Eukaryotesmentioning

confidence: 99%