Geological constraints on the origin of oxygenic photosynthesis

Farquhar, James; Zerkle, Aubrey L.; Bekker, Andrey

doi:10.1007/s11120-010-9594-0

Cited by 213 publications

(133 citation statements)

References 181 publications

(260 reference statements)

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“…The GOE represents a transition from an atmosphere that was essentially devoid of free oxygen (O 2 << 10 -5 PAL) to one with O 2 concentrations >10 -5 PAL, where estimates of oxygen levels are based on modelling massindependent S isotope (S-MIF) variations (Pavlov and Kasting, 2002). In the rock record, this event is manifested by a number of changes (see Farquhar et al, 2011Farquhar et al, , 2014, for reviews), including (1) loss of easily oxidisable detrital uraninite, pyrite, and siderite from fluvial siliciclastic sediments at ca. 2.4 Ga (e.g., Rasmussen and Buick, 1999;England et al, 2002;Hofmann et al, 2009;Johnson et al, 2014); (2) loss of iron from ancient soil horizons (paleosols) older than ca.…”

Section: Neoarchaean-palaeoproterozoic Iron Formationsmentioning

confidence: 99%

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

Konhauser

Planavsky

Hardisty

et al. 2017

Earth-Science Reviews

360

257

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Section: Neoarchaean-palaeoproterozoic Iron Formationsmentioning

confidence: 99%

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

Konhauser

Planavsky

Hardisty

et al. 2017

Earth-Science Reviews

360

257

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“…The Precambrian evolution of the oxygenated atmosphere was strongly coupled to the evolution of oxygenic photosynthesis (Farquhar, Zerkle, & Bekker, 2011). There are numerous pathways for the uptake of carbon from the environment (Boyle and Morgan, 2011), but the Rubisco protein catalyzes the addition of CO 2 and H 2 O to 1,5‐ribulose bisphosphate (RuBP) in the first major step of carbon fixation through photosynthesis.…”

Section: Introductionmentioning

confidence: 99%

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

et al. 2017

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Ribulose 1,5‐bisphosphate (RuBP) carboxylase/oxygenase (RuBisCO, or Rubisco) catalyzes a key reaction by which inorganic carbon is converted into organic carbon in the metabolism of many aerobic and anaerobic organisms. Across the broader Rubisco protein family, homologs exhibit diverse biochemical characteristics and metabolic functions, but the evolutionary origins of this diversity are unclear. Evidence of the timing of Rubisco family emergence and diversification of its different forms has been obscured by a meager paleontological record of early Earth biota, their subcellular physiology and metabolic components. Here, we use computational models to reconstruct a Rubisco family phylogenetic tree, ancestral amino acid sequences at branching points on the tree, and protein structures for several key ancestors. Analysis of historic substitutions with respect to their structural locations shows that there were distinct periods of amino acid substitution enrichment above background levels near and within its oxygen‐sensitive active site and subunit interfaces over the divergence between Form III (associated with anoxia) and Form I (associated with oxia) groups in its evolutionary history. One possible interpretation is that these periods of substitutional enrichment are coincident with oxidative stress exerted by the rise of oxygenic photosynthesis in the Precambrian era. Our interpretation implies that the periods of Rubisco substitutional enrichment inferred near the transition from anaerobic Form III to aerobic Form I ancestral sequences predate the acquisition of Rubisco by fully derived cyanobacterial (i.e., dual photosystem‐bearing, oxygen‐evolving) clades. The partitioning of extant lineages at high clade levels within our Rubisco phylogeny indicates that horizontal transfer of Rubisco is a relatively infrequent event. Therefore, it is possible that the mutational enrichment periods between the Form III and Form I common ancestral sequences correspond to the adaptation of key oxygen‐sensitive components of Rubisco prior to, or coincident with, the Great Oxidation Event.

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“…The deposition of sedimentary organic matter also can also be correlated with changes in the nitrogen cycle (Farquhar et al 2010 and references therein) that would likely have involved the cyanobacteria as significant contributors. However, the general assumption is that much of the fixed carbon in sediments is from anoxic photosynthetic bacteria, the presumed independent progenitors of the photosynthetic reaction centers (RCI, RCII).…”

Section: Two Photosystems and The Water Splitting Complexmentioning

confidence: 99%

“…The co-editors of this volume (Gantt and Falkowski) have invited specialists from a broad range of disciplines to benefit those readers interested in a comprehensive understanding of oxygenic photosynthesis. Major topics being addressed in the accompanying series of articles relate to the evidence and time-lines of oxygenic photosynthesis on the earth (Farquhar et al 2010), the resultant gains of an aerobic atmosphere and the increase in organismal size and diversity, as well as multicellularity (Payne et al 2010). At the organismal level, some of the biggest questions are: what were the original key characteristics from which the photosynthetic reaction centers were derived (Allen and Williams 2010), what essential changes were required for electron production by the water splitting complex (Williamson et al 2010), and what is the evidence for the timeline of how long cyanobacteria have been around (Schopf 2010)?…”

Section: Introductionmentioning

confidence: 99%

“…Among geologists and geochemists, it is generally agreed that the atmosphere and oceans were devoid of oxygen until ca. 2.45 BYa, the time of the great oxidation event (Canfield 2005;Farquhar et al 2010). Yet considerable allowances have to be made for a lag in time, differences in local environments before the notable O 2 rise resulted in a transition from anoxia to the estimated ca.…”

Section: Introductionmentioning

confidence: 99%

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Oxygenic photosynthesis and the distribution of chloroplasts

Gantt

2010

Photosynth Res

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The integrated functioning of two photosystems (I and II) whether in cyanobacteria or in chloroplasts is the outstanding sign of a common ancestral origin. Many variations on the basic theme are currently evident in oxygenic photosynthetic organisms whether they are prokaryotes, unicellular, or multicellular. By conservative estimates, oxygenic photosynthesis has been around for at least ca. 2.2-2.7 billions years, consistent with cyanobacteria-type microfossils, biomarkers, and an atmospheric rise in oxygen to less than 1.0% of the present concentration. The presumptions of chloroplast formation by the cyanobacterial uptake into a eukaryote prior to 1.6 BYa ago are confounded by assumptions of host type(s) and potential tolerance of oxygen toxicity. The attempted dating and interrelationships of particular chloroplasts in various plant or animal lineages has relied heavily on phylogenomic analysis and evaluations that have been difficult to confirm separately. Many variations occur in algal groups, involving the type and number of accessory pigments, and the number(s) of membranes (2-4) enclosing a chloroplast, which can both help and complicate inferences made about early or late origins of chloroplasts. Integration of updated phylogenomics with physiological and cytological observations remains a special challenge, but could lead to more accurate assumptions of initial and extant endosymbiotic event(s) leading toward stable chloroplast associations.

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Geological constraints on the origin of oxygenic photosynthesis

Cited by 213 publications

References 181 publications

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

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

Constraining the timing of the Great Oxidation Event within the Rubisco phylogenetic tree

Oxygenic photosynthesis and the distribution of chloroplasts

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