Abstract
The record of the coevolution of oxygenic phototrophs and the environment is preserved in three forms: genomes of modern organisms, diverse geochemical signals of surface oxidation and diagnostic Proterozoic microfossils. When calibrated by fossils, genomic data form the basis of molecular clock analyses. However, different interpretations of the geochemical record, fossil calibrations and evolutionary models produce a wide range of age estimates that are often conflicting. Here, we show that multiple interpretations of the cyanobacterial fossil record are consistent with an Archean origin of crown-group Cyanobacteria. We further show that incorporating relative dating information from horizontal gene transfers greatly improves the precision of these age estimates, by both providing a novel empirical criterion for selecting evolutionary models, and increasing the stringency of sampling of posterior age estimates. Independent of any geochemical evidence or hypotheses, these results support oxygenic photosynthesis evolving at least several hundred million years before the Great Oxygenation Event (GOE), a rapid diversification of major cyanobacterial lineages around the time of the GOE, and a post-Cryogenian origin of extant marine picocyanobacterial diversity.
Highlights
The evolution of oxygenic photosynthesis dramatically expanded the role of biological processes in Earth’s geochemical cycles, altered the redox properties of Earth’s surface and increased the fluxes within the surface carbon cycle [1,2]
When only eukaryotic primary and secondary fossil calibrations were used as calibrations, they recovered substantially younger, but still very likely pre-Great Oxygenation Event (GOE) dates for crown Cyanobacteria
Age estimates for total group Cyanobacteria were similar under the CIR_nobd model, with the BE schema recovering a mean age of 3468 Ma with a 95% CI age range extending to 3716 Ma, and the BJ schema recovering a mean age of 3450 Ma, with a 95% CI age range extending to 3824 Ma
Summary
The evolution of oxygenic photosynthesis dramatically expanded the role of biological processes in Earth’s geochemical cycles, altered the redox properties of Earth’s surface and increased the fluxes within the surface carbon cycle [1,2]. HGTs represent cross-cutting events between genome lineages and, can establish the relative ages of donor and recipient clades This information has been used in several ways: propagating absolute date constraints along reticulated branches within gene trees [32,33]; establishing the temporal coexistence of lineages and consistency with fossil-calibrated divergence times [34]; co-estimating phylogenomic reconciliations and chronograms [35] or constraining the sampling of molecular clock posterior age estimates [19]. We demonstrate how the use of HGTs can improve model selection criteria and impose more stringent constraints on posterior subsampling for divergence time estimates These analyses provide consistent support for an Archean origin of crown Cyanobacteria, and a long history of Archean biogenic oxygen production, as well as more precise age estimates for other key divergences in bacterial evolutionary history
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