Early Archean origin of Photosystem <scp>II</scp>

Cardona, Tanai; Sánchez‐Baracaldo, Patricia; Rutherford, A. William; Larkum, Anthony W. D.

doi:10.1111/gbi.12322

Cited by 101 publications

(117 citation statements)

References 163 publications

(294 reference statements)

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“…Phylogenetic analyses mostly suggest that cyanobacteria originated by 2.8 Ga. Molecular clocks must be calibrated by physical evidence, and phylogenetic methods are themselves debated. While some argue that oxygenic photosynthesis evolved only 50 to 100 Ma before the GOE (115), most studies suggest an earlier Paleoarchean or Mesoarchean age [e.g., (3,118,119)].…”

Section: Archean Atmospheric Gasesmentioning

confidence: 99%

The Archean atmosphere

2020

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The atmosphere of the Archean eon—one-third of Earth’s history—is important for understanding the evolution of our planet and Earth-like exoplanets. New geological proxies combined with models constrain atmospheric composition. They imply surface O2 levels <10−6 times present, N2 levels that were similar to today or possibly a few times lower, and CO2 and CH4 levels ranging ~10 to 2500 and 102 to 104 times modern amounts, respectively. The greenhouse gas concentrations were sufficient to offset a fainter Sun. Climate moderation by the carbon cycle suggests average surface temperatures between 0° and 40°C, consistent with occasional glaciations. Isotopic mass fractionation of atmospheric xenon through the Archean until atmospheric oxygenation is best explained by drag of xenon ions by hydrogen escaping rapidly into space. These data imply that substantial loss of hydrogen oxidized the Earth. Despite these advances, detailed understanding of the coevolving solid Earth, biosphere, and atmosphere remains elusive, however.

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Section: Archean Atmospheric Gasesmentioning

confidence: 99%

The Archean atmosphere

2020

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“…The origin of oxygenic photosynthesis remains less tightly constrained, with some proxies (e.g., U-Th-Pb isotopic ratios) placing it as far back as 3.7 Ga (Rosing & Frei 2004), although unambiguous evidence from microfossils appears to date back only to 1.9 Ga (Lyons et al 2014;Fischer et al 2016). Despite this uncertainty, there are multiple grounds for contending that oxygenic photosynthesis may have evolved by 2.7 Ga, based on isotopic ratios, phylogenetics and microfossils (Buick 2008;Schirrmeister et al 2016), thus amounting to its emergence by at least several 100 Myr prior to the Great Oxidation Event at ∼ 2.4 Ga; see also Knoll et al (2016); Lingam & Loeb (2019c); Cardona et al (2019). In toto, it is not altogether unreasonable to surmise that both anoxygenic and oxygenic photosynthesis might have evolved over a time span ranging from 10 8 to 10 9 yrs after the origin of life on Earth.…”

Section: Timescales For the Evolution Of Photosynthesismentioning

confidence: 99%

Active Galactic Nuclei: Boon or Bane for Biota?

Lingam

Ginsburg

Bialy

2019

ApJ

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Active Galactic Nuclei (AGNs) emit substantial fluxes of high-energy electromagnetic radiation, and have therefore attracted some recent attention for their negative impact on galactic habitability. In this paper, we propose that AGNs may also engender the following beneficial effects: (i) prebiotic synthesis of biomolecular building blocks mediated by ultraviolet (UV) radiation, and (ii) powering photosynthesis on certain free-floating planets and moons. We also reassess the harmful biological impact of UV radiation originating from AGNs, and find that their significance could have been overestimated. Our calculations suggest that neither the positive nor negative ramifications stemming from a hypothetical AGN in the Milky Way are likely to affect putative biospheres in most of our Galaxy. On the other hand, we find that a sizable fraction of all planetary systems in galaxies with either disproportionately massive black holes (∼ 10 9−10 M ) or high stellar densities (e.g., compact dwarf galaxies) might be susceptible to both the beneficial and detrimental consequences of AGNs, with the former potentially encompassing a greater spatial extent than the latter.Corresponding author: Manasvi Lingam manasvi.lingam@cfa.harvard.edu 1 In actuality, our analysis applies to black holes at the centers of galaxies, which are not always "supermassive" ( 10 5 M ) in nature. However, for the sake of brevity, we employ the notation SMBHs henceforth for all central black holes.

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“…That the three different anoxygenic Type II reaction centers show distinct mechanisms of redox tuning on key positions around Bch M and other photochemical pigments could indicate that these lineages radiated soon after the L and M duplication. Furthermore, given that anoxygenic Type II reaction centers show up to five times faster rates of evolution than cyanobacterial PSII 30 and that the emergence of at least some of major clades of phototrophs with anoxygenic Type II reaction centers postdate the GEO 50 , it is possible that the duplication of L and M subunits, and the radiation of the known anoxygenic Type II reaction centers occurred after the origin of oxygenic photosynthesis 30 . Therefore, the idea that extant forms of anoxygenic phototrophy powered by heterodimeric Type II reaction centers represent a "primitive" form of photosynthesis is not supported by the available data.…”

Section: Discussionmentioning

confidence: 99%

“…A total of 14 L and 12 M amino acid sequences were collected from the compiled metagenome data. The sequences were added to a dataset of Type II reaction center subunits compiled before 30 , which included sequences from Cyanobacteria, Proteobacteria, and Chloroflexi. Sequence alignments were done in Clustal Omega 31 using 10 combined guide trees and Hidden Markov Model iterations.…”

Section: Reaction Center Evolution Analysesmentioning

confidence: 99%

Evolutionary Implications of Anoxygenic Phototrophy in the Bacterial PhylumCandidatusPalusbacterota (WPS-2)

Ward

Cardona

Holland‐Moritz

2019

Preprint

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Genome-resolved environmental metagenomic sequencing has uncovered substantial previously unrecognized microbial diversity relevant for understanding the ecology and evolution of the biosphere, providing a more nuanced view of the distribution and ecological significance of traits including phototrophy across diverse niches. Recently, the capacity for bacteriochlorophyll-based anoxygenic photosynthesis has been found in the uncultured bacterial WPS-2 clade that are in close association with boreal moss. Here, we use phylogenomic analysis to investigate the diversity and evolution of phototrophic WPS-2. We demonstrate that phototrophic WPS-2 show significant genetic and metabolic divergence from other phototrophic and non-phototrophic lineages. The genomes of these organisms encode a completely new family of anoxygenic Type II photochemical reaction centers and other phototrophy-related proteins that are both phylogenetically and structurally distinct from those found in previously described phototrophs. We propose the name Candidatus Palusbacterota for the phylum-level aerobic WPS-2 clade which contains phototrophic lineages, from the Latin for "bog bacteria", distinguishing it from the anaerobic, non-phototrophic sister phylum Candidatus Eremiobacterota for "desert bacteria", typically found in dry environments.

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Early Archean origin of Photosystem II

Cited by 101 publications

References 163 publications

The Archean atmosphere

The Archean atmosphere

Active Galactic Nuclei: Boon or Bane for Biota?

Evolutionary Implications of Anoxygenic Phototrophy in the Bacterial PhylumCandidatusPalusbacterota (WPS-2)

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