2020
DOI: 10.1098/rsfs.2019.0101
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Harnessing hypoxia as an evolutionary driver of complex multicellularity

Abstract: Animal tissue requires low-oxygen conditions for its maintenance. The need for low-oxygen conditions contrasts with the idea of an evolutionary leap in animal diversity as a result of expanding oxic conditions. To accommodate tissue renewal at oxic conditions, however, vertebrate animals and vascular plants demonstrate abilities to access hypoxia. Here, I argue that multicellular organisms sustain oxic conditions first after internalizing hypoxic conditions. The ‘harnessing’ of hypoxia has allowed multicellula… Show more

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Cited by 17 publications
(13 citation statements)
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References 105 publications
(146 reference statements)
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“…Dates of emergence of animal-specific NAD-IDH subunit β (~ 1249 Ma) and NAD-IDH subunit γ (~ 1532 Ma) provide support for an earlier emergence of metazoans compared to previous estimates that date their origin to ~ 800 Ma 71 , 72 . If animal divergence began in the Mesoproterozoic or even later in the Neoproterozoic, as suggested by recent molecular estimates 26 , 35 , 73 , hypoxic conditions should have prevailed in most environmental settings for more than half of animal evolutionary history 74 . An alternative scenario could be the existence of oxygenic niches present at the microscale since the rise of oxidative photosynthesis about 3.0 Ga 74 , 75 .…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…Dates of emergence of animal-specific NAD-IDH subunit β (~ 1249 Ma) and NAD-IDH subunit γ (~ 1532 Ma) provide support for an earlier emergence of metazoans compared to previous estimates that date their origin to ~ 800 Ma 71 , 72 . If animal divergence began in the Mesoproterozoic or even later in the Neoproterozoic, as suggested by recent molecular estimates 26 , 35 , 73 , hypoxic conditions should have prevailed in most environmental settings for more than half of animal evolutionary history 74 . An alternative scenario could be the existence of oxygenic niches present at the microscale since the rise of oxidative photosynthesis about 3.0 Ga 74 , 75 .…”
Section: Discussionmentioning
confidence: 99%
“…If animal divergence began in the Mesoproterozoic or even later in the Neoproterozoic, as suggested by recent molecular estimates 26 , 35 , 73 , hypoxic conditions should have prevailed in most environmental settings for more than half of animal evolutionary history 74 . An alternative scenario could be the existence of oxygenic niches present at the microscale since the rise of oxidative photosynthesis about 3.0 Ga 74 , 75 . In spite of the strong debate surrounding those conditions 76 79 , the fact is that hypoxic niches may have prevailed for most of Earth’s history.…”
Section: Discussionmentioning
confidence: 99%
“…Hammarlund [64] presents a new take on the role of oxygen in early animal evolution. Rather than viewing increased oxicity of Neoproterozoic environments as having released a constraint on size and complexity in animal evolution, she presents this same biogeochemical transition as a hurdle that early animals and their forebears had to overcome.…”
Section: Oxygen As a Problem For Early Animalsmentioning
confidence: 99%
“…Both the initial hyperspeciation of animals and plants and hyperspeciation events after numerous mass extinctions can be argued to associate with circumstances where either environmental or biological conditions are in flux, i.e. varying ocean chemistry [75] or predation pressure [76]. The recovery after mass extinction may resemble a relapse in cancer rather than a revolutionary organismal event, and both may demonstrate how populations with traits of phenotypic toggling and evolvability hold the evolutionary advantage under dynamic settings.…”
Section: Clues From Tissue Structure Advance Our Models Of Animal Evomentioning
confidence: 99%