Publication: Constraining the oxygen requirements for modern microbial eukaryote diversity

Significance: Modern eukaryotes were present, but marginalized, in ecosystems until no later than ~800 Ma or so, when the biosphere began transitioning to a eukaryote-rich state. Why eukaryotes diversified around this time in Earth history remains unclear. For decades, the most popular proposed driver for this early diversification of eukaryotes has been a contemporaneous increase in atmospheric oxygen (O₂). The oxygen levels required to drive such a diversification event, however, remain unknown. To empirically constrain these requirements, we explored the diversity of microbial eukaryotes living along a modern marine oxygen gradient. Our results suggest that only a rise in atmospheric oxygen from below to above 2 to 3% of modern levels would have directly driven the early diversification of modern microbial eukaryotes.

Abstract: Eukaryotes originated prior to the establishment of modern marine oxygen (O₂) levels. According to the body fossil and lipid biomarker records, modern (crown) microbial eukaryote lineages began diversifying in the ocean no later than ~800 Ma. While it has long been predicted that increasing atmospheric O₂ levels facilitated the early diversification of microbial eukaryotes, the O₂ levels needed to permit this diversification remain unconstrained. Using time-resolved geochemical parameter and gene sequence information from a model marine oxygen minimum zone spanning a range of dissolved O₂ levels and redox states, we show that microbial eukaryote taxonomic richness and phylogenetic diversity remain the same until O₂ declines to around 2 to 3% of present atmospheric levels, below which these diversity metrics become significantly reduced. Our observations suggest that increasing O₂ would have only directly promoted early crown-eukaryote diversity if atmospheric O₂ was below 2 to 3% of modern levels when crown-eukaryotes originated and then later met or surpassed this range as crown-eukaryotes diversified. If atmospheric O₂ was already consistently at or above 2 to 3% of modern levels by the time that crown-eukaryotes originated, then the subsequent diversification of modern microbial eukaryotes was not directly driven by atmospheric oxygenation.