Abstract
The absence of genome complexity in prokaryotes, being the evolutionary precursors to eukaryotic cells comprising all complex life (the prokaryote–eukaryote divide), is a long-standing question in evolutionary biology. A previous study hypothesized that the divide exists because prokaryotic genome size is constrained by bioenergetics (prokaryotic power per gene or genome being significantly lower than eukaryotic ones). However, this hypothesis was evaluated using a relatively small dataset due to lack of data availability at the time, and is therefore controversial. Accordingly, we constructed a larger dataset of genomes, metabolic rates, cell sizes and ploidy levels to investigate whether an energetic barrier to genome complexity exists between eukaryotes and prokaryotes while statistically controlling for the confounding effects of cell size and phylogenetic signals. Notably, we showed that the differences in bioenergetics between prokaryotes and eukaryotes were less significant than those previously reported. More importantly, we found a limited contribution of power per genome and power per gene to the prokaryote–eukaryote dichotomy. Our findings indicate that the prokaryote–eukaryote divide is hard to explain from the energetic perspective. However, our findings may not entirely discount the traditional hypothesis; in contrast, they indicate the need for more careful examination.
Highlights
Eukaryotic cells arose from prokaryotes and are comprised of all complex life
Inspired by the previous study of Lane & Martin [6], we investigated the differences in metabolic power between prokaryotes and eukaryotes and re-confirmed that the metabolic power of eukaryotes was greater than that of prokaryotes
0.67 0.117 1.35 (2.9 × 10–6) 0.99 cell mass. These results indicate no difference in power per genome and power per gene between prokaryotes and eukaryotes, which is not consistent with Lane & Martin’s conclusion that the prokaryotic genome size is constrained by bioenergetics
Summary
Eukaryotic cells arose from prokaryotes and are comprised of all complex life. Biological complexity (e.g. genome complexity, cellular complexity and multicellularity) is believed to harbour several advantages. Genome size and the number of genes (i.e. genome complexity) increase with environmental variability because organisms need more functional (e.g. metabolic) genes to royalsocietypublishing.org/journal/rsos R. Adapt to changing environments (e.g. nutrient variability) [1,2]. Cellular complexity may enhance biological 2 robustness [3], and multicellular organisms have evolved sophisticated, higher-level functionality via cooperation among component cells with complementary behaviours [4,5]. Only some prokaryotes have evolved biological complexity. The large gap between prokaryotes and eukaryotes (the prokaryote–eukaryote divide) is a long-standing mystery in evolutionary biology [6,7,8]
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