Abstract
The photosynthetic picoeukaryotes (PPEs) comprise a rare example of free-living eukaryotes that have undergone genome reduction. Here, we examine a duality in the process; the proposed driver of genome reduction (the Black Queen hypothesis, BQH), and the resultant impact of genome information loss (the Proteomic Constraint hypothesis, PCH). The BQH predicts that some metabolites may be shared in the open ocean, thus driving loss of redundant metabolic pathways in individual genomes. In contrast, the PCH predicts that as the information content of a genome is reduced, the total mutation load is also reduced, leading to loss of DNA repair genes due to the resulting reduction in selective constraint. Consistent with the BQH, we observe that biosynthetic pathways involved with soluble metabolites such as amino acids and carotenoids are preferentially lost from the PPEs, in contrast to biosynthetic pathways involved with insoluble metabolites, such as lipids, which are retained. Consistent with the PCH, a correlation between proteome size and the number of DNA repair genes, and numerous other informational categories, is observed. While elevated mutation rates resulting from the loss of DNA repair genes have been linked to reduced effective population sizes in intracellular bacteria, this remains to be established. This study shows that in microbial species with large population sizes, an underlying factor in modulating their DNA repair capacity appears to be information content.
Highlights
Photosynthetic picoeukaryotes (PPEs) are single celled eukaryotic algae of cell size less than 3 μm in diameter[1]
We have conducted a comparative genomic analysis to test the effect of Black Queen, Proteomic Constraint and genetic drift on genome reduction of photosynthetic picoeukaryotes (PPEs)
When additional PPE genomes from diverse lineages are sequenced, some convergence should be observed in the genes that are lost, if they are influenced by the metabolites present in ocean water
Summary
Photosynthetic picoeukaryotes (PPEs) are single celled eukaryotic algae of cell size less than 3 μm in diameter[1]. The reduction in cell size of both marine PPEs and picocyanobacteria has occurred concomitantly with a reduction in genome size These two groups of photosynthetic microbes represent rare examples of free-living organisms that have undergone reduction in genome size, the evolutionary forces and environmental factors leading to genome reduction in these two lineages are not well understood[11,12]. Adhering to the strict definition of public goods that they are non-rivalrous means they are not susceptible to freeloading/cheating behaviors, as they cannot be over-exploited This is likely the case with metabolites and other gene products present in the open ocean
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