Transcriptome and evolutionary analysis of Pseudotrichomonas keilini , a free-living anaerobic eukaryote

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Abstract

The early evolution of eukaryotes and their adaptations to low-oxygen environments are fascinating open questions in biology. Genome-scale data from novel eukaryotes, and particularly from free-living lineages, are key to answering these questions. The Parabasalia are an ancient lineage of anaerobes, and the most speciose lineage of Metamonada, a major lineage of eukaryotes. The most well-studied metamonads are parasitic parabasalids including Trichomonas vaginalis, Tritrichomonas foetus , and Giardia intestinalis , but very little genome-scale data is available for free-living members of the group. Here, we sequenced the transcriptome of Pseudotrichomonas keilini , a free-living parabasalian. Comparative genomic analysis indicated that P. keilini possesses a metabolism and gene complement that are in many respects similar to its parasitic relative Trichomonas vaginalis , and that in the time since their most recent common ancestor, it is the Trichomonas vaginalis lineage that has experienced more genomic change, likely due to the transition to a parasitic lifestyle. Features shared between P. keilini and Trichomonas vaginalis include a hydrogenosome (anaerobic mitochondrial homologue) that we predict to function much as in Trichomonas vaginalis , and a complete glycolytic pathway that is likely to represent one of the primary means by which P. keilini obtains ATP. Phylogenomic analysis indicates that P. keilini branches within a clade of endobiotic parabasalids, consistent with the hypothesis that different parabasalid lineages evolved towards parasitic or free-living lifestyles from an endobiotic, anaerobic or microaerophilic common ancestor.

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