Monocercomonoides exilis is a model species of the amitochondrial eukaryotic group Oxymonadida, which makes it a suitable organism for studying the consequences of mitochondrial loss. Although M. exilis has an endobiotic lifestyle, it can be cultured in vitro in polyxenic conditions alongside an uncharacterized prokaryotic community, while attempts to create axenic cultures have not been successful. In this study, we used metagenomic sequencing, transcriptomics, and metabolomics to characterize the microbial consortium that supports the growth of M. exilis. We assembled genomes for 24 bacterial species and identified at least 30 species in total. M. exilis accounted for less than 1.5% of the DNA reads, while bacterial species dominated the sequence data and shifted in abundance over time. Our metabolic reconstruction and differential gene expression analyses show that the bacterial community relies on organic carbon oxidation, fermentation, and hydrogen production, but does not engage in methanogenesis. We observed rapid depletion of amino acids, nucleotides, glyceraldehyde, lactate, fatty acids, and alcohols in the medium, indicating a reliance on external nutrient recycling. The nitrogen cycle in this community is incomplete, with limited nitrogen fixation and no ammonia oxidation. Despite detailed metabolic profiling, we did not find any direct biochemical connections between M. exilis and the prokaryotes. Several bacterial species produce siderophores to assist themselves and others in the community in acquiring iron. However, M. exilis does not appear to benefit directly from siderophore-mediated iron transport and lacks known iron uptake pathways. This indicates that M. exilis may rely indirectly on the iron metabolism of other bacteria through phagocytosis. Additionally, some bacteria synthesize polyamines like spermidine and phosphatidylcholine, which M. exilis may need but cannot produce on its own. As the culture ages, M. exilis shows changes in gene expression consistent with starvation responses, including the upregulation of carbohydrate storage pathways and processes related to exocytosis. These findings provide new insights into microbial interactions within xenic cultures and emphasize the complex nature of maintaining amitochondriate eukaryotes in vitro.

• Publication type
• Journal Article MeSH

The notion that mitochondria cannot be lost was shattered with the report of an oxymonad Monocercomonoides exilis, the first eukaryote arguably without any mitochondrion. Yet, questions remain about whether this extends beyond the single species and how this transition took place. The Oxymonadida is a group of gut endobionts taxonomically housed in the Preaxostyla which also contains free-living flagellates of the genera Trimastix and Paratrimastix. The latter two taxa harbour conspicuous mitochondrion-related organelles (MROs). Here we report high-quality genome and transcriptome assemblies of two Preaxostyla representatives, the free-living Paratrimastix pyriformis and the oxymonad Blattamonas nauphoetae. We performed thorough comparisons among all available genomic and transcriptomic data of Preaxostyla to further decipher the evolutionary changes towards amitochondriality, endobiosis, and unstacked Golgi. Our results provide insights into the metabolic and endomembrane evolution, but most strikingly the data confirm the complete loss of mitochondria for all three oxymonad species investigated (M. exilis, B. nauphoetae, and Streblomastix strix), suggesting the amitochondriate status is common to a large part if not the whole group of Oxymonadida. This observation moves this unique loss to 100 MYA when oxymonad lineage diversified.

• MeSH
• Eukaryota * genetics   MeSH
• Phylogeny MeSH
• Genomics MeSH
• Mitochondria genetics   MeSH
• Oxymonadida * genetics   metabolism   MeSH
• Publication type
• Journal Article MeSH

The endobiotic flagellate Monocercomonoides exilis is the only known eukaryote to have lost mitochondria and all its associated proteins in its evolutionary past. This final stage of the mitochondrial evolutionary pathway may serve as a model to explain events at their very beginning such as the initiation of protein import. We have assessed the capability of proteins from this eukaryote to enter emerging mitochondria using a specifically designed in vitro assay. Hydrogenosomes (reduced mitochondria) of Trichomonas vaginalis were incubated with a soluble protein pool derived from a cytosolic fraction of M. exilis, and proteins entering hydrogenosomes were subsequently detected by mass spectrometry. The assay detected 19 specifically and reproducibly imported proteins, and in 14 cases the import was confirmed by the overexpression of their tagged version in T. vaginalis. In most cases, only a small portion of the signal reached the hydrogenosomes, suggesting specific but inefficient transport. Most of these proteins represent enzymes of carbon metabolism, and none exhibited clear signatures of proteins targeted to hydrogenosomes or mitochondria, which is consistent with their inefficient import. The observed phenomenon may resemble a primaeval type of protein import which might play a role in the establishment of the organelle and shaping of its proteome in the initial stages of endosymbiosis.

• Keywords
• evolution of protein targeting, hydrogenosome, mitochondrion-free eukaryote, protein import,
• MeSH
• Eukaryota * metabolism   MeSH
• Mitochondria metabolism   MeSH
• Organelles chemistry   metabolism   MeSH
• Protozoan Proteins * metabolism   MeSH
• Protein Transport MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• Protozoan Proteins * MeSH