Molecular and morphological characterization of four new ancyromonad genera and proposal for an updated taxonomy of the Ancyromonadida

Studying fundamental aspects of eukaryotic biology through genetic information can face numerous challenges, including contamination and intricate biotic interactions, which are particularly pronounced when working with uncultured eukaryotes. However, existing tools for predicting open reading frames (ORFs) from transcriptomes are limited in these scenarios. Here we introduce Transcript Identification and Selection (TIdeS), a framework designed to address these non-trivial challenges associated with current ‘omics approaches. Using transcriptomes from 32 taxa, representing the breadth of eukaryotic diversity, TIdeS outperforms most conventional ORF-prediction methods (i.e., TransDecoder), identifying a greater proportion of complete and in-frame ORFs. Additionally, TIdeS accurately classifies ORFs using minimal input data, even in the presence of ‘heavy contamination’. This built-in flexibility extends to previously unexplored biological interactions, offering a robust single-stop solution for precise ORF predictions and subsequent decontamination. Beyond applications in phylogenomic-based studies, TIdeS provides a robust means to explore biotic interactions in eukaryotes (e.g., host-symbiont, prey-predator) and for reproducible dataset curation from transcriptomes and genomes.

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Phylogenomics of neglected flagellated protists supports a revised eukaryotic tree of life

Torruella,

Galindo,

Moreira

et al. 2024

Preprint

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Eukaryotes radiated from their last common ancestor, diversifying into several supergroups with unresolved deep evolutionary connections. Heterotrophic flagellates, often branching deeply in phylogenetic trees, are arguably the most diverse eukaryotes. However, many of them remain undersampled and/or incertae sedis. Here, we conducted comprehensive phylogenomics analyses with an expanded taxon sampling of early-branching protists including 22 newly sequenced transcriptomes (apusomonads, ancyromonads, Meteora). They support the monophyly of Opimoda, one of the largest eukaryotic supergroups, with CRuMs being sister to the Amorphea (amoebozoans, breviates, apusomonads, and opisthokonts -including animals and fungi-), and the ancyromonads+malawimonads clade. By mapping traits onto this phylogenetic framework, we infer a biflagellate opimodan ancestor with an excavate-like feeding groove. Breviates and apusomonads retained the ancestral biflagellate state. Other Amorphea lost one or both flagella, enabling the evolution of amoeboid shapes, novel feeding modes, and palintomic cell division resulting in multinucleated cells, which likely facilitated the subsequent evolution of fungal and metazoan multicellularity.

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Molecular and morphological characterization of four new ancyromonad genera and proposal for an updated taxonomy of the Ancyromonadida

Cited by 3 publications

References 43 publications

Phylogenomics of neglected flagellated protists supports a revised eukaryotic tree of life

Phylogenomics of neglected flagellated protists supports a revised eukaryotic tree of life

TIdeS: A Comprehensive Framework for Accurate Open Reading Frame Identification and Classification in Eukaryotic Transcriptomes

Phylogenomics of neglected flagellated protists supports a revised eukaryotic tree of life

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