Abstract
Transposons impact eukaryotic genome size and evolution. Horizontal transfer of transposons (HTT) is important for their long-term persistence, but has only been systematically studied in animals, and thus the abundance, impact, and factors that shape HTTs in lineages outside animals is unknown. Fungi are at least as ancient and diverse as animals and are characterized by extensive genome size variation caused by transposons. Here, we screened 1,348 genomes across fungal biodiversity, genome sizes, and lifestyles to detect extensive HTTs, that generated on average 7% but up to 70% of the transposon content in some taxa. We in total identified at least 5,518 independent HTTs, mostly involving Tc1/Mariner DNA transposons. While the majority of HTTs occur between closely related taxa, irrespective of their lifestyles, HTTs were particularly common in Mucoromycotina, Sordariomycetes, Dothideomycetes, and Leotiomycetes. Importantly, species lacking fungal-specific defense mechanisms against transposons and those with gene-sparse and repeat-rich genomic compartments are involved in significantly higher number of HTTs, unveiling ecological and genomic factors shaping HTTs. Our findings thus illuminate the dynamic landscape of HTTs in fungi, providing the framework to further study the impact of HTTs on genome evolution and the processes that mediate transposon transfers within and between eukaryotic lineages.
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Abstract
Transposons impact eukaryotic genome size and evolution. Horizontal transfer of transposons (HTT) is important for their long-term persistence, but has only been systematically studied in animals, and thus the abundance, impact, and factors that shape HTTs in lineages outside animals is unknown. Fungi are at least as ancient and diverse as animals and are characterized by extensive genome size variation caused by transposons. Here, we screened 1,348 genomes across fungal biodiversity, genome sizes, and lifestyles to detect extensive HTTs, that generated on average 7% but up to 70% of the transposon content in some taxa. We in total identified at least 5,518 independent HTTs, mostly involving Tc1/Mariner DNA transposons. While the majority of HTTs occur between closely related taxa, irrespective of their lifestyles, HTTs were particularly common in Mucoromycotina, Sordariomycetes, Dothideomycetes, and Leotiomycetes. Importantly, species lacking fungal-specific defense mechanisms against transposons and those with gene-sparse and repeat-rich genomic compartments are involved in significantly higher number of HTTs, unveiling ecological and genomic factors shaping HTTs. Our findings thus illuminate the dynamic landscape of HTTs in fungi, providing the framework to further study the impact of HTTs on genome evolution and the processes that mediate transposon transfers within and between eukaryotic lineages.
Competing Interest Statement
The authors have declared no competing interest.
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