Phylogenetic analysis of the Tc1/mariner superfamily reveals the unexplored diversity of pogo-like elements

Dupeyron, Mathilde; Baril, Tobias; Bass, Chris; Hayward, Alexander

doi:10.1186/s13100-020-00212-0

Cited by 43 publications

(42 citation statements)

References 74 publications

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“…We first applied our method to alignments between transposable elements drawn from the Tc1/mariner superfamily. We chose this TE family due to its wide phylogenetic distribution (Dupeyron et al, 2020), and because Tc1/mariner elements are well characterised as active TEs in C. elegans (Bessereau, 2006). We constructed a network in which each individual TE is a separate node and the weight of the connection between each node is determined by the sequence similarity.…”

Section: Resultsmentioning

confidence: 99%

“…As an example, we selected one of these clusters, mc476, which was composed of two subfamilies annotated by our pipeline as Fot1 and Tc1 (Fig 2D). Fot1 TEs are most common in fungi, although some metazoan examples have been found (Dupeyron et al, 2020). The origin of this element in nematodes is thus unknown.…”

Section: Network Properties Illuminate Cryptic Sequence Features Of Tesmentioning

confidence: 99%

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Network‐based visualisation reveals new insights into transposable element diversity

Schneider

Guo

Birch

et al. 2021

Molecular Systems Biology

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Transposable elements (TEs) are widespread across eukaryotic genomes, yet their content varies widely between different species. Factors shaping the diversity of TEs are poorly understood. Understanding the evolution of TEs is difficult because their sequences diversify rapidly and TEs are often transferred through nonconventional means such as horizontal gene transfer. We developed a method to track TE evolution using network analysis to visualise TE sequence and TE content across different genomes. We illustrate our method by first using a monopartite network to study the sequence evolution of Tc1/mariner elements across focal species. We identify a connection between two subfamilies associated with convergent acquisition of a domain from a protein-coding gene. Second, we use a bipartite network to study how TE content across species is shaped by epigenetic silencing mechanisms. We show that the presence of Piwi-interacting RNAs is associated with differences in network topology after controlling for phylogenetic effects. Together, our method demonstrates how a network-based approach can identify hitherto unknown properties of TE evolution across species.

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Section: Resultsmentioning

confidence: 99%

Section: Network Properties Illuminate Cryptic Sequence Features Of Tesmentioning

confidence: 99%

Network‐based visualisation reveals new insights into transposable element diversity

Schneider

Guo

Birch

et al. 2021

Molecular Systems Biology

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“…We included transposases from all DDE superfamilies in our analyses, updating the 17 superfamily framework of Yuan and Wessler (13), i.e. Tc1/mariner, Merlin, PIF/Harbinger, MULE (Mutator + Rehavkus), P, hAT, Kolobok, Novosib, Sola1, Sola2, Sola3, PiggyBac, CMC (CACTA, Mirage, Chapaev), Transib, Academ, Ginger, Zator , to include a total of 19 superfamilies, with the follow changes in line with recent research: (i) we split Pogo from Tc1/mariner to form its own distinct superfamily (59, 60) (ii); we grouped PIF/Harbinger with Spy as the superfamily PHIS (61); (iii) we included the newly described GingerRoot family (62).…”

Section: Methodsmentioning

confidence: 99%

“…We used the transposase amino acid sequences from Yuan and Wessler (13) for our database searches, except for MULE, Pogo, Tc1/mariner , and GingerRoot, where we used sequences from more recent analyses (53, 54, 62). We queried the NCBI nr database with BLASTp (63, 64), using a script to parse outputs, specifying table format output, including a column containing the subject sequence.…”

Section: Methodsmentioning

confidence: 99%

Broadscale evolutionary analysis of eukaryotic DDE transposons

Dupeyron

Baril

Hayward

2021

Preprint

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DDE transposons are widespread selfish genetic elements, often comprising a large proportion of eukaryotic genomic content. DDE transposons have also made important contributions to varied host functions during eukaryotic evolution, and their transposases may be the most abundant and ubiquitous genes in nature. Yet much remains unknown about their basic biology. We employ a broadscale screen of DDE transposase diversity to characterise major evolutionary patterns for all 19 DDE transposon superfamilies. We identify considerable variation in DDE transposon superfamily size, and find a dominant association with animal hosts. While few DDE transposon superfamilies specialise in plants or fungi, the four largest superfamilies contain major plant-associated clades, at least partially underlying their relative success. We recover a pattern of host conservation among DDE transposon lineages, punctuated by occasional horizontal transfer to distantly related hosts. Host range and horizontal transfer are strongly positively correlated with DDE transposon superfamily size, arguing against variation in the capacity for generalism. We find that rates of horizontal transfer decrease sharply with increasing levels of host taxonomy, supporting the existence of host-associated barriers to DDE transposon spread. Overall, despite their relatively simple genetic structure, our results imply that trade-offs in host adaptation are important in defining DDE transposon-host relationships and evolution. In addition, our study provides a phylogenetic framework to facilitate the identification and further analysis of DDE transposons.

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“…Nine families are classically considered, and most of their phylogenetic relationships have been updated and are well defined: DD34E/Tc1 [25], DD34D/mariner [26], DD37D/maT [23], DD39D/GT [23], DD41D/VS [24], DD35E/TR [20], DD36E/IC [21], DD37E/TRT [27] and DD38E/IT [22]. However, until recently, studies have shown that many groups of ITm transposons carry the same DDE/D signatures but have different phylogenetic origins [28][29][30]. In particular, the DD34E/Gambol [31] and DDxD/pogo [30] transposons, which were designated as the Tc1/mariner superfamily, have been shown to form two separate superfamilies with good bootstrap support [30].…”

Section: Introductionmentioning

confidence: 99%

Prokaryotic and Eukaryotic Horizontal Transfer of Sailor (DD82E), a New Superfamily of IS630-Tc1-Mariner DNA Transposons

Shi

Пузаков

Guan

et al. 2021

Biology

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Here, a new superfamily of IS630-Tc1-mariner (ITm) DNA transposons, termed Sailor, is identified, that is characterized by a DD82E catalytic domain and is distinct from all previously known superfamilies of the ITm group. Phylogenetic analyses revealed that Sailor forms a monophyletic clade with a more intimate link to the clades of Tc1/mariner and DD34E/Gambol. Sailor was detected in both prokaryotes and eukaryotes and invaded a total of 256 species across six kingdoms. Sailor is present in nine species of bacteria, two species of plantae, four species of protozoa, 23 species of Chromista, 12 species of Fungi and 206 species of animals. Moreover, Sailor is extensively distributed in invertebrates (a total of 206 species from six phyla) but is absent in vertebrates. Sailor transposons are 1.38–6.98 kb in total length and encoded transposases of ~676 aa flanked by TIRs with lengths between 18, 1362 and 4 bp (TATA) target-site duplications. Furthermore, our analysis provided strong evidence of Sailor transmissions from prokaryotes to eukaryotes and internal transmissions in both. These data update the classification of the ITm group and will contribute to the understanding of the evolution of ITm transposons and that of their hosts.

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Phylogenetic analysis of the Tc1/mariner superfamily reveals the unexplored diversity of pogo-like elements

Cited by 43 publications

References 74 publications

Network‐based visualisation reveals new insights into transposable element diversity

Network‐based visualisation reveals new insights into transposable element diversity

Broadscale evolutionary analysis of eukaryotic DDE transposons

Prokaryotic and Eukaryotic Horizontal Transfer of Sailor (DD82E), a New Superfamily of IS630-Tc1-Mariner DNA Transposons

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