Insights into early animal evolution form the genome of the xenacoelomorph worm

Schiffer, Philipp H; Natsidis, Paschalis; Leite, Daniel J; Robertson, Helen E; Lapraz, François; Marlétaz, Ferdinand; Fromm, Bastian; Baudry, Liam; Simpson, Fraser; Høye, Eirik; Zakrzewski, Anne C; Kapli, Paschalia; Hoff, Katharina J; Mueller, Steven; Marbouty, Martial; Marlow, Heather; Copley, Richard R; Koszul, Romain; Sarkies, Peter; Telford, Maximilian J

doi:10.7554/eLife.94948

Insights into early animal evolution form the genome of the xenacoelomorph worm

Schiffer, Philipp H; Natsidis, Paschalis; Leite, Daniel J; Robertson, Helen E; Lapraz, François; Marlétaz, Ferdinand; Fromm, Bastian; Baudry, Liam; Simpson, Fraser; Høye, Eirik; Zakrzewski, Anne C; Kapli, Paschalia; Hoff, Katharina J; Mueller, Steven; Marbouty, Martial; Marlow, Heather; Copley, Richard R; Koszul, Romain; Sarkies, Peter; Telford, Maximilian J

Authors

Philipp H Schiffer

Paschalis Natsidis

Dr Daniel Leite daniel.j.leite@durham.ac.uk
Academic Visitor

Helen E Robertson

François Lapraz

Ferdinand Marlétaz

Bastian Fromm

Liam Baudry

Fraser Simpson

Eirik Høye

Anne C Zakrzewski

Paschalia Kapli

Katharina J Hoff

Steven Mueller

Martial Marbouty

Heather Marlow

Richard R Copley

Romain Koszul

Peter Sarkies

Maximilian J Telford

Abstract

The evolutionary origins of Bilateria remain enigmatic. One of the more enduring proposals highlights similarities between a cnidarian-like planula larva and simple acoel-like flatworms. This idea is based in part on the view of the Xenacoelomorpha as an outgroup to all other bilaterians which are themselves designated the Nephrozoa (protostomes and deuterostomes). Genome data can provide important comparative data and help to understand the evolution and biology of enigmatic species better. Here we assemble and analyse the genome of the simple, marine xenacoelomorph , a key species for our understanding of early bilaterian evolution. Our highly contiguous genome assembly of has a size of ~111 Mbp in 18 chromosome like scaffolds, with repeat content and intron, exon and intergenic space comparable to other bilaterian invertebrates. We find to have a similar number of genes to other bilaterians and to have retained ancestral metazoan synteny. Key bilaterian signalling pathways are also largely complete and most bilaterian miRNAs are present. Overall, we conclude that has a complex genome typical of bilaterians, which does not reflect the apparent simplicity of its body plan that has been so important to proposals that the Xenacoelomorpha are the simple sister group of the rest of the Bilateria. [Abstract copyright: © 2024, Schiffer et al.]

Citation

Schiffer, P. H., Natsidis, P., Leite, D. J., Robertson, H. E., Lapraz, F., Marlétaz, F., Fromm, B., Baudry, L., Simpson, F., Høye, E., Zakrzewski, A. C., Kapli, P., Hoff, K. J., Mueller, S., Marbouty, M., Marlow, H., Copley, R. R., Koszul, R., Sarkies, P., & Telford, M. J. (in press). Insights into early animal evolution form the genome of the xenacoelomorph worm. eLife, 13, Article e94948. https://doi.org/10.7554/eLife.94948

Journal Article Type	Article
Acceptance Date	Jul 3, 2024
Online Publication Date	Aug 7, 2024
Deposit Date	Aug 30, 2024
Publicly Available Date	Aug 30, 2024
Journal	eLife
Electronic ISSN	2050-084X
Publisher	eLife Sciences Publications
Peer Reviewed	Peer Reviewed
Volume	13
Article Number	e94948
DOI	https://doi.org/10.7554/eLife.94948
Keywords	genomics, evolutionary biology, genetics
Public URL	https://durham-repository.worktribe.com/output/2770760