Acoel Single-Cell Transcriptomics: Cell Type Analysis of a Deep Branching Bilaterian

Overview

Journal Mol Biol Evol

Publisher Oxford University Press

Specialty Biology

Date 2020 Dec 23

PMID 33355655

Citations 10

Authors

Jules Duruz

Cyrielle Kaltenrieder

Peter Ladurner

Remy Bruggmann

Pedro Martinez

Simon G Sprecher

Affiliations

Soon will be listed here.

Abstract

Bilaterian animals display a wide variety of cell types, organized into defined anatomical structures and organ systems, which are mostly absent in prebilaterian animals. Xenacoelomorpha are an early-branching bilaterian phylum displaying an apparently relatively simple anatomical organization that have greatly diverged from other bilaterian clades. In this study, we use whole-body single-cell transcriptomics on the acoel Isodiametra pulchra to identify and characterize different cell types. Our analysis identifies the existence of ten major cell type categories in acoels all contributing to main biological functions of the organism: metabolism, locomotion and movements, behavior, defense, and development. Interestingly, although most cell clusters express core fate markers shared with other animal clades, we also describe a surprisingly large number of clade-specific marker genes, suggesting the emergence of clade-specific common molecular machineries functioning in distinct cell types. Together, these results provide novel insight into the evolution of bilaterian cell types and open the door to a better understanding of the origins of the bilaterian body plan and their constitutive cell types.

Citing Articles

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The Acoel nervous system: morphology and development.

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Single cell atlas of Xenoturbella bocki highlights limited cell-type complexity.

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