Login

Search

Advanced Search

Browse

Research Area
Research Team (MDC)
Research Team (ECRC)
Journal Title
Year

Statistics

Latest Additions
High Impact Papers
Downloads

Feeds

Atom

RSS 1.0

RSS 2.0

Comparative single-cell analyses reveal evolutionary repurposing of a conserved gene program in bat wing development

Tools

[thumbnail of Preprint]

Preview

PDF (Preprint) - Requires a PDF viewer such as GSview, Xpdf or Adobe Acrobat Reader
19MB

Item Type:	Preprint
Title:	Comparative single-cell analyses reveal evolutionary repurposing of a conserved gene program in bat wing development
Creators Name:	Schindler, M., Feregrino, C., Aldrovandi, S., Lo, B.W., Monaco, A.A., Ringel, A.R., Morales, A., Zehnder, T., Behncke, R.Y., Glaser, J., Barclay, A., Andrey, G., Kragesteen, B.K., Hägerling, R., Haas, S., Vingron, M., Ulitsky, I., Marti-Renom, M., Hechavarria, J., Fasel, N., Hiller, M., Lupianez, D.G., Mundlos, S. and Real, F.M.
Abstract:	Bats are the only mammals capable of self-powered flight, an evolutionary innovation based on the transformation of forelimbs into wings. The bat wing is characterized by an extreme elongation of the second to fifth digits and a wing membrane called chiropatagium connecting them. Here we investigated the developmental and cellular origin of this structure by comparing bat and mouse limbs using omics tools and single-cell analyses. Despite the substantial morphological differences between the species, we observed an overall conservation of cell populations and gene expression patterns including interdigital apoptosis. Single-cell analyses of micro-dissected embryonic chiropatagium identified a specific fibroblast population, independent of apoptosis-associated interdigital cells, as the origin of this tissue. These distal cells express a conserved gene program including the transcription factors MEIS2 and TBX3 , which are commonly known to specify and pattern the early proximal limb. Transgenic ectopic expression of MEIS2 and TBX3 in mouse distal limb cells resulted in the activation of genes expressed during wing development and phenotypic changes related to wing morphology, such as the fusion of digits. Our results elucidate fundamental molecular mechanisms of bat wing development and illustrate how drastic morphological changes can be achieved through repurposing of existing developmental programs during evolution.
Keywords:	Animals, Bats
Source:	bioRxiv
Publisher:	Cold Spring Harbor Laboratory Press
Article Number:	2024.10.10.617585
Date:	13 October 2024
Official Publication:	https://doi.org/10.1101/2024.10.10.617585

Repository Staff Only: item control page

Download Statistics

Download Statistics

Downloads

Downloads per month over past year

Open Access

OA at the MDC
OA at Helmholtz
OAI-PMH

MDC Library

Library
Catalogue
Journals
Databases

MDC Repository is powered by EPrints 3 which is developed by the School of Electronics and Computer Science at the University of Southampton.