Regulation of axial elongation by Cdx

The primordia of the post-otic mouse embryo forms largely from a bipotential cell population containing neuromesodermal progenitors (NMP) which reside in the tail bud and contribute to the elaboration of the major body axis after gastrulation. The mechanisms by which the NMP population is both maint...

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Veröffentlicht in:Developmental biology 2022-03, Vol.483, p.118-127
Hauptverfasser: Zhu, Yalun, Lohnes, David
Format: Artikel
Sprache:eng
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Zusammenfassung:The primordia of the post-otic mouse embryo forms largely from a bipotential cell population containing neuromesodermal progenitors (NMP) which reside in the tail bud and contribute to the elaboration of the major body axis after gastrulation. The mechanisms by which the NMP population is both maintained and subsequently directed down mesodermal and neural lineages is incompletely understood. The vertebrate transcription factor Cdx2, is essential for axial elongation and has been implicated in maintaining the NMP niche and in specification of NMP derivatives. To better understand the role of the Cdx family in axial elongation, we employed a conditional mutant allele which evokes total loss of Cdx function, and enriched for tail bud progenitors through the use of a Pax2-GFP transgenic reporter. Using this approach, we identified 349 Cdx-dependent genes by RNA sequencing (RNA-seq). From these, Gene Ontology and chromatin immunoprecipitation analysis further revealed a number of putative direct Cdx candidate target genes implicated in axial elongation, including Sp8, Isl1, Evx1, Zic3 and Nr2f1. Additional analysis of available single-cell RNA-seq data from mouse tail buds revealed the co-expression of Sp8, Isl1, Evx1 and Zic3 with Cdx2 in putative NMP cells, while Nr2f1 was excluded from this population. These findings identify a number of novel Cdx targets and provide further insight into the critical roles for Cdx in elaborating the post-otic embryo. [Display omitted] •Loss of Cdx function leads to premature axial termination of the mouse embryo.•Cdx-dependent gene expression in E9.5 mouse tail buds was profiled by RNA-seq.•Novel candidate Cdx target genes including Sp8, Isl1, Evx1, Zic3 and Nr2f1 were identified.•These finding suggest that Cdx regulates multiple aspects of axial elongation.
ISSN:0012-1606
1095-564X
DOI:10.1016/j.ydbio.2021.12.011