Litcius/Paper detail

Timely TGFβ signalling inhibition induces notochord

Tiago Rito, Ashley R.G. Libby, Madeleine Demuth, Marie‐Charlotte Domart, Jake Cornwall-Scoones, James Briscoe

2024Nature30 citationsDOIOpen Access PDF

Abstract

Abstract The formation of the vertebrate body involves the coordinated production of trunk tissues from progenitors located in the posterior of the embryo. Although in vitro models using pluripotent stem cells replicate aspects of this process 1–10 , they lack crucial components, most notably the notochord—a defining feature of chordates that patterns surrounding tissues 11 . Consequently, cell types dependent on notochord signals are absent from current models of human trunk formation. Here we performed single-cell transcriptomic analysis of chick embryos to map molecularly distinct progenitor populations and their spatial organization. Guided by this map, we investigated how differentiating human pluripotent stem cells develop a stereotypical spatial organization of trunk cell types. We found that YAP inactivation in conjunction with FGF-mediated MAPK signalling facilitated WNT pathway activation and induced expression of TBXT (also known as BRA). In addition, timely inhibition of WNT-induced NODAL and BMP signalling regulated the proportions of different tissue types, including notochordal cells. This enabled us to create a three-dimensional model of human trunk development that undergoes morphogenetic movements, producing elongated structures with a notochord and ventral neural and mesodermal tissues. Our findings provide insights into the mechanisms underlying vertebrate notochord formation and establish a more comprehensive in vitro model of human trunk development. This paves the way for future studies of tissue patterning in a physiologically relevant environment.

Topics & Concepts

NotochordBiologyChordateWnt signaling pathwayCell biologyProgenitor cellEmbryonic stem cellVertebrateProgenitorAnatomyEmbryoStem cellNeuroscienceSignal transductionEmbryogenesisGeneticsGeneCongenital heart defects researchDevelopmental Biology and Gene RegulationHippo pathway signaling and YAP/TAZ