Reconstituting Human Somitogenesis in Vitro

Overview

Journal Nature

Specialty Science

Date 2022 Dec 21

PMID 36543322

Authors

Yoshihiro Yamanaka

Sofiane Hamidi

Kumiko Yoshioka-Kobayashi

Sirajam Munira

Kazunori Sunadome

Yi Zhang

Yuzuru Kurokawa

Rolf Ericsson

Ai Mieda

Jamie L Thompson

Janet Kerwin

Steven Lisgo

Takuya Yamamoto

Naomi Moris

Alfonso Martinez-Arias

Taro Tsujimura

Cantas Alev

Affiliations

Soon will be listed here.

Abstract

The segmented body plan of vertebrates is established during somitogenesis, a well-studied process in model organisms; however, the details of this process in humans remain largely unknown owing to ethical and technical limitations. Despite recent advances with pluripotent stem cell-based approaches, models that robustly recapitulate human somitogenesis in both space and time remain scarce. Here we introduce a pluripotent stem cell-derived mesoderm-based 3D model of human segmentation and somitogenesis-which we termed 'axioloid'-that captures accurately the oscillatory dynamics of the segmentation clock and the morphological and molecular characteristics of sequential somite formation in vitro. Axioloids show proper rostrocaudal patterning of forming segments and robust anterior-posterior FGF-WNT signalling gradients and retinoic acid signalling components. We identify an unexpected critical role of retinoic acid signalling in the stabilization of forming segments, indicating distinct, but also synergistic effects of retinoic acid and extracellular matrix on the formation and epithelialization of somites. Comparative analysis demonstrates marked similarities of axioloids to the human embryo, further validated by the presence of a Hox code in axioloids. Finally, we demonstrate the utility of axioloids for studying the pathogenesis of human congenital spine diseases using induced pluripotent stem cells with mutations in HES7 and MESP2. Our results indicate that axioloids represent a promising platform for the study of axial development and disease in humans.

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