Mechanics of human embryo compaction
Julie Firmin,
Nicolas Ecker,
Diane Rivet Danon,
Özge Özgüç,
Virginie Barraud Lange,
Hervé Turlier,
Catherine Patrat and
Jean-Léon Maître ()
Additional contact information
Julie Firmin: INSERM U934
Nicolas Ecker: Université PSL, FHU Prema
Diane Rivet Danon: FHU Prema
Özge Özgüç: INSERM U934
Virginie Barraud Lange: FHU Prema
Hervé Turlier: Université PSL, FHU Prema
Catherine Patrat: FHU Prema
Jean-Léon Maître: INSERM U934
Nature, 2024, vol. 629, issue 8012, 646-651
Abstract:
Abstract The shaping of human embryos begins with compaction, during which cells come into close contact1,2. Assisted reproductive technology studies indicate that human embryos fail compaction primarily because of defective adhesion3,4. On the basis of our current understanding of animal morphogenesis5,6, other morphogenetic engines, such as cell contractility, could be involved in shaping human embryos. However, the molecular, cellular and physical mechanisms driving human embryo morphogenesis remain uncharacterized. Using micropipette aspiration on human embryos donated to research, we have mapped cell surface tensions during compaction. This shows a fourfold increase of tension at the cell–medium interface whereas cell–cell contacts keep a steady tension. Therefore, increased tension at the cell–medium interface drives human embryo compaction, which is qualitatively similar to compaction in mouse embryos7. Further comparison between human and mouse shows qualitatively similar but quantitively different mechanical strategies, with human embryos being mechanically least efficient. Inhibition of cell contractility and cell–cell adhesion in human embryos shows that, whereas both cellular processes are required for compaction, only contractility controls the surface tensions responsible for compaction. Cell contractility and cell–cell adhesion exhibit distinct mechanical signatures when faulty. Analysing the mechanical signature of naturally failing embryos, we find evidence that non-compacting or partially compacting embryos containing excluded cells have defective contractility. Together, our study shows that an evolutionarily conserved increase in cell contractility is required to generate the forces driving the first morphogenetic movement shaping the human body.
Date: 2024
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DOI: 10.1038/s41586-024-07351-x
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