Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition

Martti Maimets; Mikhail Nikolaev; Cecilia Lövkvist; Fabien Bertillot; Hjalte List Larsen; Raul Bardini Bressan; Antonios Georgantzoglou; Nikolce Gjorevski; Eirini Filidou; Maureen Zøylner; Stine Lind Hansen; Astrid M Baattrup; Isidora Banjac; Jordi Guiu; Sara A Wickström; Matthias P. Lutolf; Kim B Jensen

doi:10.1016/j.stem.2026.01.006

Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition

Martti Maimets, Mikhail Nikolaev, Cecilia Lövkvist, Fabien Bertillot, Hjalte List Larsen, Raul Bardini Bressan, Antonios Georgantzoglou, Nikolce Gjorevski, Eirini Filidou, Maureen Zøylner, Stine Lind Hansen, Astrid M Baattrup, Isidora Banjac, Jordi Guiu, Sara A Wickström, Matthias P. Lutolf, Kim B Jensen

Jensen Lab

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

During morphogenesis, the intestine undergoes significant structural remodeling, transitioning from a simple tube of immature epithelium into a complex crypt-villus architecture housing mature cell types. However, the relationship between these structural changes and epithelial maturation has remained enigmatic. Using engineered scaffolds that replicate crypt-like geometries, we establish a robust platform for guiding the morphogenesis and differentiation of fetal intestinal cells into mature engineered tissues that mimic their in vivo counterparts. Mechanistically, tissue maturation is driven by cell crowding, leading to reduced YAP1 activation. Modulating YAP signaling in both engineered tissues and the developing mouse intestine alters epithelial lineage specification. These findings uncover a geometry-dependent mechanism that links tissue architecture to cell fate transitions. Our work provides a platform for modeling aspects of intestinal development and offers insights for refining stem cell differentiation protocols and regenerative strategies for intestinal disorders.

Original language	English
Journal	Cell Stem Cell
Volume	33
Issue number	3
Pages (from-to)	487-501.e7
ISSN	1934-5909
DOIs	https://doi.org/10.1016/j.stem.2026.01.006
Publication status	Published - 2026

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Maimets, M., Nikolaev, M., Lövkvist, C., Bertillot, F., Larsen, H. L., Bressan, R. B., Georgantzoglou, A., Gjorevski, N., Filidou, E., Zøylner, M., Hansen, S. L., Baattrup, A. M., Banjac, I., Guiu, J., Wickström, S. A., Lutolf, M. P., & Jensen, K. B. (2026). Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition. Cell Stem Cell, 33(3), 487-501.e7. https://doi.org/10.1016/j.stem.2026.01.006

Maimets, M, Nikolaev, M, Lövkvist, C, Bertillot, F, Larsen, HL, Bressan, RB, Georgantzoglou, A, Gjorevski, N, Filidou, E , Zøylner, M, Hansen, SL, Baattrup, AM , Banjac, I, Guiu, J, Wickström, SA, Lutolf, MP & Jensen, KB 2026, 'Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition', Cell Stem Cell, vol. 33, no. 3, pp. 487-501.e7. https://doi.org/10.1016/j.stem.2026.01.006

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title = "Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition",

abstract = "During morphogenesis, the intestine undergoes significant structural remodeling, transitioning from a simple tube of immature epithelium into a complex crypt-villus architecture housing mature cell types. However, the relationship between these structural changes and epithelial maturation has remained enigmatic. Using engineered scaffolds that replicate crypt-like geometries, we establish a robust platform for guiding the morphogenesis and differentiation of fetal intestinal cells into mature engineered tissues that mimic their in vivo counterparts. Mechanistically, tissue maturation is driven by cell crowding, leading to reduced YAP1 activation. Modulating YAP signaling in both engineered tissues and the developing mouse intestine alters epithelial lineage specification. These findings uncover a geometry-dependent mechanism that links tissue architecture to cell fate transitions. Our work provides a platform for modeling aspects of intestinal development and offers insights for refining stem cell differentiation protocols and regenerative strategies for intestinal disorders.",

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T1 - Engineered intestinal crypt geometry uncovers YAP1-dependent fetal-to-adult transition

AU - Maimets, Martti

AU - Nikolaev, Mikhail

AU - Lövkvist, Cecilia

AU - Bertillot, Fabien

AU - Larsen, Hjalte List

AU - Bressan, Raul Bardini

AU - Georgantzoglou, Antonios

AU - Gjorevski, Nikolce

AU - Filidou, Eirini

AU - Zøylner, Maureen

AU - Hansen, Stine Lind

AU - Baattrup, Astrid M

AU - Banjac, Isidora

AU - Guiu, Jordi

AU - Wickström, Sara A

AU - Lutolf, Matthias P.

AU - Jensen, Kim B

PY - 2026

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N2 - During morphogenesis, the intestine undergoes significant structural remodeling, transitioning from a simple tube of immature epithelium into a complex crypt-villus architecture housing mature cell types. However, the relationship between these structural changes and epithelial maturation has remained enigmatic. Using engineered scaffolds that replicate crypt-like geometries, we establish a robust platform for guiding the morphogenesis and differentiation of fetal intestinal cells into mature engineered tissues that mimic their in vivo counterparts. Mechanistically, tissue maturation is driven by cell crowding, leading to reduced YAP1 activation. Modulating YAP signaling in both engineered tissues and the developing mouse intestine alters epithelial lineage specification. These findings uncover a geometry-dependent mechanism that links tissue architecture to cell fate transitions. Our work provides a platform for modeling aspects of intestinal development and offers insights for refining stem cell differentiation protocols and regenerative strategies for intestinal disorders.

AB - During morphogenesis, the intestine undergoes significant structural remodeling, transitioning from a simple tube of immature epithelium into a complex crypt-villus architecture housing mature cell types. However, the relationship between these structural changes and epithelial maturation has remained enigmatic. Using engineered scaffolds that replicate crypt-like geometries, we establish a robust platform for guiding the morphogenesis and differentiation of fetal intestinal cells into mature engineered tissues that mimic their in vivo counterparts. Mechanistically, tissue maturation is driven by cell crowding, leading to reduced YAP1 activation. Modulating YAP signaling in both engineered tissues and the developing mouse intestine alters epithelial lineage specification. These findings uncover a geometry-dependent mechanism that links tissue architecture to cell fate transitions. Our work provides a platform for modeling aspects of intestinal development and offers insights for refining stem cell differentiation protocols and regenerative strategies for intestinal disorders.

U2 - 10.1016/j.stem.2026.01.006

DO - 10.1016/j.stem.2026.01.006

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