Altered extracellular matrix structure and elevated stiffness in a brain organoid model for disease

Maayan Karlinski Zur; Bidisha Bhattacharya; Inna Solomonov; Sivan Ben Dror; Alon Savidor; Yishai Levin; Amir Prior; Tamar Sapir; Talia Harris; Tsviya Olender; Rita Schmidt; J. M. Schwarz; Irit Sagi; Amnon Buxboim; Orly Reiner

doi:10.1038/s41467-025-59252-w

Altered extracellular matrix structure and elevated stiffness in a brain organoid model for disease

Maayan Karlinski Zur, Bidisha Bhattacharya, Inna Solomonov, Sivan Ben Dror, Alon Savidor, Yishai Levin, Amir Prior, Tamar Sapir, Talia Harris, Tsviya Olender, Rita Schmidt, J. M. Schwarz, Irit Sagi^*, Amnon Buxboim^*, Orly Reiner^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

The viscoelastic properties of tissues influence their morphology and cellular behavior, yet little is known about changes in these properties during brain malformations. Lissencephaly, a severe cortical malformation caused by LIS1 mutations, results in a smooth cortex. Here, we show that human-derived brain organoids with LIS1 mutation exhibit increased stiffness compared to controls at multiple developmental stages. This stiffening correlates with abnormal extracellular matrix (ECM) expression and organization, as well as elevated water content, measured by diffusion-weighted MRI. Short-term MMP9 treatment reduces both stiffness and water diffusion levels to control values. Additionally, a computational microstructure mechanical model predicts mechanical changes based on ECM organization. These findings suggest that LIS1 plays a critical role in ECM regulation during brain development and that its mutation leads to significant viscoelastic alterations.

Original language	English
Article number	4094
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-59252-w
State	Published - Dec 2025

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© The Author(s) 2025.

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Karlinski Zur, M., Bhattacharya, B., Solomonov, I., Ben Dror, S., Savidor, A., Levin, Y., Prior, A., Sapir, T., Harris, T., Olender, T., Schmidt, R., Schwarz, J. M., Sagi, I., Buxboim, A., & Reiner, O. (2025). Altered extracellular matrix structure and elevated stiffness in a brain organoid model for disease. Nature Communications, 16(1), Article 4094. https://doi.org/10.1038/s41467-025-59252-w

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abstract = "The viscoelastic properties of tissues influence their morphology and cellular behavior, yet little is known about changes in these properties during brain malformations. Lissencephaly, a severe cortical malformation caused by LIS1 mutations, results in a smooth cortex. Here, we show that human-derived brain organoids with LIS1 mutation exhibit increased stiffness compared to controls at multiple developmental stages. This stiffening correlates with abnormal extracellular matrix (ECM) expression and organization, as well as elevated water content, measured by diffusion-weighted MRI. Short-term MMP9 treatment reduces both stiffness and water diffusion levels to control values. Additionally, a computational microstructure mechanical model predicts mechanical changes based on ECM organization. These findings suggest that LIS1 plays a critical role in ECM regulation during brain development and that its mutation leads to significant viscoelastic alterations.",

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Karlinski Zur, M, Bhattacharya, B, Solomonov, I, Ben Dror, S, Savidor, A, Levin, Y, Prior, A, Sapir, T, Harris, T, Olender, T, Schmidt, R, Schwarz, JM, Sagi, I, Buxboim, A & Reiner, O 2025, 'Altered extracellular matrix structure and elevated stiffness in a brain organoid model for disease', Nature Communications, vol. 16, no. 1, 4094. https://doi.org/10.1038/s41467-025-59252-w

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AU - Savidor, Alon

AU - Levin, Yishai

AU - Prior, Amir

AU - Sapir, Tamar

AU - Harris, Talia

AU - Olender, Tsviya

AU - Schmidt, Rita

AU - Schwarz, J. M.

AU - Sagi, Irit

AU - Buxboim, Amnon

AU - Reiner, Orly

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AB - The viscoelastic properties of tissues influence their morphology and cellular behavior, yet little is known about changes in these properties during brain malformations. Lissencephaly, a severe cortical malformation caused by LIS1 mutations, results in a smooth cortex. Here, we show that human-derived brain organoids with LIS1 mutation exhibit increased stiffness compared to controls at multiple developmental stages. This stiffening correlates with abnormal extracellular matrix (ECM) expression and organization, as well as elevated water content, measured by diffusion-weighted MRI. Short-term MMP9 treatment reduces both stiffness and water diffusion levels to control values. Additionally, a computational microstructure mechanical model predicts mechanical changes based on ECM organization. These findings suggest that LIS1 plays a critical role in ECM regulation during brain development and that its mutation leads to significant viscoelastic alterations.

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Altered extracellular matrix structure and elevated stiffness in a brain organoid model for disease

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