Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids

M. Bertin; H. Todorov; S. Frank; S. Käseberg; R. Menon; E. Gabassi; C. Foerster; N. Bobon; F. Furlanetto; A. Soliman; H. M. B. Ibrahim; V. Engelhardt; L. Birschmann; H. Brennenstuhl; B. Lohrer; A. Mas-Sanchez; E. Cesare; J. Winter; J. Krummeich; J. Winkler; B. Winner; E. Weis; S. Diederich; K. Luck; P. Lunt; S. Gerber; P. Baumann; N. Elvassore; B. Berninger; MF Basilicata; S. Schweiger; S. Falk; M. Karow

doi:10.1038/s41467-026-68428-x

Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids

M. Bertin, H. Todorov, S. Frank, S. Käseberg, R. Menon, E. Gabassi, C. Foerster, N. Bobon, F. Furlanetto, A. Soliman, H. M. B. Ibrahim, V. Engelhardt, L. Birschmann, H. Brennenstuhl, B. Lohrer, A. Mas-Sanchez, E. Cesare, J. Winter, J. Krummeich, J. WinklerB. Winner, E. Weis, S. Diederich, K. Luck, P. Lunt, S. Gerber, P. Baumann, N. Elvassore, B. Berninger, MF Basilicata, S. Schweiger^*, S. Falk^*, M. Karow^*

^*Corresponding author for this work

Bristol Medical School (PHS)

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

While random X-chromosome inactivation in female cells of placental mammals silences one allele of the majority of X-chromosomal genes, a considerable fraction is only incompletely and variably inactivated. Human model systems to study the dynamics of incomplete X-inactivation are limited mostly to postmortem tissue, thereby disregarding developmental trajectories. Here, we used clonal human female induced pluripotent stem cells to track allele-specific expression of X-chromosomal genes along neural differentiation. We discovered dynamic reactivation and late-silencing of gene expression from the inactive X-chromosome leading to differentiation-induced locus- and lineage-specific usage of the two X-chromosomal alleles. In brain organoids modeling Opitz BBB/G syndrome, an X-linked neurodevelopmental disorder, reactivation of alleles from the inactive X-chromosome rescued cellular phenotypes and led to intermediate manifestations in female tissue. Taken together, our data demonstrate that alleles on the inactive X-chromosome can serve as a critical reservoir dynamically used during differentiation, thereby enhancing resilience of female neural tissue.

Original language	English
Article number	599
Number of pages	22
Journal	Nature Communications
Volume	17
Issue number	1
Early online date	14 Jan 2026
DOIs	https://doi.org/10.1038/s41467-026-68428-x
Publication status	Published - 15 Jan 2026

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Bertin, M., Todorov, H., Frank, S., Käseberg, S., Menon, R., Gabassi, E., Foerster, C., Bobon, N., Furlanetto, F., Soliman, A., Ibrahim, H. M. B., Engelhardt, V., Birschmann, L., Brennenstuhl, H., Lohrer, B., Mas-Sanchez, A., Cesare, E., Winter, J., Krummeich, J., ... Karow, M. (2026). Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids. Nature Communications, 17(1), Article 599. https://doi.org/10.1038/s41467-026-68428-x

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title = "Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids",

abstract = "While random X-chromosome inactivation in female cells of placental mammals silences one allele of the majority of X-chromosomal genes, a considerable fraction is only incompletely and variably inactivated. Human model systems to study the dynamics of incomplete X-inactivation are limited mostly to postmortem tissue, thereby disregarding developmental trajectories. Here, we used clonal human female induced pluripotent stem cells to track allele-specific expression of X-chromosomal genes along neural differentiation. We discovered dynamic reactivation and late-silencing of gene expression from the inactive X-chromosome leading to differentiation-induced locus- and lineage-specific usage of the two X-chromosomal alleles. In brain organoids modeling Opitz BBB/G syndrome, an X-linked neurodevelopmental disorder, reactivation of alleles from the inactive X-chromosome rescued cellular phenotypes and led to intermediate manifestations in female tissue. Taken together, our data demonstrate that alleles on the inactive X-chromosome can serve as a critical reservoir dynamically used during differentiation, thereby enhancing resilience of female neural tissue.",

author = "M. Bertin and H. Todorov and S. Frank and S. K{\"a}seberg and R. Menon and E. Gabassi and C. Foerster and N. Bobon and F. Furlanetto and A. Soliman and Ibrahim, \{H. M. B.\} and V. Engelhardt and L. Birschmann and H. Brennenstuhl and B. Lohrer and A. Mas-Sanchez and E. Cesare and J. Winter and J. Krummeich and J. Winkler and B. Winner and E. Weis and S. Diederich and K. Luck and P. Lunt and S. Gerber and P. Baumann and N. Elvassore and B. Berninger and MF Basilicata and S. Schweiger and S. Falk and M. Karow",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = jan,

day = "15",

doi = "10.1038/s41467-026-68428-x",

language = "English",

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Bertin, M, Todorov, H, Frank, S, Käseberg, S, Menon, R, Gabassi, E, Foerster, C, Bobon, N, Furlanetto, F, Soliman, A, Ibrahim, HMB, Engelhardt, V, Birschmann, L, Brennenstuhl, H, Lohrer, B, Mas-Sanchez, A, Cesare, E, Winter, J, Krummeich, J, Winkler, J, Winner, B, Weis, E, Diederich, S, Luck, K, Lunt, P, Gerber, S, Baumann, P, Elvassore, N, Berninger, B, Basilicata, MF, Schweiger, S, Falk, S & Karow, M 2026, 'Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids', Nature Communications, vol. 17, no. 1, 599. https://doi.org/10.1038/s41467-026-68428-x

TY - JOUR

T1 - Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids

AU - Bertin, M.

AU - Todorov, H.

AU - Frank, S.

AU - Käseberg, S.

AU - Menon, R.

AU - Gabassi, E.

AU - Foerster, C.

AU - Bobon, N.

AU - Furlanetto, F.

AU - Soliman, A.

AU - Ibrahim, H. M. B.

AU - Engelhardt, V.

AU - Birschmann, L.

AU - Brennenstuhl, H.

AU - Lohrer, B.

AU - Mas-Sanchez, A.

AU - Cesare, E.

AU - Winter, J.

AU - Krummeich, J.

AU - Winkler, J.

AU - Winner, B.

AU - Weis, E.

AU - Diederich, S.

AU - Luck, K.

AU - Lunt, P.

AU - Gerber, S.

AU - Baumann, P.

AU - Elvassore, N.

AU - Berninger, B.

AU - Basilicata, MF

AU - Schweiger, S.

AU - Falk, S.

AU - Karow, M.

PY - 2026/1/15

Y1 - 2026/1/15

N2 - While random X-chromosome inactivation in female cells of placental mammals silences one allele of the majority of X-chromosomal genes, a considerable fraction is only incompletely and variably inactivated. Human model systems to study the dynamics of incomplete X-inactivation are limited mostly to postmortem tissue, thereby disregarding developmental trajectories. Here, we used clonal human female induced pluripotent stem cells to track allele-specific expression of X-chromosomal genes along neural differentiation. We discovered dynamic reactivation and late-silencing of gene expression from the inactive X-chromosome leading to differentiation-induced locus- and lineage-specific usage of the two X-chromosomal alleles. In brain organoids modeling Opitz BBB/G syndrome, an X-linked neurodevelopmental disorder, reactivation of alleles from the inactive X-chromosome rescued cellular phenotypes and led to intermediate manifestations in female tissue. Taken together, our data demonstrate that alleles on the inactive X-chromosome can serve as a critical reservoir dynamically used during differentiation, thereby enhancing resilience of female neural tissue.

AB - While random X-chromosome inactivation in female cells of placental mammals silences one allele of the majority of X-chromosomal genes, a considerable fraction is only incompletely and variably inactivated. Human model systems to study the dynamics of incomplete X-inactivation are limited mostly to postmortem tissue, thereby disregarding developmental trajectories. Here, we used clonal human female induced pluripotent stem cells to track allele-specific expression of X-chromosomal genes along neural differentiation. We discovered dynamic reactivation and late-silencing of gene expression from the inactive X-chromosome leading to differentiation-induced locus- and lineage-specific usage of the two X-chromosomal alleles. In brain organoids modeling Opitz BBB/G syndrome, an X-linked neurodevelopmental disorder, reactivation of alleles from the inactive X-chromosome rescued cellular phenotypes and led to intermediate manifestations in female tissue. Taken together, our data demonstrate that alleles on the inactive X-chromosome can serve as a critical reservoir dynamically used during differentiation, thereby enhancing resilience of female neural tissue.

U2 - 10.1038/s41467-026-68428-x

DO - 10.1038/s41467-026-68428-x

M3 - Article (Academic Journal)

C2 - 41535291

SN - 2041-1723

VL - 17

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 599

ER -

Dynamic allele usage of X-linked genes ameliorates neurodevelopmental disease phenotypes in brain organoids

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