Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening

Anand Ramani; Giovanni Pasquini; Niklas J. Gerkau; Vaibhav Jadhav; Omkar Suhas Vinchure; Nazlican Altinisik; Hannes Windoffer; Sarah Muller; Ina Rothenaigner; Sean Lin; Aruljothi Mariappan; Dhanasekaran Rathinam; Ali Mirsaidi; Olivier Goureau; Lucia Ricci-Vitiani; Quintino Giorgio D’Alessandris; Bernd Wollnik; Alysson Muotri; Limor Freifeld; Nathalie Jurisch-Yaksi; Roberto Pallini; Christine R. Rose; Volker Busskamp; Elke Gabriel; Kamyar Hadian; Jay Gopalakrishnan

doi:https://doi.org/10.1038/s41467-024-55226-6

Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening

Anand Ramani, Giovanni Pasquini, Niklas J. Gerkau, Vaibhav Jadhav, Omkar Suhas Vinchure, Nazlican Altinisik, Hannes Windoffer, Sarah Muller, Ina Rothenaigner, Sean Lin, Aruljothi Mariappan, Dhanasekaran Rathinam, Ali Mirsaidi, Olivier Goureau, Lucia Ricci-Vitiani, Quintino Giorgio D’Alessandris, Bernd Wollnik, Alysson Muotri, Limor Freifeld, Nathalie Jurisch-YaksiRoberto Pallini, Christine R. Rose, Volker Busskamp, Elke Gabriel, Kamyar Hadian, Jay Gopalakrishnan

Biomedical Engineering

Technion - Israel Institute of Technology

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

Abstract

Brain organoids offer unprecedented insights into brain development and disease modeling and hold promise for drug screening. Significant hindrances, however, are morphological and cellular heterogeneity, inter-organoid size differences, cellular stress, and poor reproducibility. Here, we describe a method that reproducibly generates thousands of organoids across multiple hiPSC lines. These High Quantity brain organoids (Hi-Q brain organoids) exhibit reproducible cytoarchitecture, cell diversity, and functionality, are free from ectopically active cellular stress pathways, and allow cryopreservation and re-culturing. Patient-derived Hi-Q brain organoids recapitulate distinct forms of developmental defects: primary microcephaly due to a mutation in CDK5RAP2 and progeria-associated defects of Cockayne syndrome. Hi-Q brain organoids displayed a reproducible invasion pattern for a given patient-derived glioma cell line. This enabled a medium-throughput drug screen to identify Selumetinib and Fulvestrant, as inhibitors of glioma invasion in vivo. Thus, the Hi-Q approach can easily be adapted to reliably harness brain organoids’ application for personalized neurogenetic disease modeling and drug discovery.

Original language	English
Article number	10703
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-55226-6
State	Published - Dec 2024

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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https://doi.org/10.1038/s41467-024-55226-6

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Ramani, A., Pasquini, G., Gerkau, N. J., Jadhav, V., Vinchure, O. S., Altinisik, N., Windoffer, H., Muller, S., Rothenaigner, I., Lin, S., Mariappan, A., Rathinam, D., Mirsaidi, A., Goureau, O., Ricci-Vitiani, L., D’Alessandris, Q. G., Wollnik, B., Muotri, A., Freifeld, L., ... Gopalakrishnan, J. (2024). Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening. Nature Communications, 15(1), Article 10703. https://doi.org/10.1038/s41467-024-55226-6

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title = "Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening",

abstract = "Brain organoids offer unprecedented insights into brain development and disease modeling and hold promise for drug screening. Significant hindrances, however, are morphological and cellular heterogeneity, inter-organoid size differences, cellular stress, and poor reproducibility. Here, we describe a method that reproducibly generates thousands of organoids across multiple hiPSC lines. These High Quantity brain organoids (Hi-Q brain organoids) exhibit reproducible cytoarchitecture, cell diversity, and functionality, are free from ectopically active cellular stress pathways, and allow cryopreservation and re-culturing. Patient-derived Hi-Q brain organoids recapitulate distinct forms of developmental defects: primary microcephaly due to a mutation in CDK5RAP2 and progeria-associated defects of Cockayne syndrome. Hi-Q brain organoids displayed a reproducible invasion pattern for a given patient-derived glioma cell line. This enabled a medium-throughput drug screen to identify Selumetinib and Fulvestrant, as inhibitors of glioma invasion in vivo. Thus, the Hi-Q approach can easily be adapted to reliably harness brain organoids{\textquoteright} application for personalized neurogenetic disease modeling and drug discovery.",

author = "Anand Ramani and Giovanni Pasquini and Gerkau, {Niklas J.} and Vaibhav Jadhav and Vinchure, {Omkar Suhas} and Nazlican Altinisik and Hannes Windoffer and Sarah Muller and Ina Rothenaigner and Sean Lin and Aruljothi Mariappan and Dhanasekaran Rathinam and Ali Mirsaidi and Olivier Goureau and Lucia Ricci-Vitiani and D{\textquoteright}Alessandris, {Quintino Giorgio} and Bernd Wollnik and Alysson Muotri and Limor Freifeld and Nathalie Jurisch-Yaksi and Roberto Pallini and Rose, {Christine R.} and Volker Busskamp and Elke Gabriel and Kamyar Hadian and Jay Gopalakrishnan",

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doi = "https://doi.org/10.1038/s41467-024-55226-6",

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Ramani, A, Pasquini, G, Gerkau, NJ, Jadhav, V, Vinchure, OS, Altinisik, N, Windoffer, H, Muller, S, Rothenaigner, I, Lin, S, Mariappan, A, Rathinam, D, Mirsaidi, A, Goureau, O, Ricci-Vitiani, L, D’Alessandris, QG, Wollnik, B, Muotri, A, Freifeld, L, Jurisch-Yaksi, N, Pallini, R, Rose, CR, Busskamp, V, Gabriel, E, Hadian, K & Gopalakrishnan, J 2024, 'Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening', Nature Communications, vol. 15, no. 1, 10703. https://doi.org/10.1038/s41467-024-55226-6

TY - JOUR

T1 - Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening

AU - Ramani, Anand

AU - Pasquini, Giovanni

AU - Gerkau, Niklas J.

AU - Jadhav, Vaibhav

AU - Vinchure, Omkar Suhas

AU - Altinisik, Nazlican

AU - Windoffer, Hannes

AU - Muller, Sarah

AU - Rothenaigner, Ina

AU - Lin, Sean

AU - Mariappan, Aruljothi

AU - Rathinam, Dhanasekaran

AU - Mirsaidi, Ali

AU - Goureau, Olivier

AU - Ricci-Vitiani, Lucia

AU - D’Alessandris, Quintino Giorgio

AU - Wollnik, Bernd

AU - Muotri, Alysson

AU - Freifeld, Limor

AU - Jurisch-Yaksi, Nathalie

AU - Pallini, Roberto

AU - Rose, Christine R.

AU - Busskamp, Volker

AU - Gabriel, Elke

AU - Hadian, Kamyar

AU - Gopalakrishnan, Jay

PY - 2024/12

Y1 - 2024/12

N2 - Brain organoids offer unprecedented insights into brain development and disease modeling and hold promise for drug screening. Significant hindrances, however, are morphological and cellular heterogeneity, inter-organoid size differences, cellular stress, and poor reproducibility. Here, we describe a method that reproducibly generates thousands of organoids across multiple hiPSC lines. These High Quantity brain organoids (Hi-Q brain organoids) exhibit reproducible cytoarchitecture, cell diversity, and functionality, are free from ectopically active cellular stress pathways, and allow cryopreservation and re-culturing. Patient-derived Hi-Q brain organoids recapitulate distinct forms of developmental defects: primary microcephaly due to a mutation in CDK5RAP2 and progeria-associated defects of Cockayne syndrome. Hi-Q brain organoids displayed a reproducible invasion pattern for a given patient-derived glioma cell line. This enabled a medium-throughput drug screen to identify Selumetinib and Fulvestrant, as inhibitors of glioma invasion in vivo. Thus, the Hi-Q approach can easily be adapted to reliably harness brain organoids’ application for personalized neurogenetic disease modeling and drug discovery.

AB - Brain organoids offer unprecedented insights into brain development and disease modeling and hold promise for drug screening. Significant hindrances, however, are morphological and cellular heterogeneity, inter-organoid size differences, cellular stress, and poor reproducibility. Here, we describe a method that reproducibly generates thousands of organoids across multiple hiPSC lines. These High Quantity brain organoids (Hi-Q brain organoids) exhibit reproducible cytoarchitecture, cell diversity, and functionality, are free from ectopically active cellular stress pathways, and allow cryopreservation and re-culturing. Patient-derived Hi-Q brain organoids recapitulate distinct forms of developmental defects: primary microcephaly due to a mutation in CDK5RAP2 and progeria-associated defects of Cockayne syndrome. Hi-Q brain organoids displayed a reproducible invasion pattern for a given patient-derived glioma cell line. This enabled a medium-throughput drug screen to identify Selumetinib and Fulvestrant, as inhibitors of glioma invasion in vivo. Thus, the Hi-Q approach can easily be adapted to reliably harness brain organoids’ application for personalized neurogenetic disease modeling and drug discovery.

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U2 - https://doi.org/10.1038/s41467-024-55226-6

DO - https://doi.org/10.1038/s41467-024-55226-6

M3 - مقالة

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 10703

ER -

Reliability of high-quantity human brain organoids for modeling microcephaly, glioma invasion and drug screening

Abstract

All Science Journal Classification (ASJC) codes

UN SDGs

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