A Multiplex Human Pluripotent Stem Cell Platform Defines Molecular and Functional Subclasses of Autism-Related Genes

Autism is a clinically heterogeneous neurodevelopmental disorder characterized by impaired social interactions, restricted interests, and repetitive behaviors. Despite significant advances in the genetics of autism, understanding how genetic changes perturb brain development and affect clinical symp...

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Veröffentlicht in:	Cell stem cell 2020-07, Vol.27 (1), p.35-49.e6
Hauptverfasser:	Cederquist, Gustav Y., Tchieu, Jason, Callahan, Scott J., Ramnarine, Kiran, Ryan, Sean, Zhang, Chao, Rittenhouse, Chelsea, Zeltner, Nadja, Chung, Sun Young, Zhou, Ting, Chen, Shuibing, Betel, Doron, White, Richard M., Tomishima, Mark, Studer, Lorenz
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Sprache:	eng
Schlagworte:	autism Autistic Disorder - genetics Cell Differentiation - genetics genetics human pluripotent stem cells Humans neural development Neurodevelopmental Disorders Neurogenesis Pluripotent Stem Cells prefrontal cortex
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creator	Cederquist, Gustav Y. Tchieu, Jason Callahan, Scott J. Ramnarine, Kiran Ryan, Sean Zhang, Chao Rittenhouse, Chelsea Zeltner, Nadja Chung, Sun Young Zhou, Ting Chen, Shuibing Betel, Doron White, Richard M. Tomishima, Mark Studer, Lorenz
description	Autism is a clinically heterogeneous neurodevelopmental disorder characterized by impaired social interactions, restricted interests, and repetitive behaviors. Despite significant advances in the genetics of autism, understanding how genetic changes perturb brain development and affect clinical symptoms remains elusive. Here, we present a multiplex human pluripotent stem cell (hPSC) platform, in which 30 isogenic disease lines are pooled in a single dish and differentiated into prefrontal cortex (PFC) lineages to efficiently test early-developmental hypotheses of autism. We define subgroups of autism mutations that perturb PFC neurogenesis and are correlated to abnormal WNT/βcatenin responses. Class 1 mutations (8 of 27) inhibit while class 2 mutations (5 of 27) enhance PFC neurogenesis. Remarkably, autism patient data reveal that individuals carrying subclass-specific mutations differ clinically in their corresponding language acquisition profiles. Our study provides a framework to disentangle genetic heterogeneity associated with autism and points toward converging molecular and developmental pathways of diverse autism-associated mutations. [Display omitted] •hPSC-based multiplex platform for interrogation of autism-associated mutations•Prefrontal cortex paradigm in hPSCs identifies autism-related neurogenesis defects•Abnormal WNT/βcatenin responses in class of autism genes with neurogenesis defects•Endophenotypes in hPSCs correlate with clinical data in autism patients Large-scale sequencing studies have identified hundreds of autism-associated genes, yet a systematic understanding of their functional consequences during human neurodevelopment remains elusive. Cederquist et al. develop a pooled human pluripotent stem cell-based phenotypic screening platform and identify subclasses of autism genes with convergent molecular, developmental, and clinical associations.
doi_str_mv	10.1016/j.stem.2020.06.004
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Despite significant advances in the genetics of autism, understanding how genetic changes perturb brain development and affect clinical symptoms remains elusive. Here, we present a multiplex human pluripotent stem cell (hPSC) platform, in which 30 isogenic disease lines are pooled in a single dish and differentiated into prefrontal cortex (PFC) lineages to efficiently test early-developmental hypotheses of autism. We define subgroups of autism mutations that perturb PFC neurogenesis and are correlated to abnormal WNT/βcatenin responses. Class 1 mutations (8 of 27) inhibit while class 2 mutations (5 of 27) enhance PFC neurogenesis. Remarkably, autism patient data reveal that individuals carrying subclass-specific mutations differ clinically in their corresponding language acquisition profiles. Our study provides a framework to disentangle genetic heterogeneity associated with autism and points toward converging molecular and developmental pathways of diverse autism-associated mutations. [Display omitted] •hPSC-based multiplex platform for interrogation of autism-associated mutations•Prefrontal cortex paradigm in hPSCs identifies autism-related neurogenesis defects•Abnormal WNT/βcatenin responses in class of autism genes with neurogenesis defects•Endophenotypes in hPSCs correlate with clinical data in autism patients Large-scale sequencing studies have identified hundreds of autism-associated genes, yet a systematic understanding of their functional consequences during human neurodevelopment remains elusive. Cederquist et al. develop a pooled human pluripotent stem cell-based phenotypic screening platform and identify subclasses of autism genes with convergent molecular, developmental, and clinical associations.</description><identifier>ISSN: 1934-5909</identifier><identifier>EISSN: 1875-9777</identifier><identifier>DOI: 10.1016/j.stem.2020.06.004</identifier><identifier>PMID: 32619517</identifier><language>eng</language><publisher>United States: Elsevier Inc</publisher><subject>autism ; Autistic Disorder - genetics ; Cell Differentiation - genetics ; genetics ; human pluripotent stem cells ; Humans ; neural development ; Neurodevelopmental Disorders ; Neurogenesis ; Pluripotent Stem Cells ; prefrontal cortex</subject><ispartof>Cell stem cell, 2020-07, Vol.27 (1), p.35-49.e6</ispartof><rights>2020 Elsevier Inc.</rights><rights>Copyright © 2020 Elsevier Inc. 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Despite significant advances in the genetics of autism, understanding how genetic changes perturb brain development and affect clinical symptoms remains elusive. Here, we present a multiplex human pluripotent stem cell (hPSC) platform, in which 30 isogenic disease lines are pooled in a single dish and differentiated into prefrontal cortex (PFC) lineages to efficiently test early-developmental hypotheses of autism. We define subgroups of autism mutations that perturb PFC neurogenesis and are correlated to abnormal WNT/βcatenin responses. Class 1 mutations (8 of 27) inhibit while class 2 mutations (5 of 27) enhance PFC neurogenesis. Remarkably, autism patient data reveal that individuals carrying subclass-specific mutations differ clinically in their corresponding language acquisition profiles. Our study provides a framework to disentangle genetic heterogeneity associated with autism and points toward converging molecular and developmental pathways of diverse autism-associated mutations. [Display omitted] •hPSC-based multiplex platform for interrogation of autism-associated mutations•Prefrontal cortex paradigm in hPSCs identifies autism-related neurogenesis defects•Abnormal WNT/βcatenin responses in class of autism genes with neurogenesis defects•Endophenotypes in hPSCs correlate with clinical data in autism patients Large-scale sequencing studies have identified hundreds of autism-associated genes, yet a systematic understanding of their functional consequences during human neurodevelopment remains elusive. Cederquist et al. develop a pooled human pluripotent stem cell-based phenotypic screening platform and identify subclasses of autism genes with convergent molecular, developmental, and clinical associations.</description><subject>autism</subject><subject>Autistic Disorder - genetics</subject><subject>Cell Differentiation - genetics</subject><subject>genetics</subject><subject>human pluripotent stem cells</subject><subject>Humans</subject><subject>neural development</subject><subject>Neurodevelopmental Disorders</subject><subject>Neurogenesis</subject><subject>Pluripotent Stem Cells</subject><subject>prefrontal cortex</subject><issn>1934-5909</issn><issn>1875-9777</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp9kE1v1DAQhi0Eoh_wBzggH7kkjLN2nEhcVlvaIrUCUThbjjOWvHLixR8V_Hu8bOGI5jCj0fO-o3kJecOgZcD69_s2ZVzaDjpooW8B-DNyzgYpmlFK-bzO44Y3YoTxjFyktAcQkoF8Sc42Xc9GweQ5yVt6X3x2B48_6W1Z9Eq_-BLdIWRcM32oB-gOva9bnW2IC71C61ZM9D54NMXrSPU60-uymuzCqj19KJPxOqXKBEu3Jbu0NF-x6nGmN1i1r8gLq33C10_9kny__vhtd9vcfb75tNveNYYD5EZIa0HrCWsN2lpt0UozQy8BzGi7cZpmYzfcjgPvB-TYDeMEU8_MJIQWuLkk706-hxh-FExZLS6Z-o1eMZSkOt4B42IAXtHuhJoYUopo1SG6RcdfioE6pq326pi2OqatoFfwR_T2yb9MC87_JH_jrcCHE4D1y0eHUSXjcDU4u4gmqzm4__n_BoDak5I</recordid><startdate>20200702</startdate><enddate>20200702</enddate><creator>Cederquist, Gustav Y.</creator><creator>Tchieu, Jason</creator><creator>Callahan, Scott J.</creator><creator>Ramnarine, Kiran</creator><creator>Ryan, Sean</creator><creator>Zhang, Chao</creator><creator>Rittenhouse, Chelsea</creator><creator>Zeltner, Nadja</creator><creator>Chung, Sun Young</creator><creator>Zhou, Ting</creator><creator>Chen, Shuibing</creator><creator>Betel, Doron</creator><creator>White, Richard M.</creator><creator>Tomishima, Mark</creator><creator>Studer, Lorenz</creator><general>Elsevier Inc</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope></search><sort><creationdate>20200702</creationdate><title>A Multiplex Human Pluripotent Stem Cell Platform Defines Molecular and Functional Subclasses of Autism-Related Genes</title><author>Cederquist, Gustav Y. ; 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Our study provides a framework to disentangle genetic heterogeneity associated with autism and points toward converging molecular and developmental pathways of diverse autism-associated mutations. [Display omitted] •hPSC-based multiplex platform for interrogation of autism-associated mutations•Prefrontal cortex paradigm in hPSCs identifies autism-related neurogenesis defects•Abnormal WNT/βcatenin responses in class of autism genes with neurogenesis defects•Endophenotypes in hPSCs correlate with clinical data in autism patients Large-scale sequencing studies have identified hundreds of autism-associated genes, yet a systematic understanding of their functional consequences during human neurodevelopment remains elusive. 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subjects	autism Autistic Disorder - genetics Cell Differentiation - genetics genetics human pluripotent stem cells Humans neural development Neurodevelopmental Disorders Neurogenesis Pluripotent Stem Cells prefrontal cortex
title	A Multiplex Human Pluripotent Stem Cell Platform Defines Molecular and Functional Subclasses of Autism-Related Genes
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