Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells

Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells

Abstract Background Autism spectrum disorder (ASD) is a neurodevelopmental disorder with a high co-morbidity of epilepsy and associated with hundreds of rare risk factors. NRXN1 deletion is among the commonest rare genetic factors shared by ASD, schizophrenia, intellectual disability, epilepsy, and...

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Main Authors: Sahar Avazzadeh, Katya McDonagh, Jamie Reilly, Yanqin Wang, Stephanie D. Boomkamp, Veronica McInerney, Janusz Krawczyk, Jacqueline Fitzgerald, Niamh Feerick, Matthew O’Sullivan, Amirhossein Jalali, Eva B. Forman, Sally A. Lynch, Sean Ennis, Nele Cosemans, Hilde Peeters, Peter Dockery, Timothy O’Brien, Leo R. Quinlan, Louise Gallagher, Sanbing Shen
Format: Article
Language:English
Published: BMC 2019-12-01
Series:Molecular Autism
Subjects:
Autism
Calcium signaling
Induced pluripotent stem cells
Neurons
NRXN1α
Transcriptome
Online Access:https://doi.org/10.1186/s13229-019-0303-3
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language English
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author Sahar Avazzadeh
Katya McDonagh
Jamie Reilly
Yanqin Wang
Stephanie D. Boomkamp
Veronica McInerney
Janusz Krawczyk
Jacqueline Fitzgerald
Niamh Feerick
Matthew O’Sullivan
Amirhossein Jalali
Eva B. Forman
Sally A. Lynch
Sean Ennis
Nele Cosemans
Hilde Peeters
Peter Dockery
Timothy O’Brien
Leo R. Quinlan
Louise Gallagher
Sanbing Shen
spellingShingle Sahar Avazzadeh
Katya McDonagh
Jamie Reilly
Yanqin Wang
Stephanie D. Boomkamp
Veronica McInerney
Janusz Krawczyk
Jacqueline Fitzgerald
Niamh Feerick
Matthew O’Sullivan
Amirhossein Jalali
Eva B. Forman
Sally A. Lynch
Sean Ennis
Nele Cosemans
Hilde Peeters
Peter Dockery
Timothy O’Brien
Leo R. Quinlan
Louise Gallagher
Sanbing Shen
Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
Molecular Autism
Autism
Calcium signaling
Induced pluripotent stem cells
Neurons
NRXN1α
Transcriptome
author_facet Sahar Avazzadeh
Katya McDonagh
Jamie Reilly
Yanqin Wang
Stephanie D. Boomkamp
Veronica McInerney
Janusz Krawczyk
Jacqueline Fitzgerald
Niamh Feerick
Matthew O’Sullivan
Amirhossein Jalali
Eva B. Forman
Sally A. Lynch
Sean Ennis
Nele Cosemans
Hilde Peeters
Peter Dockery
Timothy O’Brien
Leo R. Quinlan
Louise Gallagher
Sanbing Shen
author_sort Sahar Avazzadeh
title Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
title_short Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
title_full Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
title_fullStr Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
title_full_unstemmed Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cells
title_sort increased ca2+ signaling in nrxn1α +/− neurons derived from asd induced pluripotent stem cells
publisher BMC
series Molecular Autism
issn 2040-2392
publishDate 2019-12-01
description Abstract Background Autism spectrum disorder (ASD) is a neurodevelopmental disorder with a high co-morbidity of epilepsy and associated with hundreds of rare risk factors. NRXN1 deletion is among the commonest rare genetic factors shared by ASD, schizophrenia, intellectual disability, epilepsy, and developmental delay. However, how NRXN1 deletions lead to different clinical symptoms is unknown. Patient-derived cells are essential to investigate the functional consequences of NRXN1 lesions to human neurons in different diseases. Methods Skin biopsies were donated by five healthy donors and three ASD patients carrying NRXN1α +/− deletions. Seven control and six NRXN1α +/− iPSC lines were derived and differentiated into day 100 cortical excitatory neurons using dual SMAD inhibition. Calcium (Ca2+) imaging was performed using Fluo4-AM, and the properties of Ca2+ transients were compared between two groups of neurons. Transcriptome analysis was carried out to undercover molecular pathways associated with NRXN1α +/− neurons. Results NRXN1α +/− neurons were found to display altered calcium dynamics, with significantly increased frequency, duration, and amplitude of Ca2+ transients. Whole genome RNA sequencing also revealed altered ion transport and transporter activity, with upregulated voltage-gated calcium channels as one of the most significant pathways in NRXN1α +/− neurons identified by STRING and GSEA analyses. Conclusions This is the first report to show that human NRXN1α +/− neurons derived from ASD patients’ iPSCs present novel phenotypes of upregulated VGCCs and increased Ca2+ transients, which may facilitate the development of drug screening assays for the treatment of ASD.
topic Autism
Calcium signaling
Induced pluripotent stem cells
Neurons
NRXN1α
Transcriptome
url https://doi.org/10.1186/s13229-019-0303-3
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spelling doaj-b803d63fdbf846af810983483fa07c782021-01-03T12:09:59ZengBMCMolecular Autism2040-23922019-12-0110111610.1186/s13229-019-0303-3Increased Ca2+ signaling in NRXN1α +/− neurons derived from ASD induced pluripotent stem cellsSahar Avazzadeh0Katya McDonagh1Jamie Reilly2Yanqin Wang3Stephanie D. Boomkamp4Veronica McInerney5Janusz Krawczyk6Jacqueline Fitzgerald7Niamh Feerick8Matthew O’Sullivan9Amirhossein Jalali10Eva B. Forman11Sally A. Lynch12Sean Ennis13Nele Cosemans14Hilde Peeters15Peter Dockery16Timothy O’Brien17Leo R. Quinlan18Louise Gallagher19Sanbing Shen20Regenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayRegenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayRegenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayRegenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayRegenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayHRB Clinical Research Facility, National University of Ireland (NUI)Department of Haematology, Galway University HospitalSchool of Medicine, Trinity College DublinSchool of Medicine, Trinity College DublinSchool of Medicine, Trinity College DublinSchool of Medicine, Conway Institute, University College DublinChildren’s University HospitalDepartment of Clinical Genetics, OLCHCUCD Academic Centre on Rare Diseases, School of Medicine and Medical Science, University College DublinCentre for Human Genetics, University Hospital LeuvenAcademic Center on Rare Diseases, School of Medicine and Medical Science, University College DublinCentre for Microscopy and Imaging, Anatomy, School of Medicine, National University of Ireland (NUI)Regenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayPhysiology and Human Movement Laboratory, CÚRAM SFI Centre for Research in Medical Devices, School of Medicine, National University of Ireland (NUI)School of Medicine, Trinity College DublinRegenerative Medicine Institute, School of Medicine, Biomedical Science Building BMS-1021, National University of Ireland GalwayAbstract Background Autism spectrum disorder (ASD) is a neurodevelopmental disorder with a high co-morbidity of epilepsy and associated with hundreds of rare risk factors. NRXN1 deletion is among the commonest rare genetic factors shared by ASD, schizophrenia, intellectual disability, epilepsy, and developmental delay. However, how NRXN1 deletions lead to different clinical symptoms is unknown. Patient-derived cells are essential to investigate the functional consequences of NRXN1 lesions to human neurons in different diseases. Methods Skin biopsies were donated by five healthy donors and three ASD patients carrying NRXN1α +/− deletions. Seven control and six NRXN1α +/− iPSC lines were derived and differentiated into day 100 cortical excitatory neurons using dual SMAD inhibition. Calcium (Ca2+) imaging was performed using Fluo4-AM, and the properties of Ca2+ transients were compared between two groups of neurons. Transcriptome analysis was carried out to undercover molecular pathways associated with NRXN1α +/− neurons. Results NRXN1α +/− neurons were found to display altered calcium dynamics, with significantly increased frequency, duration, and amplitude of Ca2+ transients. Whole genome RNA sequencing also revealed altered ion transport and transporter activity, with upregulated voltage-gated calcium channels as one of the most significant pathways in NRXN1α +/− neurons identified by STRING and GSEA analyses. Conclusions This is the first report to show that human NRXN1α +/− neurons derived from ASD patients’ iPSCs present novel phenotypes of upregulated VGCCs and increased Ca2+ transients, which may facilitate the development of drug screening assays for the treatment of ASD.https://doi.org/10.1186/s13229-019-0303-3AutismCalcium signalingInduced pluripotent stem cellsNeuronsNRXN1αTranscriptome

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