Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System

Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System

Abstract The ability to generate human‐induced pluripotent stem cell (hiPSC)‐derived neural cells displaying region‐specific phenotypes is of particular interest for modeling central nervous system biology in vitro. We describe a unique method by which spinal cord hiPSC‐derived astrocytes (hiPSC‐A)...

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Main Authors: Arens Taga, Raha Dastgheyb, Christa Habela, Jessica Joseph, Jean‐Philippe Richard, Sarah K. Gross, Giuseppe Lauria, Gabsang Lee, Norman Haughey, Nicholas J. Maragakis
Format: Article
Language:English
Published: Wiley 2019-12-01
Series:Stem Cells Translational Medicine
Subjects:
Electrophysiology
Spinal cord
Glutamate receptor
Gap junction
Glia
Online Access:https://doi.org/10.1002/sctm.19-0147
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spelling doaj-90f3a373826542afa217b6c5c8f992af2020-11-25T01:34:39ZengWileyStem Cells Translational Medicine2157-65642157-65802019-12-018121272128510.1002/sctm.19-0147Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array SystemArens Taga0Raha Dastgheyb1Christa Habela2Jessica Joseph3Jean‐Philippe Richard4Sarah K. Gross5Giuseppe Lauria6Gabsang Lee7Norman Haughey8Nicholas J. Maragakis9Department of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USAFondazione I.R.C.C.S. Istituto Neurologico Carlo Besta Milan ItalyDepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USADepartment of Neurology Johns Hopkins University Baltimore Maryland USAAbstract The ability to generate human‐induced pluripotent stem cell (hiPSC)‐derived neural cells displaying region‐specific phenotypes is of particular interest for modeling central nervous system biology in vitro. We describe a unique method by which spinal cord hiPSC‐derived astrocytes (hiPSC‐A) are cultured with spinal cord hiPSC‐derived motor neurons (hiPSC‐MN) in a multielectrode array (MEA) system to record electrophysiological activity over time. We show that hiPSC‐A enhance hiPSC‐MN electrophysiological maturation in a time‐dependent fashion. The sequence of plating, density, and age in which hiPSC‐A are cocultured with MN, but not their respective hiPSC line origin, are factors that influence neuronal electrophysiology. When compared to coculture with mouse primary spinal cord astrocytes, we observe an earlier and more robust electrophysiological maturation in the fully human cultures, suggesting that the human origin is relevant to the recapitulation of astrocyte/motor neuron crosstalk. Finally, we test pharmacological compounds on our MEA platform and observe changes in electrophysiological activity, which confirm hiPSC‐MN maturation. These findings are supported by immunocytochemistry and real‐time PCR studies in parallel cultures demonstrating human astrocyte mediated changes in the structural maturation and protein expression profiles of the neurons. Interestingly, this relationship is reciprocal and coculture with neurons influences astrocyte maturation as well. Taken together, these data indicate that in a human in vitro spinal cord culture system, astrocytes support hiPSC‐MN maturation in a time‐dependent and species‐specific manner and suggest a closer approximation of in vivo conditions. Stem Cells Translational Medicine 2019;8:1272&1285https://doi.org/10.1002/sctm.19-0147ElectrophysiologySpinal cordGlutamate receptorGap junctionGlia
collection DOAJ
language English
format Article
sources DOAJ
author Arens Taga
Raha Dastgheyb
Christa Habela
Jessica Joseph
Jean‐Philippe Richard
Sarah K. Gross
Giuseppe Lauria
Gabsang Lee
Norman Haughey
Nicholas J. Maragakis
spellingShingle Arens Taga
Raha Dastgheyb
Christa Habela
Jessica Joseph
Jean‐Philippe Richard
Sarah K. Gross
Giuseppe Lauria
Gabsang Lee
Norman Haughey
Nicholas J. Maragakis
Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
Stem Cells Translational Medicine
Electrophysiology
Spinal cord
Glutamate receptor
Gap junction
Glia
author_facet Arens Taga
Raha Dastgheyb
Christa Habela
Jessica Joseph
Jean‐Philippe Richard
Sarah K. Gross
Giuseppe Lauria
Gabsang Lee
Norman Haughey
Nicholas J. Maragakis
author_sort Arens Taga
title Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
title_short Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
title_full Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
title_fullStr Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
title_full_unstemmed Role of Human‐Induced Pluripotent Stem Cell‐Derived Spinal Cord Astrocytes in the Functional Maturation of Motor Neurons in a Multielectrode Array System
title_sort role of human‐induced pluripotent stem cell‐derived spinal cord astrocytes in the functional maturation of motor neurons in a multielectrode array system
publisher Wiley
series Stem Cells Translational Medicine
issn 2157-6564
2157-6580
publishDate 2019-12-01
description Abstract The ability to generate human‐induced pluripotent stem cell (hiPSC)‐derived neural cells displaying region‐specific phenotypes is of particular interest for modeling central nervous system biology in vitro. We describe a unique method by which spinal cord hiPSC‐derived astrocytes (hiPSC‐A) are cultured with spinal cord hiPSC‐derived motor neurons (hiPSC‐MN) in a multielectrode array (MEA) system to record electrophysiological activity over time. We show that hiPSC‐A enhance hiPSC‐MN electrophysiological maturation in a time‐dependent fashion. The sequence of plating, density, and age in which hiPSC‐A are cocultured with MN, but not their respective hiPSC line origin, are factors that influence neuronal electrophysiology. When compared to coculture with mouse primary spinal cord astrocytes, we observe an earlier and more robust electrophysiological maturation in the fully human cultures, suggesting that the human origin is relevant to the recapitulation of astrocyte/motor neuron crosstalk. Finally, we test pharmacological compounds on our MEA platform and observe changes in electrophysiological activity, which confirm hiPSC‐MN maturation. These findings are supported by immunocytochemistry and real‐time PCR studies in parallel cultures demonstrating human astrocyte mediated changes in the structural maturation and protein expression profiles of the neurons. Interestingly, this relationship is reciprocal and coculture with neurons influences astrocyte maturation as well. Taken together, these data indicate that in a human in vitro spinal cord culture system, astrocytes support hiPSC‐MN maturation in a time‐dependent and species‐specific manner and suggest a closer approximation of in vivo conditions. Stem Cells Translational Medicine 2019;8:1272&1285
topic Electrophysiology
Spinal cord
Glutamate receptor
Gap junction
Glia
url https://doi.org/10.1002/sctm.19-0147
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