Mutant C9orf72 human iPSC-derived astrocytes cause non-cell autonomous motor neuron pathophysiology

Chen Zhao; Anna-Claire Devlin; Amit Kumar Chouhan; Bhuvaneish Selvaraj; Maria Stavrou; Karen Burr; Veronica Brivio; Xin He; Arpan Mehta; David  Story; Christopher Shaw; Owen Dando; Giles  Hardingham; Gareth Brian Miles; Siddharthan Chandran

doi:10.1002/glia.23761

Mutant C9orf72 human iPSC-derived astrocytes cause non-cell autonomous motor neuron pathophysiology

Chen Zhao, Anna-Claire Devlin, Amit Kumar Chouhan, Bhuvaneish Selvaraj, Maria Stavrou, Karen Burr, Veronica Brivio, Xin He, Arpan Mehta, David Story, Christopher Shaw, Owen Dando, Giles Hardingham, Gareth Brian Miles, Siddharthan Chandran

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

Abstract

Mutations in C9orf72 are the most common genetic cause of amyotrophic lateral sclerosis (ALS). Accumulating evidence implicates astrocytes as important non‐cell autonomous contributors to ALS pathogenesis, although the potential deleterious effects of astrocytes on the function of motor neurons remains to be determined in a completely humanized model of C9orf72 ‐mediated ALS. Here, we use a human iPSC‐based model to study the cell autonomous and non‐autonomous consequences of mutant C9orf72 expression by astrocytes. We show that mutant astrocytes both recapitulate key aspects of C9orf72 ‐related ALS pathology and, upon co‐culture, cause motor neurons to undergo a progressive loss of action potential output due to decreases in the magnitude of voltage‐activated Na⁺ and K⁺ currents. Importantly, CRISPR/Cas‐9 mediated excision of the C9orf72 repeat expansion reverses these phenotypes, confirming that the C9orf72 mutation is responsible for both cell‐autonomous astrocyte pathology and non‐cell autonomous motor neuron pathophysiology.

Original language	English
Pages (from-to)	1046-1064
Number of pages	19
Journal	Glia
Volume	68
Issue number	5
Early online date	16 Dec 2019
DOIs	https://doi.org/10.1002/glia.23761
Publication status	Published - 11 Mar 2020

Keywords

ALS
C9orf72
iPSCs
Motor neuron
Non-cell autonomous

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10.1002/glia.23761Licence: CC BY

Zhao_2019_Glia_C9orf72_CC
Copyright © 2019 The Authors. GLIA published by Wiley Periodicals, Inc. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
Final published version, 6.63 MBLicence: CC BY

MNDA Studentship: Deciphering mechanisms underlying the dysfunction of motoneorons derived from ALS patient iPSCs
Miles, G. B. (PI)
27/09/15 → 26/09/18
Project: Studentship
Edin Uni: EMC MNDA Studentship 2014
Miles, G. B. (PI)
1/10/14 → 30/09/15
Project: Studentship
Deciphering non-cell autonomous: Deciphering non-cell autonomous disease mechanisms in human ALS using inducible pluripotent stem (iPS) cell technology
Miles, G. B. (PI)
1/10/13 → 31/03/14
Project: Studentship

Gareth Brian Miles
- gbm4st-andrews.acuk
- School of Psychology and Neuroscience - Professor of Neuroscience
- Sir James Mackenzie Institute for Early Diagnosis
- Centre for Biophotonics
- Institute of Behavioural and Neural Sciences - Director
Person: Academic

Cite this

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title = "Mutant C9orf72 human iPSC-derived astrocytes cause non-cell autonomous motor neuron pathophysiology",

abstract = "Mutations in C9orf72 are the most common genetic cause of amyotrophic lateral sclerosis (ALS). Accumulating evidence implicates astrocytes as important non‐cell autonomous contributors to ALS pathogenesis, although the potential deleterious effects of astrocytes on the function of motor neurons remains to be determined in a completely humanized model of C9orf72 ‐mediated ALS. Here, we use a human iPSC‐based model to study the cell autonomous and non‐autonomous consequences of mutant C9orf72 expression by astrocytes. We show that mutant astrocytes both recapitulate key aspects of C9orf72 ‐related ALS pathology and, upon co‐culture, cause motor neurons to undergo a progressive loss of action potential output due to decreases in the magnitude of voltage‐activated Na+ and K+ currents. Importantly, CRISPR/Cas‐9 mediated excision of the C9orf72 repeat expansion reverses these phenotypes, confirming that the C9orf72 mutation is responsible for both cell‐autonomous astrocyte pathology and non‐cell autonomous motor neuron pathophysiology.",

keywords = "ALS, C9orf72, iPSCs, Motor neuron, Non-cell autonomous",

author = "Chen Zhao and Anna-Claire Devlin and Chouhan, {Amit Kumar} and Bhuvaneish Selvaraj and Maria Stavrou and Karen Burr and Veronica Brivio and Xin He and Arpan Mehta and David Story and Christopher Shaw and Owen Dando and Giles Hardingham and Miles, {Gareth Brian} and Siddharthan Chandran",

note = "This work has been supported by: Motor Neurone Disease Association (Miles/Oct 2014/878-792), Euan MacDonald Centre, Motor Neurone Disease Scotland, Dementias Platform UK (DPUK)-MRC stem cell partnership, MS Society and UK Dementia Research Institute. C.Z was funded by China Scholarship Council. A.R.M. and M.S are funded by the Medical Research Council and the Motor Neurone Disease Association. They also acknowledge support from the Rowling Scholars scheme, administered by the Anne Rowling Regenerative Neurology Clinic, University of Edinburgh, Edinburgh, UK.",

year = "2020",

month = mar,

day = "11",

doi = "10.1002/glia.23761",

language = "English",

volume = "68",

pages = "1046--1064",

journal = "Glia",

issn = "0894-1491",

publisher = "John Wiley & Sons, Ltd",

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T1 - Mutant C9orf72 human iPSC-derived astrocytes cause non-cell autonomous motor neuron pathophysiology

AU - Zhao, Chen

AU - Devlin, Anna-Claire

AU - Chouhan, Amit Kumar

AU - Selvaraj, Bhuvaneish

AU - Stavrou, Maria

AU - Burr, Karen

AU - Brivio, Veronica

AU - He, Xin

AU - Mehta, Arpan

AU - Story, David

AU - Shaw, Christopher

AU - Dando, Owen

AU - Hardingham, Giles

AU - Miles, Gareth Brian

AU - Chandran, Siddharthan

N1 - This work has been supported by: Motor Neurone Disease Association (Miles/Oct 2014/878-792), Euan MacDonald Centre, Motor Neurone Disease Scotland, Dementias Platform UK (DPUK)-MRC stem cell partnership, MS Society and UK Dementia Research Institute. C.Z was funded by China Scholarship Council. A.R.M. and M.S are funded by the Medical Research Council and the Motor Neurone Disease Association. They also acknowledge support from the Rowling Scholars scheme, administered by the Anne Rowling Regenerative Neurology Clinic, University of Edinburgh, Edinburgh, UK.

PY - 2020/3/11

Y1 - 2020/3/11

N2 - Mutations in C9orf72 are the most common genetic cause of amyotrophic lateral sclerosis (ALS). Accumulating evidence implicates astrocytes as important non‐cell autonomous contributors to ALS pathogenesis, although the potential deleterious effects of astrocytes on the function of motor neurons remains to be determined in a completely humanized model of C9orf72 ‐mediated ALS. Here, we use a human iPSC‐based model to study the cell autonomous and non‐autonomous consequences of mutant C9orf72 expression by astrocytes. We show that mutant astrocytes both recapitulate key aspects of C9orf72 ‐related ALS pathology and, upon co‐culture, cause motor neurons to undergo a progressive loss of action potential output due to decreases in the magnitude of voltage‐activated Na+ and K+ currents. Importantly, CRISPR/Cas‐9 mediated excision of the C9orf72 repeat expansion reverses these phenotypes, confirming that the C9orf72 mutation is responsible for both cell‐autonomous astrocyte pathology and non‐cell autonomous motor neuron pathophysiology.

AB - Mutations in C9orf72 are the most common genetic cause of amyotrophic lateral sclerosis (ALS). Accumulating evidence implicates astrocytes as important non‐cell autonomous contributors to ALS pathogenesis, although the potential deleterious effects of astrocytes on the function of motor neurons remains to be determined in a completely humanized model of C9orf72 ‐mediated ALS. Here, we use a human iPSC‐based model to study the cell autonomous and non‐autonomous consequences of mutant C9orf72 expression by astrocytes. We show that mutant astrocytes both recapitulate key aspects of C9orf72 ‐related ALS pathology and, upon co‐culture, cause motor neurons to undergo a progressive loss of action potential output due to decreases in the magnitude of voltage‐activated Na+ and K+ currents. Importantly, CRISPR/Cas‐9 mediated excision of the C9orf72 repeat expansion reverses these phenotypes, confirming that the C9orf72 mutation is responsible for both cell‐autonomous astrocyte pathology and non‐cell autonomous motor neuron pathophysiology.

KW - ALS

KW - C9orf72

KW - iPSCs

KW - Motor neuron

KW - Non-cell autonomous

U2 - 10.1002/glia.23761

DO - 10.1002/glia.23761

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SN - 0894-1491

VL - 68

SP - 1046

EP - 1064

JO - Glia

JF - Glia

IS - 5

ER -

Mutant C9orf72 human iPSC-derived astrocytes cause non-cell autonomous motor neuron pathophysiology

Abstract

Keywords

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Projects

MNDA Studentship: Deciphering mechanisms underlying the dysfunction of motoneorons derived from ALS patient iPSCs

Edin Uni: EMC MNDA Studentship 2014

Deciphering non-cell autonomous: Deciphering non-cell autonomous disease mechanisms in human ALS using inducible pluripotent stem (iPS) cell technology

Profiles

Gareth Brian Miles

Cite this