TY - JOUR
T1 - Disease-specific phenotypes in iPSC-derived neural stem cells with POLG mutations
AU - Liang, Kristina Xiao
AU - Kristiansen, Cecilie Katrin
AU - Mostafavi, Sepideh
AU - Vatne, Guro Helén
AU - Zantingh, Gina Alien
AU - Kianian, Atefeh
AU - Tzoulis, Charalampos
AU - Høyland, Lena Elise
AU - Ziegler, Mathias
AU - Perez, Roberto Megias
AU - Furriol, Jessica
AU - Zhang, Zhuoyuan
AU - Balafkan, Novin
AU - Hong, Yu
AU - Siller, Richard
AU - Sullivan, Gareth John
AU - Bindoff, Laurence A
N1 - © 2020 The Authors. Published under the terms of the CC BY 4.0 license.
PY - 2020/10/7
Y1 - 2020/10/7
N2 - Mutations in POLG disrupt mtDNA replication and cause devastating diseases often with neurological phenotypes. Defining disease mechanisms has been hampered by limited access to human tissues, particularly neurons. Using patient cells carrying POLG mutations, we generated iPSCs and then neural stem cells. These neural precursors manifested a phenotype that faithfully replicated the molecular and biochemical changes found in patient post-mortem brain tissue. We confirmed the same loss of mtDNA and complex I in dopaminergic neurons generated from the same stem cells. POLG-driven mitochondrial dysfunction led to neuronal ROS overproduction and increased cellular senescence. Loss of complex I was associated with disturbed NAD+ metabolism with increased UCP2 expression and reduced phosphorylated SirT1. In cells with compound heterozygous POLG mutations, we also found activated mitophagy via the BNIP3 pathway. Our studies are the first that show it is possible to recapitulate the neuronal molecular and biochemical defects associated with POLG mutation in a human stem cell model. Further, our data provide insight into how mitochondrial dysfunction and mtDNA alterations influence cellular fate determining processes.
AB - Mutations in POLG disrupt mtDNA replication and cause devastating diseases often with neurological phenotypes. Defining disease mechanisms has been hampered by limited access to human tissues, particularly neurons. Using patient cells carrying POLG mutations, we generated iPSCs and then neural stem cells. These neural precursors manifested a phenotype that faithfully replicated the molecular and biochemical changes found in patient post-mortem brain tissue. We confirmed the same loss of mtDNA and complex I in dopaminergic neurons generated from the same stem cells. POLG-driven mitochondrial dysfunction led to neuronal ROS overproduction and increased cellular senescence. Loss of complex I was associated with disturbed NAD+ metabolism with increased UCP2 expression and reduced phosphorylated SirT1. In cells with compound heterozygous POLG mutations, we also found activated mitophagy via the BNIP3 pathway. Our studies are the first that show it is possible to recapitulate the neuronal molecular and biochemical defects associated with POLG mutation in a human stem cell model. Further, our data provide insight into how mitochondrial dysfunction and mtDNA alterations influence cellular fate determining processes.
KW - DNA Polymerase gamma/genetics
KW - DNA, Mitochondrial/genetics
KW - Humans
KW - Induced Pluripotent Stem Cells
KW - Mutation
KW - Neural Stem Cells
KW - Phenotype
U2 - 10.15252/emmm.202012146
DO - 10.15252/emmm.202012146
M3 - Article
C2 - 32840960
SN - 1757-4676
VL - 12
SP - e12146
JO - Embo Molecular Medicine
JF - Embo Molecular Medicine
IS - 10
ER -