Preservation of neuronal functions by exosomes derived from different human neural cell types under ischemic conditions

Stem cell‐based therapies have been reported in protecting cerebral infarction‐induced neuronal dysfunction and death. However, most studies used rat/mouse neuron as model cell when treated with stem cell or exosomes. Whether these findings can be translated from rodent to humans has been in doubt....

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Veröffentlicht in:The European journal of neuroscience 2018-01, Vol.47 (2), p.150-157
Hauptverfasser: Deng, Mingyang, Xiao, Han, Peng, Hongling, Yuan, Huan, Xu, Yunxiao, Zhang, Guangsen, Tang, Jianguang, Hu, Zhiping
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container_issue 2
container_start_page 150
container_title The European journal of neuroscience
container_volume 47
creator Deng, Mingyang
Xiao, Han
Peng, Hongling
Yuan, Huan
Xu, Yunxiao
Zhang, Guangsen
Tang, Jianguang
Hu, Zhiping
description Stem cell‐based therapies have been reported in protecting cerebral infarction‐induced neuronal dysfunction and death. However, most studies used rat/mouse neuron as model cell when treated with stem cell or exosomes. Whether these findings can be translated from rodent to humans has been in doubt. Here, we used human embryonic stem cell‐derived neurons to detect the protective potential of exosomes against ischemia. Neurons were treated with in vitro oxygen–glucose deprivation (OGD) for 1 h. For treatment group, different exosomes were derived from neuron, embryonic stem cell, neural progenitor cell and astrocyte differentiated from H9 human embryonic stem cell and added to culture medium 30 min after OGD (100 μg/mL). Western blotting was performed 12 h after OGD, while cell counting and electrophysiological recording were performed 48 h after OGD. We found that these exosomes attenuated OGD‐induced neuronal death, Mammalian target of rapamycin (mTOR), pro‐inflammatory and apoptotic signaling pathway changes, as well as basal spontaneous synaptic transmission inhibition in varying degrees. The results implicate the protective effect of exosomes on OGD‐induced neuronal death and dysfunction in human embryonic stem cell‐derived neurons, potentially through their modulation on mTOR, pro‐inflammatory and apoptotic signaling pathways. Exosomes derived from different cell types differentially attenuated OGD‐induced neuronal death, mTOR, pro‐inflammatory and apoptotic signaling pathway changes, as well as basal spontaneous synaptic transmission. Exosomes purified from astrocytes derived from human ES (H9) cells were more effective in ameliorating OGD‐induced neuronal dysfunction in neurons derived from human ES (H9) cells.
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However, most studies used rat/mouse neuron as model cell when treated with stem cell or exosomes. Whether these findings can be translated from rodent to humans has been in doubt. Here, we used human embryonic stem cell‐derived neurons to detect the protective potential of exosomes against ischemia. Neurons were treated with in vitro oxygen–glucose deprivation (OGD) for 1 h. For treatment group, different exosomes were derived from neuron, embryonic stem cell, neural progenitor cell and astrocyte differentiated from H9 human embryonic stem cell and added to culture medium 30 min after OGD (100 μg/mL). Western blotting was performed 12 h after OGD, while cell counting and electrophysiological recording were performed 48 h after OGD. We found that these exosomes attenuated OGD‐induced neuronal death, Mammalian target of rapamycin (mTOR), pro‐inflammatory and apoptotic signaling pathway changes, as well as basal spontaneous synaptic transmission inhibition in varying degrees. The results implicate the protective effect of exosomes on OGD‐induced neuronal death and dysfunction in human embryonic stem cell‐derived neurons, potentially through their modulation on mTOR, pro‐inflammatory and apoptotic signaling pathways. Exosomes derived from different cell types differentially attenuated OGD‐induced neuronal death, mTOR, pro‐inflammatory and apoptotic signaling pathway changes, as well as basal spontaneous synaptic transmission. 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subjects Apoptosis
Cell culture
Cerebral infarction
Death
Electrophysiological recording
Embryos
Exosomes
Glucose
human embryonic stem cell
hypoxia
Inflammation
Ischemia
mTOR
Neural stem cells
neuronal death
Neurons
Oxygen
oxygen–glucose deprivation
Preservation
Progenitor cells
Rapamycin
Signal transduction
Stem cells
Synaptic transmission
TOR protein
Western blotting
title Preservation of neuronal functions by exosomes derived from different human neural cell types under ischemic conditions
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