Astrocytes initiate autophagic flux and maintain cell viability after internalizing non-active native extracellular α-synuclein

Astrocytes are tasked with regulating the synaptic environment. Early stages of various neurodegenerative diseases are characterized by synapse loss, and astrocytic atrophy and dysfunction has been proposed as a possible cause. α-Synuclein (αS) is a highly expressed neuronal protein located in the s...

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Veröffentlicht in:Molecular and cellular neuroscience 2024-12, Vol.131, p.103975, Article 103975
Hauptverfasser: Andromidas, Fotis, Mackinnon, Brooke E., Myers, Abigail J., Shaffer, Melanie M., Brahimi, Ayat, Atashpanjeh, Saeid, Vazquez, Tiana L., Le, Timmy, Jellison, Evan R., Staurovsky, Susan, Koob, Andrew O.
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container_title Molecular and cellular neuroscience
container_volume 131
creator Andromidas, Fotis
Mackinnon, Brooke E.
Myers, Abigail J.
Shaffer, Melanie M.
Brahimi, Ayat
Atashpanjeh, Saeid
Vazquez, Tiana L.
Le, Timmy
Jellison, Evan R.
Staurovsky, Susan
Koob, Andrew O.
description Astrocytes are tasked with regulating the synaptic environment. Early stages of various neurodegenerative diseases are characterized by synapse loss, and astrocytic atrophy and dysfunction has been proposed as a possible cause. α-Synuclein (αS) is a highly expressed neuronal protein located in the synapse that can be released in the extracellular space. Evidence points to astrocytes as being responsible for uptake and degradation of extracellular αS. Therefore, misfolded active fibrillized αS resulting in protein inclusions and aggregates could be due to astrocytic dysfunction. Despite these pathological hallmarks and lines of evidence, the autophagic function of astrocytes in response to monomeric non-active αS to model healthy conditions has not been investigated. Human primary cortical astrocytes were treated with 100 nM of extracellular monomeric non-active αS alone, and in combination with N-terminal binding monomeric γ-synuclein (γS) as a control. Western blot analysis and super resolution imaging of HiLyte-488 labeled αS confirmed successful internalization of αS at 12, 24 and 48 h after treatment, while αS dimers were only observed at 48 h. Western blot analysis also confirmed αS's ability to induce autophagic flux by 48 h. Annexin V/PI flow cytometry results revealed increased early apoptosis at 24 h, but which resolved itself by 48 h, indicating no cell death in cortical astrocytes at all time points, suggesting astrocytes can manage the protein degradation demand of monomeric αS in healthy physiological conditions. Likewise, astrocytes reduced secretion of apolipoprotein (ApoE), a protein involved in pro-inflammatory pathways, synapse regulation, and autophagy by 12 h. Similarly, total c-JUN protein levels, a transcription factor involved in pro-inflammatory pathways increased by 12 h in the nuclear fraction. Therefore, astrocytes are able to respond and degrade αS in healthy physiological conditions, and astrocyte dysfunction could precede detrimental αS accumulation. •Human astrocytes initiate autophagic flux in response to non-active α-synuclein.•Induction of autophagy is dependent on the N-terminal region of α-synuclein.•Non-active α-synuclein induces early apoptosis but not cell death in astrocytes.•Non-active α-synuclein reduces apoE release and increases c-JUN levels in astrocytes.
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Early stages of various neurodegenerative diseases are characterized by synapse loss, and astrocytic atrophy and dysfunction has been proposed as a possible cause. α-Synuclein (αS) is a highly expressed neuronal protein located in the synapse that can be released in the extracellular space. Evidence points to astrocytes as being responsible for uptake and degradation of extracellular αS. Therefore, misfolded active fibrillized αS resulting in protein inclusions and aggregates could be due to astrocytic dysfunction. Despite these pathological hallmarks and lines of evidence, the autophagic function of astrocytes in response to monomeric non-active αS to model healthy conditions has not been investigated. Human primary cortical astrocytes were treated with 100 nM of extracellular monomeric non-active αS alone, and in combination with N-terminal binding monomeric γ-synuclein (γS) as a control. 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Early stages of various neurodegenerative diseases are characterized by synapse loss, and astrocytic atrophy and dysfunction has been proposed as a possible cause. α-Synuclein (αS) is a highly expressed neuronal protein located in the synapse that can be released in the extracellular space. Evidence points to astrocytes as being responsible for uptake and degradation of extracellular αS. Therefore, misfolded active fibrillized αS resulting in protein inclusions and aggregates could be due to astrocytic dysfunction. Despite these pathological hallmarks and lines of evidence, the autophagic function of astrocytes in response to monomeric non-active αS to model healthy conditions has not been investigated. Human primary cortical astrocytes were treated with 100 nM of extracellular monomeric non-active αS alone, and in combination with N-terminal binding monomeric γ-synuclein (γS) as a control. 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Therefore, astrocytes are able to respond and degrade αS in healthy physiological conditions, and astrocyte dysfunction could precede detrimental αS accumulation. •Human astrocytes initiate autophagic flux in response to non-active α-synuclein.•Induction of autophagy is dependent on the N-terminal region of α-synuclein.•Non-active α-synuclein induces early apoptosis but not cell death in astrocytes.•Non-active α-synuclein reduces apoE release and increases c-JUN levels in astrocytes.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><pmid>39368763</pmid><doi>10.1016/j.mcn.2024.103975</doi></addata></record>
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subjects alpha-Synuclein - metabolism
Apolipoprotein E
Apoptosis
Astrocytes
Astrocytes - metabolism
Autophagy
Autophagy - physiology
c-JUN
Cell Survival - physiology
Cells, Cultured
Humans
Synuclein
title Astrocytes initiate autophagic flux and maintain cell viability after internalizing non-active native extracellular α-synuclein
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