Induction of de novo α-synuclein fibrillization in a neuronal model for Parkinson’s disease

Induction of de novo α-synuclein fibrillization in a neuronal model for Parkinson’s disease

Lewy bodies (LBs) are intraneuronal inclusions consisting primarily of fibrillized human α-synuclein (hα-Syn) protein, which represent the major pathological hallmark of Parkinson’s disease (PD). Although doubling hα-Syn expression provokes LB pathology in humans, hα-Syn overexpression does not trig...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2016-02, Vol.113 (7), p.E912-E921
Hauptverfasser: Fares, Mohamed-Bilal, Maco, Bohumil, Oueslati, Abid, Rockenstein, Edward, Ninkina, Natalia, Buchman, Vladimir L., Masliah, Eliezer, Lashuel, Hilal A.
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alpha-Synuclein - genetics
alpha-Synuclein - metabolism
Animals
Biological Sciences
Disease Models, Animal
Mice
Mice, Knockout
Neurons - metabolism
Parkinson Disease - metabolism
PNAS Plus
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container_end_page E921
container_issue 7
container_start_page E912
container_title Proceedings of the National Academy of Sciences - PNAS
container_volume 113
creator Fares, Mohamed-Bilal
Maco, Bohumil
Oueslati, Abid
Rockenstein, Edward
Ninkina, Natalia
Buchman, Vladimir L.
Masliah, Eliezer
Lashuel, Hilal A.
description Lewy bodies (LBs) are intraneuronal inclusions consisting primarily of fibrillized human α-synuclein (hα-Syn) protein, which represent the major pathological hallmark of Parkinson’s disease (PD). Although doubling hα-Syn expression provokes LB pathology in humans, hα-Syn overexpression does not trigger the formation of fibrillar LB-like inclusions in mice. We hypothesized that interactions between exogenous hα-Syn and endogenous mouse synuclein homologs could be attenuating hα-Syn fibrillization in mice, and therefore, we systematically assessed hα-Syn aggregation propensity in neurons derived from α-Syn–KO, β-Syn–KO, γ-Syn–KO, and triple-KO mice lacking expression of all three synuclein homologs. Herein, we show that hα-Syn forms hyperphosphorylated (at S129) and ubiquitin-positive LB-like inclusions in primary neurons of α-Syn–KO, β-Syn–KO, and triple-KO mice, as well as in transgenic α-Syn–KO mouse brains in vivo. Importantly, correlative light and electron microscopy, immunogold labeling, and thioflavin-S binding established their fibrillar ultrastructure, and fluorescence recovery after photobleaching/photoconversion experiments showed that these inclusions grow in size and incorporate soluble proteins. We further investigated whether the presence of homologous α-Syn species would interfere with the seeding and spreading of α-Syn pathology. Our results are in line with increasing evidence demonstrating that the spreading of α-Syn pathology is most prominent when the injected preformed fibrils and host-expressed α-Syn monomers are from the same species. These findings provide insights that will help advance the development of neuronal and in vivo models for understanding mechanisms underlying hα-Syn intraneuronal fibrillization and its contribution to PD pathogenesis, and for screening pharmacologic and genetic modulators of α-Syn fibrillization in neurons.
doi_str_mv 10.1073/pnas.1512876113
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Although doubling hα-Syn expression provokes LB pathology in humans, hα-Syn overexpression does not trigger the formation of fibrillar LB-like inclusions in mice. We hypothesized that interactions between exogenous hα-Syn and endogenous mouse synuclein homologs could be attenuating hα-Syn fibrillization in mice, and therefore, we systematically assessed hα-Syn aggregation propensity in neurons derived from α-Syn–KO, β-Syn–KO, γ-Syn–KO, and triple-KO mice lacking expression of all three synuclein homologs. Herein, we show that hα-Syn forms hyperphosphorylated (at S129) and ubiquitin-positive LB-like inclusions in primary neurons of α-Syn–KO, β-Syn–KO, and triple-KO mice, as well as in transgenic α-Syn–KO mouse brains in vivo. Importantly, correlative light and electron microscopy, immunogold labeling, and thioflavin-S binding established their fibrillar ultrastructure, and fluorescence recovery after photobleaching/photoconversion experiments showed that these inclusions grow in size and incorporate soluble proteins. We further investigated whether the presence of homologous α-Syn species would interfere with the seeding and spreading of α-Syn pathology. Our results are in line with increasing evidence demonstrating that the spreading of α-Syn pathology is most prominent when the injected preformed fibrils and host-expressed α-Syn monomers are from the same species. 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Importantly, correlative light and electron microscopy, immunogold labeling, and thioflavin-S binding established their fibrillar ultrastructure, and fluorescence recovery after photobleaching/photoconversion experiments showed that these inclusions grow in size and incorporate soluble proteins. We further investigated whether the presence of homologous α-Syn species would interfere with the seeding and spreading of α-Syn pathology. Our results are in line with increasing evidence demonstrating that the spreading of α-Syn pathology is most prominent when the injected preformed fibrils and host-expressed α-Syn monomers are from the same species. 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subjects alpha-Synuclein - genetics
alpha-Synuclein - metabolism
Animals
Biological Sciences
Disease Models, Animal
Mice
Mice, Knockout
Neurons - metabolism
Parkinson Disease - metabolism
PNAS Plus
title Induction of de novo α-synuclein fibrillization in a neuronal model for Parkinson’s disease
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