Somatic copy number gains of α-synuclein (SNCA) in Parkinson’s disease and multiple system atrophy brains

Mokretar, Katya; Pease, Daniel Patrick; Taanman, Jan‐Willem; Soenmez, Aynur; Ejaz, Ayesha; Lashley, Tammaryn; Ling, Helen; Gentleman, Steve; Houlden, Henry; Holton, Janice L.; Schapira, Anthony H.V.; Nacheva, E.; Proukakis, Christos

doi:10.1093/brain/awy157

Cited by 64 publications

(57 citation statements)

References 66 publications

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“…Most cases of these diseases are considered as sporadic, but some cases can be genetically triggered by duplication or triplication of the a-syn-encoding (SNCA) gene, leading to constitutive overexpression of the protein, or by mutations in the N-terminal region of the protein, which favor its oligomerization and aggregation (A30P, E46K, or A53T, for instance) (1). Evidence of somatic SNCA gains in brain, more commonly in nigral dopaminergic neurons of PD than in controls, and possibly commonest in some MSA cases, was also recently described by Mokretar et al (2), suggesting that this may be a risk factor for sporadic synucleinopathies or, alternatively, a result of the disease process.…”

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confidence: 74%

Seeded propagation of α‐synuclein aggregation in mouse brain using protein misfolding cyclic amplification

et al. 2019

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α‐Synuclein (α‐syn) protein aggregation is associated with several neurodegenerative disorders collectively referred to as synucleinopathies, including Parkinson's disease. We used protein misfolding cyclic amplification (PMCA) to study α‐syn aggregation in brain homogenates of wild‐type or transgenic mice expressing normal (D line) or A53T mutant (M83 line) human α‐syn. We found that sonication‐incubation cycles of M83 mouse brain gradually produce large quantities of SDS‐resistant α‐syn aggregates, involving both human and mouse proteins. These PMCA products, containing partially proteinase K‐resistant α‐syn species, are competent to accelerate the onset of neurologic symptoms after intracerebral inoculation to young M83 mice and to seed aggregate formation of α‐syn following PMCA, including in D and wild‐type mouse brain substrates. PMCA seeding activity in the M83 diseased brain correlates positively with regions mostly targeted by the α‐syn pathology in this model. Our data indicate that similar to prions, PMCA can reproduce some characteristics of α‐syn aggregation and seeded propagation in vitro in a complex milieu. This opens new opportunities for the molecular study of synucleinopathies.—Nicot, S., Verchère, J., Bélondrade, M., Mayran, C., Bétemps, D., Bougard, D., Baron, T. Seeded propagation of α‐synuclein aggregation in mouse brain using protein misfolding cyclic amplification. FASEB J. 33, 12073‐12086 (2019). http://www.fasebj.org

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confidence: 74%

Seeded propagation of α‐synuclein aggregation in mouse brain using protein misfolding cyclic amplification

et al. 2019

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“…This simplified scenario for initial aggregate formation determined by a low lipid/α-syn ratio as well as altered concentrations of α-syn lipid−bound and α-syn free could explain several PD-associated findings, like the α-syn-dosage effect for the development of PD. Increased α-syn expression levels by genetic locus duplication/triplication, variabilities in SNCA-promoter region REP1 or somatic copy number gains of α-syn all demonstrate the close relation of α-syn concentration and PD age of onset (Singleton et al, 2003;Chartier-Harlin et al, 2004;Maraganore et al, 2006;Fuchs et al, 2008;Mokretar et al, 2018). The lipid/α-syn ratio is likely to be lowered by elevated levels of α-syn at the synapse, thereby increasing the chance for lipid-induced spontaneous aggregation events.…”

Section: Lipid Binding Modulates Initial α-Synuclein Aggregationmentioning

confidence: 99%

The Role of Lipids in the Initiation of α-Synuclein Misfolding

Kiechle

Grozdanov

Danzer

2020

Front. Cell Dev. Biol.

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The aggregation of α-synuclein (α-syn) is inseparably connected to Parkinson's disease (PD). It is now well-established that certain forms of α-syn aggregates, oligomers and fibrils, can exert neurotoxicity in synucleinopathies. With the exception of rare familial forms, the vast majority of PD cases are idiopathic. Understanding the earliest molecular mechanisms that cause initial α-syn misfolding could help to explain why PD affects only some individuals and others not. Factors that chaperone the transition of α-syn's physiological to pathological function are of particular interest, since they offer opportunities for intervention. The relationship between α-syn and lipids represents one of those factors. Membrane interaction is crucial for normal cellular function, but lipids also induce the aggregation of α-syn, causing cell toxicity. Also, disease-causing or risk-factor mutations in genes related to lipid metabolism like PLA2G6, SCARB2 or GBA1 highlight the close connection between PD and lipids. Despite the clear link, the ambivalent interaction has not been studied sufficiently so far. In this review, we address how α-syn interacts with lipids and how they can act as key factor for orchestrating toxic conversion of α-syn. Furthermore, we will discuss a scenario in which initial α-syn aggregation is determined by shifts in lipid/α-syn ratio as well as by dyshomeostasis of membrane bound/unbound state of α-syn.

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“…Since epigenetic information is simultaneously obtained with native long-read sequencing, the preferred DNA source in the context of neurodegenerative diseases would be affected brain tissue, if available, as demonstrated for the diagnosis of brain tumors [86]. Using brain tissue would also inform us about the presence and potential impact of mosaicism [12]. This initial SVdiscovery phase would be followed by genotyping larger cohorts using (existing) short-read data, as such generating a comprehensive SV catalog.…”

Section: A Comprehensive Sv Catalog Across Populationsmentioning

confidence: 99%

“…Unexplained heritability in complex diseases such as AD might be partially attributed to unnoticed SVs. In addition, somatic and de novo SVs can potentially explain a proportion of genetically unexplained sporadic patients [11,12].…”

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Newest Methods for Detecting Structural Variations

Coster

Broeckhoven

2019

Trends in Biotechnology

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A substantial amount of structural variation in the human genome remains uninvestigated due to the limitations of existing technologies, the presence of repetitive sequences, and the complexity of a diploid genome. New technologies have been developed, increasing resolution and appreciation of structural variation and how it affects human diversity and disease. The genetic etiology of most patients with complex disorders such as neurodegenerative brain diseases is not yet elucidated, complicating disease diagnosis, genetic counseling, and understanding of underlying pathological mechanisms needed to develop therapeutic interventions. Here, we focus on innovative progress and opportunities provided by the newest methods such as linked read sequencing, strand-specific sequencing, and long-read sequencing. Finally, we describe a strategy for generating a comprehensive catalog of structural variations across populations. Structural Variation Has Been Systematically Missed Multiple projects have comprehensively cataloged small genetic variants [single nucleotide variants (SNVs)]; however, structural variants (SVs) remain largely underrepresented [1,2]. SVs are defined as regions of DNA larger than 50 bp showing a change in copy number or genomic location including copy number variants (CNVs; deletions and duplications), insertions, inversions, translocations, mobile elements, repetitive sequence expansions, and complex combinations thereof (Figure 1) [3]. SVs contribute $3.4 times more nucleotides to human genetic variation than the far more numerous SNVs [4]. Multiple sequencing technologies (see Glossary), notably longread sequencing and short-read sequencing library preparation methods such as strand-specific sequencing (strand-seq) and linked-read sequencing, have been developed, providing an unprecedented potential and accuracy of genome-wide structural variation. Here, we describe new improvements to SV detection methods, each with different strengths and shortcomings. One landmark study combined several technologies to obtain a complete haplotype-specific characterization in healthy human trios, yielding >30 000 SVs per genome, including >150 inversions and large unbalanced chromosomal rearrangements [5]. This work suggested that previous technologies missed most of the SVs due to technical limitations. The majority of SVs are novel and rare variants, implicating that structural variation databases are not saturated yet [2-7]. Highlights The genetic etiology of complex human diseases is still poorly understood, hampering diagnostics and therapeutic approaches.

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Somatic copy number gains of α-synuclein (SNCA) in Parkinson’s disease and multiple system atrophy brains

Cited by 64 publications

References 66 publications

Seeded propagation of α‐synuclein aggregation in mouse brain using protein misfolding cyclic amplification

Seeded propagation of α‐synuclein aggregation in mouse brain using protein misfolding cyclic amplification

The Role of Lipids in the Initiation of α-Synuclein Misfolding

Newest Methods for Detecting Structural Variations

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