Loss of VPS13C Function in Autosomal-Recessive Parkinsonism Causes Mitochondrial Dysfunction and Increases PINK1/Parkin-Dependent Mitophagy

Drouet, Valérie; Deramecourt, Vincent; Jacoupy, Maxime; Nicolas, Aude; Cormier‐Dequaire, Florence; Hassoun, Sidi Mohamed; Pujol, Claire; Ciura, Sorana; Erpapazoglou, Zoi; Usenko, Tatiana; Maurage, Claude‐Alain; Sahbatou, Mourad; Liebau, Stefan; Ding, Jinhui; Bılgıç, Başar; Emre, Murat; Erginel-Unaltuna, Nihan; Güven, Gamze; Leutenegger, Anne-Louise; Deleuze, Jean‐François; Tazir, Mériem; Kabashi, Edor; Corti, Olga; Viallet, François; Majounie, Elisa; Nalls, Michael A.; Hernandez, Dena G.; Gibbs, J. Raphael; Arepalli, Sampath; Barker, Roger A.; Ben-Shlomo, Yoav; Berg, Daniela; Bettella, Francesco; Bhatia, Kailash P.; Bie, Rob M.A. de; Biffi, Alessandro; Bloem, Bastiaan R.; Bochdanovits, Zoltán; Bonin, Michael; Lesage, Suzanne; Tison, François; Vidailhet, Marie; Corvol, Jean‐Christophe; Agid, Yves; Anheim, Mathieu; Bonnet, Anne‐Marie; Borg, M.; Broussolle, Emmanuel; Destée, Alain; Dürr, Alexandra; Durif, Franck; Krack, Paul; Klebe, Stephan; Lohmann, Ebba; Rascol, Olivier; Tranchant, C.; Vérin, Marc; Brás, José; Brockmann, Kathrin; Brooks, Janet; Burn, David; Charlesworth, Gavin; Chen, Honglei; Chinnery, Patrick F.; Chong, Sean; Clarke, Carl E; Cookson, Mark; Counsell, Carl; Damier, Philippe; Dartigues, Jean‐François; Deloukas, Panos; Deuschl, G.; Dexter, David T.; Dijk, Karin D. van; Dillman, Allissa; Dong, Jing; Durif, F.; Edkins, Sarah; Escott‐Price, Valentina; Evans, Jonathan; Foltynie, Thomas; Gao, Jianjun; Gardner, Michelle; Goate, Alison; Gray, Emma; Guerreiro, Rita; Harris, Clare; Hilten, Jacobus J. van; Hofman, Albert; Hollenbeck, Albert R.; Holmans, Peter; Holton, Janice L.; Hu, Michèle; Huang, Xuemei; Huber, Heiko; Hudson, Gavin; Hunt, Sarah; Huttenlocher, Johanna; Illig, Thomas; Jónsson, Pálmi V.; Kilarski, Laura L.; Jansen, Iris E.; Lambert, Jean‐Charles; Langford, Cordelia; Lees, Andrew; Lichtner, Peter; Limousin, Patricia; Lopez, Grisel; Lorenz, Delia; Lubbe, Steven; Lungu, Codrin; Martínez, María Teresa González; Mätzler, Walter; McNeill, Alisdair; Moorby, Catriona D.; Moore, Matthew; Morrison, Karen E.; Mudanohwo, Ese; O’Sullivan, Sean S.; Owen, Michael John; Pearson, Justin; Perlmutter, Joel S.; Pétursson, Hjörvar; Plagnol, Vincent; Pollak, Pierre; Post, Bart; Potter, Simon; Ravina, Bernard; Révész, Tamás; Rieß, Olaf; Rivadeneira, Fernando; Rizzu, Patrizia; Ryten, Mina; Saad, Mohamad; Simón‐Sánchez, Javier; Sawcer, Stephen; Schapira, Anthony H. V.; Scheffer, Hans; Schulte, Claudia; Sharma, Manu; Shaw, Karen; Sheerin, Una‐Marie; Shoulson, Ira; Liu, Zhandong; Sidransky, Ellen; Spencer, Chris C. A.; Stefánsson, Hreinn; Stefánsson, Kāri; Stockton, Joanna D.; Strange, Amy; Talbot, Kevin; Tanner, Carlie M.; Tashakkori-Ghanbaria, Avazeh; Trabzuni, Daniah; Traynor, Bryan J.; Uitterlinden, André G.; Velseboer, Daan C.; Walker, Robert; Warrenburg, Bart van de; Wickremaratchi, Mirdhu; Williams‐Gray, Caroline H.; Winder‐Rhodes, Sophie; Wurster, Isabel; Williams, Nigel; Morris, Huw; Heutink, Peter; Hardy, John; Wood, Nicholas; Gasser, Thomas; Singleton, Andrew B.; Brice, Alexis

doi:10.1016/j.ajhg.2016.01.014

Cited by 339 publications

(288 citation statements)

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“…The relevance of impaired mitochondrial quality control in the pathogenesis of PD is further corroborated by the recent identification of mutations in the VPS13C gene in the autosomal recessively inherited form of juvenile parkinsonism ( PARK23 ; OMIM: 616,840; Lesage et al 2016). We hypothesise that VPS13C could also have a role in organellar quality control of mitochondria.…”

Section: Mitochondrial Dysfunction Caused By Pd-related Genes: the Romentioning

confidence: 89%

“…Under physiological conditions, VPS13C was found to be localised in mitochondrial fractions and relocalises to the cytoplasm after mitochondrial damage in monkey and human cell lines (Lesage et al 2016). The PD-associated loss of VPS13C caused mitochondrial fragmentation, loss of membrane potential and increase PINK1/Parkin-mediated mitophagy after challenging cells with the mitochondrial uncoupler CCCP (carbonyl cyanide 3-chlorophenylhydrazone) (Lesage et al 2016). It has also been shown to colocalise with the lysosomal fraction in HeLa cells (Yang et al 2016).…”

Section: Mitochondrial Dysfunction Caused By Pd-related Genes: the Romentioning

confidence: 99%

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The genetic architecture of mitochondrial dysfunction in Parkinson’s disease

2018

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Mitochondrial impairment is a well-established pathological pathway implicated in Parkinson’s disease (PD). Defects of the complex I of the mitochondrial respiratory chain have been found in post-mortem brains from sporadic PD patients. Furthermore, several disease-related genes are linked to mitochondrial pathways, such as PRKN, PINK1, DJ-1 and HTRA2 and are associated with mitochondrial impairment. This phenotype can be caused by the dysfunction of mitochondrial quality control machinery at different levels: molecular, organellar or cellular. Mitochondrial unfolded protein response represents the molecular level and implicates various chaperones and proteases. If the molecular level of quality control is not sufficient, the organellar level is required and involves mitophagy and mitochondrial-derived vesicles to sequester whole dysfunctional organelle or parts of it. Only when the impairment is too severe, does it lead to cell death via apoptosis, which defines the cellular level of quality control. Here, we review how currently known PD-linked genetic variants interfere with different levels of mitochondrial quality control. We discuss the graded risk concept of the most recently identified PARK loci (PARK 17–23) and some susceptibility variants in GBA, LRRK2 and SNCA. Finally, the emerging concept of rare genetic variants in candidates genes for PD, such as HSPA9, TRAP1 and RHOT1, complete the picture of the complex genetic architecture of PD that will direct future precision medicine approaches.

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Section: Mitochondrial Dysfunction Caused By Pd-related Genes: the Romentioning

confidence: 89%

Section: Mitochondrial Dysfunction Caused By Pd-related Genes: the Romentioning

confidence: 99%

The genetic architecture of mitochondrial dysfunction in Parkinson’s disease

2018

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“…Concerning the monogenic forms of PD were found mutations in 7 genes of AD transmission (SNCA, LRRK2, GIGYF2, VPS35, EIF4G1, HTRA2, TMEM230) and even more in those of AR transmission. Recent data provide evidence for new molecular pathways involving neurodevelopmental mechanisms [207,210], modulating the signaling processes at the endocytic pathway [142], synaptic vesicles endocytosis and trafficking in PD pathogenesis [202,206], maintaining the integrity of the cytoskeleton and axonal transport in neurons [192].…”

Section: Discussionmentioning

confidence: 99%

“…A hypothesis which has been advanced to explain the mitochondrial dysfunction when parkinsonian features were signaled in designer drug abusers [223] was the inhibitory effect of MPTP on mitochondrial complex 1 of the electron transporter chain [224], functionally linked with mitochondrial DNA mutations [225,226], sustained by the extrapyramidal phenotype induction in animal models by inhibitors of mitochondrial complex l [227]. VPS13C as a mitochondrial membrane protein interacts with PINK1 and Parkin in order to provide the mitochondrial morphology and membrane potential integrity [207]. Beside mitochondrial dysfunction, the impaired pathways involved in clearing abnormal cellular proteins and damaged organelles, the ubiquitin-proteasome system and the autophagic pathway involving lysosomal activity [30,228] play a crucial role in PD etiology.…”

Section: Genes' Products Relations and Mechanisms Implicated In Mendementioning

confidence: 99%

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Mechanisms Implicated in Parkinson Disease from Genetic Perspective

Popescu¹

2016

Med Clin Rev

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Parkinson's disease (PD) etiology is based upon interactions between genetic susceptibility and the environmental exposure. Multiple environmental factors inducing oxidative stress, mitochondrial damage, impairment of the neuroprotective and autophagic mechanisms are responsible for dopaminergic neurons death. Defining the contributions of genetic and environmental factors, may have important implications for understanding the pathogenesis of PD. The linkage analysis in Mendelian forms of PD especially in multiplex highly penetrant families is essential to elucidate biological mechanisms for PD susceptibility. Concerning the monogenic forms of PD were found mutations in 7 genes of AD transmission (SNCA, LRRK2, GIGYF2, VPS35, EIF4G1, HTRA2, TMEM230) and even more in those of AR transmission. This review aims to give an overview of the existing evidence of multiples molecular pathways involving cytoplasmic organelles' function, neurodevelopmental mechanisms, synaptic vesicles endocytosis and trafficking, maintaining the integrity of the cytoskeleton and axonal transport in neurons. Understanding the molecular mechanisms following the identification of genes mutations and low-penetrance susceptibility alleles in familial and sporadic PD patients by genotyping technology and functional studies represent an essential step for the development of adequate biomarkers and potent therapies.

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Molecular Genetics of Parkinsonism

Lesage

Brice

2018

Encyclopedia of Life Sciences

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Over the past decade, genetic causes of parkinsonism have been elucidated, but they account in most populations, for less than 10% of the cases. Since the discovery of the first gene responsible for Parkinson disease (PD), SCNA encoding α‐synuclein, linkage mapping and positional cloning have identified autosomal dominantly or recessively inherited PD‐causing mutations in the genes encoding parkin , PINK1 , DJ‐1 , LRRK2 and ATP13A2 , indicating that PD has a highly heterogeneous aetiology. With the introduction of next‐generation sequencing, rare mutations in DNAJC6 , SYNJ1 , VPS13C , VPS35 , DNAJC13 , TMEM230 and CHCHD2 were then discovered to cause inherited parkinsonism. In addition, genetic studies from candidate genes, to unbiased genome‐wide approaches including association and next‐generation sequencing have nominated a number of disease determinants. In this article, we will highlight the current progress and future prospects in the field of PD genetics, since 2010. Key Concepts The introduction of next‐generation sequencing technologies associated with exome/genome sequencing has accelerated the discovery of novel causative genes and susceptibility factors in numerous Mendelian disorders. Integrative approaches combining DNA sequencing with gene expression and methylome data will support and accelerate the identification and functional characterisation of the biological variants and disease genes. Deep and accurate patient phenotyping is of major importance for the success of gene identification in heterogeneous diseases. The use of larger and more homogeneous cohorts (endophenotype) will increase the chances of identifying high/intermediate risk variants in whole exome/whole genome sequencing. Identification of additional PD and parkinsonism‐associated genes will enable further elucidation of the disease mechanisms and the development of disease‐modifying therapeutic strategies. Meta‐analysis of many genome‐wide association studies improves the power to detect more associations and to investigate the consistency or heterogeneity of these associations across diverse datasets and study populations.

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Loss of VPS13C Function in Autosomal-Recessive Parkinsonism Causes Mitochondrial Dysfunction and Increases PINK1/Parkin-Dependent Mitophagy

Cited by 339 publications

References 46 publications

The genetic architecture of mitochondrial dysfunction in Parkinson’s disease

The genetic architecture of mitochondrial dysfunction in Parkinson’s disease

Mechanisms Implicated in Parkinson Disease from Genetic Perspective

Molecular Genetics of Parkinsonism

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