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4 results on '"Vallerga, Costanza L"'

2. Examining the Impact of Imputation Errors on Fine-Mapping Using DNA Methylation QTL as a Model Trait

Author

Chundru, V Kartik, Marioni, Riccardo E, Prendergast, James G D, Vallerga, Costanza L, Lin, Tian, Berveridge, Allan J, Consortium, Sgpd, Gratten, Jacob, Hume, David A, Deary, Ian J, Wray, Naomi R, Visscher, Peter M, and McRae, Allan F

Subjects
Linkage disequilibrium, Quantitative Trait Loci, Bayesian probability, imputation, Investigations, Quantitative trait locus, Biology, Polymorphism, Single Nucleotide, 03 medical and health sciences, Quantitative Trait, Heritable, Genetics, Humans, 1000 Genomes Project, Allele, Association mapping, 030304 developmental biology, 0303 health sciences, Whole Genome Sequencing, 030305 genetics & heredity, Haplotype, Reproducibility of Results, DNA Methylation, Reference Standards, fine-mapping, CpG-SNPs, CpG Islands, DNA-methylation, Statistical Genetics and Genomics, Imputation (genetics), Genome-Wide Association Study
Abstract

This study highlights dangers in over-interpreting fine-mapping results. Chundru et al. show that genotype imputation accuracy has a large impact on fine-mapping accuracy. They used DNA methylation at CpG-sites with a variant..., Genetic variants disrupting DNA methylation at CpG dinucleotides (CpG-SNP) provide a set of known causal variants to serve as models to test fine-mapping methodology. We use 1716 CpG-SNPs to test three fine-mapping approaches (Bayesian imputation-based association mapping, Bayesian sparse linear mixed model, and the J-test), assessing the impact of imputation errors and the choice of reference panel by using both whole-genome sequence (WGS), and genotype array data on the same individuals (n = 1166). The choice of imputation reference panel had a strong effect on imputation accuracy, with the 1000 Genomes Project Phase 3 (1000G) reference panel (n = 2504 from 26 populations) giving a mean nonreference discordance rate between imputed and sequenced genotypes of 3.2% compared to 1.6% when using the Haplotype Reference Consortium (HRC) reference panel (n = 32,470 Europeans). These imputation errors had an impact on whether the CpG-SNP was included in the 95% credible set, with a difference of ∼23% and ∼7% between the WGS and the 1000G and HRC imputed datasets, respectively. All of the fine-mapping methods failed to reach the expected 95% coverage of the CpG-SNP. This is attributed to secondary cis genetic effects that are unable to be statistically separated from the CpG-SNP, and through a masking mechanism where the effect of the methylation disrupting allele at the CpG-SNP is hidden by the effect of a nearby SNP that has strong linkage disequilibrium with the CpG-SNP. The reduced accuracy in fine-mapping a known causal variant in a low-level biological trait with imputed genetic data has implications for the study of higher-order complex traits and disease.

Published
2019

3. Identification of novel risk loci, causal insights, and heritable risk for Parkinson's disease: a meta-analysis of genome-wide association studies

Author

Nalls, Mike A, Blauwendraat, Cornelis, Vallerga, Costanza L, Heilbron, Karl, Bandres-Ciga, Sara, Chang, Diana, Tan, Manuela, Kia, Demis A, Noyce, Alastair J, Xue, Angli, Bras, Jose, Young, Emily, von Coelln, Rainer, Simón-Sánchez, Javier, Schulte, Claudia, Sharma, Manu, Krohn, Lynne, Pihlstrøm, Lasse, Siitonen, Ari, Iwaki, Hirotaka, Leonard, Hampton, Faghri, Faraz, Gibbs, J Raphael, Hernandez, Dena G, Scholz, Sonja W, Botia, Juan A, Martinez, Maria, Corvol, Jean-Christophe, Lesage, Suzanne, Jankovic, Joseph, Shulman, Lisa M, Sutherland, Margaret, Tienari, Pentti, Majamaa, Kari, Toft, Mathias, Andreassen, Ole A, Bangale, Tushar, Brice, Alexis, Yang, Jian, Gan-Or, Ziv, Gasser, Thomas, Heutink, Peter, Shulman, Joshua M, Wood, Nicholas W, Hinds, David A, Hardy, John A, Morris, Huw R, Gratten, Jacob, Visscher, Peter M, Graham, Robert R, Singleton, Andrew B, 23andMe Research Team, System Genomics of Parkinson's Disease Consortium, and International Parkinson's Disease Genomics Consortium

Subjects
Aging, Parkinson's Disease, Neurology & Neurosurgery, Prevention, Human Genome, Clinical Sciences, Neurosciences, Parkinson Disease, Neurodegenerative, 23andMe Research Team, Brain Disorders, Databases, Genetic, Risk Factors, Genetic Loci, Neurological, Genetics, Humans, 2.1 Biological and endogenous factors, Genetic Predisposition to Disease, System Genomics of Parkinson's Disease Consortium, Aetiology, International Parkinson's Disease Genomics Consortium, Genome-Wide Association Study, Biotechnology
Abstract

BackgroundGenome-wide association studies (GWAS) in Parkinson's disease have increased the scope of biological knowledge about the disease over the past decade. We aimed to use the largest aggregate of GWAS data to identify novel risk loci and gain further insight into the causes of Parkinson's disease.MethodsWe did a meta-analysis of 17 datasets from Parkinson's disease GWAS available from European ancestry samples to nominate novel loci for disease risk. These datasets incorporated all available data. We then used these data to estimate heritable risk and develop predictive models of this heritability. We also used large gene expression and methylation resources to examine possible functional consequences as well as tissue, cell type, and biological pathway enrichments for the identified risk factors. Additionally, we examined shared genetic risk between Parkinson's disease and other phenotypes of interest via genetic correlations followed by Mendelian randomisation.FindingsBetween Oct 1, 2017, and Aug 9, 2018, we analysed 7·8 million single nucleotide polymorphisms in 37 688 cases, 18 618 UK Biobank proxy-cases (ie, individuals who do not have Parkinson's disease but have a first degree relative that does), and 1·4 million controls. We identified 90 independent genome-wide significant risk signals across 78 genomic regions, including 38 novel independent risk signals in 37 loci. These 90 variants explained 16-36% of the heritable risk of Parkinson's disease depending on prevalence. Integrating methylation and expression data within a Mendelian randomisation framework identified putatively associated genes at 70 risk signals underlying GWAS loci for follow-up functional studies. Tissue-specific expression enrichment analyses suggested Parkinson's disease loci were heavily brain-enriched, with specific neuronal cell types being implicated from single cell data. We found significant genetic correlations with brain volumes (false discovery rate-adjusted p=0·0035 for intracranial volume, p=0·024 for putamen volume), smoking status (p=0·024), and educational attainment (p=0·038). Mendelian randomisation between cognitive performance and Parkinson's disease risk showed a robust association (p=8·00 × 10-7).InterpretationThese data provide the most comprehensive survey of genetic risk within Parkinson's disease to date, to the best of our knowledge, by revealing many additional Parkinson's disease risk loci, providing a biological context for these risk factors, and showing that a considerable genetic component of this disease remains unidentified. These associations derived from European ancestry datasets will need to be followed-up with more diverse data.FundingThe National Institute on Aging at the National Institutes of Health (USA), The Michael J Fox Foundation, and The Parkinson's Foundation (see appendix for full list of funding sources).

Published
2019

4. Moving beyond neurons: the role of cell type-specific gene regulation in Parkinson's disease heritability

Author

Reynolds, Regina H, Botía, Juan, Gibbs, J Raphael, Duarte, Jacinto, Clarimón, Jordi, Dols-Icardo, Oriol, Infante, Jon, Marín, Juan, Kulisevsky, Jaime, Pagonabarraga, Javier, Gonzalez-Aramburu, Isabel, Rodriguez, Antonio Sanchez, Sierra, María, Hernandez, Dena G, Duran, Raquel, Ruz, Clara, Vives, Francisco, Escamilla-Sevilla, Francisco, Mínguez, Adolfo, Cámara, Ana, Compta, Yaroslau, Ezquerra, Mario, Marti, Maria Jose, Fernández, Manel, Singleton, Andrew B, Muñoz, Esteban, Fernández-Santiago, Rubén, Tolosa, Eduard, Valldeoriola, Francesc, García-Ruiz, Pedro, Heredia, Maria Jose Gomez, Errazquin, Francisco Perez, Hoenicka, Janet, Jimenez-Escrig, Adriano, Martínez-Castrillo, Juan Carlos, Reed, Xylena, Lopez-Sendon, Jose Luis, Torres, Irene Martínez, Tabernero, Cesar, Vela, Lydia, Zimprich, Alexander, Pihlstrom, Lasse, Koks, Sulev, Taba, Pille, Majamaa, Kari, Siitonen, Ari, Leonard, Hampton, Okubadejo, Njideka U, Ojo, Oluwadamilola O, Pitcher, Toni, Anderson, Tim, Bentley, Steven, Fowdar, Javed, Mellick, George, Dalrymple-Alford, John, Henders, Anjali K, Kassam, Irfahan, Blauwendraat, Cornelis, Montgomery, Grant, Sidorenko, Julia, Zhang, Futao, Xue, Angli, Vallerga, Costanza L, Wallace, Leanne, Wray, Naomi R, Yang, Jian, Visscher, Peter M, Gratten, Jacob, Faghri, Faraz, Silburn, Peter A, Halliday, Glenda, Hickie, Ian, Kwok, John, Lewis, Simon, Kennedy, Martin, Pearson, John, Bras, Jose, Guerreiro, Rita, Tucci, Arianna, Nalls, Mike A, Kia, Demis A, Houlden, Henry, Plun-Favreau, Helene, Mok, Kin Y, Wood, Nicholas W, Lovering, Ruth, R'Bibo, Lea, Rizig, Mie, Chelban, Viorica, Trabzuni, Daniah, Hardy, John, Tan, Manuela, Morris, Huw R, Middlehurst, Ben, Quinn, John, Billingsley, Kimberley, Holmans, Peter, Kinghorn, Kerri J, Lewis, Patrick, Escott-Price, Valentina, Williams, Nigel, Gagliano Taliun, Sarah A, Foltynie, Thomas, Brice, Alexis, Danjou, Fabrice, Lesage, Suzanne, Corvol, Jean-Christophe, Martinez, Maria, Giri, Anamika, Schulte, Claudia, Brockmann, Kathrin, Simon Sanchez, Javier, Ryten, Mina, Heutink, Peter, Gasser, Thomas, Rizzu, Patrizia, Sharma, Manu, Shulman, Joshua M, Robak, Laurie, Lubbe, Steven, Mencacci, Niccolo E, Finkbeiner, Steven, Lungu, Codrin, Noyce, Alastair J, Scholz, Sonja W, Gan-Or, Ziv, Rouleau, Guy A, Krohan, Lynne, van Hilten, Jacobus J, Marinus, Johan, Adarmes-Gómez, Astrid D, Bernal-Bernal, Inmaculada, Bonilla-Toribio, Marta, Buiza-Rueda, Dolores, Nicolas, Aude, Carrillo, Fátima, Carrión-Claro, Mario, Mir, Pablo, Gómez-Garre, Pilar, Jesús, Silvia, Labrador-Espinosa, Miguel A, Macias, Daniel, Vargas-González, Laura, Méndez-Del-Barrio, Carlota, Periñán-Tocino, Teresa, Cookson, Mark R, Tejera-Parrado, Cristina, Diez-Fairen, Monica, Aguilar, Miquel, Alvarez, Ignacio, Boungiorno, María Teresa, Carcel, Maria, Pastor, Pau, Tartari, Juan Pablo, Alvarez, Victoria, González, Manuel Menéndez, Bandres-Ciga, Sara, Blazquez, Marta, Garcia, Ciara, Suarez-Sanmartin, Esther, Barrero, Francisco Javier, Rezola, Elisabet Mondragon, Yarza, Jesús Alberto Bergareche, Pagola, Ana Gorostidi, de Munain Arregui, Adolfo López, Ruiz-Martínez, Javier, and Cerdan, Debora

Subjects
Regulation of gene expression, 0303 health sciences, Cell type, Parkinson's disease, Microglia, Dopaminergic, Genomics, Disease, Biology, medicine.disease, Article, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, medicine, ddc:610, Neuroscience, Gene, 030217 neurology & neurosurgery, 030304 developmental biology
Abstract

Parkinson’s disease (PD), with its characteristic loss of nigrostriatal dopaminergic neurons and deposition of α-synuclein in neurons, is often considered a neuronal disorder. However, in recent years substantial evidence has emerged to implicate glial cell types, such as astrocytes and microglia. In this study, we used stratified LD score regression and expression-weighted cell-type enrichment together with several brain-related and cell-type-specific genomic annotations to connect human genomic PD findings to specific brain cell types. We found that PD heritability attributable to common variation does not enrich in global and regional brain annotations or brain-related cell-type-specific annotations. Likewise, we found no enrichment of PD susceptibility genes in brain-related cell types. In contrast, we demonstrated a significant enrichment of PD heritability in a curated lysosomal gene set highly expressed in astrocytic, microglial, and oligodendrocyte subtypes, and in LoF-intolerant genes, which were found highly expressed in almost all tested cellular subtypes. Our results suggest that PD risk loci do not lie in specific cell types or individual brain regions, but rather in global cellular processes detectable across several cell types.

Published
2019

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