Genome-wide association study of copy number variations in Parkinson’s disease

  1. Zied Landoulsi
  2. Ashwin Ashok Kumar Sreelatha
  3. Nicole Kuznetsov
  4. Claudia Schulte
  5. Dheeraj Reddy Bobbili
  6. Ludovica Montanucci
  7. Costin Leu
  8. Lisa-Marie Niestroj
  9. Emadeldin Hassanin
  10. Cloé Domenighetti
  11. Pierre-Emmanuel Sugier
  12. Milena Radivojkov-Blagojevic
  13. Peter Lichtner
  14. Berta Portugal
  15. Connor Edsall
  16. Jens Kru□ger
  17. Dena G Hernandez
  18. Cornelis Blauwendraat
  19. George D Mellick
  20. Alexander Zimprich
  21. Walter Pirker
  22. Manuela Tan
  23. Ekaterina Rogaeva
  24. Anthony Lang
  25. Sulev Koks
  26. Pille Taba
  27. Suzanne Lesage
  28. Alexis Brice
  29. Jean-Christophe Corvol
  30. Marie-Christine Chartier-Harlin
  31. Eugenie Mutez
  32. Kathrin Brockmann
  33. Angela B Deutschländer
  34. Georges M Hadjigeorgiou
  35. Efthimos Dardiotis
  36. Leonidas Stefanis
  37. Athina Maria Simitsi
  38. Enza Maria Valente
  39. Simona Petrucci
  40. Letizia Straniero
  41. Anna Zecchinelli
  42. Gianni Pezzoli
  43. Laura Brighina
  44. Carlo Ferrarese
  45. Grazia Annesi
  46. Andrea Quattrone
  47. Monica Gagliardi
  48. Lena F Burbulla
  49. Hirotaka Matsuo
  50. Akiyoshi Nakayama
  51. Nobutaka Hattori
  52. Kenya Nishioka
  53. Sun Ju Chung
  54. Yun Joong Kim
  55. Lukas Pavelka
  56. Pierre Kolber
  57. Bart PC van de Warrenburg
  58. Bastiaan R Bloem
  59. Andrew B. Singleton
  60. Dan Vitale
  61. Mathias Toft
  62. Lasse Pihlstrom
  63. Leonor Correia Guedes
  64. Joaquim J Ferreira
  65. Soraya Bardien
  66. Jonathan Carr
  67. Eduardo Tolosa
  68. Mario Ezquerra
  69. Pau Pastor
  70. Karin Wirdefeldt
  71. Nancy L Pedersen
  72. Caroline Ran
  73. Andrea C Belin
  74. Andreas Puschmann
  75. Carl E Clarke
  76. Karen E Morrison
  77. Dimitri Krainc
  78. Matt J Farrer
  79. Dennis Lal
  80. the Global Parkinson Genetics Program (GP2)
  81. Alexis Elbaz
  82. Thomas Gasser
  83. Rejko Krüger
  84. Manu Sharma
  85. Patrick May
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Abstract

Objective

To investigate the impact of copy number variations (CNVs) on Parkinson’s disease (PD) pathogenesis using genome-wide data and explore their role in sporadic PD.

Methods

We analyzed CNV data from 11,035 PD patients (including 2,731 early-onset PD (EOPD)) and 8,901 controls from the COURAGE-PD consortium using a sliding window CNV-GWAS and genome-wide burden analysis. The independent dataset from the Global Parkinson Genetics Program (GP2) consisted of 23,089 cases and 18,824 controls were used to validate our initial findings.

Results

The exploratory dataset identifies multiple CNV regions associated with PD risk. The nominated CNV loci were not confirmed in an independent dataset, except that only a deletion in the PRKN gene, a well-established EOPD locus, remained genome-wide significant and robustly supported.

CNV burden analysis showed a higher prevalence of CNVs in PD-related genes in patients compared to controls (OR=1.56 [1.18-2.09], p=0.0013), with PRKN showing the highest burden (OR=1.47 [1.10-1.98], p=0.026). Patients with CNVs in PRKN had an earlier disease onset. Burden analysis with controls and EOPD patients showed similar results.

Interpretation

The largest CNV-based GWAS on PD highlights both the promise and pitfalls of array-based CNV detection in PD and underscores the relevance of whole-genome sequencing approaches in resolving the role of CNV in PD. The array-based findings are prone towards false positive findings that might arise either from platform limitations and/or cohort biases. Future studies require improved genotyping resolution and rigorous cross-cohort validation to reliably assess CNV contributions to PD risk.

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  1. Version published to 10.1101/2024.08.21.24311915v2 on medRxiv
  2. Version published to 10.1101/2024.08.21.24311915v1 on medRxiv