Whole-Genome Sequencing Reveals Individual and Cohort Level Insights into Chromosome 9p Syndromes

  1. Yingxi Wang
  2. Eleanor I. Sams
  3. Rachel Slaugh
  4. Sandra Crocker
  5. Emily Cordova Hurtado
  6. Sophia Tracy
  7. Ying-Chen Claire Hou
  8. Christopher Markovic
  9. Kostandin Valle
  10. Victoria Tate
  11. Khadija Belhassan
  12. Elizabeth Appelbaum
  13. Titilope Akinwe
  14. Rodrigo Starosta Tzovenos
  15. Yang Cao
  16. Amber Neilson
  17. Yu Liu
  18. Nathaniel Jensen
  19. Reza Ghasemi
  20. Tina Lindsay
  21. Juana Manuel
  22. Sophia Couteranis
  23. Milinn Kremitzki
  24. Jack Ustanik
  25. Thomas Antonacci
  26. Jeffrey K. Ng
  27. Andrew Emory
  28. Laura Metz
  29. Tracie DeLuca
  30. Katherine N. Lyons
  31. Toni Sinnwell
  32. Brianne Thomeczek
  33. Kymme Wang
  34. Nick Sisneros
  35. Megha Muraleedharan
  36. Anantha Kethireddy
  37. Marco Corbo
  38. Harsha Gowda
  39. Katherine King
  40. Christina A. Gurnett
  41. Susan K. Dutcher
  42. Catherine Gooch
  43. Yang E. Li
  44. Matthew W. Mitchell
  45. Kevin A. Peterson
  46. Amjad Horani
  47. Jill A. Rosenfeld
  48. Weimin Bi
  49. Pawel Stankiewicz
  50. Hsiao-Tuan Chao
  51. Jennifer Posey
  52. Christopher M. Grochowski
  53. Zain Dardas
  54. Erik Puffenberger
  55. Christopher E. Pearson
  56. Frank Kooy
  57. Dale Annear
  58. A. Micheil Innes
  59. Michael Heinz
  60. Richard Head
  61. Robert Fulton
  62. Stephan Toutain
  63. Lucinda Antonacci-Fulton
  64. Xiaoxia Cui
  65. Robi D. Mitra
  66. F. Sessions Cole
  67. Julie Neidich
  68. Patricia I. Dickson
  69. Jeffrey Milbrandt
  70. Tychele N. Turner
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Abstract

Previous genomic efforts on chromosome 9p deletion and duplication syndromes have utilized low resolution strategies (i.e., karyotypes, chromosome microarrays). We present the first large-scale whole-genome sequencing (WGS) study of 100 individuals from families with 9p-related syndromes including 85 unrelated probands through the 9P-ARCH (Advanced Research in Chromosomal Health: Genomic, Phenotypic, and Functional Aspects of 9p-Related syndromes) research network. We analyzed the genomic architecture of these syndromes, highlighting fundamental features and their commonalities and differences across individuals. This work includes a machine-learning model that predicts 9p deletion syndrome from gene copy number estimates using WGS data. Two Late Replicating Regions (LRR1 [a previously un-named human fragile site], LRR2) were identified that contain most structural variant breakpoints in 9p deletion syndrome pointing to replication-based issues in structural variant formation. Furthermore, we show the utility of using WGS information to obtain a comprehensive understanding of 9p-related variation in an individual with complex structural variation where chromothripsis is the likely mechanism. Genes on 9p were prioritized based on statistical assessment of human genomic variation. Furthermore, through application of spatial transcriptomics to embryonic mouse tissue we examined 9p-gene expression in craniofacial and brain development. Through these strategies, we identified 24 important genes for the majority (83%) of individuals with 9p deletion syndrome including AK3, BRD10, CD274, CDC37L1, DMRT1, DMRT2, DMRT3, DOCK8, GLIS3, JAK2, KANK1, KDM4C, PLPP6, PTPRD, PUM3, RANBP6, RCL1, RFX3, RIC1, SLC1A1, SMARCA2, UHRF2, VLDLR, and ZNG1A. Two genes (AK3, ZNG1A) are involved in mitochondrial function and testing of the mitochondrial genome revealed excess copy number in individuals with 9p deletion syndrome. This study presents the most comprehensive genomic analysis of 9p-related syndromes to date, with plans for further expansion through our 9P-ARCH research network.

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  1. Version published to 10.1101/2025.03.28.25324850v1 on medRxiv