Single-cell genomics and regulatory networks for 388 human brains

  1. Prashant S. Emani
  2. Jason J. Liu
  3. Declan Clarke
  4. Matthew Jensen
  5. Jonathan Warrell
  6. Chirag Gupta
  7. Ran Meng
  8. Che Yu Lee
  9. Siwei Xu
  10. Cagatay Dursun
  11. Shaoke Lou
  12. Yuhang Chen
  13. Zhiyuan Chu
  14. Timur Galeev
  15. Ahyeon Hwang
  16. Yunyang Li
  17. Pengyu Ni
  18. Xiao Zhou
  19. PsychENCODE Consortium
  20. Trygve E. Bakken
  21. Jaroslav Bendl
  22. Lucy Bicks
  23. Tanima Chatterjee
  24. Lijun Cheng
  25. Yuyan Cheng
  26. Yi Dai
  27. Ziheng Duan
  28. Mary Flaherty
  29. John F. Fullard
  30. Michael Gancz
  31. Diego Garrido-Martín
  32. Sophia Gaynor-Gillett
  33. Jennifer Grundman
  34. Natalie Hawken
  35. Ella Henry
  36. Gabriel E. Hoffman
  37. Ao Huang
  38. Yunzhe Jiang
  39. Ting Jin
  40. Nikolas L. Jorstad
  41. Riki Kawaguchi
  42. Saniya Khullar
  43. Jianyin Liu
  44. Junhao Liu
  45. Shuang Liu
  46. Shaojie Ma
  47. Michael Margolis
  48. Samantha Mazariegos
  49. Jill Moore
  50. Jennifer R. Moran
  51. Eric Nguyen
  52. Nishigandha Phalke
  53. Milos Pjanic
  54. Henry Pratt
  55. Diana Quintero
  56. Ananya S. Rajagopalan
  57. Tiernon R. Riesenmy
  58. Nicole Shedd
  59. Manman Shi
  60. Megan Spector
  61. Rosemarie Terwilliger
  62. Kyle J. Travaglini
  63. Brie Wamsley
  64. Gaoyuan Wang
  65. Yan Xia
  66. Shaohua Xiao
  67. Andrew C. Yang
  68. Suchen Zheng
  69. Michael J. Gandal
  70. Donghoon Lee
  71. Ed S. Lein
  72. Panos Roussos
  73. Nenad Sestan
  74. Zhiping Weng
  75. Kevin P. White
  76. Hyejung Won
  77. Matthew J. Girgenti
  78. Jing Zhang
  79. Daifeng Wang
  80. Daniel Geschwind
  81. Mark Gerstein
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Abstract

Single-cell genomics is a powerful tool for studying heterogeneous tissues such as the brain. Yet, little is understood about how genetic variants influence cell-level gene expression. Addressing this, we uniformly processed single-nuclei, multi-omics datasets into a resource comprising >2.8M nuclei from the prefrontal cortex across 388 individuals. For 28 cell types, we assessed population-level variation in expression and chromatin across gene families and drug targets. We identified >550K cell-type-specific regulatory elements and >1.4M single-cell expression-quantitative-trait loci, which we used to build cell-type regulatory and cell-to-cell communication networks. These networks manifest cellular changes in aging and neuropsychiatric disorders. We further constructed an integrative model accurately imputing single-cell expression and simulating perturbations; the model prioritized ∼250 disease-risk genes and drug targets with associated cell types.

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  1. Version published to 10.1101/2024.03.18.585576v2 on bioRxiv
  2. Version published to 10.1101/2024.03.18.585576v1 on bioRxiv