Multimodal brain cell atlas across the adult macaque lifespan

  1. Xiao Zhang
  2. Guangyao Lai
  3. Xiangyu Guo
  4. Wen Ma
  5. Yue Yuan
  6. Han Zhang
  7. Peng Fan
  8. Xingyuan Liu
  9. Pengcheng Guo
  10. Juan An
  11. Jinxiu Li
  12. Keke Huang
  13. Jing Zuo
  14. Liang Wu
  15. Shuncheng Shangguan
  16. Feng Yu
  17. Yuchen Xiang
  18. Yuebei Hu
  19. Yunting Huang
  20. Yiting Lin
  21. Dajian He
  22. Mingtian Pan
  23. Laiqiang Chen
  24. Bang Li
  25. Weili Yang
  26. Peng Yin
  27. Shihua Li
  28. Xiaolan Zhang
  29. Tao Yang
  30. Jing Chen
  31. Qiaoling Zhong
  32. Yuan Lv
  33. Baoming Qin
  34. Xiaobing Qing
  35. Qiuting Deng
  36. Yaling Huang
  37. Chang Liu
  38. Lei Han
  39. Shiping Liu
  40. Dajiang Qin
  41. Zhen Liu
  42. Yi Zhou
  43. Liang Qiao
  44. Chengyu Li
  45. YanXiao Zhang
  46. Giacomo Volpe
  47. Simon Graf
  48. Ian Ferenc Diks
  49. Matthias Flotho
  50. Rafal P. Krol
  51. Jan Mulder
  52. Andrew P. Hutchins
  53. Andreas Keller
  54. Patrick H. Maxwell
  55. David C. Rubinsztein
  56. Xiaolei Liu
  57. Hung-Fat Tse
  58. Muming Poo
  59. Bo Wang
  60. Longqi Liu
  61. Ying Gu
  62. Jun Xie
  63. Xun Xu
  64. Xiaojiang Li
  65. Chuanyu Liu
  66. Yiwei Lai
  67. Mingyuan Liu
  68. Miguel A. Esteban
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Abstract

High-throughput single-cell omics of non-human primate tissues present a remarkable opportunity to study primate brain aging. Here, we introduce a transcriptomic and chromatin accessibility landscape of 1,985,317 cells from eight brain regions of 13 cynomolgus female monkeys spanning adult lifespan including exceptionally old individuals up to 29-years old. This dataset uncovers dynamic molecular changes in critical brain functions such as synaptic communication and axon myelination, exhibiting a high degree of cell type and brain region specificity. We identify the multicellular networks of the pons and medulla as a previously unrecognized hotspot for aging. Furthermore, comparative analyses with human neurodegeneration datasets highlight both shared and distinct mechanisms contributing to aging and disease. In addition, we uncover transcription factors implicated in monkey brain aging and pinpoint aging-regulated loci linked to longevity and neurodegeneration. This spatiotemporal atlas will advance our understanding of primate brain aging and its broader implications for health and disease.

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