A Population-scale Single-cell Spatial Transcriptomic Atlas of the Human Cortex

  1. Lei Han
  2. Zhen Liu
  3. Lifang Wang
  4. Yuxuan Liu
  5. Yanrong Wei
  6. Jianyun Ma
  7. Youzhe He
  8. Yichen Zuo
  9. Jiao Fang
  10. Hui Yang
  11. Xiang Zou
  12. Zihan Wu
  13. Min Wang
  14. Wei Liu
  15. Li Gao
  16. Yuyang Liu
  17. Xinxiang Song
  18. Yao Santo Zhang
  19. Junjie Lei
  20. Huanhuan Li
  21. Leiting Li
  22. Yingjie An
  23. Bufan Jin
  24. Yanqing Zhong
  25. Qinwen Chai
  26. Quyuan Tao
  27. Xing Tan
  28. Youning Lin
  29. Ruiyi Zhang
  30. Shengpeng Wang
  31. Mingkai Chang
  32. Bolin Yang
  33. Ming Chen
  34. Lijuan Mi
  35. Liyuan Zhuang
  36. Nini Yuan
  37. Chao Li
  38. Tao Huang
  39. Xin Li
  40. Cirong Liu
  41. Yidi Sun
  42. Liang Chen
  43. Longqi Liu
  44. Xun Xu
  45. Chengyu Li
  46. Hui Guo
  47. Hao Li
  48. Muming Poo
  49. Wen-Biao Gan
  50. Jianhua Yao
  51. Wen Yuan
  52. Shiping Liu
  53. Zhiming Shen
  54. Ying Mao
  55. Wu Wei
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Abstract

The genetic and spatial determinants of cell type diversity in human cerebral cortices remain poorly defined. Here, we present a population-level single-cell spatial transcriptomic atlas of human cortices from 71 donors across the lifespan. We identified 906 layer-specific genes showing conserved and divergent laminar expression patterns between humans and other species. Spatial analysis revealed neuronal vulnerability and glial activation during aging, together with a decline in the proportion of superficial SST neurons and their interactions with other cells. Disease-associated genes exhibited high cell-type and layer-specific expression, implicating the pathogenic role of spatially specific gene expression. Spatial cis-eQTL analysis identified regulatory variants linked to genes related to diseases like Tourette syndrome. Cross-species comparison demonstrated glial expansion in the human cortex, accompanied by enhanced neuron–glia communication via the neuregulin signaling. Together, we provide a comprehensive single-cell atlas of the human cortex that is essential for understanding aging, evolution, and disease pathogenesis.

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