Tandem repeat variation shapes immune cell type-specific gene expression

  1. Hope A. Tanudisastro
  2. Anna S.E. Cuomo
  3. Ben Weisburd
  4. Matthew Welland
  5. Eleanor Spenceley
  6. Michael Franklin
  7. Angli Xue
  8. Hao Lawrence Huang
  9. Blake Bowen
  10. Jianan Fan
  11. Oscar A. Dong
  12. Albert Henry
  13. Peter C. Allen
  14. Kristof Wing
  15. Owen Tang
  16. Michael Gray
  17. Andre L.M. Reis
  18. Jonathan Margoliash
  19. Nehir E. Kurtas
  20. Jeffrey M. Pullin
  21. Arthur S. Lee
  22. Harrison Brand
  23. Michael Harper
  24. Katalina Bobowik
  25. Michael Silk
  26. Amy Miniter
  27. John Marshall
  28. Vivian Bakiris
  29. Bindu Swapna Madala
  30. Caitlin Uren
  31. Caitlin Bartie
  32. Rachael A. McCloy
  33. Anne Senabouth
  34. Harriet Dashnow
  35. Liam Fearnley
  36. Alejandro Martin-Trujillo
  37. Egor Dolzhenko
  38. Zhen Qiao
  39. Stuart M. Grieve
  40. Tung Nguyen
  41. Eyal Ben-David
  42. Ling Chen
  43. Kyle Kai-How Farh
  44. Michael Talkowski
  45. Stephen I. Alexander
  46. Owen M. Siggs
  47. Leonhard Gruenschloss
  48. Hannah R. Nicholas
  49. Jennifer Piscionere
  50. Cas Simons
  51. Chris Wallace
  52. Melissa Gymrek
  53. Ira W. Deveson
  54. Alex W. Hewitt
  55. Gemma A. Figtree
  56. Katrina M. de Lange
  57. Joseph E. Powell
  58. Daniel G. MacArthur
0 evaluations Published on
Read the full article Related papers
This article on Sciety

Abstract

Tandem repeats (TRs) - highly polymorphic, repetitive sequences across the human genome - are important regulators of gene expression but remain underexplored due to challenges in accurate genotyping and analysis 1 . Here, we generate new whole genome and single-cell RNA sequencing from >5.4 million blood-derived cells across 1,925 individuals in two cohorts [Cuomo et al. , accompanying manuscript], and perform meta-analysis to characterize the impact of variation in >1.7 million TR loci on immune cell type-specific gene expression. We identify >69,000 single-cell expression TR loci (sc-eTRs), 30.7% of which are specific to one of 28 immune cell types, and reveal dynamic regulatory effects using cell-state inference. Matched single-cell ATAC sequencing profiles from >3.4 million nuclei in 922 individuals [Xue et al. , accompanying manuscript]. uncover chromatin accessibility QTLs for nearly one-third of expression-associated TRs, supporting coordinated effects on cis-regulatory architecture. Fine-mapping implicates 1,490 TRs as candidate causal drivers of gene expression in 6.1% of tested genes, and colocalization analyses highlight >200 genes in which TRs likely mediate genetic associations with immune and hematological traits. Together, these results provide a genome-wide, multiomic view of TR-mediated regulation in the human immune system, establishing TRs as key contributors to cell type-specific regulatory variation and complex trait architecture.

Related articles

Related articles are currently not available for this article.