A haplotype-resolved view of human gene regulation

  1. Mitchell R. Vollger
  2. Elliott G. Swanson
  3. Shane J. Neph
  4. Jane Ranchalis
  5. Katherine M. Munson
  6. Ching-Huang Ho
  7. Adriana E. Sedeño-Cortés
  8. William E. Fondrie
  9. Stephanie C. Bohaczuk
  10. Yizi Mao
  11. Nancy L. Parmalee
  12. Benjamin J. Mallory
  13. William T. Harvey
  14. Younjun Kwon
  15. Gage H. Garcia
  16. Kendra Hoekzema
  17. Jeffrey G. Meyer
  18. Mine Cicek
  19. Evan E. Eichler
  20. William S. Noble
  21. Daniela M. Witten
  22. James T. Bennett
  23. John P. Ray
  24. Andrew B. Stergachis
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Abstract

Most human cells contain two non-identical genomes, and differences in their regulation underlie human development and disease. We demonstrate that Fiber-seq Inferred Regulatory Elements (FIREs) enable the accurate quantification of chromatin accessibility across the 6 Gbp diploid human genome with single-molecule and single-nucleotide precision. We find that cells can harbor >1,000 regulatory elements with haplotype-selective chromatin accessibility (HSCA) and show that these elements preferentially localize to genomic loci containing the most human genetic diversity, with the human leukocyte antigen (HLA) locus showing the largest amount of HSCA genome-wide in immune cells. Furthermore, we uncover HSCA elements with sequence non-deterministic chromatin accessibility, representing likely somatic epimutations, and show that productive transcription from the inactive X chromosome is buttressed by clustered promoter-proximal elements that escape X chromosome inactivation.

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  1. Version published to 10.1101/2024.06.14.599122v1 on bioRxiv