Genome Biology (Nov 2021)

Enhanced chromatin accessibility contributes to X chromosome dosage compensation in mammals

  • Irene Talon,
  • Adrian Janiszewski,
  • Bart Theeuwes,
  • Thomas Lefevre,
  • Juan Song,
  • Greet Bervoets,
  • Lotte Vanheer,
  • Natalie De Geest,
  • Suresh Poovathingal,
  • Ryan Allsop,
  • Jean-Christophe Marine,
  • Florian Rambow,
  • Thierry Voet,
  • Vincent Pasque

DOI
https://doi.org/10.1186/s13059-021-02518-5
Journal volume & issue
Vol. 22, no. 1
pp. 1 – 36

Abstract

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Abstract Background Precise gene dosage of the X chromosomes is critical for normal development and cellular function. In mice, XX female somatic cells show transcriptional X chromosome upregulation of their single active X chromosome, while the other X chromosome is inactive. Moreover, the inactive X chromosome is reactivated during development in the inner cell mass and in germ cells through X chromosome reactivation, which can be studied in vitro by reprogramming of somatic cells to pluripotency. How chromatin processes and gene regulatory networks evolved to regulate X chromosome dosage in the somatic state and during X chromosome reactivation remains unclear. Results Using genome-wide approaches, allele-specific ATAC-seq and single-cell RNA-seq, in female embryonic fibroblasts and during reprogramming to pluripotency, we show that chromatin accessibility on the upregulated mammalian active X chromosome is increased compared to autosomes. We further show that increased accessibility on the active X chromosome is erased by reprogramming, accompanied by erasure of transcriptional X chromosome upregulation and the loss of increased transcriptional burst frequency. In addition, we characterize gene regulatory networks during reprogramming and X chromosome reactivation, revealing changes in regulatory states. Our data show that ZFP42/REX1, a pluripotency-associated gene that evolved specifically in placental mammals, targets multiple X-linked genes, suggesting an evolutionary link between ZFP42/REX1, X chromosome reactivation, and pluripotency. Conclusions Our data reveal the existence of intrinsic compensatory mechanisms that involve modulation of chromatin accessibility to counteract X-to-Autosome gene dosage imbalances caused by evolutionary or in vitro X chromosome loss and X chromosome inactivation in mammalian cells.

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