Nature Communications (Aug 2023)

Unreprogrammed H3K9me3 prevents minor zygotic genome activation and lineage commitment in SCNT embryos

  • Ruimin Xu,
  • Qianshu Zhu,
  • Yuyan Zhao,
  • Mo Chen,
  • Lingyue Yang,
  • Shijun Shen,
  • Guang Yang,
  • Zhifei Shi,
  • Xiaolei Zhang,
  • Qi Shi,
  • Xiaochen Kou,
  • Yanhong Zhao,
  • Hong Wang,
  • Cizhong Jiang,
  • Chong Li,
  • Shaorong Gao,
  • Xiaoyu Liu

DOI
https://doi.org/10.1038/s41467-023-40496-3
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 15

Abstract

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Abstract Somatic cell nuclear transfer (SCNT) can be used to reprogram differentiated somatic cells to a totipotent state but has poor efficiency in supporting full-term development. H3K9me3 is considered to be an epigenetic barrier to zygotic genomic activation in 2-cell SCNT embryos. However, the mechanism underlying the failure of H3K9me3 reprogramming during SCNT embryo development remains elusive. Here, we perform genome-wide profiling of H3K9me3 in cumulus cell-derived SCNT embryos. We find redundant H3K9me3 marks are closely related to defective minor zygotic genome activation. Moreover, SCNT blastocysts show severely indistinct lineage-specific H3K9me3 deposition. We identify MAX and MCRS1 as potential H3K9me3-related transcription factors and are essential for early embryogenesis. Overexpression of Max and Mcrs1 significantly benefits SCNT embryo development. Notably, MCRS1 partially rescues lineage-specific H3K9me3 allocation, and further improves the efficiency of full-term development. Importantly, our data confirm the conservation of deficient H3K9me3 differentiation in Sertoli cell-derived SCNT embryos, which may be regulated by alternative mechanisms.