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

Nature communications (2023-08-10)
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
ABSTRAKT

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.

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Sigma-Aldrich
Anti-MCRS1 antibody produced in rabbit, Prestige Antibodies® Powered by Atlas Antibodies, affinity isolated antibody, buffered aqueous glycerol solution