Incomplete activation of Alyref and Gabpb1 leads to preimplantation arrest in cloned mouse embryos

Differentiated cell nuclei can be reprogrammed after nuclear transfer (NT) to oocytes and the produced NT embryos can give rise to cloned animals. However, development of NT embryos is often hampered by recurrent reprogramming failures, including the incomplete activation of developmental genes, yet specific genes responsible for the arrest of NT embryos are not well understood. Here, we searched for developmentally important genes among the reprogramming-resistant H3K9me3-repressed genes and identified Alyref and Gabpb1 by siRNA screening. Gene knockout of Alyref and Gabpb1 by the CRISPR/Cas9 system resulted in early developmental arrest in mice. Alyref was needed for the proper formation of inner cell mass by regulating Nanog, whereas Gabpb1 deficiency led to apoptosis. The supplement of Alyref and Gabpb1 mRNA supported efficient preimplantation development of cloned embryos. Alyref and Gabpb1 were silenced in NT embryos partially because of the repressed expression of Klf16 by H3K9me3. Thus, our study shows that the H3K9me3repressed genes contain developmentally required genes, and the incomplete activation of such genes results in preimplantation arrest of cloned embryos.

Automated summary

By using siRNA screening, researchers found that knocking out Alyref and Gabpb1 genes resulted in early developmental arrest in mice, with Alyref regulating Nanog for proper inner cell mass formation and Gabpb1 deficiency leading to apoptosis. Supplementing Alyref and Gabpb1 mRNA supported the preimplantation development of cloned embryos. The study suggests that the H3K9me3-repressed genes contain developmentally required genes, and the incomplete activation of these genes leads to the preimplantation arrest of cloned embryos.