Background <p>The maternal-effect protein PADI6, which is part of the subcortical maternal complex, is involved in proper spindle assembly, organelle distribution, ribosome storage, and cytoplasmic lattice organization in mouse oocytes. In humans, variants of PADI6 are associated with female infertility and multilocus imprinting disturbance in offspring. Recently, it was demonstrated that PADI6 plays a role in the storage and cytoplasmic localization of epigenetic factors, including UHRF1 and DNMT1. Moreover, maternal PADI6 depletion leads to defective epigenetic reprogramming and zygotic genome activation but not to an imprinting defect in two-cell mouse embryos. These findings raise the possibility that imprinting disturbances arise later in development.</p> Results <p>By employing combined single-blastocyst RNA-seq/BS-seq and immunostaining validation in the embryos derived from <i>Padi6</i><sup>P620A</sup>-mutant oocytes, we investigated the role of <i>Padi6</i> in late preimplantation development. We demonstrated that embryos that overcame the two-cell stage block had a dramatic reduction in UHRF1 and DNMT1 protein levels, a decrease in H3K9me3, and whole-genome hypomethylation, including most imprinted loci and repetitive elements, at the blastocyst stage. Furthermore, these maternal mutant embryos showed deregulation of inner cell mass markers and defective blastocyst implantation, but no effect on trophoblast differentiation.</p> Conclusion <p>Our results demonstrate that maternal PADI6 is a key regulator of the stability of epigenetic factors required to maintain repressive marks in late preimplantation mouse embryos. Its deficiency results in genomic imprinting defects that closely resemble those found in human patients and provide a mechanistic explanation for MLID caused by maternal PADI6 variants. Furthermore, the impairment of blastocyst implantation capacity, likely due to dysregulation of inner cell mass differentiation, provides new mechanistic insights into the control of female fertility and embryo development exerted by PADI6.</p>

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Loss of maternal PADI6 disrupts DNA methylation and genomic imprinting maintenance in late preimplantation mouse embryos

  • Carlo Giaccari,
  • Francesco Cecere,
  • Angela Pagano,
  • Emilia D’Angelo,
  • Abu Saadat,
  • Lucia Mele,
  • Paolo Salerno,
  • Giuseppe Merla,
  • Flavia Cerrato,
  • Andrea Riccio

摘要

Background

The maternal-effect protein PADI6, which is part of the subcortical maternal complex, is involved in proper spindle assembly, organelle distribution, ribosome storage, and cytoplasmic lattice organization in mouse oocytes. In humans, variants of PADI6 are associated with female infertility and multilocus imprinting disturbance in offspring. Recently, it was demonstrated that PADI6 plays a role in the storage and cytoplasmic localization of epigenetic factors, including UHRF1 and DNMT1. Moreover, maternal PADI6 depletion leads to defective epigenetic reprogramming and zygotic genome activation but not to an imprinting defect in two-cell mouse embryos. These findings raise the possibility that imprinting disturbances arise later in development.

Results

By employing combined single-blastocyst RNA-seq/BS-seq and immunostaining validation in the embryos derived from Padi6P620A-mutant oocytes, we investigated the role of Padi6 in late preimplantation development. We demonstrated that embryos that overcame the two-cell stage block had a dramatic reduction in UHRF1 and DNMT1 protein levels, a decrease in H3K9me3, and whole-genome hypomethylation, including most imprinted loci and repetitive elements, at the blastocyst stage. Furthermore, these maternal mutant embryos showed deregulation of inner cell mass markers and defective blastocyst implantation, but no effect on trophoblast differentiation.

Conclusion

Our results demonstrate that maternal PADI6 is a key regulator of the stability of epigenetic factors required to maintain repressive marks in late preimplantation mouse embryos. Its deficiency results in genomic imprinting defects that closely resemble those found in human patients and provide a mechanistic explanation for MLID caused by maternal PADI6 variants. Furthermore, the impairment of blastocyst implantation capacity, likely due to dysregulation of inner cell mass differentiation, provides new mechanistic insights into the control of female fertility and embryo development exerted by PADI6.