Karyopherin α deficiency contributes to human preimplantation embryo arrest

J Clin Invest. 2023 Jan 17;133(2):e159951. doi: 10.1172/JCI159951.

Abstract

Preimplantation embryo arrest (PREMBA) is a common cause of female infertility and recurrent failure of assisted reproductive technology. However, the genetic basis of PREMBA is largely unrevealed. Here, using whole-exome sequencing data from 606 women experiencing PREMBA compared with 2,813 controls, we performed a population and gene-based burden test and identified a candidate gene, karyopherin subunit α7 (KPNA7). In vitro studies showed that identified sequence variants reduced KPNA7 protein levels, impaired KPNA7 capacity for binding to its substrate ribosomal L1 domain-containing protein 1 (RSL1D1), and affected KPNA7 nuclear transport activity. Comparison between humans and mice suggested that mouse KPNA2, rather than mouse KPNA7, acts as an essential karyopherin in embryonic development. Kpna2-/- female mice showed embryo arrest due to zygotic genome activation defects, recapitulating the phenotype of human PREMBA. In addition, female mice with an oocyte-specific knockout of Rsl1d1 recapitulated the phenotype of Kpna2-/- mice, demonstrating the vital role of substrate RSL1D1. Finally, complementary RNA (cRNA) microinjection of human KPNA7, but not mouse Kpna7, was able to rescue the embryo arrest phenotype in Kpna2-/- mice, suggesting mouse KPNA2 might be a homologue of human KPNA7. Our findings uncovered a mechanistic understanding for the pathogenesis of PREMBA, which acts by impairing nuclear protein transport, and provide a diagnostic marker for PREMBA patients.

Keywords: Fertility; Genetic diseases; Genetics; Population genetics; Reproductive Biology.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Active Transport, Cell Nucleus
  • Animals
  • Blastocyst / metabolism
  • Female
  • Humans
  • Karyopherins / metabolism
  • Mice
  • Oocytes / metabolism
  • Pregnancy
  • Pregnancy Proteins* / metabolism
  • Ribosomal Proteins / metabolism
  • alpha Karyopherins* / genetics
  • alpha Karyopherins* / metabolism

Substances

  • alpha Karyopherins
  • Karyopherins
  • RSL1D1 protein, human
  • Pregnancy Proteins
  • Ribosomal Proteins