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Commentary Open Access | 10.1172/JCI166279
1Department of Obstetrics and Gynecology,
2Division of Reproductive Endocrinology and Infertility,
3Divisions of Maternal Fetal Medicine and Prenatal and Reproductive Genetics, and
4Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA.
Address correspondence to: Ignatia B. Van den Veyver, Duncan Neurological Research Institute, Texas Children’s Hospital, 1250 Moursund Street, Room 1025.14, Houston, Texas 77030, USA. Phone: 832.824.8125; Email: iveyver@bcm.edu.
Find articles by Sharif, M. in: JCI | PubMed | Google Scholar |
1Department of Obstetrics and Gynecology,
2Division of Reproductive Endocrinology and Infertility,
3Divisions of Maternal Fetal Medicine and Prenatal and Reproductive Genetics, and
4Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA.
Address correspondence to: Ignatia B. Van den Veyver, Duncan Neurological Research Institute, Texas Children’s Hospital, 1250 Moursund Street, Room 1025.14, Houston, Texas 77030, USA. Phone: 832.824.8125; Email: iveyver@bcm.edu.
Find articles by Detti, L. in: JCI | PubMed | Google Scholar
1Department of Obstetrics and Gynecology,
2Division of Reproductive Endocrinology and Infertility,
3Divisions of Maternal Fetal Medicine and Prenatal and Reproductive Genetics, and
4Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA.
Address correspondence to: Ignatia B. Van den Veyver, Duncan Neurological Research Institute, Texas Children’s Hospital, 1250 Moursund Street, Room 1025.14, Houston, Texas 77030, USA. Phone: 832.824.8125; Email: iveyver@bcm.edu.
Find articles by Van den Veyver, I. in: JCI | PubMed | Google Scholar
Published January 17, 2023 - More info
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.
Wenjing Wang, Yoichi Miyamoto, Biaobang Chen, Juanzi Shi, Feiyang Diao, Wei Zheng, Qun Li, Lan Yu, Lin Li, Yao Xu, Ling Wu, Xiaoyan Mao, Jing Fu, Bin Li, Zheng Yan, Rong Shi, Xia Xue, Jian Mu, Zhihua Zhang, Tianyu Wu, Lin Zhao, Weijie Wang, Zhou Zhou, Jie Dong, Qiaoli Li, Li Jin, Lin He, Xiaoxi Sun, Ge Lin, Yanping Kuang, Lei Wang, Qing Sang
The genetic basis of preimplantation embryo arrest is slowly being unraveled. Recent discoveries point to maternally expressed proteins required for cellular functions before the embryonic genome is activated. In this issue of the JCI, Wang, Miyamoto, et al. suggest a critical role for karyopherin-mediated protein cargo transport between oocyte cytoplasm and nucleus. Defective maternal oocyte–expressed human karyopherin subunit α7 (KPNA7) and mouse KPNA2 fail to bind a critical substrate, ribosomal L1 domain-containing protein 1 (RSL1D1), affecting its transport to the nucleus. As shown in embryos of Kpna2-null females, the consequences are disrupted zygotic genome activation and arrest of development. These findings have important implications for diagnosis and treatment of female infertility.
Infertility affects 15% of couples (1). A myriad of male and female factors can cause infertility, and the clinical work-up for female infertility is complex, involving evaluation of ovarian and uterine function and anatomy and underlying medical disorders that can affect ability to conceive (2). The clinical genetic work-up for female infertility is still limited and often includes no more than testing for a few conditions that affect fertility, such as parental chromosome constitution or maternal carrier status for fragile X premutation, associated with premature ovarian insufficiency.
Exome and genome sequencing of DNA from cohorts of women with infertility has yielded insights into underlying genetic causes (reviewed in refs. 2–5). The implicated gene deficiencies are broadly categorized into those causing oocyte maturation defects, fertilization and zygotic defects, and preimplantation embryo arrest (Figure 1A). These genetic deficiencies explain only a small proportion of these forms of infertility, and more are yet to be discovered. Identifying these genes helps in understanding of the processes required for the transition from highly specialized, transcriptionally silent gametes to a pluripotent, rapidly dividing, early preimplantation embryo. The maternal-to-zygotic transition (MZT) depends on maternally expressed genes to facilitate meiotic cell division, spindle formation, epigenetic reprogramming, storage of maternal RNAs and proteins in mature oocytes, and their timely degradation after fertilization, when the embryo begins to transcribe its own genome (6). Factors from the nucleus, cytoplasm (in particular the oocyte subcortical maternal complex and cytoplasmic lattices), cell membrane, and zona pellucida all play a role in this transition (3).
Maternal genetic factors are implicated in oocyte and early embryonic development. (A) There are several maternal genetic factors implicated in oocyte development, fertilization, zygotic cleavage, and early embryonic development. The genetic factors are broadly categorized based on their primary phenotypes and developmental defects. KPNA7 is implicated in preimplantation embryo arrest. (B) Karyopherin-mediated protein cargo transport between oocyte cytoplasm and nucleus is essential for proper ZGA. If defective, maternal oocyte–expressed human KPNA7 and its mouse homolog KPNA2 fail to bind RSD1L1, affecting its transport to the nucleus. The consequences are clinical infertility due to disrupted ZGA and early embryonic arrest (reported by Wang et al., ref. 7).
A major cornerstone of infertility treatment involves in vitro fertilization (IVF) with short-term embryo culture (up to 5–7 days). This method allows assessment of oocyte, zygote, and embryonic phenotypes associated with unsuccessful IVF. In this issue of the JCI, Wang, Miyamoto, et al. (7) focus on identifying maternal genetic causes of preimplantation embryo arrest, whereby retrieved metaphase II–stage (MII-stage) oocytes appear healthy and can be fertilized, forming normal zygotes, but the embryos stop developing after one or a few cell divisions. Using exome sequencing of DNA from 606 women with this type of infertility, the authors identified deleterious compound heterozygous or homozygous variants in karyopherin subunit α7 (KPNA7) in ten (1.7%) families. The genetic burden of KPNA7 matches that of PADI6, the most frequently implicated maternal gene in preimplantation embryo arrest (8, 9). This result revealed the requirement of another class of proteins, karyopherins, for early human embryo development (7). The finding supports the idea that nuclear shuttling of certain proteins affects development of preimplantation embryos and in particular the proper initiation of zygotic genome activation (ZGA), which requires both correctly timed degradation of maternal RNAs and proteins and activation of transcription and translation of the embryonic genome.
A collection of maternal RNAs, proteins, and other biomolecules drives the developmental processes in early embryogenesis until the embryonic genome is activated during MZT. It is not surprising that impaired nuclear transport interrupts the intracellular trafficking of substrates that are essential for ZGA initiation. This transport is mediated by karyopherin α (also known as importin α), of which mammals encode multiple subtypes (10, 11); six have been identified in the mouse and seven in humans, referred to as karyopherin α1–α7 (KPNA1, KPNA2, KPNA3, KPNA4, KPNA5, KPNA6, and KPNA7). The transcript abundance of these seven karyopherin α’s changes substantially during development from the germinal vesicle (GV) oocyte to the embryo blastocyst stage (12), strongly suggesting that the protein family serves a critical function during embryogenesis. Among human KPNA genes, KPNA7 (importin α8) is the most abundant karyopherin α in human GV and MII-stage oocytes, where DNA methylation may account for its oocyte-specific expression (13). KPNA7 remains present in early embryos, but its RNA is quickly degraded during ZGA (12, 14–16) and it becomes barely detectable in morulas and blastocysts, consistent with a role in transporting essential nuclear factors required for MZT (14). In a series of elegant experiments combining human sequence data, in vitro cell culture data, and mouse models, Wang, Miyamoto, et al. (7) first found that specific variants reduced protein levels of mutant KPNA7 and impaired binding to and transport of selected protein cargo into the nucleus. The authors identified protein RSD1L1, which is highly expressed in oocytes, as an important cargo of KPNA7 and then showed, using mutant mouse models, that Kpna2 is the mouse homolog of human KPNA7 (7) (Figure 1B). Maternal loss of Kpna2 in mice affected nuclear transport of RSD1L1 and led to a phenotype of early embryo arrest with altered transcriptome at initiation of ZGA in two-cell embryos. The authors then found that maternal loss of Rsd1l1 in mice also caused preimplantation embryo arrest, confirming the importance of RSD1L1 in this process (7). Interestingly, studies in other species had already implicated maternal karyopherin α encoded by KPNA7 homologs in early embryo development. RNAi-based knockdown experiments in bovine (14) and porcine (12) embryos showed that KPNA7 is necessary for cleavage development. Kpna7 has also recently been described as a maternal effect gene in zebrafish (17). These data support that a conserved mechanism, important for embryonic genome activation and early development, exists across various species. Finally, Wang, Miyamoto, et al. showed that injection of Kpna7 complementary RNA (cRNA) into maternal Kpna2-null mouse zygotes could reverse embryo arrest, pointing toward therapeutic possibilities for this form of early embryo arrest (7). Although exciting, considering ethical complexities, such therapy is not currently an option that can be considered in humans.
The study by Wang, Miyamoto, and colleagues adds to a growing list of maternal genes implicated in infertility caused by preimplantation embryo arrest (7). This and other studies raise the question of whether it is time for genome-wide or gene-panel sequencing for the clinical work-up of female infertility. This question is important because maternal-effect genetic causes of KPNA7-related and similar forms of infertility have a relatively low chance for effective treatment with IVF, as the primary maternal genetic defect affects all the woman’s oocytes. Whether women with infertility should be offered this genetic testing or whether it should be considered only after failed IVF with relevant oocyte or preimplantation embryo phenotypes remains an open question.
MS is supported by National Research Service Award (NRSA) institutional training grant T32 HD 098068. IBVDV is supported in part by grants from the Eunice Kennedy Shriver National Institute of Child Health & Human Development of the NIH (R01HD079442, R01HD092746, and P50HD103555) (for use of the Administrative and Clinical Translational Core facilities). The content is solely the responsibility of the authors and does not necessarily represent the official views of the NIH.
Address correspondence to: Ignatia B. Van den Veyver, Duncan Neurological Research Institute, Texas Children’s Hospital, 1250 Moursund Street, Room 1025.14, Houston, Texas 77030, USA. Phone: 832.824.8125; Email: iveyver@bcm.edu.
Conflict of interest: IBVDV is a member of the Scientific Advisory Board of Baylor Genetics. IBVDV is an investigator on an NIH-funded genome-sequencing study that receives support in the form of reagents from Illumina.
Copyright: © 2023, Sharif et al. This is an open access article published under the terms of the Creative Commons Attribution 4.0 International License.
Reference information:J Clin Invest. 2023;133(2):e166279. https://doi.org/10.1172/JCI166279.
See the related article at Karyopherin 03B1> deficiency contributes to human preimplantation embryo arrest.