Biallelic mutations in MOS cause female infertility characterized by human early embryonic arrest and fragmentation.

Early embryonic arrest and fragmentation (EEAF) is a common phenomenon leading to female infertility, but the genetic determinants remain largely unknown. The Moloney sarcoma oncogene (MOS) encodes a serine/threonine kinase that activates the ERK signaling cascade during oocyte maturation in vertebrates. Here, we identified four rare variants of MOS in three infertile female individuals with EEAF that followed a recessive inheritance pattern. These MOS variants encoded proteins that resulted in decreased phosphorylated ERK1/2 level in cells and oocytes, and displayed attenuated rescuing effects on cortical F-actin assembly. Using oocyte-specific Erk1/2 knockout mice, we verified that MOS-ERK signal pathway inactivation in oocytes caused EEAF as human. The RNA sequencing data revealed that maternal mRNA clearance was disrupted in human mature oocytes either with MOS homozygous variant or with U0126 treatment, especially genes relative to mitochondrial function. Mitochondrial dysfunction was observed in oocytes with ERK1/2 deficiency or inactivation. In conclusion, this study not only uncovers biallelic MOS variants causes EEAF but also demonstrates that MOS-ERK signaling pathway drives human oocyte cytoplasmic maturation to prevent EEAF.

Next-generation sequence-based preimplantation genetic testing for monogenic disease resulting from maternal mosaicism.

BACKGROUND: Mosaicism poses challenges for genetic counseling and preimplantation genetic testing for monogenic disorders (PGT-M). NGS-based PGT-M has been extensively used to prevent the transmission of monogenic defects, but it has not been evaluated in the application of PGT-M resulting from mosaicism. METHODS: Four women suspected of mosaicism were confirmed by ultra-deep sequencing. Blastocyst trophectoderm cells and polar bodies were collected for whole genome amplification, followed by pathogenic variants detection and haplotype analysis based on NGS. The embryos free of the monogenic disorders were transplantable. RESULTS: Ultra-deep sequencing confirmed that the four women harbored somatic mosaic variants, with the proportion of variant cells at 1.12%, 9.0%, 27.60%, and 91.03%, respectively. A total of 25 blastocysts were biopsied and detected during four PGT cycles and 5 polar bodies were involved in one cycle additionally. For each couple, a wild-type embryo was successfully transplanted and confirmed by prenatal diagnosis, resulting in the birth of four healthy infants. CONCLUSIONS: Mosaic variants could be effectively evaluated via ultra-deep sequencing, and could be prevented the transmission by PGT. Our work suggested that an NGS-based PGT approach, involving pathogenic variants detection combined with haplotype analysis, is crucial for accurate PGT-M with mosaicism.

Neonatal outcomes of live births after blastocyst biopsy in preimplantation genetic testing cycles: a follow-up of 1,721 children.

OBJECTIVE: To investigate whether blastocyst biopsy in preimplantation genetic testing (PGT) increases the risk of adverse neonatal outcomes. DESIGN: Retrospective cohort study. SETTING: University-affiliated center. PATIENTS: Live births after blastocyst biopsy combined with frozen ET (PGT group) and frozen blastocyst transfer after in vitro fertilization or intracytoplasmic sperm injection (control group). INTERVENTION(S): Blastocyst biopsy. MAIN OUTCOME MEASURE(S): Gestational age (GA), birth weight (BW), and rates of preterm birth (PB), very preterm birth (VPB), extreme preterm birth (EPB), low birth weight (LBW), very low birth weight (VLBW), and macrosomia. RESULT(S): No significant differences were observed in the sex ratio, GA, PB, VPB, EPB, BW, or rates of LBW, VLBW, and macrosomia between the PGT and control groups for either singletons or twins. However, the cesarean section rate of the PGT group was significantly higher than that of the control group for twins (adjusted odds ratio, 2.383 [1.079, 5.259]). Regarding fluorescence in situ hybridization-PGT neonates, neonatal outcomes, including GA, BW, and rates of PB, VPB, LBW, and VLBW, did not differ between the different groups of biopsied cells (≥10 group and <10 group) for either the grade B or grade C trophectoderm score subgroups; however, in the grade B trophectoderm score subgroup, the rate of boy babies in the ≥10 group was significantly higher than that in the <10 group (83.3% vs. 40.9%). The association between the number of biopsied cells and GA/BW was not statistically significant. CONCLUSION(S): Blastocyst biopsy may not add additional risk to neonatal outcomes when compared with a control group.

Identification of biparental and diploid blastocysts from monopronuclear zygotes with the use of a single-nucleotide polymorphism array.

OBJECTIVE: To select normal fertilized diploid blastocysts in patients who had only monopronucleated (1PN) embryos for transfer. DESIGN: Experimental study. SETTING: University-affiliated center. PATIENT(S): Couples who were undergoing intracytoplasmic sperm injection treatment and had 1PN blastocysts. INTERVENTION(S): In a preliminary test, limited cells of parthenogenetic human embryonic stem cells (phESCs) and normal fertilized blastocysts were analyzed with the use of a low-density single-nucleotide polymorphism (SNP) array to identify the distribution pattern and rate of heterozygosity. In the clinical application, 1PN blastocysts were analyzed with the use of the SNP array. Only diagnosed normal blastocysts were transferred. The diagnosed uniparental blastocysts were validated by imprinted gene expression. MAIN OUTCOME MEASURE(S): Distribution pattern and rate of heterozygosity between parthenogenesis and normal fertilization. RESULT(S): In the pretest, phESCs exhibited distinct distribution pattern and lower rate of heterozygosity, compared with normal fertilized blastocysts after SNP analysis. In particular, homozygous hESCs showed a panhomozygosity distribution pattern, hybrid phESCs showed a partial homozygosity distribution pattern, and normal fertilized blastocysts exhibited a panheterozygosity distribution pattern with an average of 20.21% heterozygosity rate; 13.6% was found to be the minimum cutoff to predict normal fertilized samples. In the clinical application, 24 1PN blastocysts were analyzed; 10/24 showed chromosomal abnormalities, 3/24 showed panhomozygosity with 0.45%-0.8% heterozygosity, and 1/24 showed partial homozygosity with 6.54% heterozygosity. The remaining 10 blastocysts, with a panheterozygosity distribution pattern and higher genomic heterozygosity rate, were diagnosed as normal-fertilization diploid embryos; three were transferred and resulted in two healthy newborns. CONCLUSION(S): The low-density SNP array might serve as a cost-effective method to identify biparental origin and diploid 1PN blastocysts for transfer.

The clinical and neonatal outcomes after stimulation of immotile spermatozoa using SperMagic medium.

To evaluate the efficiency and safety of SperMagic medium on stimulating the immotile spermatozoa in testicular sperm extraction (TESE) and absolute asthenozoospermia, 96 patients with TESE and 106 patients with absolute asthenozoospermia were enrolled in this study. The motile spermatozoa were detected in 47 TESE patients and 68 absolute asthenozoospermia and these patients were assigned to control group. The immotile spermatozoa in 49 TESE patients and 34 absolute asthenozoospermia were stimulated with SperMagic medium. Patients were treated by standard intracytoplasmic sperm injection (ICSI). There were no significant differences in fertilisation, cleavage, implantation, pregnancy, live birth and neonatal outcomes. SperMagic medium does not increase incidence of adverse neonatal outcomes and is a reliable tool for selection of viable spermatozoa in ICSI.

Inner cell mass incarceration in 8-shaped blastocysts does not increase monozygotic twinning in preimplantation genetic diagnosis and screening patients.

BACKGROUND: The use of assisted reproductive technology (ART) has been reported to increase the incidence of monozygotic twinning (MZT) compared with the incidence following natural conception. It has been hypothesized that splitting of the inner cell mass (ICM) through a small zona hole may result in MZT. In this study, using a cohort of patients undergoing preimplantation genetic diagnosis/screening (PGD/PGS), we compared the clinical and neonatal outcomes of human 8-shaped blastocysts hatching with ICM incarceration with partially or fully hatched blastocysts, and attempted to verify whether this phenomenon increases the incidence of MZT pregnancy or negatively impact newborns. METHODS: This retrospective study included 2059 patients undergoing PGD/PGS between March 1, 2013, and December 31, 2015. Clinical and neonatal outcomes were only collected from patients who received a single blastocyst transfer after PGD/PGS (n = 992). A 25- to 30-µm hole was made in the zona of day 3 embryos by laser. The blastocysts were biopsied and vitrified on day 6. The biopsied trophectoderm (TE) cells were analyzed using different genetic methods. One tested blastocyst was thawed and transferred to each patient in the subsequent frozen embryo transfer cycle. All the biopsied blastocysts were divided into three types: 8-shaped with ICM incarceration (type I), partially hatched without ICM incarceration (type II), and fully hatched (type III). ICM/TE grading, clinical and neonatal outcomes were compared between the groups. RESULTS: The percentage of grade A ICMs in type I blastocysts (22.2%) was comparable to that in type III blastocysts (20.1%) but higher than that in type II blastocysts (4.5%). The percentage of grade A TEs in type I blastocysts (4.2%) was comparable to that in type II (3.6%) but lower than that in type III (13.5%). There were no significant differences in clinical pregnancy, MZT pregnancy, miscarriage, live birth, MZT births, and neonatal outcomes between the groups. CONCLUSIONS: Compared to partially and fully hatched blastocysts, 8-shaped blastocysts with ICM incarceration showed relatively higher ICM and lower TE grades. ICM incarceration in 8-shaped blastocysts does not increase the incidence of MZT and has no negative effects on newborns in PGD/PGS patients.

Polar body transfer restores the developmental potential of oocytes to blastocyst stage in a case of repeated embryo fragmentation.

PURPOSE: We aimed to determine the developmental potential of human reconstructed oocytes after polar body genome transfer (PBT) and to report the case of a woman with multiple cycles of severe embryo fragmentation. METHODS: Fresh and cryopreserved first polar bodies (PB1s) were transferred to enucleated metaphase II oocytes (PB1T), while fresh PB2s were removed from fertilized oocytes and used instead of the female pronucleus in donor zygotes. Reconstructed oocytes underwent intracytoplasmic sperm injection (ICSI) and were cultured to blastocyst. Biopsied trophectoderm cells of PBT-derived blastocysts were screened for chromosomes by next-generation sequencing (NGS). Then, cryopreserved PB1T was carried out in one woman with a history of several cycles of extensive embryo fragmentation, and the blastocysts derived from PB1T were screened for aneuploidy but not transferred to the patient. RESULTS: There were no significant differences in the rates of normal fertilization and blastocyst formation between fresh and cryopreserved PB1T and control oocytes. Of the three fresh and three cryopreserved PB1T-derived blastocysts, two and one blastocysts exhibited normal diploidy respectively. In contrast, 17 PB2 transfers yielded 16 two pronuclei (2PN) zygotes with one normal and one small-sized pronucleus each and no blastocyst formation. In the female patient, 18 oocytes were inseminated by ICSI in the fourth cycle and the PB1s were biopsied. Although the embryos developed from the patient's own oocytes showed severe fragmentation, the oocytes reconstructed after PB1T produced three chromosomally normal blastocysts. CONCLUSIONS: Normal blastocysts can develop from human reconstructed oocytes after PB1T. The application of the first PB transfers may be beneficial to patients with a history of poor embryo development and excessive fragmentation.

Pronuclear removal of tripronuclear zygotes can establish heteroparental normal karyotypic human embryonic stem cells.

PURPOSE: This study aimed to derive heteroparental normal karyotypic human embryonic stem cells (hESCs) from microsurgically corrected tripronuclear (3PN) zygotes. METHODS: After sequential culture for 5-6 days, embryos developed from microsurgically corrected 3PN zygotes were analyzed by fluorescence in situ hybridization (FISH) using probes for chromosomes 17, X and Y. Intact 3PN zygotes from clinical in vitro fertilization (IVF) cycles were cultured as the control group. The inner cell mass (ICM) of blastocysts that developed from microsurgically corrected 3PN zygotes was used to derive hESC lines, and the stem cell characteristics of these lines were evaluated. G-banding analysis was adopted to identify the karyotype of the hESC line, and the heteroparental inheritance of the hESC line was analyzed by DNA fingerprinting analysis. RESULTS: The blastocyst formation rate (13.5 %) of the microsurgically corrected 3PN zygotes was significantly higher (P < 0.05) than that of intact 3PN zygotes (8.7 %). The diploid rate of the blastocysts (55.0 %) was significantly higher (P < 0.05) than that of the arrested cleavage-stage embryos (18.4 %) in microsurgically corrected 3PN zygotes. The triploid rate of the microsurgically corrected 3PN zygotes (5.7 %) was significantly lower (P < 0.01) than that of intact 3PN zygotes (19.4 %). Furthermore, we established one heteroparental normal karyotypic hESC line from the microsurgically corrected tripronuclear zygotes. CONCLUSIONS: Pronuclear removal can effectively remove the surplus chromosome set of 3PN zygotes. A combination of pronuclear removal and blastocyst culture enables the selection of diploidized blastocysts from which heteroparental normal karyotypic hESC lines can be derived.