4,4'-dimethoxychalcone increases resistance of mouse oocytes to postovulatory aging in vitro.

RESEARCH QUESTION: Does 4,4'-dimethoxychalcone (DMC), a natural antioxidant compound, effectively improve the quality of postovulatory ageing (POA) oocytes? DESIGN: Freshly ovulated MII oocytes were cultured in 10-µM DMC for 12 h in vitro. Reactive oxygen species (ROS) production, apoptosis rate, mitochondrial distribution, formation of the actin cap, and fertilization and development potential of POA oocytes, were studied. The change of autophagy level was detected, and the autophagy inhibitor 3-methyladenine (3-MA) was used to establish the relationship between DMC and autophagy. RESULTS: DMC supplementation eliminated the accumulated ROS (P < 0.0001) and ROS dependent 4 hydroxynonenal products (P = 0.0399), and decreased apoptosis (P = 0.0033), reduced abnormal mitochondrion distribution (P = 0.0280), improved mitochondrial membrane potential (P = 0.0135) and restored the formation of the actin cap (P = 0.0487), thus improving fertilization ability (P = 0.0156) and developmental potential (P = 0.0130) in POA oocytes. The role autophagy plays in the effects of DMC supplementation was investigated. The immunofluorescence results showed that POA leads to the accumulation of SQSTM1/p62 (P = 0.0083) but DMC supplementation could eliminate this (P < 0.0001). The western blot result of p62 protein was similar to the immunofluorescence results of the POA group (P = 0.0441) and DMC supplementation group (P = 0.0154). After inhibiting autophagy by 3-MA, the DMC supplementation group could no longer eliminate the accumulation of ROS (P = 0.1704). CONCLUSIONS: DMC supplementation activates autophagy to protect oocytes from postovulatory ageing. This approach can feasibly improve the reproductive outcome of ART.

Expanding the Genetic and Phenotypic Spectrum of Female Infertility Caused by TUBB8 Mutations.

Tubulin beta eight class VIII (TUBB8) is a subtype of ß-tubulin that only exists in primates. TUBB8 mutations have been reported to cause arrest of oocyte maturation and embryonic development. We aim to further investigate the mutational spectrum of TUBB8 and its relevance with female infertility. In our study, infertile patients were recruited, and their basal and clinical characteristics were analyzed. Genomic DNA was extracted from peripheral blood donated by patients. Candidate variants were identified by whole-exome sequencing, selected by relevant criteria, and validated by Sanger sequencing. We found five heterozygous variants: c.C208A(p.P70T), c.T907C(p.C303R), c.G173A(p.R58K), c.G326T(p.G109V), and c.C916T(p.R306C) in TUBB8 among six infertile patients characterized by abnormal phenotypes in oocyte maturation, fertilization, or embryo development. Most of oocytes retrieved from affected individuals were arrested at GV (germinal vesicle) stage and early embryos were arrested at variable stages. In vitro experiments were performed, and the relationship between variant c.G173A(p.R58K), c.C208A(p.P70T), and infertility phenotype was confirmed. We also discussed the possibility about patient II-1 from family 4 is affected by germinal/germline mosaicism. These results expand the kinds of variants and phenotypic spectrum of TUBB8 variants with regard to female infertility.

Maternal RNF114-mediated target substrate degradation regulates zygotic genome activation in mouse embryos.

Zygotic genomic activation (ZGA) is a landmark event in the maternal-to-zygotic transition (MZT), and the regulation of ZGA by maternal factors remains to be elucidated. In this study, the depletion of maternal ring finger protein 114 (RNF114), a ubiquitin E3 ligase, led to developmental arrest of two-cell mouse embryos. Using immunofluorescence and transcriptome analysis, RNF114 was proven to play a crucial role in major ZGA. To study the underlying mechanism, we performed protein profiling in mature oocytes and found a potential substrate for RNF114, chromobox 5 (CBX5), ubiquitylation and degradation of which was regulated by RNF114. The overexpression of CBX5 prevented embryonic development and impeded major ZGA. Furthermore, TAB1 was abnormally accumulated in mutant two-cell embryos, which was consistent with the result of in vitro knockdown of Rnf114. Knockdown of Cbx5 or Tab1 in maternal RNF114-depleted embryos partially rescued developmental arrest and the defect of major ZGA. In summary, our study reveals that maternal RNF114 plays a precise role in degrading some important substrates during the MZT, the misregulation of which may impede the appropriate activation of major ZGA in mouse embryos.

Heterozygous mutations in ZP1 and ZP3 cause formation disorder of ZP and female infertility in human.

The human zona pellucida (ZP) is a highly organized glycoprotein matrix that encircles oocytes and plays an essential role in successful reproduction. Previous studies have reported that mutations in human ZP1, ZP2 and ZP3 influence their functions and result in a lack of ZP or in an abnormal oocytes and empty follicle syndrome, which leads to female infertility. Here, we performed whole-exome sequencing in two probands with primary infertility whose oocytes lacked a ZP, and we identified a heterozygous mutation in ZP1 (NM_207341:c.326G>A p.Arg109His), which is situated in the N-terminus, and a heterozygous mutation in ZP3 (NM_001110354:c.400G>A p.Ala134Thr), which is situated in the ZP domain. The effects of the mutations were investigated through structure prediction and in vitro studies in HeLa cells. The results, which were in line with the phenotype, suggested that these mutations might impede the function of cross-linking and secretion of ZP proteins. Our study showed that the two mutations in ZP1 and ZP3 influenced the formation of the ZP, causing female infertility. Meanwhile, these data highlight the importance of the ZP1 N-terminus in addition to the conserved domains for ZP1 function and ZP formation. Additionally, the patient with the ZP1 mutation delivered a baby following intracytoplasmic sperm injection (ICSI); thus, we suggest the targeted genetic diagnosis of ZP genes to choose appropriate fertilization methods and improve the success rate of assisted reproductive technology (ART) treatments.

Oocyte competence is maintained by m6A methyltransferase KIAA1429-mediated RNA metabolism during mouse follicular development.

KIAA1429 (also known as vir-like m6A methyltransferase-associated protein (VIRMA)), a newly identified component of the RNA m6A methyltransferase complex, plays critical roles in guiding region-selective m6A deposition. However, in mammals, whether KIAA1429 mediates RNA m6A regulatory pathway functions in vivo remains unknown. Here, we show that the Kiaa1429-specific deficiency in oocytes resulted in female infertility with defective follicular development and fully grown germinal vesicle (GV) oocytes failing to undergo germinal vesicle breakdown (GVBD) and consequently losing the ability to resume meiosis. The oocyte growth is accompanied by the accumulation of abundant RNAs and posttranscriptional regulation. We found that the loss of Kiaa1429 could also lead to abnormal RNA metabolism in GV oocytes. RNA-seq profiling revealed that Kiaa1429 deletion altered the expression pattern of the oocyte-derived factors essential for follicular development. In addition, our data show that the conditional depletion of Kiaa1429 decreased the m6A levels in oocytes and mainly affected the alternative splicing of genes associated with oogenesis. In summary, the m6A methyltransferase KIAA1429-mediated RNA metabolism plays critical roles in folliculogenesis and the maintenance of oocyte competence.