Project description:In-vitro-grow (IVG) of preantral follicles is essential for female fertility preservation, while effective approach to improve it is far from being explored. Here, we report the dynamic location of TRKB in human and mouse ovaries, and a positive relation between human oocyte maturation and NT-4 level in follicular fluid. For the first time, we observe the improving effect of NT-4 on mice preantral follicle IVG, including follicle diameter, hormone production and oocyte maturation. Single-cell transcriptome analysis shows that the reparative effect of NT-4 on oocyte maturation in IVG may be mediated by regulation of PI3K-Akt signaling pathway and subsequent organization of F-actin. Suppression of advanced stimulated complement system in granulosa cells may also contribute to the improvement. Cell-specific network analysis reveals that NT-4 may recover the inflammation damage induced by abnormal lipid metabolism in IVG environment. Collectively, our data suggest that NT-4 is involved in the ovarian physiology and may serve to improve the efficiency of preantral follicle IVG for fertility preservation.

Project description:Vitrification is increasingly used to cryopreserve gametes and embryos in assisted reproductive technology (ART). Our prior research demonstrates that vitrification preserves the viability and functionality of ovarian follicles. However, its impact on follicle-enclosed oocyte remains unknown. The current study investigates whether vitrification, combined with a 3D encapsulated in vitro follicle growth (eIVFG) system, maintains oocyte transcriptome during in vitro follicle development and oocyte maturation. Immature mouse preantral follicles were vitrified and cultured in eIVFG for 8 days to grow to the preovulatory stage, followed with the induction of ovulation and oocyte maturation on day 9, with fresh follicles as the control. Oocytes at germinal vesicle (GV) stage from grown preovulatory follicles on day 8 and oocytes at metaphase II (MII) upon ovulation on day 9 were collected for single-oocyte Smart-Seq2 RNA sequencing analysis. The principal component analysis (PCA) separated GV and MII oocytes into two distinct clusters, but oocytes from fresh and vitrified follicles were largely overlapped. Differential gene expression (DEG) analysis revealed that GV or MII oocytes from fresh and vitrified follicles had comparable expression of maternal effect genes and other genes related to oocyte meiotic and developmental competence. There was a significant transcriptomic change during the GV-to-MII transition. Gene ontology (GO) and KEGG analysis identified DEGs between GV and MII oocytes related to cell cycle, RNA processing, mitochondria, and ribosome. In summary, our study demonstrates that vitrification preserves oocyte transcriptome during in vitro follicle development and oocyte maturation, supporting its potential in fertility preservation. Moreover, our single-oocyte RNA sequencing analysis identifies key DEGs upon GV-to-MII transition, indicating their potential functions in underpinning oocyte meiotic and developmental competence.

Project description:Reproductive aging is a major cause of fertility decline, attributed to decreased oocyte quantity and competence. Follicular somatic cells play crucial roles in the growth and development of the oocyte by providing nutrients and regulatory factors. Here we investigated how oocyte quality is affected by its somatic cell environment by creating chimeric follicles, whereby an oocyte from one follicle was transplanted into and cultured within another follicle whose native oocyte was removed. Somatic cells within the chimeric follicle re-establish connections with the oocyte and support oocyte growth and maturation in a three-dimensional (3D) culture system. We show that young oocytes transplanted into aged follicles exhibited reduced meiotic maturation and developmental potential, whereas the young follicular environment significantly improved the rates of maturation, blastocyst formation and live birth of aged oocytes. Aged oocytes cultured within young follicles exhibited enhanced interaction with somatic cells, more youth-like transcriptome, remodelled metabolome, improved mitochondrial function, and enhanced fidelity of meiotic chromosome segregation. These findings provide the basis for a future follicular somatic cell-based therapy to treat age-associated female infertility.

Project description:Vitrification is a method for long-term biological sample cryopreservation without causing intra- and extra-cellular ice formation. We recently established a novel closed vitrification system to cryopreserve mouse ovarian follicles. Using the 3D alginate hydrogel encapsulated in vitro follicle growth (eIVFG) method, we have demonstrated that compared to freshly-harvested follicles, vitrified follicles have normal follicle and oocyte reproductive outcomes. Our recent study further demonstrated the faithful preservation of molecular signatures of follicle-stimulating hormone (FSH)-stimulated follicle maturation in vitrified follicles. However, it is unknown whether ovulation, another crucial gonadotropin-dependent follicular event, and involved ovulatory gene regulatory pathways are well conserved in vitrified follicles. Fresh and vitrified follicles grown for 8 days by eIVFG were collected at 0, 1, 4 and 8-hour post human chorionic gonadotropin (hCG) treatment for the single-follicle RNA sequencing. Principal component analysis (PCA) and Pearson’s correlation analysis revealed that vitrified follicles have similar transcriptomic profiles to fresh follicles. Furthermore, the expression of several genes essential for ovulation were comparable between vitrified and fresh follicles. In summary, these results demonstrate that our closed vitrification system preserves follicular transcriptomic dynamics during ex vivo ovulation. Together with our previous findings that vitrification preserves FSH-stimulated follicle maturation, the integration of vitrification of immature follicles and eIVFG has a great potential to serve as an additional fertilization preservation approach for young cancer patients and endangerers species. Moreover, follicle vitrification enables a high-content ovarian follicle biobank, which can greatly improve the throughput of eIVFG for studying ovulation biology, anovulatory disease, toxicology, and novel contraceptive drug development targeting ovulation.

Project description:The ovarian cortical reserve of follicles is vital for fertility. Some medical treatments are toxic to follicles, leading to premature ovarian insufficiency. Ovarian tissue cryopreservation is an established method to preserve fertility in adults and even applied in prepuberty despite unproven efficacy. Here, we analyze transcriptomes of 120 cortical follicles from children and adults for detailed comparison. We discover heterogeneity with two main types of follicles in both age groups: one with expected oocyte-granulosa profiles and another with predicted role in signaling. Transcriptional changes during growth to the secondary stage are similar overall in children and adults, but variations related to extracellular matrix, theca cells, and miRNA profiles are found. Notably, cyclophosphamide dose correlates with interferon signaling in child follicles. Additionally, morphology alone is insufficient for follicle categorization suggesting a need for additional markers. Marker genes for early follicle activation are determined. These findings will help refine follicular classification and fertility preservation techniques across critical ages.

Project description:The ovarian cortical reserve of follicles is vital for fertility. Some medical treatments are toxic to follicles, leading to premature ovarian insufficiency. Ovarian tissue cryopreservation is an established method to preserve fertility in adults and even applied in prepuberty despite unproven efficacy. Here, we analyze transcriptomes of 120 cortical follicles from children and adults for detailed comparison. We discover heterogeneity with two main types of follicles in both age groups: one with expected oocyte-granulosa profiles and another with predicted role in signaling. Transcriptional changes during growth to the secondary stage are similar overall in children and adults, but variations related to extracellular matrix, theca cells, and miRNA profiles are found. Notably, cyclophosphamide dose correlates with interferon signaling in child follicles. Additionally, morphology alone is insufficient for follicle categorization suggesting a need for additional markers. Marker genes for early follicle activation are determined. These findings will help refine follicular classification and fertility preservation techniques across critical ages.

Project description:The ovarian cortical reserve of follicles is vital for fertility. Some medical treatments are toxic to follicles, leading to premature ovarian insufficiency. Ovarian tissue cryopreservation is an established method to preserve fertility in adults and even applied in prepuberty despite unproven efficacy. Here, we analyze transcriptomes of 120 cortical follicles from children and adults for detailed comparison. We discover heterogeneity with two main types of follicles in both age groups: one with expected oocyte-granulosa profiles and another with predicted role in signaling. Transcriptional changes during growth to the secondary stage are similar overall in children and adults, but variations related to extracellular matrix, theca cells, and miRNA profiles are found. Notably, cyclophosphamide dose correlates with interferon signaling in child follicles. Additionally, morphology alone is insufficient for follicle categorization suggesting a need for additional markers. Marker genes for early follicle activation are determined. These findings will help refine follicular classification and fertility preservation techniques across critical ages.

Project description:Oocyte competence is progressively acquired during follicle growth, with large follicles containing more often competent oocytes than small follicles. A competent oocyte is able to mature in vitro, be fertilized, and develop to the blastocyst stage. Extracellular vesicles (EVs) and their cargo micro RNAs (miRNAs) are critical in mediating intercellular communication inside the follicle and facilitating oocyte maturation. Whether follicular EVs are also involved in the acquisition of oocyte competence in the growing follicle remains unclear. Here, we have been using an individual culture system to distinguish follicular fluid and their corresponding bovine oocytes as competent or noncompetent. We used a qEV single-column method to isolate EVs from follicular fluid. RNA sequencing revealed 16 differentially expressed (DE) miRNAs in EVs from follicular fluid derived from either competent or noncompetent oocytes . Among the up-regulated miRNAs, we selected bta-miR-34c to further validate its effect on oocyte competence during in vitro maturation using mimics and inhibitors. By supplementing miR-34c mimics to the oocyte maturation medium, we could significantly improve blastocyst quality, as evidenced by higher cell numbers, while supplementation of miR-34c inhibitors produced the opposite effect. Taken together, the up-regulation of miR-34c in EVs derived from follicular fluid from competent oocytes is indicative of its regulatory role, and, when added during in vitro maturation of unselected oocytes, is able to increase total cell number and inner cell mass of resulting embryos, thus contributing to the development of healthy offspring

Project description:The aim of this study was to assess the impact of oocyte competence on subsequent fertility. Based on knowledge already accessible in mammals and on bioinformatics tools including the chicken genome sequence, we focused on the expression of genes involved in the processes of fertilization and of early embryo development. A differential kinetic study is performed on INRA lines selected on the basis of their fertility potential in purpose of hopefully access gene markers of fertility performance. We use 4 different hen lines:; - one line of laying hens with 3 different samples: the just ovulated oocyte, the oocyte collected 24 hours before ovulation (F1 stage), and granulosa cells collected at the F1 stage. We could compare different tissue and developmental stages. - one line of hen with rapid growth speed; - two lines of laying hens; For the 3 last lines we used animals with different fertility levels. We collected the oocyte of the largest follicle before ovulation (F1). The aim of the study is to identify genes involved in fertility or early embryo mortality. Experiment Overall Design: 6 arrays - Gallus gallus

Project description:Background: Melatonin (MLT) supplementation has been shown to improve the quality of oocytes and embryos in vitro through its antioxidant mechanism. However, it is unclear whether endogenous MLT plays a role in oocyte quality control, casting doubt on the rationality of oral MLT in improving oocyte quality or fecundity. Methods:we measured the effects of PMSG on MLT synthesis in follicles, evaluated the effects of MLT on oocyte growth and quality in mice and goat, used RNA-seq to explore the mechanism underlying MLT’s effects on oocyte growth and quality, and generated SNAT-knockout mice to assess the effects of endogenous MLT on oocyte growth and quality. Lastly, we investigated the feasibility of short-term MLT intake to improve the fertility of older mice. Result: we revealed that the follicle-stimulating hormone induces the expression of intra-ovarian SNAT, resulting in increased levels of intra-ovarian MLT in mice. Administering MLT during the gonadotropin-dependent phase improved the oocyte size and quality in both mice and goat by enhancing nutrient accumulation and mitochondrial function. Deficiency of MLT in mice reduced oocyte size and weakened mitochondrial function. Furthermore, our findings demonstrate that short-term MLT intake during the gonadotropin phase improves the litter size of older mice. Conclusion: This study reveals that endogenous MLT is involved in determining oocyte quality as a target molecule of follicle-stimulating hormone, shedding light on its potential utilization in improving oocyte quality or rejuvenating aged mammalian oocytes.