Project description:The gut microbiota plays a vital role in maintaining the physiological function of host health and the pathogenesis of various diseases. However, its relationship with maternal age-associated decline in oocyte quality remains elusive. Here, we report that establishment of gut microbiota from young donors in aged mice by fecal microbiota transplantation (FMT) is an effective method to rejuvenate the quality of maternally aged oocytes. Specifically, young gut microbiota promoted the ovulation and maturation of aged oocytes, and inhibited occurrence of cytoplasm fragmentation and spindle/chromosome abnormalities, hence enhancing the oocyte quality and female fertility. By integrating metagenome and untargeted metabolome of intestinal digesta, as well as targeted metabolome of ovaries and micro-transcriptome of oocytes, we identified that Bacteroides_caecimuris-modulated glutamic acid levels mediated the restorative effects of young gut microbiota on the aged oocytes through strengthening the mitochondria function. In addition, we demonstrated that in vivo supplementation of glutamic acid also enhanced the quality of aged oocytes, and the improvement of oocyte quality by glutamic acid was conserved across species. Altogether, our findings highlight the importance of gut microbiota in the oocyte aging and provide potential improvement strategies for age-related decline in oocyte quality and female fertility.

Project description:The gut microbiota plays a vital role in maintaining the physiological function of host health and the pathogenesis of various diseases. However, its relationship with maternal age-associated decline in oocyte quality remains elusive. Here, we report that establishment of gut microbiota from young donors in aged mice by fecal microbiota transplantation (FMT) is an effective method to rejuvenate the quality of maternally aged oocytes. Specifically, young gut microbiota promoted the ovulation and maturation of aged oocytes, and inhibited occurrence of cytoplasm fragmentation and spindle/chromosome abnormalities, hence enhancing the oocyte quality and female fertility. By integrating metagenome and untargeted metabolome of intestinal digesta, as well as targeted metabolome of ovaries and micro-transcriptome of oocytes, we identified that Bacteroides_caecimuris-modulated glutamic acid levels mediated the restorative effects of young gut microbiota on the aged oocytes through strengthening the mitochondria function. In addition, we demonstrated that in vivo supplementation of glutamic acid also enhanced the quality of aged oocytes, and the improvement of oocyte quality by glutamic acid was conserved across species. Altogether, our findings highlight the importance of gut microbiota in the oocyte aging and provide potential improvement strategies for age-related decline in oocyte quality and female fertility.

Project description:The gut microbiota plays a vital role in maintaining the physiological function of host health and the pathogenesis of various diseases. However, its relationship with maternal age-associated decline in oocyte quality remains elusive. Here, we report that establishment of gut microbiota from young donors in aged mice by fecal microbiota transplantation (FMT) is an effective method to rejuvenate the quality of maternally aged oocytes. Specifically, young gut microbiota promoted the ovulation and maturation of aged oocytes, and inhibited occurrence of cytoplasm fragmentation and spindle/chromosome abnormalities, hence enhancing the oocyte quality and female fertility. By integrating metagenome and untargeted metabolome of intestinal digesta, as well as targeted metabolome of ovaries and micro-transcriptome of oocytes, we identified that Bacteroides_caecimuris-modulated glutamic acid levels mediated the restorative effects of young gut microbiota on the aged oocytes through strengthening the mitochondria function. In addition, we demonstrated that in vivo supplementation of glutamic acid also enhanced the quality of aged oocytes, and the improvement of oocyte quality by glutamic acid was conserved across species. Altogether, our findings highlight the importance of gut microbiota in the oocyte aging and provide potential improvement strategies for age-related decline in oocyte quality and female fertility.

Project description:The decline in oocyte quality is a limiting factor of female fertility; however, strategies to maintain the oocyte quality of aged women are not available. In this study, we showed that growth hormone (GH) supplementation in vivo not only alleviated the decline in oocyte number caused by aging, but also improved the quality and developmental potential of aged oocytes. Strikingly, GH supplementation reduced aneuploidy in aged oocytes. Proteomic analysis indicated that the ERK1/2 pathway was involved in the reduction in aneuploidy rate of aged oocytes, as confirmed both in vivo and in vitro. In addition, JAK2 might be involved in the regulation of ERK1/2 by GH in aged oocytes. Collectively, our findings revealed that GH supplementation protects oocytes from aging-related aneuploidy and enhances the quality of aged oocytes, and could be used to improve the outcome of assisted reproduction in aged women.

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:Decreased oocyte quality is a major determinant of age-associated fertility decline which lacks an effective treatment strategy. The secretome of mesenchymal stem cells (MSC-sec) contains various bioactive factors and has the potential to improve oocyte quality. In this study, MSC-sec treatment significantly increased first polar body emission, improved spindle assembly, reduced aneuploidy rate, and promoted maternal mRNA degradation in aged mouse oocytes, whereas the addition of BDNF antibody blocked the effects of MSC-sec. Furthermore, BDNF treatment alone also improved the oocyte quality from aged mice. Mechanistically, both MSC-sec and BDNF activated the ERK1/2 signaling pathway to increase the expression of DAZL and BTG4 in aged oocytes. Furthermore, injection of MSC-sec or BDNF into aged mouse ovaries significantly improved oocyte quality and early embryonic development. Finally, we demonstrated that BDNF treatment increased both the fertilization rate and blastocyst formation of aged human oocytes. Our study identified BDNF as the functional component of MSC-sec to improve the quality and development potential of aged oocytes by activating the ERK1/2 signaling pathway, suggesting that BDNF has the potential to mitigate age-related decline in oocyte quality.

Project description:Advanced maternal age is a key factor in female infertility, primarily due to declines in ovarian reserve and oocyte quality. However, the metabolic mechanisms underlying reproductive aging remain unclear. Here, we show that uridine levels in the plasma and ovaries of aged mice are significantly reduced compared with young controls. Building on this, we find that uridine supplementation significantly improves meiotic maturation, fertilization, and early embryonic development of aged oocytes, both in vivo and in vitro. Further microtranscriptomic analyses reveal that uridine enhances oocyte quality by inhibiting ferroptosis and enhancing mitochondrial function. Moreover, integrating Limited Proteolysis-Small Molecule Mapping, western blot and siRNA-based functional assays, we identify that uridine binds Poly(rC)-binding protein 1, thereby suppressing ferroptosis and preserving mitochondrial function. Collectively, these findings demonstrate that uridine supplementation improves fertility in aged female mice and provide mechanistic insight into ferroptosis in oocyte aging.

Project description:<p>Advanced maternal age is a key factor in female infertility, primarily due to declines in ovarian reserve and oocyte quality. However, the metabolic mechanisms underlying reproductive aging are still poorly understood. Here, we show that uridine levels in the plasma and ovaries of aged mice are significantly reduced compared with young controls. Building on this, we find that uridine supplementation significantly improves meiotic maturation, fertilization, and early embryonic development of aged oocytes, both in vivo and in vitro. Further microtranscriptomic analyses reveal that uridine enhances oocyte quality by inhibiting ferroptosis, enhancing mitochondrial function and removing excessive reactive oxygen species (ROS). Moreover, integrating Limited Proteolysis-Small Molecule Mapping (LiP-SMap), surface plasmon resonance (SPR) analyses and siRNA-based functional assays, we identify that uridine binds Poly(rC)-binding protein 1 (PCBP1), thereby suppressing ferroptosis and preserving mitochondrial function. In conclusion, this study demonstrates that uridine supplementation can effectively improve fertility of aged female mice. Our research also provides important insights into the role of ferroptosis in oocyte aging, thereby advancing our understanding of reproductive aging mechanisms.</p>

Project description:Female reproductive aging is characterized by the decline in oocytes quality and developmental potentials, but the underlying mechanisms remain insufficiently investigated. In this study, we analyze the transcriptomes of individual oocytes from young and aged mice, identifying a distinct group of aged oocytes, which display morphological abnormalities, such as fragmentation and darkened cytoplasm. These defective aged oocytes show a global shrink in gene expression, with yet a notable expression increase in mitochondrial RNA. Further gene expression analysis indicates that these defective oocytes exhibit typical features of programmed cell death (PCD), and functional assays demonstrate that those oocytes are specifically subject to both apoptosis and ferroptosis. Blocking the PCD pathways largely reverses the defective morphology. Interestingly, the expression of tissue-type plasminogen activator (tPA, or Plat) decreases with age, and even becomes undetectable in defective oocytes. Loss of Plat expression in oocytes downregulates Erk1/2 pathway activity, closely resembling the effects observed in Erk1/2 deficiency. Combining with tPA-interactome assay, it is suggested that Plat functions as an upstream regulator of Erk1/2 pathway activity, likely through Erk1/2 phosphorylation. Supplementing exogenous tPA in oocyte cultures reduces defect rate and therefore improves oocyte quality. Collectively, our findings highlight Plat as a pivotal factor in protecting aged mouse oocytes from PCD, with potential implications for developing better clinical strategies to enhance oocyte quality in aging females.

Project description:Chromosome aneuploidy increases in oocytes with maternal age, and is considered the leading cause for the increased incidence of infertility, miscarriage, and birth defects. Using mRNA-Sequencing of oocytes from 12 month old mouse versus 3 month young mouse, we identified a spindle assembly checkpoint gene, BubR1, whose expression was significantly decreased. We employed a mRNA microinjection based approach to increase BubR1 expression in aging oocytes. We find that increased expression of BubR1 protects against aneuploidy and chromosome misalignment in aging oocytes. After in vitro fertilization, the embryos derived from BubR1 increased expression aging oocytes exhibited chromosome stability as robust as those of the young ones. Furthermore, following embryo transfer, these embryos showed greatly improved developmental competency, with comparable levels of full-term development to those of the young ones. These results indicate that the decline in oocyte quality may be reversible and could lead to treatments that prolong female fertility. Examination of the effect of maternal aging on the mRNA expression in the mature oocytes of the female mice. Naturally ovulated mature oocytes (MII stage) were collected from 6 young (3 month) and 6 aging (12 month) female mice (3 oocytes per mice, 18 oocytes for each group).