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:Advanced age is a primary risk factor for female infertility due to reduced ovarian reserve and declining oocyte quality. However, as an important contributing factor, the role of metabolic regulation during reproductive aging is poorly understood. Here, we applied untargeted metabolomics to identify spermidine as a critical metabolite in ovaries to protect oocytes against aging. In particular, we found that spermidine level was reduced in aged ovaries and supplementation of spermidine promoted follicle development, oocyte maturation, early embryonic development and female fertility of aged mice. By micro-transcriptomic analysis, we further discovered that recovery of oocyte quality by spermidine was mediated by enhancement of mitophagy activity and mitochondrial function in aged mice, and this action mechanism was conserved in porcine oocytes under oxidative stress. Altogether, our findings demonstrate that spermidine supplementation is a potentially effective strategy to ameliorate oocyte quality and reproductive outcome of women at an advanced age.

Project description:Ovarian aging has reproductive and overall health implications with increased infertility, miscarriage rates, and adverse outcomes associated with menopause. Mitochondrial dysfunction is one of the main mechanisms of female reproductive aging. Mitochondrial protein homeostasis maintains mitochondrial function and globally dysregulated unfolded mitochondrial protein response accelerates reproductive aging. However, the role of oocyte mitochondrial proteostasis in determining oocyte quality is unknown. ClpX (Caseinolytic Protease X) is a mitochondrial protein unfoldase that maintains mitochondrial protein homeostasis. In this study, we uncovered that Clpx deficiency, either through genetic ablation or natural decline with aging in mice, leads to the disrupted mitochondrial proteostasis in oocytes. Oocyte-specific knockout of Clpx impaired oocyte quality and developmental competence, thereby leading to female subfertility. Transcriptomic and micro-proteomic analyses of Clpx null oocytes revealed dysregulated mitochondrial function, protein processing and meiosis. Notably, Clpx deficiency promoted PGD2 synthesis and DP1/PKA/cAMP and DP2/AKT/mTOR signaling pathways by upregulating Ptgds. The PGD2 synthesis inhibitor AT-56 restored the developmental competence of Clpx knockout and aged oocytes. Our findings indicate the pivotal role of oocyte mitochondrial proteostasis in the regulation of oocyte quality with aging and pave the way for future investigations assessing the potential therapeutic value of these pathways to improve infertility treatment outcomes.

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:Advanced maternal age, defined as 35 years or older, is associated with a decline in both ovarian reserve and oocyte quality, which leads to the female infertility, pregnancy loss, fetal anomalies, stillbirth, and obstetric complications. At present, the effective approaches to counteract the maternal age-related decay of oocyte quality are still not fully determined. Here, we report that in vivo supplementation of nicotinamide mononucleotide (NMN) efficaciously ameliorates the quality of oocytes from naturally aged mice by recovering nicotinamide adenine dinucleotide (NAD + ) levels in oocytes. NMN supplementation increases the number of antral follicles, ovulated oocytes and matured oocytes from aged mice. Specifically, NMN supplementation maintains the normal spindle/chromosome structure and dynamics of cortical granule component ovastacin to ensure the meiotic competency and fertilization ability of aged oocytes. Moreover, single cell transcriptome analysis shows that the beneficial effect of NMN on the aged oocytes is mediated by the restoration of the mitochondrial function, thereby reducing the accumulated ROS to suppress the occurrence of apoptosis. To sum up, our data reveal that supplementation of NMN is a feasible approach to prevent oocyte quality from advanced maternal age-related deterioration, contributing to improve the reproductive outcome of aged women and the assisted reproductive technology.

Project description:Reproductive aging is one of the earliest human aging phenotypes, and mitochondrial dysfunction has been linked to a decline in oocyte quality. However, it is not known which mitochondrial metabolic processes are critical for oocyte quality maintenance with age. To understand how mitochondrial processes contribute to C. elegans oocyte quality, we characterized the mitochondrial proteomes of young and aged wild-type and long-reproductive daf-2 mutants. The mitochondrial proteomic profiles of young wild-type and daf-2 worms are similar and share upregulation of branched-chain amino acid (BCAA) metabolism pathway enzymes. Reduction of bcat-1 shortens reproduction, elevates mitochondrial ROS levels, and shifts mitochondrial localization. Moreover, bcat-1 knockdown decreases daf-2’s oocyte quality and reduces reproductive capability, indicating the importance of this pathway in the maintenance of oocyte quality with age. Importantly, we can delay oocyte quality deterioration and extend reproduction in wild-type animals both by bcat-1 overexpression and by supplementing with Vitamin B1, a cofactor needed for BCAA metabolism.

Project description:Ovarian aging has reproductive and overall health implications with increased infertility, miscarriage rates, and adverse outcomes associated with menopause. Mitochondrial dysfunction is one of the main mechanisms of female reproductive aging. Mitochondrial protein homeostasis maintains mitochondrial function and globally dysregulated unfolded mitochondrial protein response accelerates reproductive aging. However, the role of oocyte mitochondrial proteostasis in determining oocyte quality is unknown. ClpX (Caseinolytic Protease X) is a mitochondrial protein unfoldase that maintains mitochondrial protein homeostasis. In this study, we uncovered that Clpx deficiency, either through genetic ablation or natural decline with aging in mice, leads to the disrupted mitochondrial proteostasis in oocytes. Oocyte-specific knockout of Clpx impaired oocyte quality and developmental competence, thereby leading to female subfertility. Transcriptomic and micro-proteomic analyses of Clpx null oocytes revealed dysregulated mitochondrial function, protein processing and meiosis. Notably, Clpx deficiency promoted PGD2 synthesis and DP1/PKA/cAMP and DP2/AKT/mTOR signaling pathways by upregulating Ptgds. The PGD2 synthesis inhibitor AT-56 restored the developmental competence of Clpx knockout and aged oocytes. Our findings indicate the pivotal role of oocyte mitochondrial proteostasis in the regulation of oocyte quality with aging and pave the way for future investigations assessing the potential therapeutic value of these pathways to improve infertility treatment outcomes.

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:We investigated the contentious role of mitochondrial reactive oxygen species (ROS) on mitochondrial DNA (mtDNA) quality and quantity in female reproductive aging. By conditionally knocking out the Sod2 gene in female mouse germline, we observed increased mitochondrial ROS and decreased oocyte quality, primarily due to impacts on OXPHOS complex II and mtDNA encoded mRNA levels. Interestingly, we found no increased mtDNA mutations, but alterations in mtDNA quantity, indicating the susceptibility of mtDNA to the mitochondrial ROS during reproductive aging. Notably, when we further decreased the basal level of mtDNA quantity by deactivating the mtSSB protein in Sod2 conditional knockout females, we observed an exacerbation of reproductive aging effects. This highlights the crucial role of mtDNA quantity in mitigating the impact of oxidative stress on 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.