Peroxiredoxin 4 secreted by cumulus cells ameliorates the maturation of oocytes in vitro.

BACKGROUND: Peroxiredoxin 4 (Prdx4) in the endoplasmic reticulum (ER) is the only secretory member of the antioxidant Prdx family. Our previous studies demonstrated that Prdx4 in cumulus cells (CCs) ameliorated the maturation of oocytes in vitro and enhanced oocyte developmental competence by preventing CCs apoptosis caused by oxidative stress (OS) through gap junctions. In this study, we aimed to determine whether Prdx4 released by CCs can repair meiotic defects in mouse oocytes by co-culturing immature (germinal vesicle) oocytes with CCs from mature oocytes in the absence of gap junctions. RESULTS: The OS-induced meiotic defects in mouse oocytes were impeded by co-culture with CCs, as evidenced by the increased first polar body (PB1) extrusion rate and decreased ROS level. CCs increased Prdx4 expression and lowered IRE1α, Bip expression in H2O2-treated oocytes. After knockdown of Prdx4 expression in CCs, the rate of PB1 extrusion in the oocytes was significantly reduced to the level detected in H2O2 group, and ER stress was not alleviated. CO-IP and immunofluorescence co-localization experiments demonstrated that Prdx4 interacted with PDIA6 in the oocytes and the Pearson's R value was 0.69 calculated using ImageJ. CONCLUSIONS: Cumulus cells can promote the maturation of oocytes in vitro by secreting Prdx4 in a paracrine manner and serve as a promising therapeutic antioxidant for improving the quality of oocytes, especially aging oocytes, in clinical in vitro maturation (IVM).

Nucleoporin37 may play a role in early embryo development in human and mice.

Maternal-effect genes (MEGs) play an important role in maintaining the survival and development of mammalian embryos at the cleavage stage after fertilization. Despite long-term efforts, the MEGs that regulate preimplantation embryo development remain largely unknown. Here, using whole-exome sequencing and homozygosity mapping, we identified a potential candidate gene associated with early embryo development: nucleoporin37 (NUP37), a nucleoporin gene that encodes a member of the nuclear pore complexes and regulates nuclear pore permeability and nucleocytoplasmic transport. Moreover, we determined the temporal and spatial expression patterns of Nup37 in mouse oocytes and early embryos, and explored the role of NUP37 in oocyte maturation and preimplantation embryo development. Immunoprecipitation assays confirmed that yes-associated protein-1 (YAP1) binds to TEA domain transcription factor 4 (TEAD4) and NUP37. Furthermore, Nup37 gene knockdown reduced the nuclear import of YAP1 and down-regulated the expression of YAP1-TEAD pathway downstream genes Rrm2 and Rpl13 in early embryos. Our study provides evidence that maternal NUP37 contributes to the nuclear import of YAP1 and then activates the YAP1-TEAD pathway, a signalling pathway essential for zygotic genome activation. Nup37 may be a key gene involved in preimplantation embryo development in mammals.

Culture and Identification of Bone Marrow Mesenchymal Stem Cells from Enhanced Green Fluorescent Protein-transgenic Rats.

OBJECTIVE: To isolate, culture, and identify bone marrow mesenchymal stem cells (BMSCs) from enhanced green fluorescent protein (EGFP)-transgenic rats in vitro. METHODS: Bone marrows were isolated from tibia and femur of healthy EGFP-transgenic rats of specific pathogen free (SPF) grade. Then,the whole bone marrow adherent method was used for isolation,culture,and purification of BMSCs. The morphological change was noted by continuous observation under inverted fluorescence microscope. The growth curve of cells was drawn through the method of CCK-8 and the proliferation compared with wild type BMSCs. The surface markers of BMSCs were detected by flow cytometry. The BMSCs were induced to differentiate into osteoblasts, adipocytes, and chondrocytes lineages. The EGFP-BMSCs were transplanted into the rats intravenously, and the expression of GFP was detected. RESULTS: BMSCs stably expressing EGFP gene were obtained successfully, with the fusiform-shaped appearance and the forming of circinate cell colonies. The growth curve of EGFP-MSCs showed the characteristic of active proliferation, showing no significant difference compared with the wild-type BMSCs. The expression rates of the surface markers of BMSCs CD29, CD90, CD34, CD49d, and CD45 were 99.4%, 96.4%, 0.171%, 0.049%, and 0.038%. The GFP were detected in lung 3 days after transplantation. After osteogenic, adipogenic, and chondrogenic induction, oil red-O and alizarin red positive signals and toluidine blue positive cells were detected. CONCLUSIONS: High-purity BMSCs stably expressing green fluorescent protein gene can be cultured using the whole bone marrow adherent method. EGFP does not affect the stem cell properties and expresses stably after transplantation. The cells can be used as seed cells for subsequent research.

Peroxiredoxin 4 deficiency induces accelerated ovarian aging through destroyed proteostasis in granulosa cells.

Ovarian aging, a complex and challenging concern within the realm of reproductive medicine, is associated with reduced fertility, menopausal symptoms and long-term health risks. Our previous investigation revealed a correlation between Peroxiredoxin 4 (PRDX4) and human ovarian aging. The purpose of this research was to substantiate the protective role of PRDX4 against ovarian aging and elucidate the underlying molecular mechanism in mice. In this study, a Prdx4-/- mouse model was established and it was observed that the deficiency of PRDX4 led to only an accelerated decline of ovarian function in comparison to wild-type (WT) mice. The impaired ovarian function observed in this study can be attributed to an imbalance in protein homeostasis, an exacerbation of endoplasmic reticulum stress (ER stress), and ultimately an increase in apoptosis of granulosa cells. Furthermore, our research reveals a noteworthy decline in the expression of Follicle-stimulating hormone receptor (FSHR) in aging Prdx4-/- mice, especially the functional trimer, due to impaired disulfide bond formation. Contrarily, the overexpression of PRDX4 facilitated the maintenance of protein homeostasis, mitigated ER stress, and consequently elevated E2 levels in a simulated KGN cell aging model. Additionally, the overexpression of PRDX4 restored the expression of the correct spatial conformation of FSHR, the functional trimer. In summary, our research reveals the significant contribution of PRDX4 in delaying ovarian aging, presenting a novel and promising therapeutic target for ovarian aging from the perspective of endoplasmic reticulum protein homeostasis.