Kaempferol ameliorates in-vitro and in-vivo postovulatory oocyte ageing in mice.

RESEARCH QUESTION: Does kaempferol alleviate postovulatory oocyte ageing, thereby maintaining their early embryonic development capacity? DESIGN: The effects of kaempferol on postovulatory ageing were investigated in vitro and in vivo by short-term kaempferol administration (mature oocytes were cultured in a kaempferol-containing medium for 12 h; mice were intragastrically administered with the appropriate amount of kaempferol for 21 days). Spindle morphology and chromosome alignment, levels of oxidative stress and the gap junction were assessed by immunofluorescence. Fertilization ability and early embryonic development ability of each oocyte group was detected by IVF. Fertilization of the ageing oocyte model was used to explore whether kaempferol could improve adverse pregnancy outcome. RNA-sequencing and quantitative polymerase chain reaction were used to identify the cellular pathways through which kaempferol relieves postovulatory oocyte ageing in vivo. RESULTS: Kaempferol administration altered various processes in the ageing oocytes, including oxidative stress, the peroxisome, TNF signalling, cAMP signalling and the gap junction pathway. Expression of several important genes, such as Sirt1, Mapk1, Ampk and Foxo3, was regulated. Moreover, kaempferol ameliorated adverse pregnancy outcomes of fertilized ageing oocytes. IVF results indicate that kaempferol could partially counteract the effects of oocyte ageing on fertilization capacity (pronucleus: kaempferol, 69.08 ± 2.37% versus aged, 38.95 ± 3.58%) and early embryonic development (blastocyst: kaempferol, 50.02 ± 3.34% versus aged, 30.83 ± 5.46%). CONCLUSIONS: Our results indicate that kaempferol may be a potent natural antioxidant, have implications for animal husbandry and may help improve the success rate of IVF and ICSI. Further clinical trials are needed.

Fbf1 regulates mouse oocyte meiosis by influencing Plk1.

Fas binding factor 1 (Fbf1) is one of the distal appendage proteins in the centriole, located at its distal and proximal ends. It influences the duplication and separation of centrosomes, thereby affecting the progression of the cell cycle during mitosis. However, the function of Fbf1 in meiosis has remained unclear. To explore the role of Fbf1 in the in vitro maturation of mouse oocyte, immunofluorescence staining was used to examine the Fbf1 location in the oocyte and their phenotype after protein deletion. Western blot was used to examine the protein abundance. This study showed that mouse oocytes express Fbf1 which locates at the spindle poles and around the microtubules. Through taxol and nocodazole treatment, and microinjection of siRNA, it was demonstrated that Fbf1 had an important role in the spindle assembly and chromosome separation during mouse oocyte meiosis In particular, microinjection of Fbf1-siRNA resulted in severe abnormalities in the spindle and chromosome arrangement, decreased aggregation of microtubules, disrupted the first oocyte meiosis, and the extrusion of the first polar body. Furthermore, in the Fbf1-siRNA group, there was reduced expression of Plk1 and its agglutination at the spindle poles, along with retarded chromosome segregation due to the activation of the spindle assembly checkpoint (SAC) component BubR1. These results indicate that Fbf1 may function in microtubule depolymerization and agglutination, control the microtubule dynamics, spindle assembly and chromosome arrangement and, thus, influence the mouse oocyte meiotic maturation.