It is well established that mammalian cumulus cell (CC) expansion requires BMP15 (bone morphogenetic protein bone morphogenetic protein 15) and GDF9 (growth differentiation factor 9). However, the mechanisms of the factors in CC expansion are largely unclear. This study was conducted to examine the two paracrine factors and their receptor SMAD intracellular signaling mechanism of mediating porcine CC expansion and oocyte maturation, and to compare COCs (Cumulus–oocyte complexes) maturation to DOs (Denuded oocytes). COCs and DOs were in vitro matured in medium with FSH, LH and TGFB superfamily antagonists. Our results showed that the expansion of COCs was unaffected by addition of GDF9 and BMP15 recombinant protein, but cumulus cell proliferation and DOs maturation rate were enhanced. The mRNA expressions of SMAD receptor confirmed that oocytes secreted factors that activate SMAD3,4 and SMAD1 in granulosa cells and oocytes, but unaffected SMAD2. Treatment of COCs with a SMAD2/3 phosphorylation inhibitor (SB431542) inhibited CC expansion and expression of TNFAIP6. SB431542 also was revealed to inhibit DOs maturation. The activation of CC SMAD signaling by oocytes, and the requirement of SMAD2/3 signaling for expansion and oocyte maturation were studied in pig. Nonetheless, porcine oocyte maturation without SMAD2/3 signaling is likely to be needed for optimal matrix formation, but also BMP15 and GDF9 is likely to be needed in oocyte.

It is well established that mitochondrial genome is strictly maternally inherited in mammalian, despite the fact that paternal mitochondria enter into oocyte during fertilization. To date, although some mechanisms have been extrapolated to interpret the elimination of paternal mitochondria, the exact mechanism still is unclear. Recent studies suggest that autophagy process and the ubiquitin-mediated degradation pathway may be involved in elimination of paternal mitochondria. However, the dynamic profiles of autophagy and ubiquitination associated with paternal mitochondria degradation have not been determined in mouse model. Through immunostaining with specific antibody LC3 and Ubiquitin and confocal microscopy, we investigated the dynamic profiles of LC3 and Ubiquitin signals in mouse embryos during preimplantation development. In addition, embryos were stained with MitoTracker Red for tracking the degradation process of paternal mitochondria. Our results showed that paternal mitochondria gradually degraded during postfertilization development, and sporadic paternal mitochondria were found at least in 16 cell embryos. LC3 and Ubiquitin signals appeared in the midpiece of sperm at 3 h postfertilization, and they were strictly colocalizated with paternal mitochondria from zygote to 2 cell embryo. Nevertheless, the colocalization became loose at 4 cell embryos, and gradually disappeared beyond 4 cell embryos. Our results confirmed that autophagy process and the ubiquitin-mediated degradation pathway may take part in the postfertilization remove of paternal mitochondria.

Superovulation, or ovarian stimulation is a commonly used ART for treatment of human infertility/subfertility. Recent studies suggest that superovulation unaffects methylated imprints acquisition in mouse oocytes during oogenesis, whereas disrupts DNA methylation maintenance in embryos during preimplantation development. However, the mechanisms of defects in methylation maintanence caused by superovulation remain largely unclear. We hypothesized that superovulation may disrupt the expression of DNA methyltransferases (Dnmts), the enzymes which catalyze DNA methylation acquisition and maintenance. The mice were subjected to superovulate with low (6 IU) and high (10 IU) dosage hormone. We examined the global DNA methylation levels in zygotes and DNA methylation of repeated sequences (IAP and Line 1) in blastocyst stage embryos. In addition, we investigated the expression of Dnmts (Dnmt3a, Dnmt3b, Dnmt3l and Dnmt1o) in ovulated oocytes and zygotes. Through staining with antibody 5mC and Di-H3K9 coupled with confocal microscopy, we found that global methylation profiles in zygotes derived from females after low or high dosage hormone treatment were not affected when compared to control counterpart. Moreover, methylation at IAP in blastocysts also was unaffected by superovulation, irrespective of hormone dosage. In contrast, methylation level at Line 1 decreased when the females were administered by high dosage hormone. Furthermore, expression of de novo DNA methyltransferase Dnmt3a, Dnmt3b, Dnmt3L, as well as maintenance Dnmt1o in MII oocytes and zygotes was not disrupted by superovulation. Given superovulation adversely affected methylation maintenance in blastocysts during preimplantation development but with normal expression of Dnmts in oocytes and zygotes, it is indicated that defects of embryonic methylation didn’t originate from abnormal expression of Dnmts.

Although evidences showed that histone deacetylation plays an important role in the mitotic and meiotic cell cycle, but the mechanisms are still unclear. Level of histone acetylation can be easily changed by deacetylase inhibitors (HDACi) i.e trichostatin A (TSA) and valporic acid. In this study, we determined whether the inhibition of histone deacetylation by TSA could affect porcine oocyte maturation and aging process. Our results showed that treated COCs with 100 nM TSA significantly increase the GVBD in each time group than 0, 5, 50 nM but no significantly different from that of higher concentration (200 nm or 300 nM). No significant differences on maturation, blastocyst development, MAPK pattern and expressions of apoptosis gene when treated oocytes with 100 nM TSA for the first 24h of IVM compared with control and 5, 50 nM TSA. However, in the oocytes treated with 200 nM and 300 nM TSA for first 24 h, MAPK significantly decreased and abnormal spindle were observed. But, in prolonged (64 h) of TSA treated group has no significantly different in control. Another data observed that after 24h TSA-treat to prolonged group were significantly decreased of MAPK activation and normal spindle than the other group. We concluded that TSA played a critical role in meiotic progression in porcine oocytes through the regulation of arrest GVBD, which prolonging the in vitro maturation time, but unaffected the subsequent pre-implantation embryo developmental potential and embryonic qualities. Moreover, the histone deacetylase inhibitor TSA may artificially control porcine oocyte maturation time and delay porcine oocyte aging process.