Autophagy is an intracellular degradation and recycling system. Oocyte maturation is dynamic process, in which various proteins should be synthesized and degraded. In our previous study, we reported the loci of autophagosome and dynamics of autophagic activity in porcine oocytes during In Vitro maturation. In this study, we verified loci of autophagosome in porcine follicular cumulus-oocyte complex by detection of microtubule-associated protein 1A/1B-light chain 3 (LC3) which is the reliable marker of autophagosome. Porcine ovary including various sizes of follicles was fixed within 1 hour after collection from slaughterhouse. After fixation, immunohistochemistry was conducted on sliced ovary tissue containing various sizes of follicles by using LC3 antibody. As a result, LC3 signal was clearly detected in both cumulus and oocytes of various sizes of follicles. We also found ring shaped signal which represent autophagosome near oocyte membrane. Most of the signals in oocytes were localized nearby cellular membrane while evenly dispersed in cumulus cells. Therefore, this result suggests that autophagy occurs in porcine COCs (cumulus-oocyte complexes) at follicular stage.

Although in vitro production (IVP) techniques of porcine follicular oocytes have progressed and are well studied, the developmental potential of porcine oocytes matured in vitro remains low compared with those matured in vivo. It is well known that one of the reason occurred impair in vitro maturation (IVM) of porcine oocytes is the oxidative stress. Oxidative stress is mainly caused by reactive oxygen species (ROS) generation formed during cellular metabolism. β-cryptoxanthin (BCX) is one of the carotenoid pigment and possesses strong anti-oxidative and free radical scavenging activities and suppresses lipid peroxidation and nitrogen oxide production. The objective of this study was to examine the effects of BCX treatment on porcine oocyte during IVM and their in vitro developmental potential. The follicular oocytes were cultured in IVM medium supplemented with 0, 0.1, 1, 10 and 100 μM BCX (control, 0.1 B, 1 B, 10 B and 100 B). In analysis of intracellular ROS expression level after IVM, 1 B group was the lowest among all groups (p<0.05), while other BCX treated groups are similar to control group. Also, 1 B group was significantly decreased during the classified oocyte maturation stage (GVBD, MⅠ and MⅡ) than control (p<0.05). In addition, the relative mRNA expression level of antioxidant gene (superoxide dismutase-2 and peroxiredoxin-5) was significantly higher in 1 B group than control (p<0.05). After parthenogenetic activation, there was no different in the cleavage rate between two groups, however, the blastocyst formation rate was significantly higher in 1 B group than in control (p<0.05). In embryo quality, the total cell number and DNA fragmentation of blastocysts were no different between two groups. These results demonstrate that BCX is helpful for decreasing ROS level of porcine follicular oocytes and improves their developmental potential.

The objective of this study was to identify a follicular fluid ingredient inhibiting the cumulus oocyte complex (COC) expansion. Thus, follicular fluid or liquid chromatographic fractions of follicular fluid was supplemented in COC culture medium. And COCs were incubated for 48 hours to investigate about cumulus expansion and also the first polar body extrusion. The results obtained were as follows; 1. The fluid of medium follicle significantly inhibited the COC expansion. 2. The fluid of large follicle inhibited the COC expansion. 3. Follicular fluid showed six major fractions at retention volumes (RVs) 1.83, 1.91, 2.15, 2.34, 2.53 and 2.74 ml after separation with Superose 12 column. Of the major fractions, fractions RV2.15, RV2.34, RV2.53 and RV2.74 inhibited both COC expansion and polar body extrusion. Especially, fractions of RV2.15 and RV2.53 significantly inhibited COC expansion, oocyte denudation and polar body extrusion. In conclusion, porcine follicular fluid contained a COC expansion inhibiting ingredient (CEI) that may be contained largely in fractions RV2.15 and RV2.53. And CEI may inhibit oocyte maturation by inhibition of oocyte denudation and extrusion of the first polar body.

This study was conducted to find out the effect of follicle size and oocyte type on in vitro maturation of poricine follicular oocytes. TCM-HEPEAS medium was used to basic medium, and the oocyte matured in vitro was stained with the Rapid staining method. The results obtained were summarized as follows; 1. The number of follicles an ovary was 20.5. The number of A-and B-typed oocytes an ovary was 2.34. The proportion of A-and b-types oocytes was 40% of the recovery oocytes. 2. Cumulus expanison indexes(CEI) by the follicle size were 1.62∼2.34(<2mm), 1.27∼2.28(2∼5mm) and 1.46∼2.75(>5mm). It was no differ to maturation rate by the follicle size. 3. The degree of oocyte maturation based on oocyte type did not differ for B-and C-typed oocyted but the index of oocyte type A was higher than that of b-and C-typed oocytes. 4. When follicluar oocytes were cultured for 42 hours, the proportion of the Met-II(second metaphase) stage were 22.5% (degree 1), 35.4%(degree 2) and 65.5% (degree 3).