The Jeju Black Cattle (JBC) are a type of traditional Korean native cattle with a characteristic black fur that covers the entire body. Semen analysis is the most commonly used procedure to evaluate male fertility potential. This study was to evaluate the quality of 10 JBC bulls belonging to Jeju Special Self-Governing Province Promotion Institute. [JBC A∼J grade]. The freezing medium (20% egg yolk plus 20% triladyl) was added in semen sample to a final concentration of 100×106 sperm/ml. For sperm cooling, diluted semen was filled in 0.5 ml plastic straws and then kept in refrigerator at 4°C for 2 h. They were placed in 7 cm over liquid nitrogen (LN2) vapor for 10 min and then directly plunged into LN2 for storage. Thawing was done by transferring the frozen straws into water bath at 37°C for 30 sec for analysis. The sperm motility, vitality and morphology in each group was assessed using the Sperm Analysis Imaging System (SAIS Plus; Medical Supply Co, Ltd., Korea), eosin-nigrosin stain and diff-quik kit. There was no difference in the motility of the fresh groups (87.4 ~ 100%), while it was difference in the frozen-thawed groups (42.8 ~ 98.6%) (p<0.05). The best motility was shown in JBC-B (100/fresh and 98.6%/frozen-thawed). There was significant difference in the vitality of the fresh group (19.8 ~ 59.2%) and frozen-thawed group (21.2 ~ 49.8%)(p<0.05). The highest vitality was also shown in JBC-B (59.2/fresh and 49.8%/frozen-thawed). Morphologically, in fresh semen the highest normal ratio was indicated in JBC-E (90.9%) and in frozen-thawed group the highest was in JBC-C (90.2%). These results demonstrated that the analysis including motility, vitality and morphology of fresh or frozen-thawed semen is valuable to select the high quality sperm using for reproduction.

Light Mineral Oil is a material generally used as an overlay covering microdrops of culture medium in petri dishes. Although Light Mineral Oil can protect the damage by oxidation in air, it can't completely protect the damage by evaporation and alteration of pH and osmolality in culture medium. To minimize the damage by evaporation and alteration of pH and osmolality, we assumed that Heavy Mineral Oil could be used as an alternative. Heavy Mineral Oil is high purity paraffin oil which has more viscosity and density than Light Mineral Oil, so it can prevent evaporation and maintain stable osmolality and pH in culture medium more than Light Mineral Oil. The objective of this study was to examine whether the effect of Heavy Mineral Oil is superior to the effect of Light Mineral Oil during in vitro cultivation of porcine oocytes. According to the data of repeated six experiments, survival and cleavage rate of porcine oocytes, and cell number of blastocysts were not significantly different between two groups. However, the in vitro development rate of porcine parthenogenetic embryo was significantly higher in Heavy Mineral Oil group than in Light Mineral Oil group (Light, 36.6% ± 3.9%; and Heavy, 52.1% ± 6.4%, p < 0.05). Thus, these results indicated that the treatment of Heavy Mineral Oil can improve the in vitro developmental capacity of porcine parthenogenetic embryos compared to Light Mineral Oil.

Recent research on stem cell conditioned medium (CM) has been revealed that CM could influence on the embryo development when supplemented to in vitro culture medium. However, the optimal basal medium for CM production has not determined although it is the fundamental factor of CM. The purpose of this study is to examine the effect of human derived adipose stem cell CM (hASC-CM) with different basal medium on mice embryo development after parthenogenetic activation (PA). hASC-CM was collected from 2 kinds of serum free basal medium, DMEM and KSFM, respectively on day 5 from the culture of hASC isolated from human fat tissue. Intra-peritoneal injection of PMSG and hCG was conducted into 7-week-old ICR mice for superovulation. The oocytes were recovered from the oviductal ampulla, 18 h after hCG injection, and denuded using 0.1% hyaluronidase. PA of oocytes was conducted with KSOM media including strontium chloride. The parthenotes were in vitro cultured in 3 groups: 100% KSOM (Control), 75% KSOM + 25% DMEM or KSFM without FBS (DMEM or KSFM group) and 75% KSOM + 25% hASC-CM from DMEM or KSFM (DMEM-CM or KSFM-CM group). Cleavage rate was assessed after 2 days post IVC and blastocyst formation rate was evaluated after 6 days post IVC both using stereomicroscope. Total cell number of blastocysts was counted by Hoechst staining. 1way ANOVA from Graphpad prism 5 was used for statistical analysis and the values are presented as means ± standard error of mean. As a result, blastocyst formation rate of DMEM-CM group (16.09±3.32%, P<0.05) was significantly lower than control and DMEM group (34.43±2.89% and 34.49±5.34%, P<0.05) but cleavage rate and total cell number of blastocysts showed no significant difference among groups. In case of KSFM, there was no significant difference in cleavage rate, blastocyst formation rate and total cell number of blastocysts among the control, KSFM group and KSFM-CM group. The sort of basal medium used for the CM collection affected the development of parthenotes during in vitro culture differently. Therefore, further research should be conducted to find out the alternative basal medium of CM able to improve the embryo development. This research was supported by Nature Cell (#550-20170028), Cooperative Research Program of RDA (CCAR, #PJ013954022018), Research Institute for Veterinary Science and the BK21 plus program.

Secretory leukocyte protease inhibitor (SLPI), also known as neutrophil elastase and cathepsin-G protease inhibitor, functions in protection of epithelial cells from proteases. SLPI is expressed and secreted by many mucosal tissues, including lungs, seminal vesicles and cervix in women. SLPI plays an important role in protection of endometrial epithelial cells during pregnancy from degradation by degradation by proteases derived from trophoblast at the maternal-conceptus interface. In pigs, SLPI mRNA is known to be expressed in endometrial tissues, but the expression of SLPI in the endometrium throughout the estrous cycle and pregnancy has not been determined. Therefore, we analyzed the expression and regulation of SLPI mRNA in the endometrium throughout the whole stages of the estrous cycle and pregnancy in pigs. We obtained endometrial tissues from gilts on Days 0 (day of estrus), 3, 6, 9, 12, 15, and 18 of the estrous cycle and on Days 10, 12, 15, 30, 60, 90, and 114 of pregnancy. Real-time RT-PCR analysis showed that the expression of SLPI mRNA in the endometrium increases during midt-o late pregnancy. During the estrous cycle, levels of SLPPI mRNA in estrus and proestrus were higher than those in diestrus and metestrus. In situ hybridization analysis showed that SLPI mRNA was specifically localized to the glandular epithelial cells in the endometrium during pregnancy with strong signal intensity during mid-to late pregnancy. SLPI mRNA was not detectable in conceptus tissues on Days 12 and 15 of pregnancy, but SLPI mRNA was expressed in chorioallantoic tissues during mid-to term pregnancy with increasing levels toward term pregnancy. To determine the effects of steroid hormones, estrogen and progesterone, on the expression of SLPI mRNA, endometrial explant tissues from immature pigs were treated with increasing doses of estradiol-17β (E2) and progesterone (P4). Increasing doses of E2 and P4 increased the expression of SLPI mRNA in endometrial tissues. These results showed that SLPI was expressed in the endometrium in a pregnancy stage-and cell type-specific manner and the expression of SLPI was regulated by E2 and P4 in endometrial tissues, suggesting that SLPI may play an important role in regulating the endometrial epithelial cell function during mid-to late pregnancy in pigs. Further analysis to determine the roles of SLPI at the maternal-conceptus interface is still needed.