Our study has analyzed whether inappropriate gonadotropin secretion affects the morphological changes due to the activation of intrauterine MMP. Methods A total of each 6 mice were injected with PMSG, Progesterone, and Androgen in 5 IU of intraperitoneal injection every 2 days after estrus synchronization, and morphological and MMPs expression patterns were compared after inducing hormone secretion. Also, cell survival and death related genes were compared and analyzed. The endometrium was highly developed in the PMSG, and the androgen was not developed at all. In particular, the diameter of the uterus of the Androgen group was also very narrow. MMPs activity assay in the case of PMSG was confirmed that showed low activity, whereas, progesterone and androgen In showed high activity and, in particular, very high activity of MMPs in the case of androgen in glandular cell. The expression of VEGF in the tissues of each group was different from that of MMPs. In the PMSG group, the activity of VEGF was increased in both the Myo-metrium and the endo-metrium, whereas the progesterone group showed low overall expression in the endo-metrium. Therefore, the present study showed that the activities of the endo-metrial cells and the restructuring of the endometrial cells differed according to the type of the abnormal secretory hormone. In particular, the secretion of androgen increased the activity of MMPs throughout the uterus, The endo-metrial epithelial cells are affected by the progesterone group. In conclusion, this study suggests that inappropriate gonadotropin secretion increases the functional changes of the uterus and this reconstruction may be caused by increased activity of MMPs

We observed the external genitalia and uterus of a 24-month-old freemartin Hanwoo. The vulva was smaller than observed in a normal female Hanwoo, while the clitoris was larger in the freemartin. The angle between the external genitalia and the perineum also varied. Upon internal genital examination, the uterus of the freemartin was a thin tube approximately 18 cm in size and had not differentiated into a normal uterus and uterine horns.

Embryo transfer is one of the important process of assisted reproductive technology (ART) and that is associated with uterus endometrial receptivity. Recently, mouse endometrial stimulation by artificial injury had shown the favorable effect on conception. In this experiment, we used uterus stimulation method that injury the endometrium to increase implantation rate for spontaneous Diabetes Mellitus (sDM) rat. Rats are divided into several groups involved a control group. We performed the surgical method to Experimental group bilaterally or unilaterally After that, we investigated morphological change and calculated implanted embryos respective sides of the uterus. The number of implanted embryo in the experimental group was significantly higher and there were lots of morphological changes including glands and endometrial cells that support implantation. Our results showed that rat uterus endometrial injury in ART help enhancing implantation rate.

The successful establishment and maintenance of pregnancy is achieved by well-coordinated interactions between the maternal uterus and the implanting conceptus. In pigs, the conceptus undergoes dramatic morphological and functional changes, and secretes various biological products such as estrogens and cytokines, interleukin-1beta (IL1B), interferon-gamma (IFNG), and IFN-delta (IFND) during the implantation period. The uterine endometrium in response to the conceptus-derived molecules and ovarian progesterone becomes receptive to the conceptus by changing cell adhesion molecule expression, epithelial cell depolarization and secretory activity. Conceptus-derived estrogen acts as the maternal pregnancy recognition signal which changes the direction of endometrial prostaglandin (PG) F2 secretion from the uterine vasculature into the uterine lumen. Estrogen also induces the expression of a variety of endometrial genes, including AKR1B1, FGF7, LPAR3, and SPP1. The function of cytokines, IL1B, IFNG, and IFND, in the endometrium is not fully understood, but some recent work shows that IL1B is involved in the synthesis and transport of endometrial PGs by regulating endometrial expression of PG-synthetic enzymes, PTGS1, PTGS2, and AKR1B1, and PG transporters, ABCC4 and SLCO2A1. Estrogen and IL1B also stimulate endometrial expression of IFN signaling molecules, suggesting that estrogen and IL1B act cooperatively on priming the endometrial function of conceptus IFNG and IFND. In turn, IFNG derived from the elongating conceptuses, induces many endometrial genes, including CXCL9, CXCL10, CXCL12, and SLA-DQ. The role of IFND at the maternal-conceptus interface is not well understood yet. Further analysis of the molecules derived from the endometrium and conceptus will provide insights into the cellular and molecular basis of maternal-conceptus interactions for the establishment of successful pregnancy in pigs.

Tight junctions (TJs) form continuous intercellular contacts in intercellular junctions. TJs involve integral proteins such as occludin (OCLN) and claudins (CLDNs) as well as peripheral proteins such as zona occludens-1 (ZO-1) and junctional adhesion molecules (JAMs). TJs control paracellular transportation across cell-to-cell junctions. Although TJs have been studied for several decades, comparison of the transcriptional-translational levels of these molecules in canine organs has not yet been performed. In this study, we examined uterine expression of CLDNs, OCLN, junction adhesion molecule-A, and ZO-1 in canine. Expression levels of canine uterine TJ proteins, including CLDN1, 2, 4, 5, JAM-A, ZO-1, and OCLN, were measured using reverse transcription PCR, real-time PCR, and Western blotting, whereas TJs distribution was determined by immunohistochemistry. The mRNA and protein expression levels of OCLN, CLDN-1, 4, JAM-1, and ZO-1 were identified in the uterus. Immunohistochemistry demonstrated that TJs were localized to the endometrium and/or myometrium of the uterus. Our results show that canine TJ proteins, including CLDNs, OCLN, JAM-A, and ZO-1, were expressed in the canine uterus. Taken together, these proteins may perform unique physiological roles in the uterus. Therefore, these findings may serve as a basis for further studies on TJ proteins and their roles in the physiological or pathological condition of the canine uterus.

The present study was performed to identify the relationship between plasminogen activator (PA) and Heat Shock Protein-90 (HSP-90) in porcine uterus tissues during the estrous cycle. Porcine uterus tissues were obtained from preovulatory (Pre-Ov), post-ovulatory (Post-Ov) and early to mid-luteal (Early-mid L) stages. The protein was extracted from uterus tissue by using M-PER Mammalian Protein Extraction Reagent. Proteins were refined by RIPA Buffer and quantified by BCA methods. As results, t-PA expression was significantly (p<0.05) higher from pre-ovulatory(Epithelium tissue: 29,067 μg/μl, Myometrium tissue: 30,797 μg/μl) compared to the post-ovulatory stage(Epithelium tissue: 54,357 μg/μl, Myometrium tissue: 53,270 μg/μl) and early to mid-luteal stage(Epithelium tissue: 42,380 μg/μl, Myometrium tissue: 43,139 μg/μl). On the other hand, the uPA expression indicated higher from early to mid-luteal stage (Epithelium tissue: 0.02198 μg/μl, Myometrium tissue: 0.02412 μg/μl) than pre-ovulatory stage (Epithelium tissue: 0.01577 μg/μl, Myometrium tissue: 0.01531 μg/μl) and post-ovulatory stage(Epithelium tissue: 0.01414 μg/μl, Myometrium tissue: 0.01429 μg/μl). However, expression of u-PA did not differ from each estrous cycle in the epithelium tissue and myometrium tissue(p<0.05). Expression of HSP-90 was differ t-PA and u-PA from pre-ovulatory in Epithelium tissue(25,423 μg/μl) and early to mid-luteal stage in epithelium tissue(177,922 μg/μl) and myometrium tissue(26,664 μg/μl). These results suggest that HSP-90 and u-PA were related with change of uterus cycle according to the reformation of the tissues in porcine uterus.

The purpose of this experiment was to compare the pregnancy rate (PR) according to the state of the ovaries and uterus, according to the number of embryos transferred from cows and heifers and to investigate the method of artificial twin induction with Hanwoo in vitro fertilized (IVF) embryos by embryo transfer (ET). Looking at the PR according to the condition of the ovaries and uterus, the result was not influenced by the condition of the ovaries, but was significantly influenced by the state of the uterus. The PR according to the number of embryos transferred from cows was 36.8%, 53.0%, 50.5% for 1, 2, and 3 embryos, respectively and although there was a higher frequency of twin calves with 3 embryos than 2, the calving rate was the highest with 2 embryos. In case of heifers, the transfer of 1 embryo showed the best pregnancy and calving rate, and although the PR was similar with 2 embryos (67.7 versus 66.4), in case of 2 embryos transferred there was high frequency of embryonic loss (6.1%) occurred when a cow was diagnosed at 28 and 53 d after ET, total loss (21.3%); sum of fetal death, abortion and stillbirth after pregnant diagnosis at 60 day.

The purpose of this experiment is to compare the pregnancy rate (PR) according to the state of the ovaries and uterus, according to the number of embryos transferred from cows and heifers and to investigate the method of artificial twin induction with Hanwoo in vitro fertilized (IVF) embryos by embryo transfer (ET). Looking at the PR according to the condition of the ovaries and uterus, the result was not influenced by the condition of the ovaries, but was significantly influenced by the state of the uterus. The PR according to the number of embryos transferred from cows was 36.8%, 53.0%, 50.5% for 1, 2, and 3 embryos respectively, and although there was a higher frequency of twin calves with 3 embryos than with 2, the calving rate was the highest with 2 embryos. In case of heifers, the transfer of 1 embryo showed the best pregnancy and calving rate, and although the PR was similar with 2 embryos (67.7 versus 66.4), in case of 2 embryos transferred there was high frequency of embryonic loss( 6.1%) occurred when a cow was diagnosed at 28 and 53 d after ET, total loss (21.3%; sum of fetal death, abortion and stillbirth after pregnant diagnosis at 60 day).

This study investigated the changes of plasminogen activators (PAs) activity, expression and localization of tissue plasminogen activator (tPA) and urokinase plasminogen activator (uPA) during the estrous cycle in pigs. Estrous cycle was sorted into three group by pre-ovulation (Pre-Ov), post-ovulation (Post-Ov) and early to mid-luteal stages (Early to mid-L). Analysis for immunohistochemistry was confirmed by location of tPA and uPA. Porcine uterus tissue was cut into 1 × 1 cm squares, and were incubated in DMEM/F-12 medium for 1 h at 38℃, 5% CO2 for measurement of PA activity. Western blotting was implemented for measurement of PA quantity. In results, the blood vessels and secretory glands were increased in Post-Ov stage than Pre-Ov and Early to mid-L stages. The tPA and uPA was located mainly within lumen of blood vessels and secretory glands. The PA activity in Post-Ov (0.99±0.03) stage were significantly (p<0.01) higher than Pre-Ov stage (0.51±0.03) and Early to mid-L stage (0.21±0.04). Expression of PAs were significantly (p<0.05) higher in Early to mid-L stage than other stages. These results indicate that PAs activity and expression may change in uterus tissue during the estrous cycle in pigs.

The present study was performed to identify the role of plasminogen activator (PA) and the location of PA expression in porcine uterus tissues during the estrous cycle. Porcine uterus tissues were obtained from ovary in pre-ovulatory (Pre-Ov), post-ovulatory stage (Post-Ov) and early to mid-luteal stage (Early-mid L). The uterus tissue was immediately fixed by PBS with 10% formalin. There were fixed porcine uterus tissue for 24 hours at room temperature and porcine uterus tissue dehydrate for 12 hour in sucrose solution. For immunohistochemical staining, porcine uterus tissues were cut to 4 μm by micro frozen section microtome. The nucleus and cytoplasm of porcine uterus tissues were stained by Hematoxin and Eosin. Porcine uterus tissues were evaluated by Immunofluorescence using anti-tissue type PA (tPA) and urokinase type PA (uPA). The location of PA expression was identified by observing the PA fluorescence using fluorescent microscope and optical telescopes. As a results, when Pre-Ov and Post-Ov were identified endometrial blood vessel in an inner layer that were observed tPA and uPA. Especially, expression of PA was observed around secretory gland. But the expression of PA were not confirm in Early-mid L. Also, The expression of PA were higher in Post-Ov than Early-mid L. In conclusion, during the estrous cycle, the expression of PA were increased from Pre-Ov to Post-Ov and was decreased from Post-Ov to Early-mid L.

The present study was performed to identify the role of plasminogen activator (PA) and the location of PA expression in porcine uterus tissues during the estrous cycle. Porcine uterus tissues were obtained from ovary in pre-ovulatory (Pre-Ov), post-ovulatory stage (Post-Ov) and early to mid-luteal stage (Early-mid L). The uterus tissue was immediately fixed by PBS with 10% formalin. There were fixed porcine uterus tissue for 24 hours at room temperature and porcine uterus tissue dehydrate for 12 hour in sucrose solution. For immunohistochemical staining, porcine uterus tissues were cut to 4 μm by micro frozen section microtome. The nucleus and cytoplasm of porcine uterus tissues were stained by Hematoxin and Eosin. Porcine uterus tissues were evaluated by Immunofluorescence using anti-tissue type PA (tPA) and urokinase type PA (uPA). The location of PA expression was identified by observing the PA fluorescence using fluorescent microscope and optical telescopes. As a results, when Pre-Ov and Post-Ov were identified endometrial blood vessel in an inner layer that were observed tPA and uPA. Especially, expression of PA was observed around secretory gland. But the expression of PA were not confirm in Early-mid L. Also, The expression of PA were higher in Post-Ov than Early-mid L. In conclusion, during the estrous cycle, the expression of PA were increased from Pre-Ov to Post-Ov and was decreased from Post-Ov to Early-mid L.

Successful pregnancy requires well-coordinated interactions between the maternal uterus and the developing embryo in pigs. In pigs, implantation begins around Day 12 of pregnancy. During this period, conceptus undergoes a dramatic morphological change and secretes various factors such as estrogens, interleukin-1 beta (IL1B), and interferons. Estrogens produced by conceptuses act as the signal for maternal recognition of pregnancy, and the mechanism of estrogen action is explained by the endocrine and exocrine theory. The uterine endometrium becomes receptive to the conceptus by changing cell adhesion molecules, polarizing epithelial cells and increasing secretory activity. Some changes of uterine activity are affected by the ovarian hormone, progesterone, but the presence of conceptus in the uterus also induces changes of endometrial functions, including most importantly maternal recognition of pregnancy. Many factors, such as hormones, cytokines, enzymes, extracellular matrix proteins, and transport proteins are reported to be present at the maternal-fetal interface and function in the establishment of pregnancy in pigs. However, understanding of the cellular and molecular events occurring in the endometrium is not complete. In recent studies we made some progress on understanding of expression and function of genes involved in maternal-fetal interaction for the establishment and maintenance of pregnancy in the uterine endometrium in pigs. Firstly, we found that lysophosphatidic acid (LPA) was present at the maternal-and fetal interface at the time of implantation and LPA receptor 3 was uniquely expressed in the endometrium during early pregnancy. Secondly, we observed that salivary lipocalin (SAL1), a lipid-binding protein, was uniquely expressed in the uterine endometrium at the time of embryo implantation, and its expression was regulated by IL1B. Furthermore, expression of IL1B receptors are regulated by estrogen and IL1B, and IL1B functions in expression of genes related to prostaglandin synthesis and transport. Thirdly, we found that calcium regulatory molecules TRPV6 and S100G were dynamically regulated in the uterine endometrium during pregnancy, suggesting that regulation of calcium ion concentration may important for the embryo implantation and the maintenance of pregnancy. Finally, we observed that an MHC class II molecule, SLA-DQ, is expressed in the uterine endometrium at the time of conceptus implantation and its expression is essential for successful pregnancy, indicating that appropriate maternal-fetal immune interaction is required for the maintenance of pregnancy. Further analysis of these molecules will provide insights into the cellular and molecular basis of maternal-and fetal interaction during pregnancy in pigs.

We report herein the successful results of estrus induction, sperm cryopreservation and kids born by transcervical insemination of frozen-thawed semen in a Saanen goat. Flugestone acetate (FGA: 60 mg) was inserted into vagina for 15 days. The goat was intramuscularly injected with 400 IU PMSG and 200 IU hCG (: Intervet, Korea) a day before withdrawal of the FGA sponge. Follicles and corpora lutea were identified on both ovaries by laparoscopy. Artificial insemination was performed 46 hours after removal of FGA sponge. The concentration of frozen-thawed semen was and 0.5 ml of frozen-thawed semen was transcervically inseminated into uterine body under anesthesia. Three kids, all females, were born 144 days after artificial insemination. This is the first report producing kids by transcervical insemination of frozen-thawed semen in a Saanen goat of which the estrus was induced by FGA sponges, PMSG and hCG during non-breeding season in Korea.

Pregnancy is a unique event in which a fetus develops in the uterus despite being genetically and immunologically different from the mother, and the underlying mechanisms remain poorly understood. To analyze the differential gene expression profiles in nonpregnant and 7 days post coitus (dpc) pregnant uterus of mice, we performed a global proteomic study by 2‐D gel electrophoresis (2‐DE) and MALDI‐TOF‐MS. The uterine proteins were separated using 2‐DE. Approximately 1,000 spots were detected on staining with Coomassie brilliant blue. An image analysis using Melanie III (Swiss Institute for Bioinformatics) was performed to detect variations in protein spots between pregnant and nonpregnant uterus. Twenty‐one spots were identified as differentially expressed proteins, of which 10 were up‐regulated proteins such as alpha‐fetoprotein, chloride intracellular channel 1, transgelin, heat‐shock protein beta‐1, and carbonic anhydrase II, while 11 were down‐regulated proteins such as X‐box binding protein, glutathione S‐transferase omega 1, olfactory receptor Olfr204, and metalloproteinase‐disintegrin domain containing protein TECADAM. Most of the identified proteins appeared to be related with catabolism, cell growth, metabolism, regulation, cell protection, protein repair, or protection. Our results uncovered key proteins of mouse uterus involved in pregnancy.