One of the major hallmarks of uterine diseases is disruption of ovarian steroid hormone control of uterine cell proliferation and differentiation. Estrogen (E2) stimulates proliferation of uterine epithelial cells while progesterone (P4) is inhibitory to E2-mediated proliferation of the epithelium. Mitogen inducible gene 6 (Mig-6) is an important mediator of P4 signaling to inhibit E2 signaling in the uterus. Uterine-specific knockout of Mig-6 caused endometrial P4 resistance and infertility. Levels of ErbB2 (also known as HER2) and phospho-ERK1/2 are significantly higher in Mig-6 knockout mice as well as infertile women with endometriosis. To determine the interplay between Mig-6 and the Erbb2 signaling pathway in the uterus, we generated mice with Mig-6 and Erbb2 conditionally ablated in progesterone receptor-positive cells (Pgrcre/+ Mig-6f/f Erbb2f/f; Mig-6d/d Erbb2d/d). Mig-6d/d mice were infertile whereas control and Mig-6d/d Erbb2d/d mice exhibited normal fecundity. The uterine horns of Mig-6d/d mice had no implantation sites, whereas control and Mig-6d/d Erbb2d/d mice had averaged implantation sites. Additionally, aberrant increment of epithelial proliferation in uterus of Mig-6d/d mice did not show in Mig-6d/d Erbb2d/d mice uterus at pre-implantation stage. Microarray analysis revealed that almost altered genes in Mig-6d/d mice were recovered their expression levels in Mig-6d/d Erbb2d/d mice. The altered pathways such as cell-cycle control, DNA replication, and modification processes by Mig-6 ablation were rescued in Mig-6d/d Erbb2d/d mice. The infertility seen in Mig-6d/d mice is recovered in Mig-6d/d Erbb2d/d mice. These results suggest that Mig-6 mediates a critical P4 function to inhibit E2 signaling by inhibiting ErbB2 signaling. As MIG-6 is a mediator of P4 signaling, the activity of which can suppress unopposed-E2 signaling, our studies provide a potential new drug target for the intervention of female infertility.

Three-dimensional (3D) culture system is useful technique for study of in vivo environment and it was used various experiments. This study was investigated to establish of embryo co-culture system and changes of PAs activity in 3D cultured endometrial cells of pigs. In results, growth of stromal cells into gel matrix were detected only with endometrial and myometrial cells. The most rapid growth of stromal cells were confirmed in 2.5x105cells/ml and gel matrix containing 15% FBS. Expression of urokinase-PA (uPA) after treatment of hCG (0.5, 1.0, 1.5 and 2.0 IU/ml) were higher than without hCG, but, there are not significant difference among the treatment. On the other hand, expression of uPA after treatment of IL-1β (0.1, 1, 10 and 100 ng/ml) were higher than without IL-1β, but, there are not significant difference. Expression of uPA after treatment of estrogen (0.2, 2, 20 and 200 ng/ml) were not difference, but PA activity was significantly decreased (p＜0.05). Blastocyst was producing in PZM-3 medium containing FBS and endometrial cells were grown in PZM-3 medium. When embryos development with cultured endometrial cells, cleavage rates were not significant difference and blastocyst were not produced in co-culture with stromal cells and 3D culture system. 3D culture system had similar activity to in vivo tissue and these features are very useful for study of in vivo physiology. Nevertheless 3D culture system was not proper in embryo co-culture system. Therefore, we suggest that 3D culture system with embryo co-culture need continuous research.

Harmonized actions of ovarian estrogen (E2) and progesterone (P4) regulate cell proliferation and differentiation in the uterus with a spatiotemporal manner. Imbalance between the actions and levels of two major regulators often lead to infertility and gynecological diseases, such as endometriosis and endometrial cancer. While numerous works have shown that reduced expression and/or deletion of uterine factors associated with P4 signaling could disturb uterine physiology, local factor(s) to mediate E2 actions has not been extensively studied yet. Here we demonstrate that early growth response 1 (Egr1), a transcription factor which is rapidly induced in the uterus by E2, is required to maintain coordinated actions of E2 and P4 for uterine receptivity for embryo implantation. Given exogenous gonadotrophins to overcome LHβ deficiency in the pituitary of Egr1(－/－) mice, ovulation, fertilization and embryo development normally occurred in these mice. However, they showed complete failure of embryo implantation with reduced uterine responses to artificial decidualization stimuli. While serum levels of E2 and P4 in Egr1(－/－) mice were comparable, genes regulated by E2 and/or P4 in uterine epithelial cells (ECs) were aberrantly expressed on day 4 of pregnancy. Impaired P4 signaling along with absence of PR in ECs caused hypersensitive E2 responses shown as enhanced expression of E2-responsive genes such Muc1 and Ltf as well as reduced levels of P4-dependent genes, such as Ihh and Areg, in ECs of Egr1(－/－) mice. This is consistent with persistent proliferation in ECs and severely impaired proliferation in stromal cells (SCs) in Egr1(－/－) mice treated with E2+P4. Furthermore, primary co-culture of Egr1(－/－) ECs with Egr1(+/+) SCs and vice versa supported a notion that Egr1 itself is required for proper responses to two major regulators, E2 and P4, in both uterine cell compartments. Collectively, our results show that E2-induced Egr1 participates in P4-dependent modulation on E2 activities in the uterus by regulating a spectrum of genes essential for uterine receptivity and embryo implantation.

Early growth response 1 (Egr1) belongs to the Egr family of zinc finger transcription factors (Egr1 to Egr4) that regulates cell growth, differentiation, and apoptosis. Egr1(-/-) female mice are infertile due to anovulation resulting from luteinizing hormone β subunit (LHβ) deficiency. While it is clear that Egr1 is critical for LHβ transcription in the pituitary gland, function of Egr1 in uterus still remain unexplored. Uteri on various experimental conditions or days of pregnancy were collected for mRNA microarrays, realtime-RT-PCR, Western blotting, and histological analyses for immunofluorescence and BrdU staining. Egr1 and other Egr family members, Egr2 and Egr3 are highly expressed in the uterus on day 4 of pregnancy (Day 4). While ovulation, fertilization and embryo development normally occur in Egr1(-/-) mice treated with a superovulation regime to rescue LH deficiency, embryo implantation was completely failed. In addition to implantation failure, oviductal transport of embryos is also impaired in these mice. 17/24 Egr1(-/-) mice (71%) retained blastocysts in the oviduct as well as in the uterus of Egr1(-/-) mice on Day 4 whereas all Egr1(+/+) mice have them in the uterus. While serum levels of E2 and P4 in Egr1(-/-) mice on Day 4 were comparable to those of wildtypes, expression of E2 responsive genes which are expressed in luminal epithelium, such as Mucin 1 and lactoferrin, is aberrantly increased in Egr1(-/-) mice with embryos in the oviduct on Day 4. In contrast, P4 responsive genes such as Hoxa10 and amphiregulin are normally expressed in these mice. Collectively, these data suggest that Egr1 deficiency in the oviduct and uterus leads to estrogen hypersensitivity. BrdU incorporation experiments provided evidence that epithelial cells undergo hyperproliferation in Egr1(-/-) mice. This is consistent with microarray data that several key factors for cell cycle progression such as cyclin Ds and E2F1 are overexpressed in these mice. Furthermore, in the uteri of Egr1(-/-) mice treated with E2+P4, stromal cell proliferation is severely impaired and epithelial cells persistently proliferating. With respect to decidualization, Egr1 as well as Egr2 and Egr3 are induced immediately after decidualization stimuli were given. Although the responses were relatively less than those of wildtype mice, decidualization does occur in Egr1(-/-) mice. Relatively compromised decidualization responses seems to result from functional compensation of Egr2 and Egr3 in Egr1(-/-) deficient uteri. Collectively, our results show that Egr1 is a critical transcription factor to fine-tune estrogen responses via regulation of a spectrum of genes for embryo implantation in the uterus.

착상은 배아측과 모체측의 내분비적, 측분비적 및 자가분비적 인자들의 상호 작용에 의하여 조절된다. 착상의 적기는 일로서 이 특수한 시간대 안에서 signaling, appositioning, attachment 및 invasion을 통하여 순차적으로 배아의 착상이 이루어지는데, 이는 자궁내막과 배아로부터 여러 사이토카인, 성장인자, 부착인자와 같은 다수의 생화학 인자의 생성과 분비를 포함하며 이로 인하여 수용적인 자궁내막이 형성된다. LIF, CSF-1