Spermatogonial stem cells (SSCs; also known as Asingle [As] spermatogonia in mice) divide to self-renew or to produce progenitor cells known as Apaired(Apr) spermatogonia in basal compartment of seminiferous tubules of mammalian testis. These characterized cells are the finally differentiated product of a developmental process referred to as “spermatogenesis.” In the development of SSCs it is critical to maintain a balance between self-renewal and differentiation. because an excess of either process will lead to infertility. these two processes are tightly controlled by intrinsic signals of SSCs and extrinsic signals from the microenvironment, known as the SSC niche. The SSC niche is formed by Sertoli cells, the only somatic cells found inside the seminiferous tubules. The WNT/β-catenin pathway is known to regulate Sertoli cell functions critical to their capacity to support spermatogenesis in the postnatal testis, but The mechanisms and factors of the pathway are not well known. We found a factor TLE3 (Transducin Like Enhancer Of Split 3). The transcriptional co-repressor TLE family is known to function as transcription co-repressors within the context of Wnt signaling by interacting with histone deacetylase HDAC2. We examined the expression level of TLE3 in various mouse tissues. As a result of RT-PCR, TLE3 showed significantly higher expression in testis than that in other tissues. Immunofluorescent analysis revealed that TLE3 and HDAC2 expression are differentially regulated in the mouse testis during postnatal development. In adult testis, TLE3 and HDAC2 were co-expressed in Sertoli cells. TLE3 and HDAC2 protein are also located in nucleus in mouse TM4 Sertoli cells. Taken together, TLE3 may play a role in regulating WNT/β-catenin pathway via interaction with HDAC2 in Sertoli cell. Futher studies are needed to look into factors that regulated by siTLE3 in Sertoli cell and interated with TLE3 in WNT/β-catenin pathway.
The Hippo signaling pathway is essential for regulating proliferation, differentiation, and apoptosis in mammalian cells. Hippo signaling pathway exists in most body tissues and organs, where it controls the size of organs and tissues by keeping cell growth in check and promoting cell death as needed. It has been reported that the members of Hippo signaling pathway are highly expressed in mammalian ovaries and uteri. However, the regulatory mechanism of this pathway in the uterus during estrous cycle regulation remains unclear. Serine/Threonine Protein Kinase 4 (STK4, also known as MST1, a homolog of Hippo in Drosophila) is a major factor of Hippo signaling pathway. However STK4 in the mouse uterus has not yet been examined. The purpose of our study was to determine the expression of STK4 during the estrous cycle and regulation by estrogen in the mouse uterus. We found that STK4 was dynamically expressed in uterine endometrium during the estrous cycle. STK4 highly expressed at the estrus, diestrus, and were found to dramatically decrease as it progressed to the proestrus, metestrus stage of uterus during the estrous cycle. Expression of STK4 was dominant in glandular epithelial and luminal epithelial of proestrus, estrus, and diestrus stage, whereas in metestrus stage, expression of gene intensity was faint. Estrogen or estrogen receptor antagonist ICI 182,780 treatment, in ovariectomized mouse uterus, Expression of STK4 and its downstream genes were increased by estrogen. Our results show that the Hippo signaling pathway is estrogen-dependent in the mouse uterus. These informations will give us on sights to understand uterine dynamics during the estrous cycle.
Primary oocytes that are arrested in first meiotic prophase for years enter maturation process to meet a critical precondition for successful fertilization. During maturation, oocyte finishes meiosis I and progresses to the metaphase II stage, achieving meiotic maturity. Although importance of oocyte maturation for oocyte quality has been recognized, it is not fully understood for molecular mechanisms underlying oocyte maturation. Here, we found that dexamethasone-induced Ras-related protein 1 (RASD1), a member of RAS superfamily of small GTPases, was expressed in the mouse ovary. Immunohistochemical analysis revealed that Rasd1 expression was dominant in oocyte cytoplasm. Real-time PCR and RT-PCR analyses showed that Rasd1 mRNA was steadily expressed in germinal vesicle (GV), germinal vesicle break down (GVBD), metaphase I (MI) oocytes, but decreased in metaphase II(MII) oocytes during oocyte maturation. Konckdown of Rasd1 using RNAi system in the GV oocytes suppressed oocyte maturation through disruption of meiotic spindle and formation of misarranged chromosomes. Taken together, Rasd1 is a critical factor for MI-MII transition of oocyte and is involved in the regulation of spindle formation during oocyte maturation. Further study is needed to examine relationship between Rasd1 and spindle formation in MI-MII transition.
Tdrd family members contain Tudor domain repeat which is found in polar granules in Drophila. Tdrd12 is one of Tdrd family members. Tdrd12 contains a DEAD-box and a Tudor domain. However, the molecular mechanism and physiological function of Tdrd12 has not been described. To examine the expression pattern of Tdrd12, RT-PCR and Northern blot analysis were performed using total RNAs extracted from tissues; liver, intestine, heart, brain, kidney, lung, brain, uterus, ovary, and testis. The full-length of Tdrd12 was amplified from total RNA from mouse testis and cloning into the cloning vector. Cloned PCR products were purified,sequenced and analyzed using the ABI Prism Sequencer 3130XL. To look into Tdrd12 protein location, rabbit antibodies against mouse Tdrd12 were made using two epitopes: 1st epitope: (318~334)- SQRPNEKPLRLTEKKDC and 2nd epitope: (737~750)- LEAKEDKKARRPLC, and its specificity was tested using tissue extracts including the gonad. Here, we identified that Tdrd12 mRNA is detected in the ovary and testis, but not in other tissues. The size of its transcript is about 4.5kb on the northern blot. Antibody against Tdrd12 detects about 150 kDa protein on the western blot analysis. Immunostaining assay shows that Tdrd12 is localized at the spermatid in the seminiferous tubules. The current study is the first to investigate Tdrd12 expression is limited in the gonad. Thissuggest that Tdrd12 plays a role in the gonad like other known Tdrd family members, Tdrd1, Tdrd6, Tdrd7, and Tdrd9.