Cyclic AMP-response element binding protein zhangfei (CREBZF), a member of ATF/CREB (activating transcription factor/ cAMP response element binding protein) family, regulates numerous cellular functions and development of cells by interacting transcription factors. This study discovered the expression pattern of CREBZF in seminiferous tubule of testes during the postnatal development of mice. In testis, CREBZF mRNA expression was the highest among other organs. Immunofluorescence analyses showed that the CREBZF was specifically expressed on spermatocyte but not in spermatogonia and Sertoli cells in seminiferous epithelium of mouse testis. Semi-quantitative polymerase chain reaction (PCR) analysis showed that CREBZF transcript level was significantly elevated during postnatal development of mouse testis. Confocal imaging analysis indicated that the protein expression of CREBZF in seminiferous tubule remained low until postnatal day (PD) 14, and was dramatically increased in PD 21. Interestingly, only one type of the spermatocyte expressed CREBZF specifically among SCP3-positive spermatocytes. Taken together, these results suggest that CREBZF may be novel putative marker of the spermatocyte and regulate meiosis during postnatal development of mice.

Gonadotropins are heterodimers consisting an alpha chain (Cgα) and a beta chain. Interestingly, presence of complicated LH-β transcripts in rat testis was accidently found; testicular LH-β transcripts were confined in seminiferous tubules to spermatids, and the translated products were localized in the elongated spermatids. We hypothesized that mouse testis has potential to produce the tissue specific LH-β with similar structure to the rat testicular forms. To verify our hypothesis, we examined the adult mouse (ICR) testis using RT-PCR and immunohistochemistry. The PCR revealed the presence of the identical products in the reactions for three LH subunit types. The expected product sizes for mouse Cgα and LH-β known as pituitary type were 224 bp and 503 bp, respectively. The testicular type LH-β products were produced by a primer set based on the rat sequences, with unexpected size of 800 bp. Sequencing revealed that the proximal and distal parts (2-82 and 661- 773 bp, respectively) were homologous to rat testicular LH-β cDNA, and middle part (83-660 bp) was a unique mouse-specific region. Both Cgα and LH-β positive signals were in the round and elongated spermatids and mature sperms, and the LH-β signals were more intense. In conclusion, our study demonstrated that the presence and localization of the LH subunits in mouse testis. Further studies will be needed to understand the precise structure and function of mouse testicular LH.

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.

Estrogen is an important regulator of reproduction in both male and female. The two forms of estrogen receptor (ER) are known, ERα and ERβ. To understand the role of ERα in the testis, we investigated the expression of ERα in the mouse Leydig cells during postnatal development and the effects of estrogen on steroidogenesis and proliferation in progenitor Leydig cells (PLCs). In the testis, ERα mRNA and protein levels were markedly increased from postnatal day (PND) 1 to 14 and decreased thereafter until PND 56. During postnatal development ERα immunoreactivity was strong in the nucleus of Leydig cells at PND 14 when PLCs were abundant in the interstitium and low in the mature adult Leydig cells (ALCs). In fetal Leydig cells (FLCs), ERα immunoreactivity was negligible at birth and became increased at PND 14. This suggests an important role of ERα in Leydig cells during neonatal period. In isolated PLCs, 17β-estradiol (E2) and ERα-selective agonist, PPT suppressed the hCG-induced progesterone production and steroidogenic pathway genes expression. The hCG-induced PLCs proliferation was significantly inhibited by E2 and PPT. In conclusion, estrogen - ERα signaling may negatively regulate functional differentiation and proliferation of PLCs.

Expression of claudin-11 (CLDN11), a tight junction (TJ) protein, was examined in the Korean soft-shelled turtle (Pelodiscus maackii) testes. Spermatogenesis began during the breeding season and peaked at the end of the breeding season. Spermiation started in summer and peaked in autumn. The deduced amino acid sequence of P. maackii CLDN11 was similar to those of avian and mammalian species. During the non-breeding season when spermatogenesis and testosterone production were active, testicular Cldn11 levels were high. In the seminiferous epithelium, strong wavy CLDN11 strands parallel to the basement membrane delaminate the spermatogonia, and early spermatocytes are in the open compartment. Otherwise, CLDN11 was found beneath the early spermatocytes and in the Sertoli cell cytoplasm. Punctate zonular occludens-1 (ZO-1) immunoreactivity was found within the CLDN11 strands parallel to the basement membrane or at the outermost periphery of the seminiferous epithelium close to the basal lamina. During the breeding season, when circulating testosterone levels and spermatogenic activity was low, testicular CLDN11 level was lower than those of non-breeding season. CLDN11 was found at apicolateral contact sites between adjacent Sertoli cells devoid of the postmeiotic germ cells. At this time, lanthanum tracer diffused to the adluminal compartment of seminiferous epithelium. In cultured testis tissues, testosterone propionate significantly increased the level of Cldn11 mRNA. In P. maackii testis, CLDN11 participates in the development of the BTB where the CLDN11 expression was coupled with spermatogenic activity and circulating androgen levels, indicating the conserved nature of TJ’s expressing CLDN11 at the BTB in amniotes.

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.

The Egr family of zinc finger transcription factors is rapidly induced by various mitogens and regulates cell growth, differentiation, and apoptosis. While it is clear that loss of Egr1 leads to anovulatory infertility due to LHβ deficiency in female mice, molecular function of Egr1 in male reproduction has not been clearly investigated. Here, we demonstrate that Egr1 acts as an intrinsic transcription factor in Leydig cells to regulate their proliferation and steroidogenesis in the testis as well as an extrinsic factor for male reproduction via LHβ transcription in the pituitary. Egr1 is predominantly expressed in spermatogonia and Leydig cells in immature testes and later detected in some of these cell types in mature testes. The fertility potential of Egr1(-/-) male mice is relatively deteriorated even at 2 month-old age and aggravated with aging. The incidence of abnormalities of seminiferous tubules such as Sertoli cell only was dramatically increased with aging. The number and mean size of Leydig cells were significantly reduced in Egr1(-/-) testes. The impairment of Leydig cells is consistent with significant reduction in levels of testosterone and expression of factors critical for steroidogenesis such as StAR in Egr1(-/-) testes. Exogenous administration of hCG rapidly and transiently induced Egr1 expression in Leydig cells culture in vitro. hCG could reinstate reduced mean size of Leydig cells but not reduced number of Leydig cells and aberrantly low StAR expression, suggesting that Egr1 has critical functions for Leydig cell proliferation and their steroidgenesis. In addition, daily sperm production and in vitro fertilization (IVF) competence were significantly reduced, and apoptosis was facilitated in these mice. Furthermore, hCG administration to compensate for relatively low LH levels in Egr1(-/-) males could not restore the compromised reproductive phenotypes such as IVF competence and apoptosis in these mice. Interestingly, expression of Egr2, a member of Egr family, is significantly elevated in Egr1(-/-) Leydig cells suggesting that genetic compensation of Egr2 may alleviate phenotypic aberration of Egr1(-/-) male testes. Collectively, these results suggest that Egr1 act as an intrinsic transcription factor required for proliferation and steroidogenesis of Leydig cells to govern spermatogenesis in the testis.

Estrogen sulfotransferase (EST) is a cytosolic enzyme that catalyzes the sulfo-conjugation of estrogens at the 3-hydroxyl position. Sulfated estrogens lose their ability to interact with the estrogen receptor (ER). Previous studies have reported that testicular expression of EST is under the regulation of LH and androgen. In an effort to understand the biological significance of estrogens in the testis, we analyzed the EST gene expression in the developing mouse testis and Leydig cells and its regulation by estrogen receptor alpha (ERα). Male mice at postnatal day (PND) 1, 7, 14, 28, and 56 and ERα flox/flox Cyp17iCre male mice which show deletion of ERα specifically in Leydig cells were used for this study. Testes and Leydig cells isolated from these mice were subjected to quantitative RT-PCR analysis and immunohistochemistry. In addition, 17β-estradiol (E2), ERα-selective agonist PPT, ERβ -selective agonist DPN, and ER antagonist ICI 182,780 were treated in primary adult Leydig cell culture. These cultured cells were subjected to quantitative RT-PCR analysis. In testis, EST mRNA level was excessively low by PND 14 and markedly increased from puberty (PND 28) onward. In the interstitium, EST mRNA was not detected by PND 14 but considerably expressed from PND 28 onward. EST immunoreactivity was moderate in the interstitium by PND 14. Strong EST immunoreactivity was found in the interstitium from PND 28 onward. In ERαflox/flox Cyp17iCre mouse testis and Leydig cells, EST mRNA level was significantly lower than wild type (ERαflox/flox). In primary adult Leydig cell culture, the expression of EST mRNA was increased by E2 and PPT, but was not changed by DPN. The expression of EST in the testis is developmentally regulated. In adult Leydig cells, EST could play an important role in the steroidogenesis by modulating the activity of estrogens. Estrogen as well as LH and androgen may play a role in the regulation of EST expression in Leydig cells via ERα signaling.

Testicular expression of CLDN11 (claudin-11), a tight junction protein was examined together with spermatogenesis and circulating testosterone levels in Korean soft-shelled turtle (Pelodiscus maackii). Spermatogenesis started during the breeding season in May and peaked in August when the breeding season ended. Spermiation started in July and peaked in October, showing the typical pattern of spermatogenesis in temperate zone reptiles. Deduced amino acid sequences of P. maackii CLDN11 was highly homologous to those of avian and mammals, suggesting the conserved nature of CLDN11 in amniotes. During the non-breeding season when the spermatogenesis was active and circulating testosterone levels elevated, testicular CLDN11 mRNA and protein (19kDa) levels were high. Strong, wavy CLDN11 immunoreactive strands run parallel to basement membrane in the basal part of the seminiferous epithelium, delaminating the spermatogonia and early spermatocytes in the open compartment. Otherwise, CLDN11 was found beneath the early spermatocytes and in the Sertoli cell cytoplasm perpendicular to basement membrane. In double labeling experiment, punctate ZO-1 immunoreactivity was found within the CLDN11 strands run parallel to the basement membrane as well as at the most periphery of seminiferous epithelium where ZO-1 and CLDN11 in Sertoli cells were mostly cytoplasmic and perpendicular to basement membrane. Together, recruit of CLDN11 and ZO-1 to the inter-Sertoli TJs was tightly coupled with spermatogenic stage. At the breeding season when the circulating testosterone levels and spermatogenic activity remained low, testicular CLDN11 mRNA and protein levels were low. CLDN11 was found at apicolateral contacts between adjacent Sertoli cells devoid of the postmeiotic germ cells, suggesting that CLDN11 between adjacent Sertoli cells also participates in the maintenance of seminiferous lumen. In P. maackii testis, CLDN11 as a structural element of the blood-testis barrier dynamically changed according to spermatogenic activity and circulating androgen levels. This is the first study on the CLDN TJs at the BTB in reptilian testis.

Ultrastructural characteristics of the germ cells and accessory cells in testis during spermatogenesis and taxonomic values of mature sperm morphology of Ruditapes philippinarum were investigated by the transmission electron microscope and scanning electron microscope observations. The testis is the diffuse organ that consists of branching acini containing developing germ cells and accessory cells associated with spermatogenesis. The morphology of the spermatozoon is of the primitive type and is somewhat different to those of other bivalves. The morphologies of the sperm nucleus type and the acrosome shape of this species have a cylinderical type and a modified cone shape, respectively. As some ultrastructural characteristics of the acrosomal vesicle, the peripheral parts of two basal rings show electron opaque part, while the apex part of the acrosome shows electron lucent part. These characteristics of sperm belong to the family Veneridae in the subclass Heterodonta, unlike a characteristic of the subclass Pteriomorphia showing all part of the acrosome being composed of electron opaque part. In particular, a cylinder-like nucleus of the sperm is curved. The spermatozoon is approximately 48-51 μm in length, including a long acrosome (about 2.40 μm in length), a curved sperm nucleus (about 3.40 μm in length), and a tail flagellum. The axoneme of the sperm tail shows a 9+2 structure.

Nesfatin-1/NUCB2, which is secreted from the brain, is known to control appetite and energy metabolism. Recent studies have been shown that nesfatin-1/NUCB2 was expressed not only in the brain, but it was also expressed in the gastric organs and adipose tissue. However, little is known about the expression of nesfatin-1/NUCB2 in the male reproductive system. Therefore, we examined whether the nesfatin-1/NUCB2 and its binding site exists in the male reproductive organs. Nesfatin-1/NUCB2 mRNA and protein were detected in the mouse testis and epididymis by PCR and Western blot analysis. As a result of the immunohistochemistry staining, the nesfatin-1 protein was localized at the interstitial cells and Leydig cells in the testis. Nesfatin-1 binding sites were also displayed at boundary cells in the tunica albuginea. Furthermore, in order to examine if the expression of nesfatin-1/NUCB2 mRNA in the testis and epididymis were affected by gonadotropin, its mRNA expression was analyzed after PMSG administration into mice. NUCB2 mRNA expression levels were increased in both of the testis and epididymis after PMSG administration. These results demonstrated for the first time that nesfatin-1 and its binding site were expressed in the mouse testis and epididymis. In addition, nesfatin-1/NUCB2 mRNA expression was controlled by gonadotropin, suggesting a possible role of nesfatin-1 in the male reproductive organs as a local regulator. Due to this, further study is needed to elucidate the functions of nesfatin-1 on the male reproductive system.

Sex steroid hormones are key molecules to prepare the decidual response and their levels are important in this process. Imbalances of the levels of steroid hormones are cause of implantation failure and other diseases including physical weakness. Androgen replacement therapy or selective androgen receptor modulator are used to overcome various diseases but long-term use may cause of side effects. In previous report, it is suggested that the steroid hormonal complexes derived from pig enhance the proliferation of satellite cell. Therefore, to evaluate the possible usage of steroid hormonal complex derived from pig testis (tS-C), the effects of tS-C on uterine response were studied using the model of artificial decidua. tS-C did not disturb the rhythmical estrus cycle. Artificial-induced decidual response was normally induced in tS-C administered mice. The histological characters of the decidua of tS-C administered mice were not different from the vehicle. The expression patterns of molecular markers of decidua were not different between vehicle and tS-C group. Collectively these results suggested that tS-C does not disturb the uterine responsibility to the embryo. In addition, our results suggested that tS-C can be applied to overcome the various problems such as loss of muscle mass and anemia.

최근 고장성(20%) 생리식염수를 흰쥐 정소에 직접 주사할 경우, 혈중 테스토스테론 수준이 최저 수준에 도달하는 화학적 거세 상태에 들어감이 보고되었다. 본 연구는 이러한 간단한 생리 식염수 주사 모델의 효용성을 더 검증하기 위해 정소의 미세 해부 구조상의 변화를 조사하였다. 실험군으로는 무처리군(intact, control), 정소제거군(orchidectomy), 그리고 식염수 주사군(saline-injection)으로 하였으며, 식염수 주사군에는 정소당 750 ㎕의 멸균한 20% 식염수를 직접 주사하였다. 정소 제거 수술은 식염수 주사가 행해진 날에 시행하였다. 주사후 30일 경과 후에 동물을 희생하여 생식조직들을 채취하고 무게를 측정한 후 조직학적 조사를 위해 고정시켰다. 체중의 경우 무처리 대조군과 비교하여 정소절제군과 식염수 주사군 모두에서 유의한 변화는 없었다. 식염수 주사군의 정소 무게는 무처리 대조군에 비해 유의하게 감소하였다. 부정소와 저정낭의 무게의 경우 무처리 대조군에 비해 정소절제군과 식염수 주사군 모두에서 유의하게 감소하였으며, 전립선의 경우 무처리 대조군에 비해 정소절제군에서는 유의하게 감소하였으며, 식염수 주사군에서는 감소하는 경향은 있었지만 유의성은 없었다. 외양상으로 식염수 주사군의 정소에는 약간의 위축이 나타났으며, 백막이 정상적으로 보였다. 그러나 조직학적으로 정소 대부분에서 괴사가 발견되었으며, 헤마톡실린-에오신으로 거의 염색되지 않았다. 동일한 절편에서, 주사 부위의 정반대 부분은 비정상적인 세포층들이 염색되었다. 대부분의 세정관에서 미성숙한 생식세포들이 기질 막에서 분리되고, 내강 쪽으로 세포들이 떨어져 나간 것이 확인되었다. 본 연구는 정소내 고장성 식염수 직접 주사가 부속 생식기관에 정소절제와 유사한 테스토스테론 제거 효과를 유발할 수 있음을 확인하였다. 비록 심층적인 연구들이 더 요구되지만, 본 연구는 정소 내 고장성 식염수 직접 주사법이 비용이 덜 들고 덜 침습적이면서 정소절제술이나 화학적 거세와 거의 동일한 효용성을 가졌음을 시사한다.

Sperm specific non selective cation (CatSper) channels belong to the CatSper family of genes and are expressed only in sperm and testis. In general, gene expression profiles in the brains of humans and mice share the highest similarity with those in testis. Therefore, to identify whether CatSper genes are expressed in the mouse brain, we performed reverse transcriptase-polymerase chain reaction (RT-PCR) and Western blotting. RT-PCR detected all four CatSper mRNAs in both the testis and the brain, with CatSper3 being the most highly expressed. Consistent with RT-PCR data, Western blot analysis showed that CatSper3 was expressed in the brain. We cloned CatSper3 variant 2 from eight-week mouse brain. We named the gene as CatSper3 variant 1 (V1) because the mouse CatSper3 is orthologous to human CatSper3, and another mouse CatSper3 variant (variant 2, V2) with truncated second transmembrane helix was identified. The open reading frame of mCatSper3 V1 consists of 1185 nucleotides and encodes a putative 395-amino acid protein. At the amino acid level, CatSper3 isolated from brain is 100 and 64.8% identical to that isolated from mouse testis and human CatSper3, respectively. Based on comparison between the mCatSper3 V1 ORF and mCatSper3 V2 using TopPred software, the alignment of amino acid sequences shows that the differences exist mainly in segment 2. The CatSper3 transcript consists of eight exons and seven introns, and alternative splice is present within the third exon. In HT22 cell, a mouse hippocampal neuronal cell line, H2O2-induced changes in CatSper3 expression were studied. H2O2 dramatically increased CatSper3 expression in HT22 cells in a dose-and time-dependent manner. The H2O2-induced increase in CatSper3 expression was offset by the addition of N-acetylcysteine (NAC), which is an antioxidant. Taken together, these data strongly indicate that CatSper3 is expressed in mouse brain as variant 1 and suggest that CatSper3 could be a potential target for the modulation of ROS.

망간은 정소 독성을 나타내며, 뇌기저핵에 작용하여 혈청 프로락틴의 농도를 증가시킨다. 그리고 혈청 프로락틴 농도 상승에 의한 과프로락틴혈증(hyperprolactinemia)은 정소의 정자 생성을 억제한다. 본 연구에서는 망간의 전신 노출이 흰쥐 정소의 정자 생산과 혈청 프로락틴 농도에 미치는 영향을 조사하기 위하여 실험동물을 대조군 과 망간 노출군 (Mn )으로 나누고, 노출군은 다시 노출 기간에 따라 4주와 13주 노출군 등 4군으로 분류하였다(n=

짱둥어 정자의 미세구조 및 정자형성과정에 관한 연구를 하였다. 정소는 정자낭으로 구성되어 있으며 얇은 막으로 둘러싸여 있었다. 정자낭은 여러 발생단계의 정자들을 포함하고 있으며, 정자낭의 내강에는 다수의 정자들이 위치하고 있었다. 정소의 외막은 상피층, 콜라겐층, 근양체(myoid tissue)등으로 구성되어 있었다. 근양체는 정소 안쪽까지 연결되어서 정자낭 사이의 간질조직의 주요 구성체였다. 게 다가 핵과 다수의 미코톤드리아를 포함한 간세포(inter

In an effort to uncover the spermatogenic impairment by the polychlorinated biphenyls (PCBs), the expression of tight junctions (TJs) genes important for the formation of the blood testis barrier (BTB) were examined following the 3,3',4,4',5-pentachloro biphenyl (PCB126) treatment in cultured neonatal testis in mice. At 4 days (D4) after 10 and 100 nM PCB126 treatment the expression of claudin-11 was significantly increased when compared with vehicle control. In contrast no difference in occludin and claudin-1 expression was found among the experimental group. On D8, 100 nM PCB126 significantly increased the expression of claudin-11 but not occludin and claudin-1. 1 uM PCB126 treatment significantly decreased expressions of occludin and ciaudin -1, suggesting the general toxic effect on the Sertoli cell. Because PCB126 does not alter the proliferative activity of spermatogenic cells and Sertoli cells in neonatal testis, it is likely that increase in the expression of claudin-11 by low dose of PCB126 may attribute to the alteration of the Sertoli cells differentiation in testis. It also emphasized that PCB126 might have differentially affected the transcription of TJ genes in Sertoli cells. In conclusion, this result suggests that the structure of TJ may be targeted by PCB126 in neonatal testis in mice and that co-PCB is potentially harmful to spermatogenesis by alteration of the development of BTB.