Sirtuin-1(Sirt1)은 NAD+ dependent deacetylase로써 유전자 침묵, 포도당과 지질대사, 세포자살 등 다양한 cellular process에 연관되어 있다. 최근 이뤄진 여러 연구에서 Sirt1 Knockout mouse가 정자형성 장애와 불임증상을 가진다는 것이 보고되었다. Egr1(Early Growth Response 1)은 Egr family에 속하는 전사인자로서 mitogenesis와 differentiation에 필요한 유전자들의 전사를 활성화시킨다. 또한 이는 Sirt1의 전사를 조절하는 것으로 알려져 있다. 본 연구에서는 생쥐 정소 내에서 Egr1의 유무에 의한 Sirt1의 발현 수준 차이를 밝히고자 Egr1 knockout mouse와 wild type mouse를 이용하여 Sirt1의 발현패턴을 분석하였다.
Sirt1의 발현을 분석하기 위하여 Quantitative RT-PCR과 conventional RT-PCR을 이용하여 각각 ICR strain adult male mice와 Egr1 Knockout adult male mice의 testicular cDNA에서 mRNA 수준에서 Sirt1의 발현수준을 분석하였다. 또한 Immunohistochemistry를 이용하여 Sirt1단백질의 localization을 분석하였다.
분석한 결과, Wild type과 Egr1 Knockout mouse의 정소 내에서 Sirt1 mRNA의 발현 수준은 큰 차이를 보이지 않았으나, Egr1 Knockout mouse의 정소 내에서 Sirt1 단백질의 발현수준은 wild type과 비교하여 현저히 떨어졌으며, 이 변화는 특히 pachytene spermatocyte에서 큰 차이를 보였다. 반면, Sertoli cell에서는 Pachytene spermatocyte에서만큼 뚜렷한 차이를 관찰할 수 없었다.
본 연구에서 얻은 결과를 바탕으로 Egr1이 pachytene spermatocyte에서 Sirt1 단백질의 발현에 중요한 역할을 할 것이라는 결론을 얻을 수 있었다. Sirt1 Knockout mouse가 불임 증상을 보이며, 정자형성에 장애가 있는 반면, Egr1 KO mouse는 정상적인 생식능력을 가짐으로 보아 premeiotic 또는 meiotic stage에서의 Sirt1 결핍이 이러한 infertility의 원인이 될 것으로 추측된다.
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) is an inducible zinc finger transcription factor. Egr1 binds specific GC-rich region. Egr1 mRNA is rapidly and transiently expressed in pre-ovulatory follicles by LH and expressed in decidual cell by estrogen. Progesterone receptor (PR) is a nuclear transcription factor that is induced in granulosa cells of pre-ovulatory follicles following the LH surge. PR regulates ADAMTS1, which downstream gene of PR. In previous study, we observed ADAMTS1 mRNA expression pattern changed in Egr1 KO mice. Therefore, we expected that progesterone receptor gene expression is directly regulated by early growth response 1 in mouse ovarian granulosa cell. We could found the ER binding domain, Egr1 binding domain and CAAT box in PR promoter using the web tool AliBaba 2.1. We construct the PR promoter vectors truncated ER binding domain, Egr1 binding domain, CAAT box, respectively. We also construct the Egr1 expression vector using pcDNA 3.1 (+) vector. Granulosa cells are isolated from female ICR mice after 12h PMSG injection. To confirm the Egr1 overexpression, we performed western blot. For reporter assay, we used Dual-Luciferase reporter assay system. In conclusion, Egr1 may regulate PR expression in granulosa cell.
The early growth response protein 1 (Egr-1) is a widely reported zinc finger protein and a well known transcription factor encoded by the Egr-1 gene, which plays key roles in many aspects of vertebrate embryogenesis and in adult vertebrates. The Egr-1 expression is important in the formation of the gill vascular system in flounders, which develops during the post-hatching phase and is essential for survival during the juvenile period. However, the complete details of Egr-1 expression during embryo development in olive flounder are not available. We assessed the expression patterns of Egr-1 during the early development of olive flounders by using reverse transcription polymerase chain reaction (RT-PCR) analysis. Microscopic observations showed that gill filament formation corresponded with the Egr-1 expression. Thus, we showed that Egr-1 plays a vital role in angiogenesis in the gill filaments during embryogenesis. Further, Egr-1 expression was found to be strong at 5 days after hatching (DAH), in the development of the gill vascular system, and this strong expression level was maintained throughout all the development stages. Our findings have important implications with respect to the biological role of Egr-1 and evolution of the first respiratory blood vessels in the gills of olive flounder. Further studies are required to elucidate the Egr-1-mediated stress response and to decipher the functional role of Egr-1 in developmental stages.
The transcription factor, early growth response protein 1 (EGR1), act as immediate early response genes to control various cellular and reproductive events. Egr1-deficient female mice show infertility by anovulation resulting from luteinizing hormone-β (LH-β) subunit deficiency. While ovulation, fertilization and embryo development normally occur in Egr1-deficient mice treated with a superovulation regime to rescue LH deficiency, embryo implantation was completely failed. The morphology and ultrastructure of uterine tissues were observed by light and transmission electron microscopy during the peri-implantation period in Egr1-deficient mice. To examine alterations in cellular organelles, the uterine horns were fixed with 2.5% glutaraldehyde and postfixed with 1% osmium tetroxide in PBS. After dehydration and infiltration, the samples were embedded in Epon 812. Semi-thin sections 0.5 μm thick were cut with an ultramicrotome and stained with toluidine blue for light microscopy. Thin sections were cut with a diamond knife of the ultramicrotome and placed on copper grids. The sections were double stained and examined under a transmission electron microscope. The height of luminal epithelial cells was decreased and the polarity was poorly differentiated in the Egr1-deficient comparing to the wild mice. The abundant mucinous materials were observed in the surface of luminal epithelial cells of the Egr1-deficient. It was confirmed the microarray and real time qPCR data. The luminal epithelial cells of wild mice had many dense lipophilic granules and healthy mitochondria, but not in the Egr1-deficient. It may related to production and secretion of steroid hormones and prostaglandins in the luminal epithelial cells for successful implantation. These results show that Egr1 is a critical transcription factor to fine-tune subcellular morphological and functional changes for the receptive phase of peri-implantation period of uterine tissue in mice.
Early growth response 1 (Egr1) is a zinc-finger transcription factor to direct second-wave gene expression leading to cell growth, differentiation and/or apoptosis. While it is well-known that Egr1 controls transcription of an array of targets in various cell types, downstream target gene(s) whose transcription is regulated by Egr1 in the uterus has not been identified yet. Thus, we have tried to identify a list of potential target genes of Egr1 in the uterus by performing multi-step in silico promoter analyses. Analyses of mRNA microarray data provided a cohort of genes (102 genes) which were differentially expressed (DEGs) in the uterus between Egr1(+/+) and Egr1(–/–) mice. In mice, the frequency of putative EGR1 binding sites (EBS) in the promoter of DEGs is significantly higher than that of randomly selected non-DEGs, although it is not correlated with expression levels of DEGs. Furthermore, EBS are considerably enriched within –500 bp of DEG’s promoters. Comparative analyses for EBS of DEGs with the promoters of other species provided power to distinguish DEGs with higher probability as EGR1 direct target genes. Eleven EBS in the promoters of 9 genes among analyzed DEGs are conserved between various species including human. In conclusion, this study provides evidence that analyses of mRNA expression profiles followed by two-step in silico analyses could provide a list of putative Egr1 direct target genes in the uterus where any known direct target genes are yet reported for further functional studies.
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.
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.
Estrogen is a primary steroid hormone to govern cell fates in the endometrium. It induces expression of a spectrum of genes such as early growth response 1 (Egr1) critical for dynamic change of uterine environments for embryo implantation. Egr1 belongs to the Egr family of zinc finger transcription factors consisting of 4 members (Egr1 to Egr4) that are co-expressed in many different tissues, suggesting that they may have some redundant functions. Bisphenol A (BPA) is a well-known endocrine disruptor with potent estrogenic activity on reproductive system. Here we have demonstrated molecular pathway(s) by which estrogen (17β estradiol, E2) and BPA regulates Egr1 in uterus. Eight-week-old female mice were ovariectomized (OVX) and rested for a week. Uteri of OVX mice treated with E2, BPA and/or progesterone (P4) were collected 2 h after hormone treatment unless otherwise indicated. ICI 182,780 [estrogen receptor (ER) antagonist] and RU486 [progesterone receptor (PR) antagonist] were pretreated 30 min before hormone treatment. Collected uteri were mainly utilized for RT-PCR, realtime-RT-PCR and Western blotting. Egr1 mRNA was rapidly induced with the highest level at 2h after E2 treatment and gradually decreased to basal levels at 12 h. Pretreatment of ICI 182,780 effectively inhibited E2-induced phosphorylation of ERK1/2 and AKT as well as Egr1 transcription. U0126 (a pharmacological ERK1/2 inhibitor), but not Watmannin (a AKT inhibitor), significantly blocked E2-induced Egr1 expression as well as ERK1/2 phosphorylation in the uterus. P4 effectively dampened E2-dependent Egr1 transcription, and its antagonistic effects were partially interfered with RU486 pretreatment. Interestingly, Egr2 and Egr3 showed similar hormone-dependent expression profiles to that of Egr1 in the uterus. BPA (100 mg/kg) was able to induce immediate expression of Egr1 as effective as E2 at 2 h after treatment. ICI 182,780 and P4 considerably reduced BPA-induced expression of Egr1. In addition, RU486 counteracted inhibitory action of P4 on BPA-induced expression of Egr1. While overall patterns of BPA- induced expression of Egr2 and Egr3 were similar to that of Egr1, BPA was not as effective as E2 for induction of Egr2 and Egr3. BPA could induce phosphorylation of ERK1/2 as well as expression of Egr family members, too. Collectively, these results strongly suggest that BPA as well as E2 can activate concurrent expression profiles of Egr family members via ER-ERK1/2 pathways in the uterus.
Early growth response 1 (Egr1) is an immediate early response gene which is induced by various external stimuli and acts as transcription factor to direct second-wave gene expression leading to cell growth, differentiation and/or apoptosis. It is well known that Egr1 regulates transcription of a cluster of genes in cancers and luteinizing hormone (LH) beta subunit in the pituitary. In addition to function of Egr1 in cancers and pituitary, we recently showed that Egr1 acts as a local master regulator to mediate estrogenic actions in the uterus. However, regulatory mechanism by which Egr1 directs transcription of its downstream target genes in the uterus remains to be yet explored. Thus, we have tried to identify direct target genes of Egr1 in the uterus by analyzing mRNA microarray data sets followed by in silico promoter analyses with chromatin immunoprecipitation (CHIP). mRNA expression profiles of Egr1(-/-) uteri and Egr1(-/-) ovaries were compared to those of wildtype mice to provide a potential list of direct target genes of Egr1 in the uterus. Whereas Egr1 is rapidly and transiently induced in the ovary and the uterus by external stimuli, LH and estrogen, respectively with a similar manner, a list of differentially expressed genes between Egr1(+/+) and Egr1(-/-) mice were barely overlapped between these two datasets. This result suggests that the transcriptional network of Egr1 in the uterus is quite different from that in the ovary. The list of differentially expressed genes in Egr1(-/-) uterus was enriched by RT-PCR. In silico analyses with MatInspector provided evidence that Egr1 binding sites are relatively enriched in -500 bp promoter regions of genes in the list. CHIP assays for Egr1 antibody with uterine tissues 2 h after estrogen treatment reinforced the possibility that genes identified in this study such as Gadd45g and Lbh could be directly regulated by Egr1 in uterine context. Collectively, we show that bioinformatic analyses of expression profiles with in silico analyses could be a useful tool to enrich potential candidates of direct target genes of transcription factors.
Early growth response 1 (Egr1) belongs to the Egr family of zinc finger transcription factors 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 a critical factor to regulate transcription of LHβ in the pituitary gland, function of Egr1 and mechanisms by which estrogen (E2) and/or progesterone (P4) regulates Egr1 in uterus still remain unexplored. Using multiple approaches, here we have characterized regulatory mechanism of Egr1 induction in the uterus and uterine phenotypes of Egr1(-/-) mice. Eight-week-old female mice were ovariectomized (OVX) and rested for a week. Uteri of OVX mice treated with various concentrations of E2 and/or other hormones were collected at 2h after hormone treatment unless otherwise indicated. Collected uteri were utilized for mRNA microarrays, realtime-RT-PCR, Western blotting, and histological analyses for immunofluorescence and BrdU staining. Egr1 mRNA was rapidly induced with the highest level at 2h after E2 treatment and gradually decreased to basal levels at 12 h. E2-induced phosphorylation of ERK1/2 and AKT, and Egr1 transcription were effectively inhibited by pretreatment of ICI 182,780. Pharmacological inhibition of ERK1/2, but not AKT significantly blocked E2-induced Egr1 expression in the uterus. P4 effectively dampened E2-dependent Egr1 transcription and its antagonistic effects were partially interfered with RU486 pretreatment. Interestingly, 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 OVX Egr1(-/-) mice treated with E2+P4, stromal cell proliferation is severely impaired and epithelial cells persistently proliferating. While ovulation, fertilization and embryo development normally occur in Egr1(-/-) mice treated with a superovulation regime to rescue LH deficiency, embryo implantation is severely impaired. Blastocysts were not able to implant even on day 6 of pregnancy in Egr1(-/-) mice. In addition to embryo implantation, uterine response to artificial decidualization in hormone-primed Egr1(-/-) OVX mice was relatively less than that of wildtype mice. Collectively, our results show that Egr1, which is rapidly induced by E2-ER-ERK1/2 pathways, is a critical factor to control E2-dependent cell proliferation via regulation of a spectrum of genes for embryo implantation in the uterus.
The Egr family of zinc finger transcription factors consisting of 4 members (Egr1 to Egr4) regulates critical genetic programs involved in cellular growth, differentiation, and function. They are co-ex-pressed in many different tissues, suggesting that they may have some redundant functions. While it is clear that estrogen regulates Egr1 in estrogen sensitive breast cancer cells, function of Egr1 and mechanisms by which estrogen (E2) and/or progesterone (P4) regulates Egr1 in uterus still remain unexplored. Thus, we have examined regulatory mechanisms by which Egr1 is regulated in the uterus and abnormal uterine phenotypes of Egr1(-/-) mice. Eight-week-old female mice were ovariectomized (OVX) and rested for a week. Uteri of OVX mice treated with various concentrations of E2 and/or other hormones were collected at 2 h after hormone treatment unless otherwise indicated. ICI 182,780 [estrogen receptor (ER) antagonist] or RU486 [progesterone receptor (PR) antagonist] was injected to OVX mice 30 min prior to hormone treatments. OVX Egr1(+/+) and Egr1(-/-) mice were treated with E2 and/or P4 to examine expression patterns of genes important for estrogen responses, and steroid hormone-induced cell proliferation in the uterus. Collected uteri were utilized for RT-PCR, realtime RT-PCR, Western blotting and histological analyses. Egr1 mRNA was rapidly induced with the highest level at 2h after E2 treatment and gradually deceased to basal levels at 12 h. Pretreatment of ICI 182,780 significantly reduced E2-induced increase of Egr1. However, an agonist for GPR30, a membrane estrogen receptor failed to induce mRNA expression of Egr1, suggesting that E2-dependent Egr1 transcription is mainly regulated via nuclear estrogen receptor, ER. P4 effectively dampened E2-dependent Egr1 transcription and its antagonistic effects were partially interfered with RU486 pretreatment. Histological analyses with BrdU incorporation experiments showed that vascular permeability (an early estrogen response) but not cell proliferation (a late response) was significantly impaired in the uteri of E2 treated OVX Egr1(-/-) mice. Interestingly, some genes involved in early estrogen responses such as Bip and HIF-1a but not those in late responses are dysregulated in uteri of Egr1(-/-) mice. Collectively, our results show that E2 transiently induces Egr1 via activation of nuclear ER. P4 antagonizes E2-dependent Egr1 regulation via PR. Impaired early estrogenic responses in Egr1(-/-) uteri could be due to aberrant gene expression affected by loss of Egr1 which act as a master regulator of estrogen actions in the uterus.-ex
The amphetamine derivative 3,4-methylenedioxymethamphetamine (MDMA) is a potent monoaminergic neurotoxin with the potential to cause serotonergic neurotoxicity, but has become a popular recreational drug. Little has been known about the cellular effects induced by MDMA. This report shows that MDMA inhibits neuronal cell growth and differentiation. MDMA suppressed neuronal cell growth. The results of quantitative real-time PCR analysis showed that Egr-1 expression is elevated in mouse embryo and neuroblastoma cells after MDMA treatment. Transiently transfected Egr-1 interfered with the neuronal differentiation of neuroblastoma cells such as SH-SY5Y and PC12 cells. These findings provide evidence that the abuse of MDMA during pregnancy may impair neuronal development via an induction of Egr-1 over-expression.