Effects of 17 beta-estradiol and growth factors on c-fos gene expression in endometrial epithelial cells in primary culture

Low expression of GABARAPL1 is associated with a poor outcome for patients with hepatocellular carcinoma

Autophagy is an evolutionarily conserved cellular process that degrades cytoplasmic materials through the lysosomal pathway. The deregulation of autophagy is associated with several diseases, particularly cancer. Hepatocellular carcinoma (HCC) is one of the most aggressive cancers with a poor prognosis. The expression of autophagy-related genes in HCC and their relationships with HCC are largely unknown. In the present study, we analyzed the expression of autophagy-related genes based on the Oncomine database and quantitative PCR of HCC and adjacent liver tissues. We found that the mRNA and protein expression of GABARAPL1 was significantly decreased in HCC tissues compared with their adjacent liver tissues. In HCC cancer cell lines, overexpression of GABARAPL1 inhibited cell growth, while knockdown of GABARAPL1 expression via siRNA promoted cell growth. In addition, we found a significant correlation of low GABARAPL1 expression with poor differentiation of HCC cells (P=0.018), and with the absence of tumor capsules (P=0.047). Kaplan-Meier survival analysis showed a significant association between low GABARAPL1 expression and poor prognosis of HCC patients (P=0.0094). Our data showed for the first time that GABARAPL1 expression is associated with poor prognosis of HCC patients.

Onset of direct 17-β estradiol effects on proliferation and c-fos expression during oncogenesis of endometrial glandular epithelial cells

In normal endometrial glandular epithelial cells (GEC), 17beta-estradiol (E2) enhances proliferation and c-fos expression only in the presence of growth factors. On the contrary, growth factors are not required for the E2 effects in cancerous cells. Thus, a repression of E2 action could exist in normal cells and be turned off in cancerous cells, allowing a direct estrogen-dependent proliferation. To verify this hypothesis, we established immortalized and transformed cell models, then investigated alterations of E2 effects during oncogenesis. SV40 large T-antigen was used to generate immortalized GEC model (IGEC). After observation of telomerase reactivation, IGEC model was transfected by activated c-Ha-ras to obtain transformed cell lines (TGEC1 and TGEC2). The phenotypic, morphological, and genetic characteristics of these models were determined before studying the E2 effects. In IGEC, the E2 action on proliferation and c-fos expression required the presence of growth factors, as observed in GECs. In TGECs, this action arose in the absence of growth factors. After IGEC transformation, the activation of ras pathway would substitute the priming events required for the release of repression in GEC and IGEC and thus permit direct E2 effects. Our cell models are particularly suitable to investigate alterations of gene regulation by E2 during oncogenesis.

Neonatal diethylstilbestrol exposure induces persistent elevation of c-fos expression and hypomethylation in its exon-4 in mouse uterus

Perinatal exposure to diethylstilbestrol (DES) induces reproductive tract cancers later in life in both humans and animals. Because there is no clear evidence that perinatal DES exposure induces gene mutation, we proposed that perinatal DES exposure causes epigenetic methylation changes that result in persistent alterations in gene expression, leading to tumorigenesis. The proto-oncogene c-fos is one of the immediately induced genes in uterine epithelium after estrogen simulation and a key player in uterine carcinogenesis. Here, we investigated c-fos expression in mice neonatally exposed to DES (2 microg/pup/day on postnatal days 1-5). The mRNA levels of c-fos in uteri of neonatal DES-treated mice were persistently 1.4-1.9-fold higher than that in the control mice from day 5 to day 60. Overall, the uterine c-fos expression level in the neonatal DES-exposed group was significantly higher than that in the control group. After examination of the methylation status of the c-fos gene, we found that the CpGs in promoter and intron-1 regions were completely unmethylated. In exon-4, from day 17 to day 60, the percentage of unmethylated CpGs was higher in neonatal DES-exposed mice uteri than that in control (42%, 51%, 47%, and 42% in DES-exposed mice vs 33%, 34%, 33%, and 21% in control mice at day 17, 21, 30, and 60, respectively). These results suggest that perinatal DES exposure may permanently alter gene expression and methylation, and the methylation modification may occur in either the promoter regions or other regulatory sites in the gene.

Identification and expression of a new sulfhydryl oxidase SOx-3 during the cell cycle and the estrus cycle in uterine cells

Using differential hybridization of a guinea pig endometrial cell cDNA library, a potentially negatively estrogen-regulated gene, SOX-3, was isolated. According to the nucleotide and protein sequence similarities, SOx-3 belonged to the FAD-linked sulfhydryl oxidase family containing the egg white sulfhydryl oxidase, the rat seminal vesicle sulfhydryl oxidase-2 SOx-2, the quiescence-inducible protein hQ6. The SOX-3 transcript in the guinea pig as well as 5 different mRNAs in human tissues appeared differentially expressed in the tissues studied. In secondary endometrial cell culture, the SOX-3 mRNA level increased during a serum depletion-induced quiescence, decreased when cells enter the G1 phase after serum stimulation, and was restored during the S and G2/M phases. Thus, SOX-3 could be implicated in the negative cell cycle control. The SOx-3 protein appeared to be specific of epithelial cells in the uterus. Its expression level varied during the estrus cycle in the guinea pig, suggesting a regulation by steroid hormones.

Protooncogene c-fos Involvement in the Molecular Mechanism of Rat Brain Sexual Differentiation

Brain sexual differentiation is mediated through testosterone, which acts during the perinatal period in the form of both 5alpha-dihydrotestosterone and estradiol. In order to gain insight into the molecular mechanisms involved, we studied induction of c-fos, an index of functional neuronal activation, in the 2-day-old female rat brain after injection of a masculinizing dose of testosterone. Administration of testosterone resulted in induction of c-fos gene expression in the hypothalamus, as determined by Northern analysis. Following immunocytochemistry, we demonstrated an increase in the number of Fos-positive nuclei in the median and medial preoptic nucleus, the medial preoptic area extending to the lateral preoptic area, and the peri- and paraventricular area. In an effort to see whether testosterone acted as 5alpha-dihydrotestosterone or as estradiol, we injected either steroid and looked at fos induction. Estradiol mimicked the effect of testosterone, while 5alpha-dihydrotestosterone was without effect. Furthermore, injection of an estrogen receptor blocker, clomiphene, together with testosterone, abolished the testosterone-induced increase in Fos-positive nuclei, thus confirming the finding that testosterone induces c-fos by acting through estrogen receptors. Electrophoretic mobility shift assays showed that nuclear extracts from 2-day-old female hypothalamus contain a protein, most probably the estrogen receptor, which binds specifically to oligodeoxynucleotides with the sequence of either vitERE, the consensus estrogen-responsive element (ERE) found in the vittelogenin gene, or fosERE, the ERE found in the 3'-untranslated region of the mouse c-fos gene. This suggests that the effect of testosterone-derived estradiol on c-fos expression is a direct one, mediated by binding of estrogen receptors to an ERE in the c-fos gene-regulatory regions.

A Novel Early Estrogen-Regulated Gene gec1 Encodes a Protein Related to GABARAP

We have isolated, in guinea-pig endometrial cells, an estrogen-induced 1.8 kb RNA called gec1. Screening of a guinea-pig genomic library led to identification of gec1 gene consisting of 4 exons and 3 introns. Exon 1 contains the 5'UTR and the ATG initiation codon. A guinea-pig gec1 cDNA was obtained by 5'-RACE. The 351 bp coding sequence shares 76.8% identity with that of the human GABARAP 924 bp cDNA while UTRs of the two cDNAs differ. A gec1 probe from the 3'UTR revealed a 1.9 kb mRNA in human tissues and a human GEC1 cDNA was isolated from placenta. Its coding sequence shares 93 and 79% identity with that of guinea-pig gec1 and human GABARAP, respectively. The human and guinea-pig GEC1 proteins have 100% identity. GEC1 and GABARAP proteins have 87% identity and N terminus featuring a tubulin binding motif. Thus, estrogen-regulated gec1 is a new gene which could encode a microtubule-associated protein.

ERE environment- and cell type-specific transcriptional effects of estrogen in normal endometrial cells

Our previous results have suggested a repression of E2 (17beta-estradiol) effect on the c-fos gene of cultured guinea-pig endometrial cells. To investigate this repression, the expression of three human c-fos gene recombinants, pFC1-BL (-2250/+41), pFC2-BL (-1400/+41) and pFC2E (-1300/-1050 and -230/+41), known to be E2-responsive in Hela cells, was studied in stromal (SC) and glandular epithelial cells (GEC). In both cellular types, pFC1-BL was not induced by E2, even in the presence of growth factors or co-transfected estrogen receptor. The pattern of pFC2-BL and pFC2E expression was strikingly different and depended on the cellular type: pFC2-BL and pFC2E induction was restricted to the glandular epithelial cells and did not occur in the SCs. We argue for a repression of E2 action which is dependent on the estrogen-responsive cis-acting element (ERE) environment and also cell type-specific involving DNA/protein and/or protein/protein interactions with cellular type-specific factors.

c-fos- and c-jun-like mRNA expression in frog (Rana esculenta) testis during the annual reproductive cycle

The expression of c-fos and c-jun mRNA has been examined in the testis of a seasonal breeder (the frog, Rana esculenta) during the annual reproductive cycle, using Northern blot analysis along with measurements of plasma levels of estradiol-17 beta and androgens (testosterone + 5 alpha-dihydrotestosterone). A c-fos-like transcript of 1.9 kb was revealed using a 1.1-kb v-fos probe, while three different transcripts of 3.7, 3.4, and 2.7 kb were seen using 1.0-kb human (h)-c-jun fragment. The proto-oncogene-like mRNAs appear during the period of the year associated with the new wave of spermatogenic activity. The levels of fos-like mRNA were highest after the estradiol-17 beta peak, while low levels were concomitant with high androgen concentrations. It is concluded that there is a close correlation between c-fos- and c-jun-like expression and testicular activity in R. esculenta.

Immunohistochemical studies on the expression and estrogen dependency of EGF and its receptor and C-fos proto-oncogene in the uterus and vagina of normal and neonatally estrogen-treated mice

BACKGROUND

The final target cell response to estrogen is dependent not only on the estrogen receptor, but also on autocrine/paracrine interactions with growth factors (e.g., EGF) and proto-oncogenes (e.g., c-fos). Because neonatal estrogen treatment results in permanent changes in the female mouse genital tract (permanent vaginal cornification, cervical adenosis and tumors, changed growth control mechanisms in uterus), it was of interest to study possible acute and permanent effects of such treatment on distribution and levels of EGF, its receptor (EGF-r), and c-fos and to relate such changes to morphological development and appearance of epithelial abnormalities.

METHODS

Immunohistochemical techniques using frozen sections from the uterus and vagina of neonatal and adult (ovariectomized, estradiol-treated) females, treated with olive oil or diethylstilbestrol in neonatal life.

RESULTS

A difference in stromal-epithelial distribution of EGF was demonstrated with respect to region studied (uterus, vagina) and age (neonatal, adult). EGF was localized mainly in the uterine stroma but in both vaginal epithelium and stroma (with a different pattern compared to uterus). In neonatal females, EGF occurred in both tissue components in both regions, and the distribution pattern was quite different from that in adult females. The EGF level was increased by estrogen in adult but not in neonatal females. EGF-r and c-fos occurred in both uterine epithelium and stroma and in the vaginal epithelium; levels and distribution pattern were affected by estrogen. Neonatal estrogen treatment increased the levels of uterine EGF and c-fos in adult life.

CONCLUSIONS

There are distinct developmental changes in the distribution and estrogen sensitivity of EGF. Only further studies can prove or disprove the association between the earlier reported disturbed growth control mechanisms in the uterus of adult but neonatally estrogen-treated females and the increased levels of uterine EGF and c-fos. The present results do not seem to explain mechanisms involved in the origin of neonatally estrogen-induced cervicovaginal epithelial abnormalities, nor do they explain the earlier described difference in estrogen-induced proliferative response between the uterine cervix and uterus proper.

C-fos and c-jun expression in human endometrium and myometrium

Estrogen is a mitogen in human endometrium and is considered to be responsible also for myometrial cell proliferation. Signalling pathways of estrogen action in these tissues are not known. In various other estrogen responsive cells, estrogen induces transient expressions of c-fos and c-jun mRNAs. We examined c-fos and c-jun mRNA expressions by Northern blotting in paired samples of endometrium, myometrium and leiomyoma tissues obtained from women under various hormonal environments as well as of endometrium and myometrium at term pregnancy. In nonpregnant endometria, strong expressions of c-fos (2.2 kb) and of c-jun (2.7 kb and 3.2 kb) were detected both in the follicular and luteal phase of the menstrual cycle, and the c-fos expression was significantly stronger in proliferative phase endometrium than in the adjacent myometrium. In most of the myometrial and leiomyoma tissue samples the signals for both protooncogenes were weak, and there were no systematic differences in the expressions between normal myometrium and myomatous tissue. In pregnant endometrium and myometrium, both the c-fos and c-jun mRNA expressions were nearly undetectable, and in pregnant endometrium expressions were significantly lower than those in nonpregnant endometrium. Also in late pregnancy myometria, the expression of c-jun was significantly lower than in nonpregnant tissues. These data suggest that c-fos and c-jun activation may be a part of estrogen-induced signal transduction in the endometrium, and that in term pregnancy endometrium this signalling pathway is inhibited. Due to the strong expression of c-jun and c-fos both in the proliferative and secretory phase endometrium, it is likely that these protooncogenes are related to functions other than epithelial cell proliferation in human endometrium. The weak expressions of c-fos and c-jun in the myometrium and in leiomyomata suggest that signalling pathways mediating steroid hormone action in endometrium and myometrium are different.

Growth regulation of rabbit gastric epithelial cells and protooncogene expression

We recently developed a primary culture system for gastric epithelial cells from adult rabbits that allows the investigation of growth regulation at the cellular level. In this study, we demonstrated that epidermal growth factor (EGF), insulin, and dibutyryl adenosine 3',5'-cyclic monophosphate (dBcAMP) all stimulated cell proliferation. Insulin and dBcAMP potentiated the stimulation of cell proliferation by EGF, while transforming growth factor-beta 1 (TGF-beta 1) inhibited it. Expression of c-fos and c-myc was induced in response to the stimulation by these growth regulators, but the degree of expression did not necessarily correlate with the effects of these agents on cell proliferation. In conclusion, EGF, insulin, and dBcAMP were positive growth regulators, while TGF-beta 1 was a negative regulator in gastric epithelial cells. These growth modulators may exert their effects by distinct pathways from a standpoint of the expression of c-fos and c-myc.

Identification of the estrogen sensitive marker in human endometrial carcinoma RL95-2 cells

Estrogen exerts a variety of biological effects on human reproductive tissues. However, little is understood about the estrogenic effect on human endometrial cells in vitro. This study was designed to investigate estrogen action on c-myc and c-fos oncogenes and lactoferrin gene expression in human endometrial carcinoma RL95-2 cells. The results indicate that estrogen can induce c-myc oncogene expression in 4 h. Neither c-fos nor the lactoferrin messenger was detectable, nor could they be induced by estrogen. Transfection with human estrogen receptor expression vector to the RL95-2 cells does not restore the estrogen responsiveness. In addition to estrogen, epidermal growth factor (EGF) and tumor promoter 12-O-tetradecanoylphorbol 13-acetate (TPA) can also induce c-myc expression with no effect on c-fos or lactoferrin expression. Our data suggest that the c-myc oncogene in human endometrial carcinoma RL95-2 cells is the sensitive target gene for steroid hormone and growth factor action.

Identification and characterization of an early estrogen-regulated RNA in cultured guinea-pig endometrial cells

A cDNA library was prepared from quiescent guinea-pig endometrial glandular epithelial cells stimulated for 2 h with estradiol-17 beta (E2) in the presence of cycloheximide. It was screened by differential hybridization for estrogen-regulated sequences. Six recombinants containing E2-regulated sequences were identified. One of them, called gec1 was then characterized by Northern blot hybridization. The gec1 mRNA was 1,800 bases in size. A 2-fold increase in the gec1 mRNA level was achieved at 120 min after E2 treatment. The E2 action on gec1 gene required the presence of cycloheximide. The cloned gec1 cDNA was 1 kb in size. The sequence so far determined did not show similarity with well characterized genes. This is the first report on a cloned cDNA probe of early estrogen-induced mRNA in a primary culture of endometrial epithelial cells.

Role of local environmental factors in determining tissue-specific effects of estrogen: examination of uterine tissues transplanted to brain

Estrogen stimulates uterine epithelial cells to divide, but not estrogen-concentrating neurons in the adult brain. This effect correlates with recent evidence that estrogen can induce the expression of certain growth-related genes in uterus which are not directly induced by estrogen in the adult brain. The possibility that local diffusible factors play a major role in determining tissue-specific effects of estrogen was examined by transplanting uterine tissues into the brain, muscle and kidney of adult rats and then comparing the effects of estrogen on the incorporation of [3H]thymidine and the expression of Fos-, cdc2- and Rb-like immunoreactivity (IR) on native and transplanted uterine tissues, as well as in estrogen-concentrating regions of the brain adjacent to the uterine grafts. In native uteri, estrogen treatment stimulated Fos-, cdc2-, and Rb-like IR, as well as [3H]thymidine incorporation, within lumenal and glandular epithelial cells. All of these effects were estrogen responsive--no immunoreactive staining within uterine epithelial cells and no signs of epithelial cell proliferation were observed in the native uteri of non-estrogen-treated animals. When uterine tissues were transplanted to brain, Fos-, cdc2-, and Rb-like IR epithelial cells, as well as many [3H]thymidine-incorporating uterine epithelial cells, were observed in all estrogen-treated animals and in some non-estrogen-treated animals as well. Identical results were obtained when uterine tissues were transplanted to skeletal muscle, but not to kidney (in the kidney, transplanted epithelial cells expressed all four parameters but only in estrogen-treated animals, comparable to the native uterus). In contrast, estrogen did not stimulate cell division and did not induce Fos-, cdc2-, or Rb-like IR within estrogen-concentrating neuronal regions of the ventromedial hypothalamus. In addition, the presence of uterine tissue in the brain did not confer the ability of estrogen to stimulate any of these parameters within nearby, estrogen-concentrating regions. These data suggest that there are factors in brain and muscle which can allow uterine epithelial cells to divide in the absence of estrogen. There was no evidence of a diffusible factor in brain which inhibits uterine epithelial cell division, nor of a diffusible factor in uterus which can confer estrogenic stimulation of growth-related genes and cell division to central nervous system neurons. In addition, the data provide the first evidence for estrogen regulation of cdc2 and Rb expression in normal uterus.

Transfected endometrial cultured cells: a system to study gene-regulation by estrogens

Glandular epithelial (GE) and stromal cells were isolated from guinea-pig endometrium, cultured and subcultured separately. At the end of subculture, the purity of each cell population was higher than 95% and cells displayed a high level of estrogen receptors. Calcium phosphate transfection conditions were defined using a control plasmid containing the bacterial CAT gene driven by viral promoter and enhancer sequences. Transfection experiments were performed with other plasmids in which CAT gene was linked to different estrogen response elements (EREs) derived from those of vitellogenin genes. CAT activity was significantly increased by estradiol-17 beta treatment only when GE or stromal cells were transfected with plasmids containing EREs previously reported as functional EREs in other cell types. This induction was abolished by ICI 164,384 diethylstilbestrol was as effective as estradiol-17 beta for CAT induction and estradiol-17 alpha was ineffective. Transiently transfected endometrial cells in subculture are a suitable system to study the estrogen effect on gene regulatory elements.