Introduction of estrogen-responsiveness into mammalian cell lines.

We introduced estrogen responsiveness as a new characteristic into rat hepatoma, mouse Ltk- and human HeLatk-cells by transfecting the human estrogen receptor (ER) cDNA. To measure the estrogen response we used Xenopus vitellogenin gene A2 constructs linked to the bacterial CAT gene. Transient cotransfections of the ER cDNA and the vitellogenin gene-CAT constructs containing the estrogen responsive element (ERE) lead to a hormone dependent induction of CAT activity whereas cotransfected vitellogenin gene constructs lacking the ERE are not inducible. Stable transfections of ER cDNA into Ltk- cells give rise to cell clones that are estrogen responsive as shown by transfection of various vitellogenin gene-CAT constructs. These results prove that the transfected ER is biologically active and is sufficient to make a cell estrogen responsive.     

Hormonal regulation of vitellogenin genes: an estrogen-responsive element in the Xenopus A2 gene and a multihormonal regulatory region in the chicken II gene

Expression of the vitellogenin genes in avian and amphibian liver is regulated by estrogens. The DNA elements mediating estrogen induction of the various vitellogenin genes of chicken and Xenopus encompass one or more copies of a 13-mer palindromic sequence called the estrogen-responsive element (ERE). Here we show that upon incubation with the purified estrogen receptor (ER) from calf uterus the Xenopus vitellogenin A2 gene yields a DNase-I footprint over the ERE between -331 and -319. This element does not mediate the response to glucocorticoids or progestins in T47D cells. The three guanine residues in each half of the palindrome are protected against methylation by dimethylsulfate after incubation with ER, but not with glucocorticoid (GR) or progesterone (PR) receptors. In contrast, the chicken vitellogenin II gene exhibits multihormonal regulation by estrogens, progestins, and glucocorticoids in T47D and MCF7 cells. Regulation is mediated by the DNA region between -721 and -591 that contains four binding sites for hormone receptors, as demonstrated by DNase-I footprints and methylation protection experiments. The two distal and most proximal binding sites are recognized by ER, GR, and PR, whereas the central binding site is only bound by ER and GR. At suboptimal concentrations, estrogens and progestins or glucocorticoids act synergistically. In experiments using a DNA fragment containing an ERE adjacent to a glucocorticoid-responsive element/progesterone-responsive element, ER and PR bind synergistically to their corresponding sites, perhaps explaining the functional synergism of both hormones. Thus, two very different regulatory elements are used to mediate estrogen induction of related genes in chickens and amphibians.     

Synergism of closely adjacent estrogen-responsive elements increases their regulatory potential

Recent gene transfer experiments have shown that an estrogen-responsive DNA element (ERE) GGTCANNNTGACC mediates the estrogen inducibility of the Xenopus laevis vitellogenin A1 and A2 genes as well as the chicken vitellogenin II gene. We report here on experiments that explain the estrogen regulation of the Xenopus vitellogenin B1 and B2 genes. In these genes, two ERE homologues, which have only low, if any, regulatory capacity on their own, act synergistically to achieve high estrogen inducibility. Furthermore we show that synergism of EREs is most efficient, when the two elements are closely adjacent and that it is lost when the synergistic elements are separated by 125 basepairs. In-vitro estrogen receptor binding experiments indicate that co-operative binding of estrogen receptors to closely adjacent EREs is not essential for synergism of ERE homologues that have no intrinsic regulatory capacity. Functional synergism of EREs is observed in the human estrogen-responsive MCF-7 cell line as well as in mouse fibroblasts (Ltk-) cotransfected with estrogen receptor expression vectors. Even expression of a truncated receptor protein lacking 178 amino acid residues of the amino-terminal end allows synergism, suggesting that the amino-terminal end preceding the DNA-binding domain of the estrogen receptor is not required.     

Long-term effects of estrogen on avian liver: estrogen-inducible switch in expression of nuclear, hormone-binding proteins.

The stimulation of chicks or embryos with estrogen results in transient, hepatic expression of the vitellogenin gene, as well as long-term, propagatable alterations in the rapidity with which the gene can be reactivated. We examined the possibility that nuclear, type II estrogen-binding sites are involved in this long-term change in response characteristics. We demonstrate that the primary induction kinetics of type II sites in embryos and chicks correlated with the expression of the vitellogenin gene and that once their induction was triggered by estrogen, they accumulated, were propagated, and persisted for months after withdrawal of the hormone. We also show that their accumulation in the embryo was accompanied by prolonged expression of both the vitellogenin and very low-density apolipoprotein II genes, in the absence of elevated levels of type I receptor, and that the type II sites, like the classical receptor, appear to be preferentially associated with active or potentially active chromatin. Finally, we describe a regulatory mechanism, tested by computer modelling, that simulated the behavioral characteristics of these nuclear estrogen-binding sites and which may explain their role in mediating the long-term effects of estrogen.     

The Relationship of the Estrogen Receptor to the Induction of Vitellogenin in Chicken and Xenopus Liver

The mechanisms involved in the regulation of gene expression in eukaryote cells, although an area of active research, are still largely unknown. This is at least partly due to the lack of good experimental model systems. One type of system which is being exploited with some considerable success is the induction of proteins by steroid hormones. Studies on the effects of estrogen and progesterone on the synthesis of the egg white proteins in the chick oviduct, for instance, have yielded substantial insight into both the regulation of protein synthesis by steroid hormones [1] and the arrangement of the DNA sequences coding for these proteins [2, 3].
The need for other good inducible systems clearly exists and the induction of vitellogenin, the precursor of the major egg yolk proteins, by estrogen in the livers of the chicken and frog ( Xenopus laevis ) is one that is attracting increasing interest. In common with the chick oviduct, large amounts of a specific protein are synthesised in response to a well defined hormonal stimulus. However, the induction of vitellogenin also has the advantage that the response is not complicated by the extensive hyperplasia that follows estrogen treatment in the chick oviduct [4, 5] and that vitellogenin may be induced in vitro [6–11].
The aims of this review are first to discuss recent data on the induction of vitellogenin and vitellogenin mRNA both in vivo and in vitro and then to relate this data to the properties of the estrogen receptor, present in chicken and Xenopus liver, which is thought to mediate the induction of vitellogenin by estrogen.     

Regulation of reproduction- and biomarker-related gene expression by sex steroids in the livers and ovaries of adult female western mosquitofish (Gambusia affinis)

To assess the adverse toxicological effects of steroid hormones on western mosquitofish (Gambusia affinis), 180 adult females were exposed to individual or binary combinations of progesterone (1μg/L), testosterone (1μg/L) and 17β-estradiol (1μg/L) for eight days. The expression patterns of vitellogenin, estrogen receptor, androgen receptor, metallothionein, and cytochrome P450 1A genes in mosquitofish varied according to tissue as well as the specificity of steroids. Treatment by progesterone or testosterone alone inhibited target gene expression in the livers. The expression levels of both vitellogenin A and vitellogenin B mRNAs were up-regulated by17β-estradiol, and a parallel induction of estrogen receptor α mRNA expression was also observed in the livers. In addition, 17β-estradiol treatment alone suppressed androgen receptor α, metallothionein and cytochrome P450 1A mRNA expression in the livers. In general, multiple hormone treatments had different effects on target gene expression compared with corresponding hormone alone. The results demonstrate that steroid hormones cause multiple biological responses including the expression of vitellogenin, estrogen receptor and androgen receptor mRNA in the hormone signaling pathways and the expression of metallothionein and cytochrome P450 1A mRNA in the xenobiotic signaling pathway.     

Estrogen induces tissue specific changes in the chromatin conformation of the vitellogenin genes in Xenopus.

Nuclei from male Xenopus liver were digested extensively with DNase I and the residual amount of the four vitellogenin genes measured by hybridization with a moderate excess of vitellogenin cDNA. The saturation value was about twofold lower in chromatin isolated from liver cells of estrogen treated than from untreated males or from erythrocytes. Analyzing the disappearance of several defined restriction fragments specific for the A1 and A2 vitellogenin genes, after limited digestion with DNase I, suggested that the entire A1 and A2 vitellogenin genes are about twofold more sensitive to DNase I in chromatin of hepatocytes isolated from estrogen treated than from untreated males. Using the same assay no change in the DNase I sensitivity of the two vitellogenin genes in erythrocyte chromatin was observed. Analysis of the beta 1-globin and an albumin gene demonstrated that the DNase I sensitivity of these genes in both cell types is not altered by estrogen. All these data indicate that estrogen stimulation results in an increased DNase I sensitivity specific for the vitellogenin genes in hepatocytes.     

Quantitation of vitellogenin messenger RNA in the liver of male xenopus toads during primary and secondary stimulation by estrogen

From livers of estrogen-stimulated female Xenopus toads, large quantities of estrogen-induced, poly(A)-containing RNA could be isolated, showing the same characteristics as vitellogenin mRNA obtained from hormone-treated males.Using cDNA hybridization, vitellogenin mRNA was monitored in the cytoplasmic poly(A)-containing RNA of the liver of male toads during 13 days of primary and the initial phase of secondary stimulation with estrogen.During primary stimulation, low amounts of vitellogenin mRNA, not exceeding 0.18% of the cytoplasmic poly(A)-containing RNA, were first detected after 12 hr of hormone treatment, and vitellogenin mRNA was found to increase on the average to 34% of the cytoplasmic poly(A)-containing RNA on the seventh day of hormone treatment. After 3 days of primary stimulation, accumulation of vitellogenin mRNA leveled off, showing no significant increase in the cytoplasm up to 13 days of hormone treatment. As judged from incorporation of ³²PO₄ into blood plasma proteins of males during primary stimulation, vitellogenin was first detected after 1 day, and its synthesis was found to increase dramatically until the thirteenth day of hormone treatment. This implies that there is a coincidence between appearance and extent of synthesis of vitellogenin and the abundance of vitellogenin mRNA in the cytoplasm, but there is evidence that during later phase of primary stimulation (day 3–13), the increase in synthesis of vitellogenin cannot be attributed anymore to a significant accumulation of vitellogenin mRNA.In male Xenopus, estrogen-induced synthesis of vitellogenin is no more detectable 41 days after hormone injection, and the concentration of vitellogenin mRNA was found to be <0.03% of the cytoplasmic poly(A)-containing RNA. Secondary stimulation by estrogen of these animals results in an at least 30 fold faster accumulation of vitellogenin mRNA in the cytoplasm within the initial 12 hr of hormone treatment. This may explain the faster appearance of vitellogenin in the blood plasma.     

A retrovirus vector which transduces a functional estrogen receptor gene at high efficiency

A high titer retroviral vector containing the cDNA of human estrogen receptor (hER) was generated and used to transfer the hER gene into the rat 208F cell line. Southern blot analysis showed the integration of the provirus to be at a unique site and that the provirus was intact in the genome of recipient cells. The expression of the integrated hER gene in the infected rat cells was detected by Northern blot analysis and by a functional assay in which the hER gene product stimulated the production of a chloramphenicol acetyl transferase gene under the control of an estrogen-responsive element. These experiments demonstrate the feasibility of using a retroviral vector system to introduce a functional ER gene into cultured cells lacking this receptor.     

Estradiol and estrogen receptor-dependent stabilization of a minivitellogenin mRNA lacking 5,100 nucleotides of coding sequence.

We have developed a transfection assay to investigate the estrogen-mediated stabilization of cytoplasmic vitellogenin mRNA. A minivitellogenin (MV5) gene containing the 5' and 3' untranslated and coding regions but lacking 5,075 nucleotides of internal coding sequence was constructed. Cotransfection of the MV5 plasmid and a Xenopus estrogen receptor expression plasmid into Xenopus liver tissue culture cells yielded a 529-nucleotide MV5 mRNA, which was specifically stabilized by estrogen. MV5 mRNA exhibited the increased stability indicative of positive regulation when the estradiol-estrogen receptor complex was present and was not destabilized by unliganded estrogen receptor. Transfected estrogen receptor, estradiol, and 529 nucleotides of the 5,604-nucleotide vitellogenin B1 mRNA were sufficient for stabilization.