Effects of serial hormone treatments on egg white protein synthesis. Further evidence of translational regulation

The administration of either progesterone or estrogen to withdrawn chicks several hours after a first dose of estrogen affected ovalbumin synthesis differently than its mRNA levels [S. S. Seaver (1981) J. steroid Biochem. 14, 949-957]. This suggested that the hormones were regulating the translation of ovalbumin directly. In this paper we report that serial hormone treatments also affect the rates of synthesis of two other egg white proteins, conalbumin and ovomucoid. When progesterone was administered 4 h after estrogen, conalbumin synthesis decreased. When either progesterone or a second dose of estrogen was administered 12 h after the first dose of estrogen, conalbumin synthesis increased. Serial hormone treatments did not always affect all three proteins similarly. At later times, administering progesterone after estrogen decreased ovomucoid synthesis but did not affect conalbumin or ovalbumin synthesis. To determine if the serial hormone treatments affect egg white protein mRNA's in a similar way, changes in ovalbumin and conalbumin mRNA levels were quantified in a rabbit reticulocyte cell-free translation system and were compared to changes in ovalbumin and conalbumin synthesis as measured in chick oviduct tissue minces. When serial hormone treatments were 12 h apart, ovalbumin and conalbumin synthesis was 50-300% higher than that predicted by the changes in ovalbumin or conalbumin mRNA levels. This is further evidence that translation of both conalbumin mRNA and ovalbumin mRNA is directly regulated by steroid hormones.     

Estrogen regulation of hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase and acetyl-CoA carboxylase in xenopus laevis

Administration of estradiol-17 beta to male Xenopus laevis evokes the proliferation of the endoplasmic reticulum and the Golgi apparatus and the synthesis and secretion by the liver of massive amounts of the egg yolk precursor phospholipoglycoprotein, vitellogenin. We have investigated the effects of estrogen on three key regulatory enzymes in lipid biosynthesis, 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase, the major regulatory enzyme in cholesterol and isoprenoid synthesis, and acetyl-CoA carboxylase and fatty acid synthetase, which regulate fatty acid biosynthesis. HMG-CoA reductase activity and cholesterol synthesis increase in parallel following estrogen administration. Reductase activity in estrogen stimulated Xenopus liver cells peaks at 40-100 times the activity observed in control liver cells. The increased rate of reduction of HMG-CoA to mevalonic acid is not due to activation of pre-existing HMG-CoA reductase by dephosphorylation, as the fold induction is unchanged when reductase from control and estrogen-stimulated animals is fully activated prior to assay. The estrogen-induced increase of fatty acid synthesis is paralleled by a 16- to 20-fold increase of acetyl-CoA carboxylase activity, indicating that estrogen regulates fatty acid synthesis at the level of acetyl-CoA carboxylase. Fatty acid synthetase activity was unchanged during the induction of fatty acid biosynthesis by estrogen. The induction of HMG-CoA reductase and of acetyl-CoA carboxylase by estradiol-17 beta provides a useful model for regulation of these enzymes by steroid hormones.     

Establishment and characterization of Xenopus oviduct cells in primary culture

Based on a previously established procedure for Xenopus hepatocytes, we describe tubular oviduct cells in primary culture which continue to secrete substantial quantities of egg jelly for several days, as can be visualized microscopically. Freshly isolated cells exhibited a culture shock response [A. P. Wolffe, J. F. Glover, and J. R. Tata (1984) Exp. Cell Res. 154, 581], from which they recovered by the third day in culture. This recovery was characterized by (a) the diminished synthesis of heat shock proteins hsp 70 and hsp 85, (b) the cessation of the drop in number of estrogen receptor, and (c) the enhanced rate of synthesis of cellular and secreted proteins. The oviduct estrogen receptor had the same characteristics as those in other estrogen target tissues and was present in the same amount as in adult female Xenopus hepatocytes [A. J. Perlman, A. P. Wolffe, J. Champion, and J. R. Tata (1984) Mol. Cell. Endocrinol. 38, 51]. Unlike the latter in primary culture [M. P. R. Tenniswood, P. F. Searle, A. P. Wolffe, and J. R. Tata (1983) Mol. Cell. Endocrinol. 30, 329], oviduct cell cultures did not actively metabolize either estradiol or progesterone (t1/2 approximately equal to 55 and 7 h, respectively). The successful establishment and characterization of primary cultures of both liver and oviduct cells now fulfil the conditions required for investigating the basis for tissue specificity of regulation by estrogen of Xenopus egg protein gene expression in primary cell culture.     

Estrogen Receptor Is Not Primarily Responsible for Altered Responsiveness of Ovalbumin mRNA Induction in the Oviduct From Genetically Selected High- and Low-Albumen Chicken Lines

The role of estrogen receptor on ovalbumin mRNA induction by steroid hormones was investigated in primary cultures of oviduct cells from estrogen-stimulated immature chicks of genetically selected high- and low-albumen egg laying lines (H- and L-lines). In experiment 1,the extent of ovalbumin mRNA induction and changes in estrogen and progesterone receptors were compared between the oviduct cells from H- and L-lines with or without steroid hormones in the culture medium. In experiment 2, the effect of estrogen receptor gene transfection on the induction of ovalbumin mRNA was studied in the oviduct cells from the L-line chicks. The results showed a close correlation of the changes in ovalbumin mRNA with the numbers of nuclear and total estrogen receptors in the oviduct cells but not with the numbers of nuclear and total progesterone receptors. Estrogen receptor gene transfection induced ovalbumin mRNA to a moderate extent in the absence of the steroid hormones. To our surprise, however, estrogen receptor gene transfection apparently suppressed the ovalbumin mRNA responsiveness to estrogen to a considerable extent. It was concluded, therefore, that the extent of estrogen receptor expression might not be primarily responsible for the differences in responsiveness to steroid hormones of oviduct cells from genetically selected H- and L-line chickens.     

An estrogen receptor from xenopus laevis liver possibly connected with vitellogenin synthesis

This paper describes an estrogen receptor which is found in both the nucleus and cytoplasm of liver cells from male Xenopus laevis, and which seems to be involved in the induction of vitellogenin synthesis. It has a high affinity for estradiol (K_d = 0.5 × 10^?9 M), and the affinities of various steroids for the receptor correlate well with their ability to induce vitellogenin synthesis. It sediments at 3.5S at 0°C in 0.5 M KCI. The rate of sedimentation is unaffected by incubation at 20°C prior to centrifugation, but increases if the salt concentration is lowered to 0.1 M KCI or to zero. It has a Stokes radius of 2.6 nm and a molecular weight of approximately 40, 000. The receptor is present at very low levels compared to other steroid target tissues (50–100 fold less than chick oviduct). The cytoplasm of a single hepatocyte contains 92 ± 18 binding sites for estradiol, while each nucleus contains 99 ± 19 sites.     

An estrogen-inducible protein binds specifically to a sequence in the 3'' untranslated region of estrogen-stabilized vitellogenin mRNA.

The 3' untranslated region (3'-UTR) has been implicated in the estrogen stabilization of hepatic Xenopus laevis vitellogenin mRNA. We used RNA gel mobility shift assays to demonstrate that Xenopus liver contains a factor which binds with very high specificity to a segment of the 3'-UTR of vitellogenin B1 and B2 mRNAs. We detected a single high-affinity binding site in the vitellogenin mRNA 3'-UTR and localized the binding site to a 27-nucleotide region. Since binding was abolished by proteinase K digestion, at least a component of the factor is a protein. Following estrogen administration, binding was induced approximately four- to fivefold in extracts from liver polysomes. The hepatic vitellogenin mRNA-binding protein was found in both polysomes and cytosol. Since the protein was also estrogen inducible in cytosol, this represents a genuine induction, not simply recruitment of the cytosolic protein into polysomes. UV cross-linking studies with the 27-nucleotide recognition sequence revealed bands corresponding to bound proteins with apparent molecular weights of 71,000 and 141,000. This appears to be the first example of steroid hormone-inducible proteins binding to an mRNA 3'-UTR. Its induction by estrogen and its sequence-specific binding to a region of vitellogenin mRNA important in estrogen-mediated stabilization suggest that the protein may play a role in the regulation of mRNA stability.     

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.     

Down regulation of c-myc, c-fos and erb-B during estrogen induced proliferation of the chick oviduct

Oncogenes c-myc, H-ras, c-fos and erb-B were constitutively expressed in immature chick oviduct withdrawn from estrogen administration for 2.5 weeks after 10 d of primary estrogen stimulation. Following secondary estrogen stimulation of the withdrawn chicks, synthesis of egg white proteins is rapidly induced and remaining non-functioning tubular gland cells are stimulated to proliferate with a doubling time of 24 h. During first 12 h of secondary estrogen stimulation, H-ras mRNA levels doubled and did not increase further at 24 h and 48 h. The steady state levels of c-myc, erb-B and c-fos mRNA decreased 24 h following secondary estrogen stimulation. The levels of these oncogene RNAs in oviduct were similar at 48 h following secondary estrogen stimulation to those from immature chicks administered 10 d of primary estrogen stimulation. Thus elevated expression of c-myc and c-fos mRNA does not appear to be necessary components for sustained estrogen induced cell proliferation in the chick oviduct.     

Estrogen-mediated cell proliferation during chick oviduct development and its modulation by progesterone

The interactions of estrogen and progesterone on mitosis were examined in the surface epithelium of the developing chick oviduct. Both of these steroid hormones can stimulate cells to divide in the unstimulated oviduct. However, progesterone treatment results in a delayed suppression of cell division in both the presence and absence of estrogen. This progesterone induced depression of estrogen-mediated cell division is observed throughout oviduct development. During oviduct development estrogen is necessary for both cell division and the differentiation of specific cell types while progesterone appears to modify the action of estrogen by blocking the progression of cells through the cell cycle.     

The chicken ovalbumin promoter is under negative control which is relieved by steroid hormones.

Steroid hormone regulation of activity of the chicken ovalbumin promoter was studied by microinjection of chimeric genes into the nuclei of primary cultured oviduct tubular gland cells. The chimeric genes contained increasing lengths of ovalbumin gene 5'-flanking sequences fused to the sequence coding for the SV40 T-antigen. Promoter activity was estimated by monitoring synthesis of T-antigen. The activity of the ovalbumin promoter is cell-specifically repressed in these oviduct cells and the repression is relieved upon addition of steroid hormones. The -132 to -425 region of the ovalbumin promoter which is responsible for this negative regulation behaves as an independent functional unit containing the regulatory elements necessary for both repression (in the presence of steroid hormone antagonists) and induced derepression (in the presence of steroid hormones) of linked heterologous promoters.     

Metabolic formation of nucleoside-modified analogues of S-adenosylmethionine

A Pseudo-ovalbumin gene, bearing significant nucleotide sequence homology to the ovalbumin gene, has been cloned from genomic chick DNA. Similar to the authentic ovalbumin gene, the pseudo-gene is a unique sequence gene in the chick genome and is expressed at a low level in the immature chick oviduct. In contrast to the ovalbumin gene, expression of the pseudo-gene in the oviduct is not inducible by estrogen. The concentration of pseudo-gene RNA is only ～0.01% of that of authentic ovalbumin mRNA in estrogen-stimulated oviduct cells. Nucleotide sequence analysis of the two sequence related genes may reveal the molecular basis of differential response to steroid hormone induction in the same tissue.     

Characterization of cloned complementary DNA covering more than 6000 nucleotides (97%) of avian vitellogenin mRNA

The messenger RNA coding for chicken vitellogenin, a precursor of the egg-yolk proteins lipovitellin and phosvitin, is synthesized in the liver following estrogen injection. This mRNA is 6600 nucleotides long. We have previously reported the cloning and preliminary characterization of some cDNA fragments representing portions of the vitellogenin mRNA [Biochem. Biophys. Acta, 606, 34--46 (1980)]. In this paper we report the full characterization of a larger series of such clones, representing almost the entire length of the mRNA, by restriction endonuclease mapping, R-loop mapping, RNA-DNA hybridization and by translation in vitro of the RNA which hybridizes to the cloned DNA. From the results we conclude that the chicken vitellogenin mRNA, unlike that of Xenopus laevis, does not vary in sequence over most of its length, although some variations in the cDNA sequences were detected particularly in clones derived from the 3' terminus of the RNA. All sequence variants appear to be present in RNA prepared from single animals. The possible origins of these minor species are discussed. Furthermore, we describe a cDNA clone complementary to an mRNA which is about the same size as vitellogenin mRNA and which codes for an egg yolk protein antigenically related to lipovitellin. This mRNA is synthesized constitutively.