Conserved sequence motifs upstream from the co-ordinately expressed vitellogenin and apoVLDLII genes of chicken.

The vitellogenin and apoVLDLII yolk protein genes of chicken are transcribed in the liver upon estrogenization. To get information on putative regulatory elements, we compared more than 2 kb of their 5' flanking DNA sequences. Common sequence motifs were found in regions exhibiting estrogen-induced changes in chromatin structure. Stretches of alternating pyrimidines and purines of about 30-nucleotides long are present at roughly similar positions. A distinct box of sequence homology in the chicken genes also appears to be present at a similar position in front of the vitellogenin genes of Xenopus laevis, but is absent from the estrogen-responsive egg-white protein genes expressed in the oviduct. In front of the vitellogenin (position -595) and the VLDLII gene (position -548), a DNA element of about 300 base-pairs was found, which possesses structural characteristics of a mobile genetic element and bears homology to the transposon-like Vi element of Xenopus laevis.     

The effect of antiestrogens on egg yolk protein synthesis and estrogen-binding to chromatin in the rooster liver.

Nafoxidine and CI-628, two well known antiestrogenic compounds, reduce the stimulating effect of estradiol on the estrogen-binding capacity of the liver chromatin from roosters. In vitro both antiestrogens compete with [3H]estradiol for the binding sites on the liver chromatin. They inhibit the estrogen-induced synthesis of egg yolk proteins (vitellogenin) and fail to induce this estrogen-specific protein synthesis by themselves. They show the ability, however, to increase the estrogen-binding sites on the liver chromatin to some extent.     

The effect of antiestrogens on egg yolk protein synthesis and estrogen-binding to chromatin in the rooster liver

Nafoxidine and CI-628, two well known antiestrogenic compounds, reduce the stimulating effect of estradiol on the estrogen-binding capacity of the liver chromatin from roosters. In vitro both antiestrogens compete with [³H] estradiol for the binding sites on the liver chromatin. They inhibit the estrogen-induced synthesis of egg yolk proteins (vitellogenin) and fail to induce this estrogen-specific protein synthesis by themselves. They show the ability, however, to increase the estrogen-binding sites on the liver chromatin to some extent.     

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.     

Isolation and characterization of a cDNA clone specific for avian vitellogenin II.

A clone for vitellogenin, a major avian, estrogen responsive egg yolk protein, was isolated from the cDNA library of estrogen-induced rooster liver. Two forms of plasma vitellogenin, vitellogenin I (VTG I) and vitellogenin II (VTG II), distinguishable on the basis of their unique partial proteolysis maps, have been characterized and their corresponding hepatic precursor forms identified. We have used this criterion to specifically characterize which vitellogenin protein had been cloned. Partial proteolysis maps of BTG I and VTG II standards, synthesized in vivo, were compared to maps of protein synthesized in vitro using RNA hybrid-selected by the vitellogenin plasmid. Eight major digest fragments were found common to the in vitro synthesized vitellogenin and the VTG II standard while no fragments were observed to correspond to the VTG I map. A restriction map of the VTG II cDNA clone permits comparison to previously described cDNA and genomic vitellogenin clones.     

Estradiol-dependent trans-acting factor binds preferentially to a dyad-symmetry structure within the third intron of the avian vitellogenin gene

The secondary activation of the avian vitellogenin II gene in isolated liver nuclei by cytoplasmatic liver extracts of estradiol-treated chicks is accompanied by the binding of a protein from the extract to the structural part of the cloned gene. Both the DNA-binding and gene-stimulatory activities, which cochromatograph on heparin-Sepharose, are apparently present only in the cytoplasmatic liver extracts of estradiol-treated roosters and in the oviduct extracts of egg-laying hens. DNA-binding competition assays combined with exonuclease III footprinting showed that the factor binds to the imperfect dyad-symmetry structure 5'GTCTTGTTCCAAAC3' within the third intron of the gene. The factor is sequence specific and binds equally well to both single-and double-stranded DNA with an estimated dissociation constant of 3.5 X 10(-10) M.     

Estrogen-dependent DNA synthesis and parenchymal cell proliferation in the liver of adult male Xenopus frogs

Estradiol-17 beta treatment of adult male Xenopus laevis induces liver parenchymal cells to synthesize DNA and proliferate. DNA synthesis begins 3 to 4 days after estrogen treatment and continues for approximately 10 days. Over this 2-week period, the total number of liver parenchymal cells increases fourfold, the wet weight of the liver remains constant, and there is a 50% reduction in cell volume. The elevated number of cells persists for several months and then returns to the control value. The extent of proliferation is hormone dose dependent. Pulse-chase experiments demonstrate that as a result of hormone treatment a minority of the parenchymal cells in the initial population enter the cell cycle, and via repeated divisions become the majority (79%) of the population by Day 14. The implications of this phenomenon for estrogen-induced liver cell differentiation and vitellogenin gene function are discussed.     

Rudimentary phosvitin domain in a minor chicken vitellogenin gene

We have determined the nucleotide sequence and the derived amino acid sequence of the phosphoprotein-encoding region of the chicken vitellogenin III gene. The sequence of this minor vitellogenin could be aligned with exon 22 up to exon 27 of the previously sequenced major vitellogenin II gene (van het Schip et al., 1987). The exon 23 and 25 sequences are rich in serine codons (26% and 41%, respectively), and this region encodes at least one of the small egg yolk phosphoproteins. The major egg yolk phosphoprotein, phosvitin, is encoded by the analogous region in vitellogenin II. Comparison of the vitellogenin II and vitellogenin III sequences shows a great reduction in the size of the putative exon 23 of the latter (321 base pairs as opposed to 690). The number of serine codons is also drastically reduced from 124 in exon 23 of the vitellogenin II gene to 28 in vitellogenin III. The grouping of synonymous serine codons, as has hitherto been observed in sequenced vitellogenin phosphoproteins, has been maintained in vitellogenin III. A putative asparagine-linked N-glycosylation site which was conserved in the chicken vitellogenin II and the Xenopus laevis vitellogenin A2 gene, at the beginning of exon 23, is also present in vitellogenin III. The two chicken vitellogenins show a low conservation in the phosphoprotein-encoding region (average 33%, at the protein level) compared to that in the peripheral sequences (58% identity), which indicates that it is a rapidly evolving domain of the vertebrate vitellogenin gene.     

Both locus control region and proximal regulatory elements direct the developmental regulation of beta-globin gene cluster

Using ligation-mediated PCR and in vivo footprinting methods to study the status of DNA-protein interaction at hypersensitive site 2 of locus control region and beta(maj) promoter of erythroid cells of fetal liver and adult bone marrow, we found that during different developmental periods, the status of DNA-protein interaction at both hypersensitive site 2 and beta(maj) promoter changed significantly, and indicated that locus control region might function through a looping mechanism to regulate the expression of downstream genes, and that distal regulatory elements (locus control region, hypersensitive sites) as well as proximal regulatory elements (promoter, enhancer) of beta-globin gene cluster participate in the regulation of developmental specificity.