Isolation and characterization of genomic clones covering the chicken vitellogenin gene

A series of overlapping recombinant clones, which cover the vitellogenin gene, has been isolated from a phage-lambda linked chicken gene library. The DNA of the overlapping clones spans 28 kb of contiguous DNA sequences in the chicken genome. Electron microscopic analysis of hybrids between vitellogenin mRNA and the genomic clones indicates that the chicken vitellogenin gene has a length of approximately 22 kb, about 3.8 times the size of the mRNA. The mRNA sequence is interrupted by at least 33 intervening sequences (introns). Comparison with the vitellogenin gene A2 from Xenopus laevis (Wahli et al., 1980, Cell 20: 107-117) indicates conservation of the number and length of the exons during evolution. Heteroduplex analysis reveals a short stretch of sequence homology between the genes from chicken and frog.     

Sequence homologies within the 5'' end region of the estrogen-controlled vitellogenin gene in Xenopus and chicken.

In oviparous vertebrates vitellogenin, the precursor of the major yolk proteins, is synthesized in the liver of mature females under the control of estrogen. We have established the organization and primary structure of the 5' end region of the Xenopus laevis vitellogenin A2 gene and of the major chicken vitellogenin gene. The first three homologous exons have exactly the same length in both species, namely 53, 21 and 152 nucleotides, and present an overall sequence homology of 60%. In both species, the 5'-non-coding region of the vitellogenin mRNA measures only 13 nucleotides, nine of which are conserved. In contrast, the corresponding introns of the Xenopus and the chicken vitellogenin gene show no significant sequence homology. Within the 500 nucleotides preceding the 5' end of the genes, at least six blocks with sequence homologies of greater than 70% were detected. It remains to be demonstrated which of these conserved sequences, if any, are involved in the hormone-regulated expression of the vitellogenin genes.     

Comparison of the organization and fine structure of a chicken and a Xenopus laevis vitellogenin gene

The structural organization and the coding nucleotide sequence of the Xenopus laevis A2 and the chicken major vitellogenin genes have been compared. Both genes show the same exon-intron organization. However, the degree of homology between the nucleotide and derived amino acid sequences varies extensively along the genes. Several of the 35 exons are quite similar, and a unique cysteine motif in the lipovitellin II domain is conserved between the two genes. In contrast, one internal region is quite divergent. Part of this region encodes phosvitin, which appears to have evolved rapidly by both point mutations and duplications of serines or short other amino acid stretches. On the basis of these observations, we discuss the possible mechanism of evolution of phosvitin in vertebrates.     

Enrichment and characterization of the DNA coding for vitellogenin in Xenopus laevis.

Purified vitellogenin mRNA of Xenopus laevis was incubated with mechanically sheared DNA in high concentrations of formamide and the resulting R-loops (i.e. RNA . DNA hybrid fragments) separated from the bulk DNA by caesium chloride buoyant density centrifugation. Hybridization with 125I-labeled vitellogenin mRNA revealed a 15--30-fold enrichment of the DNA coding for vitellogenin. Restriction analysis of the R-loop-enriched DNA demonstrated that all known endonuclease HindIII fragments coding for vitellogenin of unfractionated Xenopus DNA were also present in the enriched material, including the specific fragments for the oligo(A)-containing segment of the RNA. Comparison of these restriction data with the structure found in cloned vitellogenin cDNA, indicates the presence of at least one intervening sequence in the genomic DNA coding for vitellogenin.     

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.     

Vitellogenin genes and their products in closely and distantly related species of Xenopus

Plasma vitellogenins from two closely related species of Xenopus, X. laevis and X. borealis, and a more ancient species, X. tropicalis, exhibited the same size on gel electrophoresis and were immunologically related. Partial peptide maps of 125I-labelled plasma vitellogenins, however, revealed marked differences in th structure and organisation of vitellogenin in the three Xenopus species. Northern blot hybridisation of liver RNA from oestrogen-treated males and females, probed with cloned vitellogenin cDNA, revealed the presence of mRNA of the same size in the three species of Xenopus, which was absent in untreated male liver. Cell-free translation of total liver RNA showed the presence of functional mRNA coding for vitellogenin subunit of the same size (Mr congruent to 210,000). Restriction endonuclease digestion patterns of genomic DNA from the three Xenopus species, using cloned X. laevis vitellogenin cDNA as the hybridisation probe, revealed significant differences in the organisation of these genes, which occur at a higher multiplicity in X. laevis and X. borealis than in X. tropicalis. Thus, despite a high degree of conservation of size, overall sequence and immunological identity of vitellogenin genes and their products in the three species of Xenopus, there is a substantial structural rearrangement during evolution of Xenopus within this multigene family.     

Sequence of lamprey vitellogenin. Implications for the lipovitellin crystal structure.

The amino acid sequence of lamprey vitellogenin has been predicted from the nucleotide sequence of cloned cDNA. The sites of proteolytic cleavage that produce the lipovitellin complex from the vitellogenin have been located by comparing the N-terminal sequences of two lamprey lipovitellin polypeptides with the predicted sequence. These results also confirm that the vitellogenin sequence derived here corresponds to the lipovitellin complex for which the crystal structure has been solved previously. Predictions of secondary structure indicate that the region most likely to correspond to the large alpha-helical domain of the crystallographic model consists of vitellogenin residues 300 to 600. Similar to the lipovitellins of Xenopus laevis, lamprey lipovitellin appears to lack approximately 200 C-terminal residues that are present in vitellogenin. However, the lamprey lipovitellin differs from those of Xenopus and chicken in two respects. First, most of the serine-rich domain that is present as the phosvitin polypeptide in the lipovitellins of the higher vertebrates appears to be lost in the maturation of lamprey vitellogenin to lipovitellin. Second, the domains that constitute the large lipovitellin-1 polypeptide in Xenopus and chicken are present in two polypeptides in lamprey, owing to an additional proteolytic processing event.     

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.     

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.     

Comparative analysis of Xenopus tropicalis and Xenopus laevis vitellogenin gene sequences

Analysis of cDNA clones synthesized from vitellogenin mRNA of X. tropicalis revealed three different types of cDNA clones, i.e. A, A* and B. A and A* clones have a sequence divergence of about 6% and are both related to X. laevis vitellogenin cDNAs of subgroup A1 as well as A2 with a sequence divergence of 6-9%. B clones however, are related to X. laevis cDNA clones of subgroup B1 and B2 with a sequence divergence of about 7%. While the A and B clones correspond to vitellogenin mRNAs of similar abundance, A* clone is complementary to a vitellogenin mRNA about 100 fold less abundant than A and B mRNAs although all three vitellogenin mRNAs are encoded by single copy genes. Furthermore, two forms of A* mRNA were found. One of the two is lacking an internal fragment of about 900 bp. Since this DNA fragment is highly repeated in the genome, we suggest that this A* clone was synthesized from a processing intermediate of the A* precursor vitellogenin mRNA.     

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.     

Vitellogenesis in Xenopus laevis and chicken: cognate ligands and oocyte receptors. The binding site for vitellogenin is located on lipovitellin I

Vitellogenesis is the process of yolk formation in rapidly growing oocytes of oviparous species. The transport of yolk precursor proteins from the blood plasma into the oocyte is achieved by receptor-mediated endocytosis. Although the Xenopus oocyte is one of the prime experimental systems for expression of foreign genes and their products, the receptor for the main vitellogenic protein, vitellogenin, from this extensively utilized cell has not been identified. Here we have applied ligand and immunoblotting to visualize the Xenopus laevis oocyte receptor for vitellogenin as a protein with an apparent Mr of 115,000 in sodium dodecyl sulfate-polyacrylamide gels under nonreducing conditions. The receptor from the amphibian oocyte also recognizes chicken vitellogenin, and vice versa; furthermore, the two receptor proteins are immunologically related as revealed by Western blotting with anti-chicken vitellogenin receptor antibodies. The receptors from both species bind the lipovitellin moiety of vitellogenin, as revealed by ligand blotting with radiolabeled lipovitellin polypeptides as well as by a novel reverse ligand blotting procedure utilizing nitrocellulose-immobilized ligand. Since vitellogenins of chicken and Xenopus have been shown to be structurally similar and evolutionarily related (Nardelli, D., van het Schip, F. D., Gerber-Huber, S., Haefliger, J.-A., Gruber, M., AB, G., and Wahli, W. (1987) J. Biol. Chem. 262, 15377-15383), it appears that conservation of key structural elements required for efficient vitellogenesis extends from the ligands to their receptors on the oocyte plasma membrane.     

In vitro translation and estradiol-17beta induction of Xenopus laevis vitellogenin messenger RNA.

Administration of estradiol-17beta to male Xenopus laevis induces synthesis and secretion by the liver of the egg yolk precursor protein vitellogenin. RNA extracted from livers of estradiol-17beta-treated Xenopus laevis directs the synthesis of the entire 200,000-dalton vitellogenin monomer in a cell-free protein synthesizing system derived from rabbit reticulocytes. Vitellogenin synthesized in vitro was isolated and quantitated by indirect immunoprecipitation and identified by comparison to authentic [14C]vitellogenin. The in vitro product and [14C]vitellogenin co-migrate on electrophoresis in sodium dodecyl sulfate-polyacrylamide gels and they exhibit identical immunoprecipitation curves. Xenopus laevis vitellogenin messenger RNA has a sedimentation coefficient of approximately 30 S in sucrose density gradients. It can be purified approximately 60-fold from cell RNA by poly(U)-Sepharose chromatography and therefore appears to contain a polyadenylate sequence. Vitellogenin mRNA and vitellogenin synthesis in vivo could not be detected in unstimulated male Xenopus laevis. The relative rate of vitellogenin synthesis and the level of vitellogenin mRNA were determined at various times following the administration of estradiol-17beta. Vitellogenin synthesis is maximal 12 days after estradiol-17beta administration when it comprises approximately 70% of cell protein synthesis. The level of vitellogenin mRNA and the intracellular rate of vitellogenin synthesis exhibit a close correspondence from 4 to 16 days after administration of estradiol-17beta.