Isolation and translation in vitro of four related vitellogenin mRNAs of estrogen-stimulated Xenopus laevis

The utility of vitellogenin as a biomarker of estrogenic endocrine disrupting chemicals in molluscs

Estrogenic endocrine disrupting chemicals (EDCs) are natural hormones, synthetic compounds or industrial chemicals that mimic estrogens due to their structural similarity with estrogen's functional moieties. They typically enter aquatic environments through wastewater treatment plant effluents or runoff from intensive livestock operations. Globally, most natural and synthetic estrogens in receiving aquatic environments are in the low ng/L range, while industrial chemicals (such as bisphenol A, nonylphenol and octylphenol) are present in the μg to low mg/L range. These environmental concentrations often exceed laboratory-based predicted no effect concentrations (PNECs) and have been evidenced to cause negative reproductive impacts on resident aquatic biota. In vertebrates, such as fish, a well-established indicator of estrogen-mediated endocrine disruption is overexpression of the egg yolk protein precursor vitellogenin (Vtg) in males. Although the vertebrate Vtg has high sensitivity and specificity to estrogens, and the molecular basis of its estrogen inducibility has been well studied, there is growing ethical concern over the use of vertebrate animals for contaminant monitoring. The potential utility of the invertebrate Vtg as a biomonitor for environmental estrogens has therefore gained increasing attention. Here we review evidence providing support that the molluscan Vtg holds promise as an invertebrate biomarker for exposure to estrogens. Unlike vertebrates, estrogen signalling in invertebrates remains largely unclarified and the classical genomic pathway only partially explains estrogen-mediated activation of Vtg. In light of this, in the latter part of this review, we summarise recent progress towards understanding the molecular mechanisms underlying the activation of the molluscan Vtg gene by estrogens and present a hypothetical model of the interplay between genomic and non-genomic pathways in the transcriptional regulation of the gene.

Vitellogenin of Fujian oyster, Crassostrea angulata: Synthesized in the ovary and controlled by estradiol-17β

In this study, we cloned a full-length cDNA encoding vitellogenin (Vg) in the Fujian oyster Crassostrea angulata. The complete Vg cDNA consists of 5160 nucleotides with a long open reading frame encoding 1641 amino acid residues. The deduced amino acid sequence shared high similarity with the Vgs of other mollusc, fish, nematode and arthropod species, particularly in the N-terminal region. We analyzed the spatiotemporal expression of caVg transcripts by Real-time Quantitative PCR. In common with other mollusc Vgs, the caVg gene was expressed primarily in the ovary, and the levels were 348 and 177 times higher in maturation and ripeness stages (P<0.01), respectively, than in the partially spent stage. There was negligible expression in male oysters. In situ hybridization analysis further localized caVg mRNA to the follicle cells (also named auxiliary cells) surrounding the oocytes in the ovary. Moreover, in vivo waterborne exposure experiments in early gametogenesis oysters showed that estradiol-17β (E2) administration resulted in a significant increase in caVg mRNA expression. We conclude that caVg is synthesized in the follicle cell surrounding the vitellogenic oocyte in C. angulata, and directly passed to oocytes through the extracellular space without mediation through hemolymph. Also, we hypothesize that this process is mediated by E2 in a dose dependent.

Molecular characterization and expression of vitellogenin (Vg) genes from the cyclopoid copepod, Paracyclopina nana exposed to heavy metals

Induction of vitellogenin (Vg) has been used as a biomarker of exposure to heavy metals and endocrine-disruption chemicals (EDCs) in aquatic organisms. Here, we identified the full-length Vg1 and Vg2 sequence from the brackish water copepod, Paracyclopina nana. Vg1 gene contained 5718bp of the open reading frame (ORF) that encoded the putative protein of 1905 amino acids residues, while Vg2 gene consisted of 5442bp of ORF, encoding the putative protein of 1813 amino acids residues. P. nana Vgs showed highly conserved domains in the N-terminal region. The phylogenetic analysis revealed that P. nana Vgs are distinct from other arthropods, such as insects and decapods, as it formed a clade with other copepods, Tigriopus japonicus and salmon louse (Lepeophtheirus salmonis). The expression of Vg transcripts was detectable after the copepodid stages 4-5. Female copepods expressed over 83 times and 223 times more Vg1 and Vg2 transcripts, respectively, than males. When copepods were exposed to heavy metals (0.1mg/L Cd, 0.4mg/L Cu, and 2mg/L AsIII) for 24, 48, 72, and 96h, P. nana Vg transcripts were highly induced in a time-dependent manner. Interestingly, Vg2 gene was more susceptible than Vg1 to trace heavy metal exposure. This finding indicates that P. nana Vgs provide a potential indicator for assessing the toxic effect of heavy metals. In addition, we suggest P. nana as a potential model species for risk-assessment to environmental pollutants in brackish water.

Precursor-product relationship between vitellogenin and the yolk proteins as derived from the complete sequence of a Xenopus vitellogenin gene

In Xenopus laevis four estrogen-responsive genes are expressed simultaneously to produce vitellogenin, the precursor of the yolk proteins. One of these four genes, the gene A2, was sequenced completely, as well as cDNAs representing 75% of the coding region of the gene. From this data the exon-intron structure of the gene was established, revealing 35 exons that give a transcript of 5,619 bp without the poly A-tail. This A2 transcript encodes a vitellogenin of 1,807 amino acids, whose structure is discussed with respect to its function. At the nucleic acid as well as at the protein level no extensive homologies with any sequences other than vitellogenin were observed. Comparison of the amino acid sequence of the vitellogenin A2 molecule with biochemical data obtained from the different yolk proteins allowed us to localize the cleavage products on the vitellogenin precursor as follows: NH2 - lipovitellin I - phosvitin (or phosvette II - phosvette I) - lipovitellin II - COOH.

Persistence, methylation and expression of vitellogenin gene derivatives after injection into fertilized eggs of Xenopus laevis

We report the fate of different derivatives of the vitellogenin genes after injection into fertilized eggs of Xenopus. We injected a constructed minigene as well as a 5' fragment of the A2 vitellogenin gene. The minigene survives in embryogenesis much better than the 5' A2 fragment and is retained more frequently and at a higher level in frog tissues. The mosaic distribution of the foreign DNA in different frog tissues indicates that no integration occurred before the first cleavage stage. The persisting DNA may be partially integrated but is mostly found in an episome-like form. This unintegrated form is not supercoiled and is rearranged. Methylation of the Hpa II sites prior to injection has no influence on the survival of the injected sequences and the Hpa II sites of the surviving DNA are unmethylated irrespective whether the injected DNA was methylated or not. Whereas the derivatives are transcribed in embryos, they cannot be activated by estrogen in the liver of young frogs.

Unequal activation by estrogen of individual Xenopus vitellogenin genes during development

Using a technique of filter hybridization under very stringent conditions to HindIII fragments of complementary DNA cloned in plasmids, we have measured the accumulation in hepatocytes of mRNA specified by each of the four vitellogenin genes (A1, A2, B1, B2) at different stages of development of Xenopus laevis. The ontogenic competence of embryonic liver to respond to the first exposure to estradiol-17 beta, in terms of activation of transcription of this multigene family, is acquired late in metamorphosis at around Nieuwkoop-Faber stage 58. Upon hormonal induction, the four mRNAs accumulate under non-steady-state conditions at different rates and to different extents at all developmental stages in vivo and in cultured adult hepatocytes. A1 and B1 mRNAs appear more rapidly and accumulate to levels that are five- to eightfold those specified by genes A2 and B2, with higher amounts of B1 than A1 mRNA. A threefold higher absolute rate of synthesis of A1 and B1 mRNAs in hepatocyte cultures, relative to the A2-B2 pair, suggests that hormonal regulation of differential accumulation of vitellogenin mRNA occurs at the transcriptional level. At the early developmental stages (up to stage 61) of acquired competence, there appears to be no fixed pattern of expression, but a pattern of unequal activation of individual genes of the Xenopus vitellogenin multigene family is established thereafter and then retained at all developmental stages of tadpoles, froglets, and in both male and female adults.

Globin gene expression in Xenopus laevis: anemia induces precocious globin transition and appearance of adult erythroblasts during metamorphosis

The expression of Xenopus laevis larval and adult globin genes after phenylhydrazine-induced anemia has been investigated at the cellular and molecular levels by means of cloned cDNA probes specific for the four main larval and the four main adult globin mRNA species. In the circulating blood of anemic metamorphic larvae there are at least two distinct populations of erythroblasts containing either larval or adult globin mRNA sequences. The cells expressing adult sequences replace those expressing larval ones at the end of metamorphosis. Under the influence of anemia the qualitative pattern of transcribed RNA species is not changed, but the larval to adult transition takes place earlier during development. This would imply that this transition is not strongly correlated with the morphological changes of metamorphosis. The abundance of the different larval globin mRNA species is similar and, as compared to control animals, not affected by the phenylhydrazine treatment. In anemic adults no reactivation of larval gene expression has been observed. The different adult globin mRNA species are present in comparable abundance, but the phenylhydrazine treatment appears to enhance expression of the alpha A II and beta A II genes, as compared to nonanemic individuals.

Vitellogenin B2 gene in Xenopus laevis: isolation, in vitro transcription and relation to other vitellogenin genes

The isolation of the four Xenopus laevis vitellogenin genes has been completed by the purification from a DNA library of the B2 gene together with its flanking sequences. The overlapping DNA fragments analyzed cover 34 kilobases. The B2 gene which has a length of 17.5 kilobases was characterized by heteroduplex and R-loop mapping in the electron microscope and by in vitro transcription in a HeLa whole-cell extract. Its structural organization is compared with that of the closely related B1 gene. The mRNA-coding sequence of about 6 kilobases is interrupted 34 times in the B1 gene and 33 times in the B2 gene. Sequence homology between the two genes was not only found in exons. In addition, 54% of the intron sequences as well as 63% and 48.5% respectively of the 5' and 3' flanking sequences, show enough homology to form stable duplexes. These findings are compared with earlier results obtained with the two other closely related members of the vitellogenin gene family, the A1 and the A2 genes.

Differential responsiveness of avian vitellogenin I and vitellogenin II during primary and secondary stimulation with estrogen

Avian vitellogenin consists of two major species, VTG I and VTG II, which show major differences in structure and immunological properties suggesting that VTG I and VTG II are distinct gene products. During primary stimulation with estrogen, VTG I was found to accumulate in plasma much more slowly than VTG II. At 1 day after hormone treatment VTG I was only 1-3% of VTG II, but by day 5 VTG I increased to approximately 25% of VTG II. Measurements of hepatic vitellogenin synthesis confirmed the slower induction and reduced expression of VTG I. A further difference was noted in the amnestic or memory response to secondary estrogen treatment. Measurements of VTG I and VTG II accumulation and synthesis after primary and secondary estrogen treatment showed that the memory response occurs to a much greater extent for VTG I than VTG II. These differences indicate that the inductions of VTG I and VTG II are not tightly coupled.

In contrast to other Xenopus genes the estrogen-inducible vitellogenin genes are expressed when totally methylated

The methylation-sensitive restriction enzymes Hha I and Hpa II were used to analyze the methylation pattern of four Xenopus laevis genes in DNA of embryos, of erythrocytes, and of untreated and estrogen-treated hepatocytes. Within these four genes all sites tested are fully modified in embryonic DNA. However, the adult beta 1-globin gene is unmethylated in DNA of erythrocytes, where it is expressed, and the 68 kd albumin gene, active only in hepatocytes, is specifically hypomethylated in hepatic DNA. The vitellogenin genes A1 and A2, in hepatocytes simultaneously expressed upon estrogen treatment, are heavily methylated in all adult tissues, irrespective of expression. Our results reveal that specific genes can be actively transcribed even when they are fully methylated and that changes in the methylation pattern are not a general prerequisite for gene activation.

Simultaneous analysis of conformation and transcription of A and B groups of vitellogenin genes in male and female Xenopus during primary and secondary activation by estrogen

In male Xenopus, primary estradiol administration results in noncoordinate activation in the liver of the A and B groups of vitellogenin genes, both as judged by transcription and DNase I sensitivity in isolated nuclei, B group genes being activated preferentially in the first 20 hr. Secondary induction in males or "primary" induction in females results in a coordinate and equal transcription of these two groups of genes. The elevated transcriptional activity following primary estrogen stimulation returns to low levels rapidly but the high DNase I sensitivity of these genes persists for 2-3 months. A non-coordinate activation of the A and B groups of vitellogenin genes is however re-established in response to a second administration of estradiol 8 months after primary stimulation of male Xenopus.

Coordinate and non-coordinate estrogen-induced expression of A and B groups of vitellogenin genes in male and female Xenopus Hepatocytes in culture

The concentration of mRNA transcribed from A and B groups of vitellogenin genes, induced by estrogen added to primary cultures of hepatocytes from male and female adult Xenopus, was measured by a technique of filter disc hybridization with cloned Xenopus vitellogenin cDNA probes. In cells from naive male Xenopus (i.e. not previously exposed to hormone in vivo or in vitro), the two groups of the multigene family were non-coordinately expressed during the early stages of response to estradiol in vitro. Only B group transcripts could be detected for the first 2-3 h. At later times, or upon successive additions of estradiol to the male cell cultures, both A and B group mRNAs accumulated at the same rate and to the same extent. In female hepatocytes both groups of mRNAs accumulated in parallel at all stages of their response to estrogen, reaching levels 10-fold higher than in naive male cells similarly exposed to the hormone. However, hepatocytes from male Xenopus that had received a single injection of estradiol 5 weeks before the cells were prepared, now exhibited identical rates and extent of accumulation of A and B groups of vitellogenin mRNAs to those observed in female cells. Pulse-labeling of RNA in cultured male Xenopus hepatocytes confirmed that the coordinate and non-coordinate accumulation of mRNAs were largely a function of differential or equal transcription of the A and B groups of vitellogenin genes. A phenomenon analogous to the hormone-induced shift from non-coordinate to coordinate expression of two groups of genes of the same multigene family has not been described previously, and we discuss possible mechanisms underlying the transition.

Vitellogenin genes A1 and B1 are linked in the Xenopus laevis genome

Genomic clones containing the Xenopus laevis vitellogenin gene B1 have been isolated from DNA libraries and characterized by heteroduplex mapping in the electron microscope, restriction endonuclease analysis, and in vitro transcription in a HeLa whole-cell extract. Sequences from the 3'-flanking region of the previously isolated A1 vitellogenin gene were found in the 5'-flanking region of this B1 gene. Thus, the two genes are linked, with 15.5 kilobase pairs of DNA between them. Their length is about 22 kilobase pairs (A1 gene) and 16.5 kilobase pairs (B1 gene) and they have the following arrangement: 5'-A1 gene-spacer-B1 gene-3'. The analysis of heteroduplexes formed between the two genes revealed several regions of homology. Both genes are in the same orientation and, therefore, are transcribed from the same DNA strand. The possible events by which the vitellogenin gene family arose in Xenopus laevis are discussed.

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.

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.

Differential sensitization to deoxyribonuclease I of Xenopus vitellogenin and albumin genes during primary and secondary induction of vitellogenesis by oestradiol

The sensitivity to DNAase (deoxyribonuclease) I (which preferentially digests transcribed sequences) of vitellogenin and albumin genes in liver and erythrocytes of male Xenopus after primary and secondary induction of vitellogenesis by oestrogen was measured by hybridization to cDNA (complementary DNA) of the residual DNA after enzymic digestion of isolated nuclei. Vitellogenin sequences were rendered selectively more sensitive to limited DNAase-I digestion (15-20% of DNA rendered acid-soluble) during primary hormonal activation (5 days) of vitellogenin genes in liver, but not erythrocyte, nuclei. Hormone withdrawal (25 days after first injection) did not result in reversion to a pre-activation gene configuration, nor did secondary hormonal stimulation (5 days after second and 25 days after first injection) augment the sensitivity of the genes to digestion by the nuclease. Similar hormone treatment did not affect the sensitivity of the constitutively expressed albumin genes in liver nuclei, nor their insensitivity in erythrocyte nuclei. Under the same conditions, globin genes remained indigestible in liver nuclei. It is concluded that primary induction of vitellogenesis in male Xenopus liver is accompanied by relatively long-lasting (3-4 weeks) change in the configuration of vitellogenin genes in hepatic nuclei which is not reversed or further modified during short-term oestrogen withdrawal or upon secondary stimulation.

Evolutionary conservation of vitellogenin genes

Homologous and heterologous hybridizations in solution were performed between sheared genomic DNA and DNA complementary to vitellogenin mRNA of Xenopus, chicken, and migratory locust. The kinetics of hybridization and the thermal stability of the hybrids formed suggested a high degree of conservation of coding sequences of insect, amphibian, and avian vitellogenin genes. These cDNA probes hybridized to calf thymus DNA to a slight, but significant, extent, and not at all to Micrococcus lysodektikus DNA. DNA complementary to Xenopus albumin mRNA did not cross-hybridize significantly with locust or chicken DNA. Further evidence for the evolutionary conservation of vitellogenin genes was obtained from Southern blot analysis of restriction endonuclease-digested genomic DNA from a variety of vertebrate and invertebrate oviparous animals (Xenopus, chicken, migratory and desert locusts, yellow meal worm, carab moth, and Mediterranean fruitfly). When probed with cloned vitellogenin cDNAs from Xenopus and migratory locust, the DNA of these organisms showed varying degrees of homology of parts of the vitellogenin coding sequences. Southern blot analysis also showed that a part of the sequence specified in the cloned Xenopus vitellogenin cDNA was represented as repetitive DNA in the locust genome. However, cloned locust vitellogenin cDNA hybridized to discrete fragments of the restricted vertebrate DNA. These studies demonstrate a remarkably high degree of conservation of insect, amphibian, and avian vitellogenin genes.

Quantitation of DNase I sensitivity in Xenopus chromatin containing active and inactive globin, albumin and vitellogenin genes

The disappearance of defined restriction fragments of the beta 1-globin, an albumin and the A1 vitellogenin gene was quantitated after DNase I digestion and expressed by a sensitivity factor defined by a mathematical model. Analysis of naked DNA showed that the gene fragments have similar but not identical sensitivity factors. DNase I digestion of chromatin revealed for the same gene fragments sensitivity factors differing over a much wilder range. This is correlated to the activity of the genes analyzed: the beta 1-globin gene fragment is more sensitive to DNase I in chromatin of erythrocytes compared to hepatocytes whereas the albumin gene fragment is more sensitive to DNase I in chromatin of hepatocytes. The A1 vitellogenin gene has the same DNase I sensitivity in both cell types. Comparing the DNase I sensitivity of the three genes in their inactive state we suggest that different chromatin conformations may exist for inactive genes.

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.

Vitellogenesis and the vitellogenin gene family

Vitellogenin is synthesized under estrogen control in the liver, extensively modified, transported to the ovary, and there processed to the yolk proteins lipovitellin and phosvitin. In the frog Xenopus laevis there are at least four distinct but related vitellogenin genes. The two genes A1 and A2 have a 95 percent sequence homology in their messenger RNA coding regions, and contain 33 introns that interrupt the coding region (exons) at homologous positions. Sequences and lengths of analogous introns differ, and many introns contain repetitive DNA elements. The introns in these two genes that have apparently arisen by duplication have diverged extensively by events that include deletions, insertions, and probably duplications. Rapid evolutionary change involving rearrangements and the presence of repeated DNA suggests that the bulk of the sequences within introns may not have any specific function.

Four different vitellogenin proteins of Xenopus identified by translation in vitro

Kinetic analysis of vitellogenin mRNA translation in a cell-free reticulocyte lysate translation system revealed that a serine-rich sequence, most probably containing the phosvitin molecule, is located toward the end of the translational product and therefore resides near to the carboxy terminus of the vitellogenin molecule. Translation of the four different vitellogenin mRNAs in vitro and cleavage of the translational products with cyanogen bromide revealed that vitellogenin consists of four different polypeptides, each containing a serine-rich sequence toward its carboxy terminus.