Mutational studies reveal a complex set of positive and negative control elements within the chicken vitellogenin II promoter

Hepatic expression profiles of three subtypes of vitellogenin and estrogen receptor during vitellogenesis in cultured female yellowtail

Estradiol-17β (E₂) promotes the transcription of vitellogenin (Vtg) via nuclear estrogen receptor (ER). Three Vtg (VtgAa, VtgAb, and VtgC) and ER subtypes (ERα, ERβ1, and ERβ2) have been reported in perciform fish; however, the relationship between the transcriptional regulation of Vtg and ER subtypes remains unclear. Molecular characterization was performed and the expression profiles of vtg and er subtypes were investigated to elucidate mechanisms of synthesis of vtg subtypes in yellowtail, Seriola quinqueradiata. Primary structures and promoter regions were revealed in three subtypes of vtg and er, and all the vtg subtypes and erα were presumed to be estrogen-responsive genes. When all vtg subtypes were expressed significantly in the liver, hepatic expression levels of all the er subtypes also increased. Conversely, although plasma E₂ concentrations did not change significantly, the concentrations were high at the same time. Hepatic expression levels of all the vtg subtypes were highly correlated with hepatic erα, rather than with hepatic erβ subtypes and plasma E₂. A high positive correlation was also observed between erβ1 and β2, which seemed to be highly expressed at the pre- and late-vitellogenic stages. The results of the present study suggest that the transcription of the three vtg subtypes are regulated by three ER subtypes jointly, and ERα is the key transcription factor regulating the three vtg subtypes in yellowtail.

Ectopic Methylation of a Single Persistently Unmethylated CpG in the Promoter of the Vitellogenin Gene Abolishes Its Inducibility by Estrogen through Attenuation of Upstream Stimulating Factor Binding

The enhancer/promoter of the vitellogenin II gene (VTG) has been extensively studied as a model system of vertebrate transcriptional control. While deletion mutagenesis and in vivo footprinting identified the transcription factor (TF) binding sites governing its tissue specificity, DNase hypersensitivity and DNA methylation studies revealed the epigenetic changes accompanying its hormone-dependent activation. Moreover, upon induction with estrogen (E₂), the region flanking the estrogen-responsive element (ERE) was reported to undergo active DNA demethylation. We now show that although the VTG ERE is methylated in embryonic chicken liver and in LMH/2A hepatocytes, its induction by E₂ was not accompanied by extensive demethylation. In contrast, E₂ failed to activate a VTG enhancer/promoter-controlled luciferase reporter gene methylated by SssI. Surprisingly, this inducibility difference could be traced not to the ERE but rather to a single CpG in an E-box (CACGTG) sequence upstream of the VTG TATA box, which is unmethylated in vivo but methylated by SssI. We demonstrate that this E-box binds the upstream stimulating factor USF1/2. Selective methylation of the CpG within this binding site with an E-box-specific DNA methyltransferase, Eco72IM, was sufficient to attenuate USF1/2 binding in vitro and abolish the hormone-induced transcription of the VTG gene in the reporter system.

Molecular cloning of vitellogenin gene promoters and in vitro and in vivo transcription profiles following estradiol-17β administration in the cutthroat trout

Transcription of vitellogenin (vtg) genes are initiated when estradiol-17β (E₂)-estrogen receptor (ER) complexes bind estrogen response elements (ERE) located in the gene promoter region. Transcriptional regulation of dual vtg subtypes (major salmonid A-type vtg: vtgAs; minor C-type vtg: vtgC) by E₂ was investigated under co-expression of a potential major transcriptional factor, erα1, in cutthroat trout. Two forms of trout vtgAs promoters (1 and 2) and one vtgC promoter were sequenced. These promoters structurally differ based on the number of EREs present. The vtgAs promoter 1 exhibited the highest maximal transcriptional activity by in vitro gene reporter assays. The concentration of E₂ that induces 50% of gene reporter activity (half-maximal effective concentrations, EC₅₀) was similar among all vtg promoters and also to the EC₅₀ of E₂ administered to induce vtg transcription in vivo. This study revealed a difference in transcriptional properties of multiple vtg promoters for the first time in a salmonid species, providing the basis to understand mechanisms underlying regulation of vitellogenesis via dual vtg gene expression.

Estrogen-responsive genes encoding egg yolk proteins vitellogenin and apolipoprotein II in chicken are differentially regulated by selective estrogen receptor modulators

In a hen, large quantities of the egg yolk proteins, apolipoprotein II (apo-II) and vitellogenin (VG), are expressed in the liver and transported to the oviduct during egg production. Estrogenic stimulation of the hepatic expression of apo-II and VG is due to both transcriptional increase and mRNA stabilization. The nucleolytic degradation of apo-II messenger RNA (mRNA) is prevented by estrogen-regulated mRNA-stabilizing factor (E-RmRNASF). Gene-specific effects of a select panel of selective estrogen receptor modulators (SERMs) on the hepatic expression of the estrogen-responsive genes encoding apo-II, VG, and E-RmRNASF in the chicken liver were investigated. In the present study, 6-week-old roosters were treated with the vehicle, estrogen, the SERMs genistein, resveratrol, tamoxifen, pterostilbene, raloxifene, catechin, and clomiphene or a combination of estrogen and a 200-fold excess of each of the SERMs. Results from mRNA stabilization studies conducted to investigate the stimulation of expression of E-RmRNASF in the liver by these agents showed that the expression of E-RmRNASF in the liver was stimulated by estrogen and the SERMs genistein, resveratrol, tamoxifen, pterostilbene, and catechin but not by the vehicle, clomiphene or raloxifene. The expression of apo-II and VG from the aforementioned treatments was determined by Northern blot analysis, RNase protection assays, and Western blot analysis. The transcription and protein expression of both apo-II and VG genes were seen in response to treatment with estrogen but not with the SERMs or combinations of estrogen and each of the SERMs. The SERMs that stimulated the expression of E-RmRNASF antagonized the stimulation of the expression of both apo-II and VG by estrogen, demonstrating a gene-specific, selective regulation of the aforementioned genes in the chicken liver by the SERMs. The above panel of SERMs may likely have adverse effects on egg production.

Aryl hydrocarbon receptor activation leads to impairment of estrogen-driven chicken vitellogenin promoter activity in LMH cells

The aryl hydrocarbon receptor (AHR) is a ligand-activated transcription factor that mediates most of the toxic effects of environmental contaminants. Among the multiple pleiotropic responses elicited by AHR agonists, the antiestrogenic and endocrine-disrupting action of the receptor activation is one of the most studied. It has been demonstrated that some AHR agonists disrupt estradiol-induced vitellogenin synthesis in the fish liver via a mechanism that involves crosstalk between the AHR and the estrogen receptor (ER). Chicken hepatocytes have become a model for the study of AHR action in birds and the induction of the signal and its effect in these cells are well established. However, the impact of AHR activation on estradiol-regulated responses in the chicken liver remains to be demonstrated. The aim of the present study was, therefore, to determine the effect of AHR action on ER-driven transcription in a convenient model of chicken liver cells. For this purpose, we designed a reporter construct bearing the 5' regulatory region of the chicken vitellogenin II gene and used it to transfect chicken hepatoma LMH cells. We found that β-naphthoflavone represses ER-driven vitellogenin promoter activity and that this action is mediated by the AHR. This inhibitory crosstalk between both pathways appears to be unidirectional, since estradiol did not alter the transcript levels of an AHR target gene. Besides, and highly relevant, we show that LMH cell line transfected with a reporter construct bearing the chicken vitellogenin promoter sequence is a useful and convenient model for the study of AHR-ER interaction in chicken liver-derived cells.

Characterization of the regulatory region of Adra2c, the gene encoding the murine alpha2C adrenoceptor subtype

The 5' flanking sequence (3,227 base pairs, bp) of the mouse Adra2c subtype gene was determined and characterized. The transcription start site was mapped to nucleotide 'A' of two initiator motifs in tandem array, i.e. 1,159 and 1,153 bp upstream from the initiation codon of the open reading frame (ORF) of Adra2c, respectively. One structural feature salient to the 5' regulatory region of Adra2c is present in the sequence 1 kb immediately upstream from the receptor ORF, which is highly enriched in GC content (76%) and CpG island counts (i.e. CpG/GpC, 146:177), and thus rich in Sp1-binding motifs. At the 3' flanking region, the polyadenylation signal was mapped to 481 bp downstream from the termination codon. The transcript defined by sequence data thereby is consistent with a size of 3 kb (brain form) determined by Northern blot analysis. The transgene, Adra2c-NN- lacZ, which links the promoter region of Adra2c to the lacZ reporter gene, was constructed in order to evaluate the functional capacity of the promoter and the putative motifs residing within the defined regulatory region (1.9 kb upstream from the ORF) in directing the reporter gene expression in vitro in transiently transfected cells and in vivo in transgenic (Tg) mice. Permissive cell types to Adra2c-NN include those derived from neural and kidney lineages. Significant Adra2c-NN-driven reporter expression in Tg mice established suggests that alpha2C adrenoceptor expression is permissive under Adra2c-NN in central (cerebral cortex, hippocampus, subthalamus, hypothalamus, superior colliculus, cerebellum, and brain stem) and peripheral (pancreatic beta-islets) tissues.

Upstream stimulatory factor (USF) is recruited into a steroid hormone-triggered regulatory circuit by the estrogen-inducible transcription factor delta EF1

In the past decade, investigation into steroid hormone signaling has focused on the mechanisms of steroid hormone receptors as they act as signaling molecules and transcription factors in cells. However, the majority of hormone-responsive genes are not directly regulated by hormone receptors. These genes are termed secondary response genes. To explore the molecular mechanisms by which the steroid hormone estrogen regulates secondary response genes, the ovalbumin (Ov) gene was analyzed. Three protein-protein complexes (Chirp-I, -II, -III), which do not contain the estrogen receptor, are induced by estrogen to bind to the 5'-flanking region of the Ov gene. The Chirp-III DNA binding site, which is required for estrogen induction, binds a complex of proteins that contains the estrogen-inducible transcription factor deltaEF1. Experiments undertaken to identify proteins complexed with deltaEF1 led to the elucidation of a novel mechanism of action of upstream stimulatory factor-1 (USF-1), which involves its tethering to the Ov gene 5'-flanking region by deltaEF1. Gel mobility shift assays and co-immunoprecipitation experiments identify USF-1 as a component of Chirp-III. However, USF-1 is not able to bind to the Chirp-III site independently. In addition, USF-1 overexpression is able to induce Ov gene promoter activity in transfection experiments. USF-1 can also potentiate the induction of the Ov gene by the transcription factor deltaEF1. Moreover, mutating the deltaEF1 binding sites in the 5'-flanking region of the Ov gene abrogates induction of the gene by USF-1. These data begin to establish a molecular mechanism by which hormone-inducible transcription factors and ubiquitous transcription factors cooperate to regulate estrogen-induced secondary response gene expression.

Alterations in chromatin structure are implicated in the activation of the steroid hormone response unit of the ovalbumin gene

Hormone-responsive genes rely on complex regulatory elements known as hormone response units to integrate various regulatory signals. Characterization of the steroid-dependent regulatory element (SDRE) in the check ovalbumin gene (--892 to --796) suggests that it functions as a hormone response unit. Previous studies using gel mobility shift assays and several types of footprinting analyses demonstrated that proteins bind to this entire element in vitro even in the absence of steroid hormones. However, the genomic footprinting experiments described herein indicate that the binding of three different proteins or protein complexes to the SDRE requires estrogen and corticosterone, suggesting that the chromatin structure of this site is restricted in vivo. Transfection experiments using linker scanning and point mutations support the contention that the binding of these three complexes is essential for induction of the ovalbumin gene by steroid hormones. In addition, functional analyses suggest that a fourth complex is also necessary for maximal induction. These and other data suggest that the SDRE functions as a hormone response unit to coordinate signals generated by two steroid hormones.

Two functionally different protein isoforms are produced from the chicken estrogen receptor-alpha gene

The existence of two forms of the chicken estrogen receptor-alpha protein (ER-alpha) in chicken tissues is demonstrated: the previously reported receptor (cER-alpha form I), which has a size of 66 kDa, and a new form (cER-alpha form II), which lacks the N-terminal 41 amino acids present in form I and thus gives rise to a protein of 61 kDa. Whereas the 66-kDa protein is the translation product of several cER-alpha mRNAs (A1-D), the cER-alpha protein isoform II is encoded by a new cER-alpha mRNA (A2), which is transcribed in vivo from a specific promoter that is located in the region of the previously assigned translation start site of the cER-alpha gene. SI nuclease mapping analysis reveals that cER-alpha mRNA A2 is liver enriched. The resulting cER-alpha forms I and II differ in their ability to modulate estrogen target gene expression in a promoter- and cell type-specific manner. Whereas cER-alpha form I activates or represses in a strictly E2-dependent manner, the truncated form is characterized by a partial transactivating or repressing activity in the absence of its ligand. Comparison of the N-terminal coding regions of different vertebrate ER-alpha reveal a conservation of the translation start methionine of the protein ER-alpha form II in other oviparous species but not in mammals. The expression of two classes of ER-alpha transcripts encoding the two ER-alpha receptor forms in the liver of Xenopus laevis and rainbow trout is demonstrated. Therefore, the existence of two functionally different protein isoforms produced from the ER-alpha gene is probably a common and specific feature in oviparous species.

Mitogenic up-regulation of the PRL-1 protein-tyrosine phosphatase gene by Egr-1. Egr-1 activation is an early event in liver regeneration

The cellular signals that initiate cell growth are incompletely understood. Insight could be provided by understanding the signals regulating the transcriptional induction of immediate-early genes which occurs within minutes of the growth stimulus. The expression of the PRL-1 gene, which encodes a unique nuclear protein-tyrosine phosphatase, is rapidly induced in regenerating liver and mitogen-treated cells. Transcription of the PRL-1 gene increased in the rat liver remnant within a few minutes after partial hepatectomy and largely explained the increase in steady-state PRL-1 mRNA in the first few hours posthepatectomy. Egr-1 (early growth response factor) specifically bound a region of the proximal PRL-1 promoter P1 (-99). Egr-1 binding activity was more rapidly induced in regenerating liver than mitogen-treated H35 and NIH 3T3 cells, remained elevated through 4 h posthepatectomy, and appeared to be dependent not only on new Egr-1 protein synthesis but on post-translational regulation of Egr-1. Egr-1 efficiently transactivated a PRL-1 promoter reporter construct containing an intact not mutant Egr-1 site, and the Egr-1 site largely accounted for PRL-1 gene up-regulation in response to mitogen stimulation. These data predict that Egr-1 activation is an early event in liver regeneration and mitogen-activated cells that provides a regulatory stimulus for a subset of immediate-early genes.

The nucleosome: a powerful regulator of transcription

Nucleosomes provide the architectural framework for transcription. Histones, DNA elements, and transcription factors are organized into precise regulatory complexes. Positioned nucleosomes can facilitate or impede the transcription process. These structures are dynamic, reflecting the capacity of chromatin to adopt different functional states. Histones are mobile with respect to DNA sequence. Individual histone domains are targeted for posttranslational modifications. Histone acetylation promotes transcription factor access to nucleosomal DNA and relieves inhibitory effects on transcriptional initiation and elongation. The nucleosomal infrastructure emerges as powerful contributor to the regulation of gene activity.

A composite regulatory element in the first intron of the estrogen-responsive very low density apolipoprotein II gene

During periods of egg laying in the chicken, when circulating levels of estrogen are increased, the liver-specific estrogen-dependent very low density apolipoprotein II (apoVLDLII) gene is expressed. This expression takes place primarily at the level of transcription, driven by two estrogen response elements that reside in the promoter. In transient transfection assays, expression is increased fourfold when the first intron is added to the promoter construct, indicating that 75% of the regulation comes from intron A. Using in vitro DNase I footprinting, six protein-binding sites were revealed throughout the first intron. The functional significance of these binding sites was evaluated by mutation and transient transfection. Two of the protein-binding regions were shown to increase transcription. Site-specific mutations introduced at either the +66 to +86 or +112 to +129 sites disrupted trans-factor binding and reduced the estrogen-dependent expression by 45% and 34%, respectively. A plasmid containing both mutations resulted in a 43% decrease in expression, indicating that the contributions of these regions are not additive. Competition with known sequences in electrophoretic mobility shift assays suggested that the +66 to +86 site binds a chicken member of the nuclear receptor transcription factor family.

The gene encoding human nuclear protein tyrosine phosphatase, PRL-1. Cloning, chromosomal localization, and identification of an intron enhancer

Expression of the rat PRL-1 gene, which encodes a unique nuclear protein tyrosine phosphatase, is positively associated with cellular growth during liver development, regeneration, and oncogenesis but with differentiation in intestine and other tissues. Here, we analyzed the structure of the human PRL-1 gene and localized it to chromosome 6 within band q12. Human, rat, and mouse PRL-1 are 100% conserved at the amino acid level and 55% identical to a newly identified Caenorhabditis elegans PRL-1. The presence of two promoter activities, P1 and P2, in the human PRL-1 gene were identified by primer extension and RNase protection assays. A functional TATA box was identified in promoter P1 upstream of the non-coding first exon. A non-canonical internal promoter, P2, was found in the first intron that results in PRL-1 transcripts beginning 8 base pairs downstream of the 5'-end of exon 2 and causes no alteration in the encoded protein. The first 200-base pair region of either promoter P1 or P2 conferred high basal transcriptional activity. An enhancer that bound a developmentally regulated factor, PRL-1 intron enhancer complex (PIEC), was localized to the first intron of the human PRL-1 gene. The presence of PIEC correlated with the ability of the intron enhancer to confer transcriptional activation in HepG2 and F9 cells. The intron enhancer contributed significantly to PRL-1 promoter activity in HepG2 cells which contain PIEC but not to NIH 3T3 cells which do not.

Regulation of the vitellogenin gene B1 promoter after transfer into hepatocytes in primary cultures

The estrogen-dependent and tissue-specific regulation of the Xenopus laevis vitellogenin gene B1 promoter has been studied by lipid-mediated DNA transfer into Xenopus hepatocytes in primary culture. Hepatocytes achieve an efficient hormonal control of this promoter through a functional interaction between the estrogen responsive elements and a promoter proximal region upstream of the TATA box, which is characterized by a high density of binding sites for the transcription factors CTF/NF-1, C/EBP and HNF3. DNA accessibility to restriction enzymes within the chromosomal copy of the vitellogenin gene B1 promoter shows that the estrogen responsive unit and the promoter proximal region are sensitive to digestion in uninduced and estrogen-induced hepatocytes but not in erythrocyte nuclei. Together, these findings support the notion that chromatin configuration as well as the interplay of promoter elements mediate proper hormone-dependent and tissue-specific expression of the B1 vitellogenin gene.

The isolation and characterization of the promoter of the human type 1 inositol 1,4,5-trisphosphate receptor

In humans, at least three types of inositol (1,4,5)-trisphosphate receptor (IP3R) are present. The gene encoding type 1 IP3R (IP3R-I) is expressed in all cell types, although expression predominates in Purkinje cells. To study the regulation of the human IP3R-I gene, we isolated and characterized a 2.1-kb 5' flanking region. In transient expression assays using a rat cell line, analysis of various deletion mutants demonstrated that a fragment of only 86 bp 5' of the putative tsp displayed a promoter activity similar to that of the 2.1-kb fragment. Also, we compared the sequence of the human IP3R-I promoter with the sequence of the mouse IP3R-I promoter. Considerable sequence homology is present in four distinct domains, which include several conserved putative binding sites for transcription factors. Further, we demonstrate a decrease in the activity of the isolated human IP3R-I promoter and of the endogenous IP3R-I promoter after 48 h of treatment with retinoic acid. Analysis of deletion constructs of the human promoter indicates that the decreased promoter activity in response to retinoic acid is likely to be mediated by a conserved AP-2 binding site.

Liver-enriched transcription factors, HNF-1, HNF-3, and C/EBP, are major contributors to the strong activity of the chicken CYP2H1 promoter in chick embryo hepatocytes

Chicken CYP2H1 promoter constructs express strongly in chick embryo hepatocytes at a level comparable with that of Rous sarcoma viral promoter. We have identified the transcription factors responsible for the active CYP2H1 promoter. Binding sites for transcription factors were located within the first 160 bp of promoter sequence using promoter deletion experiments and DNase I footprint analysis. Sequence analysis revealed characteristic sites for the liver-enriched transcription factors of the HNF-1, HNF-3, and C/EBP families and for the ubiquitous factor, USF. Protein binding to these sites was established by gel mobility shift assays. Mutagenesis and transient transfection experiments demonstrated that these sites, in combination, were responsible for the strong promoter activity with a substantial contribution from HNF-1 and HNF-3. The promoter was also active in mammalian HepG2 and COS-1 cell lines where expression was dependent on the identified transcription factor binding sites but promoter activity in the HeLa cells was low. Transactivation experiments revealed that promoter expression could be activated through the appropriate binding sites by exogenously expressed rat HNF-1alpha or HNF-1beta, rat HNF-3alpha or HNF-3beta and chicken C/EBP alpha. Transcriptional synergism between HNF-1 and C/EBP was observed in these transactivation experiments. A Barbie box-like sequence overlapped the USF element but was not functional. The results demonstrate that liver-enriched transcription factors and USF direct strong expression of the CYP2H1 promoter in transiently transfected cells. By comparison, in vivo expression of this gene in uninduced chick embryo hepatocytes is low but markedly increased by phenobarbital. Drug induction may therefore substantially reflect derepression of this inherently active promoter.

Carbohydrate regulation of hepatic gene expression. Evidence against a role for the upstream stimulatory factor

Hepatic expression of the genes encoding L-type pyruvate kinase (L-PK) and S14 is induced in rats upon feeding them a high carbohydrate, low fat diet. A carbohydrate response element (ChoRE) containing two CACGTG-type E boxes has been mapped in the 5'-flanking region of both of these genes. The nature of the ChoRE suggests that a member of the basic/helix-loop-helix/leucine zipper family of proteins may be responsible for mediating the response to carbohydrate. Indeed, the upstream stimulatory factor (USF), a ubiquitous basic/helix-loop-helix/leucine zipper protein, is present in hepatic nuclear extracts and binds to the ChoREs of L-PK and S14 in vitro. We have conducted experiments to determine whether USF is involved in the carbohydrate-mediated regulation of L-PK and S14. For this purpose, dominant negative forms of USF that are capable of heterodimerizing with endogenous USF but not of binding to DNA were expressed in primary hepatocytes. Expression of these forms did not block either S14 or L-PK induction by glucose. In addition, we have constructed mutant ChoREs that retain their carbohydrate responsiveness but have lost the ability to bind USF. Together, these data suggest that USF is not the carbohydrate-responsive factor that stimulates S14 and L-PK expression and that a distinct hepatic factor is likely to be responsible for the transcriptional response.

Apolipoprotein (apo) B and apoII gene expression are both estrogen-responsive in chick embryo liver but only apoII is estrogen-responsive in kidney

Estrogen regulates the hepatic synthesis of a variety of proteins required for egg yolk production in oviparous vertebrates. In chickens, two of these proteins, apolipoprotein (apo) B and apoII, comprise the major protein components of specialized very low density lipoprotein particles that transport triacylglycerols and cholesterol to the developing egg yolk. In the adult, apoB is synthesized constitutively in liver, small intestine, and kidney but is estrogen-responsive only in the liver. In this work we have examined the embryonic expression of the apoB and apoII genes in yolk sac, liver, kidney, and small intestine. The 14 kb apoB mRNA was first detected at day 3 of development in vascular yolk sac, a tissue involved in the transfer of yolk lipids into the embryonic circulation. Constitutive apoB mRNA expression was detectable in liver at day 6.5 and in kidney at day 7.5, but in intestine was barely detectable before hatching. The hepatic apoB gene acquired estrogen-responsiveness at day 6.5 and its hormone-dependent expression increased throughout development in concert with the estrogen-responsive expression of the apoII gene. In contrast, the constitutively expressed apoB gene in kidney remained unresponsive to estrogen. Surprisingly, the apoII gene was found to be responsive to estrogen in both the embryonic kidney and small intestine. ApoII mRNA induction by estrogen in kidney at day 11 was at 10% of the level in the liver but estrogen-responsiveness decreased later in development and was low in the adult.(ABSTRACT TRUNCATED AT 250 WORDS)

The 5' flanking region of the serotonin 2 receptor gene directs brain specific expression in transgenic animals

The neuron is the predominant cell type expressing the serotonin 2 (5-HT2) receptor in the central nervous system. Transcriptional control elements involved in the restriction of 5-HT2 receptor gene expression to neuronal cells and tissues were studied using both transgenic mice and cultured cells. Sequences extending from a site near the translational initiation codon to -5.6 kb in the 5' flanking region of the murine receptor gene were found to be sufficient to target gene expression to the brain in transgenic animals. In transient transfection experiments a basal promoter was identified which was functional in both neuronal and nonneuronal cells. Upstream of the basal promoter two repressor domains were found within the 5' flanking sequence of the receptor gene. These sequences repressed gene activity in all cells except cells of neuronal origin, thus the repressor domains are the primary determinants to generate neuronal cell-specific transcription of the 5-HT2 receptor gene.

Constitutive expression of a microinjected glucose-regulated protein (grp78) fusion gene during early Xenopus laevis development

In this study we have found that a rat glucose-regulated protein (grp) 78 chloramphenicol acetyltransferase (CAT) fusion gene deleted to -456 bp at the 5' end and injected into fertilized Xenopus eggs was first expressed in a constitutive manner in late blastula stage embryos and displayed increased expression as the embryos developed to the gastrula and neurula stages. Using a series of internal deletion mutants and linker-scanner mutants of the rat grp78 promoter, we have found that a CCAAT box and CCAAT-like element within the region -129 to -90 were essential for constitutive expression of the chimeric genes in neurula stage embryos. These results suggest conservation of the regulatory sequences within the grp78 promoter between rat and Xenopus. Interestingly, deletion or alteration of sequences between -130 and -149 had a dramatic stimulatory effect on basal promoter activity. This effect, which was not observed previously in rat cells, may be the result of upstream elements that are transcriptionally active in Xenopus and that can compensate for the mutated or deleted sequences. It is also possible that these results indicate the presence of a negative regulatory element that is recognized by the Xenopus transcriptional apparatus.

Cis-acting elements reinforcing the activity of the estrogen-response element in the very-low-density apolipoprotein II gene promoter

The gene coding for chicken very low density apolipoprotein II (apoVLDLII) is expressed exclusively in liver in response to estrogen. Previous work in our laboratory identified several protein binding sites, identified by the letters A to F, and their cognate factors within the first 300 bp flanking the gene. Here we present an extensive functional analysis of the apoVLDLII promoter by gene transfer experiments using a chicken hepatoma cell line and cultured non-hepatic cells. Deletion analysis revealed that the -301 to -163-bp promoter region, comprising elements E1, E2 and F, is sufficient for strong estrogen-dependent expression. Mutation analysis demonstrated that efficient transcription requires the interplay of the major estrogen response element E1 with several other cis-acting elements. Analysis of individual protein binding sites showed that element E1 is sufficient by itself to confer weak estrogen-induced transcription from the apoVLDLII promoter, and that additional promoter elements are required for full estrogen-responsiveness. Elements F and B1 were capable of strongly potentiating the activity of element E1. In general, the activity of certain cis-acting elements appeared to be strongly promoter-context dependent. Cultured non-liver cells expressed transfected VLDL-CAT reporter plasmids in the presence of cotransfected estrogen receptor expression vector in a hormone-dependent way, indicating that for the control of tissue specificity the 5'-proximal promoter region is not sufficient.

Negative regulation of transcription in eukaryotes

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Glial cell-specific expression of the serotonin 2 receptor gene: selective reactivation of a repressed promoter

The 5' flanking region of the 5-HT2 receptor gene has been cloned, sequenced and its transcriptional regulatory functions analyzed. The promoter lacks an identifiable TATA motif, and utilizes at least 11 clustered start sites. Promoter function was analyzed by transient assays in rat C6 glioma cells, which were shown to express the endogenous 5-HT2 receptor gene, as well as in rat CREF and human HeLa cells which do not express the endogenous gene. The basal promoter functioned equally well in all three cell lines; and a repression domain, located upstream of the basal promoter, inhibited activity of the promoter in all three cell lines. A far upstream cell specific activator domain restored promoter activity in C6 glioma cells, but did not reactivate the silenced promoter in CREF or HeLa cells. The upstream activator domain, repressor domain and basal promoter functioned in concert to achieve cell type specific expression. The activator domain did not direct C6 glioma cell specific expression in the absence of the repressor domain or in constructs carrying a heterologous basal promoter. These results indicate that glial cell expression of the 5-HT2 receptor gene is achieved through a cell type specific reactivation of a repressed promoter.

Characterization of the chicken apolipoprotein A-I gene 5'-flanking region

Apolipoprotein A-I (apoA-I) is a major protein component of plasma high-density lipoprotein in all species studied, and plays an important role in cholesterol homeostasis. In an earlier study, we cloned and structurally characterized the chicken apoA-I gene. In this study, the 5'-flanking region of the chicken apoA-I gene was sequenced and functionally characterized. Sequence analysis of the 510-nucleotide 5' upstream region revealed the presence of TATA and CCAAT boxes. In addition, we identified binding sites for several transcription factors such as Sp1, AP1, and NFI.2. When the 5' fragment was ligated into a promoterless CAT vector and transfected into a chicken hepatocarcinoma cell line (LMH), the bacterial chloramphenicol acetyl transferase (CAT) gene was expressed, suggesting transcriptional regulation is associated with this region. Transfection studies with other 5' deletion constructs revealed that the sequence spanning the region -82 to +87 contained the major transcriptional activity. DNase I footprinting, gel retardation, and Southwestern blot analyses showed that the fragment interacts with nuclear proteins.

Vitellogenin synthesis in cultured hepatocytes; an in vitro test for the estrogenic potency of chemicals

We describe here an in vitro technique to assess the estrogenic activity of chemicals. This technique is based on rainbow trout hepatocytes incubated in a basic medium free of any additional growth factors or estrogenic chemicals and uses the production of vitellogenin (VTG) as a marker for the estrogenic potency of the compounds tested. The system allows at least some of the metabolic transformations which are undertaken by the liver cells in vivo and could therefore be used for xenobiotic compounds which exhibit estrogenic activities after liver metabolic transformation. A dose-response curve was always consistently obtained using estradiol-17 beta (E2), with a mid point at around 100 nM E2 and a maximum response at around 1000 nM. Established estrogens such as 17 a 1 ethynylestradiol (EE2) or diethylstilboestrol (DES) were also tested. EE2 appeared to be equipotent with E2 and DES slightly less potent. E2 conjugates were, perhaps surprisingly, also very potent. Estradiol-3-sulfate was equipotent with E2 and estradiol-17 beta-glucuronide approx. 10% as potent. Other steroids such as androgens and progesterone, though active in the bioassay, were 3 orders of magnitude less potent than E2. Of the various steroids tested, only cortisol, at concentrations up to 50 microM, was completely inactive. Six different phytoestrogens were tested in the assay. All were weakly estrogenic, possessing approximately one thousandth the potency of E2 (they were as potent as the androgens and progesterone). All six phytoestrogens, as well as the androgens and progesterone, were tested in the presence of tamoxifen. In all cases tamoxifen reduced the production of VTG significantly, demonstrating that the estrogenic action of all of these compounds was most likely mediated by the E2 receptor. The potencies determined here may not reflect the situation in vivo but can provide complementary results about the activity of chemicals which need an hepatic metabolization to be estrogenic. Hepatocyte cultures would profitably be developed in other species to sustain these results.

Characterization and developmental expression of Xenopus C/EBP gene

The Xenopus homolog of the transcription factor C/EBP (CCAAT/enhancer core binding protein), cloned from an adult Xenopus liver cDNA library, encodes a protein whose sequence is 67% homologous to that of rat C/EBP at the amino acid level, with virtually identical sequence of the basic-zipper region at the carboxyl terminus. As determined by gel electrophoretic mobility shift assays, the protein synthesized from xC/EBP cDNA bound specifically to the consensus binding site for C/EBP-like proteins. Northern blotting and RNase protection revealed a single species of xC/EBP mRNA of 2.7 kb which was most abundant in adult Xenopus liver, with smaller amounts in spleen, kidney, oviduct and brain and undetectable in heart and skeletal muscle. Although a small amount of this transcript could be detected in unfertilized eggs and early embryos, its accumulation rose sharply at the onset of metamorphosis (stage 55/56), and continued to increase through metamorphic climax to reach its highest level in stage 66 froglet liver, but thereafter declining in adult liver. In situ hybridization revealed a uniform pattern of distribution of xC/EBP mRNA in the liver and fat body throughout metamorphosis. Towards the end of metamorphosis, high levels of xC/EBP mRNA were detected in epithelial cells of the digestive tract. However, the spatial pattern of cells expressing the transcript changed markedly in the developing kidney. Our results suggest that xC/EBP may be involved as a transcription factor in the establishment of the adult phenotype during post-embryonic development of Xenopus.