Enhancer, repressor, and promoter specificities combine to regulate the rat alpha-fetoprotein gene

Construction of a plasmid vector for liver-specific inhibition of hepatocyte nuclear factor 4 alpha expression

Hepatocyte nuclear factor-4alpha (HNF-4a) is an important transcription factor in the liver, and regulates a large number of genes involved in many aspects of hepatocyte functions. In this study, a liver-specific transcriptional regulatory element comprised of albumin promoter (ALBp) and alpha-fetoprotein enhancer (AFPe) was obtained and cloned into the plasmid pHNF4sh-CMV(short hairpin RNA targeting HNF4α) with original CMV promoter removed, resulting to pHNF4sh-EP for liver-specific knockdown of HNF4α expression. In an attempt to verify its characteristics, pHNF4sh-EP was transfected to L02, HepG2, and COS1 cell lines in vitro and delivered into mice in vivo. pHNF4sh-CMV and pNCsh-EP were used as controls. For in vitro, the level of HNF4α mRNA and protein was decreased in all cell lines transfected with pHNF4sh-CMV whereas HNF4α mRNA and protein decreasing was only observed in L02 and HepG2 cell lines upon transfection with pHNF4sh-EP, and this decreasing was more significant as compared with pHNF4sh-CMV transfected cells. For in vivo, the decreasing of HNF4α mRNA and protein was observed in both liver and kidney tissues upon transfection with pHNF4sh-CMV. After transfection with pHNF4sh-EP, decreasing of HNF4α mRNA and protein was only found in liver tissue and this decreasing was more significant. No obvious HNF4α mRNA and protein decreasing was detected either in vitro or in vivo after transfected with pNCsh-EP. In conclusion, pHNF4sh-EP could highly-active and liver-specific knockdown of HNF4α expression liver and it will be useful for further study of the funcitions of HNF4α in liver.

Construction of a highly-active, liver-specific transcriptional regulatory element through combination of the albumin promoter and α-fetoprotein enhancer

In an attempt to construct a highly active, liver-specific transcriptional regulatory element, the mouse albumin promoter (ALBp) and α-fetoprotein enhancer (AFPe) were obtained. To verify its hepatic specificity and activity, the AFPe-ALBp-containing fragment was cloned into the plasmids, pVAX-S and pGL3-Luc with original promoter removed. Plasmid pVAX-AFPe-ALBp-S was then transfected into hepatic and non-hepatic cells in vitro, and delivered into mouse by intravenous injection and intramuscular injection, respectively. In addition, pGL3-AFPe-ALBp-Luc was transfected into hepatic and non-hepatic cell lines; pVAX1, pVAX1/S, and pGL3-ALBp-Luc were used as controls. The expression of hepatitis B surface antigen (HBsAg) was observed, and luciferase activity in cells was measured. For plasmid pVAX-AFPe-ALBp-S, the expression of HBsAg was observed in hepatic cell lines, but not in a non-hepatic cell line. Using pVAX-S, the expression of HBsAg was observed in both hepatic and non-hepatic cell lines. In cells expressing pGL3-AFPe-ALBp-Luc, the level of luciferase activity was significantly higher in hepatic cell lines, compared with the non-hepatic cell lines. In addition, the level of luciferase activity in cells expressing pGL3-AFPe-ALBp-Luc was significantly higher than that of pGL3-ALBp-Luc in hepatic cell lines, suggesting that AFPe could enhance target gene expression under the control of ALBp. The expression of HBsAg was detected in mouse liver, but not muscle when using pVAX-AFPe-ALBp-S. In contrast, the expression of HBsAg was detected in both mouse liver and muscle upon transfection with pVAX-S. In conclusion, the AFPe-ALBp element could be used as a tool to induce liver-specific expression of a target gene.

The alpha-fetoprotein enhancer region activates the albumin and alpha-fetoprotein promoters during liver development

The four members of the albumin gene family encode the serum transport proteins albumin, alpha-fetoprotein, alpha-albumin, and vitamin D-binding protein. These genes are transcribed primarily in the liver with each having a different pattern of developmental expression. The tight linkage of these genes, particularly that of albumin, alpha-fetoprotein and alpha-albumin, and their liver-specific expression, has led to the suggestion that these genes share common regulatory elements. To directly examine whether the alpha-fetoprotein enhancer region could regulate the albumin gene family, expression of these genes was monitored in mice in which this region was deleted by homologous recombination. Our data indicate that this enhancer region is required for alpha-fetoprotein and albumin activation early in liver development and alpha-fetoprotein reactivation during liver regeneration, but that albumin, alpha-albumin, and vitamin D-binding protein expression later in hepatic development is not affected by the absence of these enhancers. We also demonstrate that RNA polymerase II loading on the alpha-fetoprotein and albumin promoters is reduced in the absence of this enhancer region, indicating a direct role for these enhancers in the assembly of the RNA Polymerase II complex during liver development.

Characterization of Distant Enhancers and Promoters in the Albumin-α-Fetoprotein Locus during Active and Silenced Expression

The albumin and alpha-fetoprotein genes are adjacent and express closely related serum proteins. Both genes are strongly expressed in fetal liver, primarily through activation by distant enhancers, but the AFP gene selectively undergoes developmental silencing. We used chromatin immunoprecipitation to study enhancers and promoters during active and silenced gene expression. In adult phenotype cells, the silenced AFP gene was actively repressed at the promoter and two proximal enhancers, characterized by the absence of coactivators and acetylated histone 4, and the presence of corepressors and K9-methylated histone 3. Specific transcription factors, TBP, and RNA polymerase II were all detected on both active and silenced genes, indicating that both states were actively regulated. Surprisingly, promoter-specific factors were also detected on enhancers, especially with reduced chromatin shearing. Under these conditions, an enhancer-specific factor was also detected on the albumin promoter. Association of promoter- and enhancer-specific factors was confirmed by sequential immunoprecipitation. Because no binding was detected on intervening segments, these promoter-enhancer associations suggest looping.

AUF1-like protein binds specifically to DAS cis-acting element that regulates mouse alpha-fetoprotein gene expression

Alpha-fetoprotein (AFP) is one of the major serum proteins in the early life of mammals. We have previously identified a novel cis-acting element designated as DAS at the 5'-flanking region of the AFP gene and demonstrated that the DAS sequence can be specifically recognized by nuclear protein DAP-II in AFP-producing hepatoma cells and retinoic acid (RA)-induced AFP-producing F9 cells. In this study, we used DNA affinity chromatography to purify the DAP-II proteins from the nuclear extracts (NE) of RA-treated F9 cells. The purified DAP-II complex mainly contained five proteins, with molecular weights of 45, 42, 32, 30, and 20 kDa, respectively. The identification of these proteins was determined by MALDI-TOF mass spectrometric analysis and a database search. These proteins were found to belong to the AUF1 RNA-binding protein family. Protein (30 kDa), one of five proteins in an isolated DAP-II complex, was matched with amino acid sequence highly similar to muAUF1-3. The expression of this protein is inducible by RA, and the pattern of the protein expression is the same as DAP-II proteins in F9 cells after treatment with RA during differentiation. Our results suggest that the 30-kDa protein is a novel isoform of AUF1 family and is the main component of the DAP-II complex that binds to the DAS sequence.

The human vitamin D-binding protein gene contains locus control determinants sufficient for autonomous activation in hepatic chromatin

The human vitamin D-binding protein (hDBP) gene is a member of a cluster that includes albumin, alpha-fetoprotein and alpha-albumin genes. The common origin, physical linkage and hepatic expression of these four genes predict shared regulatory element(s). However, separation of hDBP from the other three genes by 1.5 Mb argues that hDBP may be under autonomous control. To test for hDBP autonomy, mouse lines were generated with a transgene containing the hDBP gene along with extensive flanking sequences. Expression of this transgene was hepatic, robust and proportional to transgene copy number. DNase I hypersensitive site (HS) mapping revealed five liver-specific HS at the hDBP locus: HSI and HSIII at -2.1 kb and -0.13 kb upstream of the transcription initiation site, HSIV and HSV within intron 1 and HSVII located 3' to the poly(A) site. A second transgene with minimal flanking sequences confirmed the sufficiency of these gene-proximal determinants for hepatic activation. The hepatic-specific HS aligned with segments of phylogenetically conserved non-coding sequences. These data demonstrate the autonomy of the hDBP locus and suggest that this control is mediated by chromatin-based locus control determinants in close proximity to, and within the transcription unit.

Striking differences between the mouse and the human alpha-fetoprotein enhancers

The alpha-fetoprotein (AFP) gene is expressed abundantly in the fetal liver and transcriptionally repressed in the adult liver, but can be reactivated during liver regeneration and in liver tumors. Previous studies identified three enhancers, E1, E2, and E3, upstream of the mouse and rat Afp genes and a single enhancer upstream of the human gene. We have compared the sequences upstream of the rodent and primate AFP genes. Our analysis demonstrates that the previously identified human enhancer is the counterpart to mouse E2. This comparison also reveals that a functional primate counterpart to the rodent E1 is absent due to a deletion that removes the core region of this enhancer. Furthermore, our studies identify a novel human enhancer corresponding to rodent E3. Despite the overall similarity of E3 between human and mouse, we found differences in transcription factor binding sites between these species. A C/EBP binding site is conserved but two other motifs in rodent E3, one that binds orphan nuclear receptors and a second that binds FoxA proteins, are not conserved in humans. The human counterpart to the rodent FoxA site can bind COUP-TF factors. Despite the overall sequence similarity in E3 between mice and humans, the difference in factor binding sites in E3, as well as the absence of E1 in primates, indicates that different mechanisms regulate AFP transcription in these different species.

Functional mapping of tissue-specific elements of the human alpha-fetoprotein gene enhancer

Serum alpha-fetoprotein (AFP) levels in hepatocellular carcinoma (HCC) patients and expression of the protein in cultured HCC cell lines are highly variable. These observations may arise from features correlated with tissue-specific expression of the gene. Extremely strong and potent liver-specific enhancer activity is confined from -4.1 to -3.3 kb upstream to the human AFP gene in contrast with that of the rodent which exists in three widely separated regions. To understand the tissue-specific expression of AFP, we examined cis-acting elements in the enhancer. Results revealed binding sites for selected liver-enriched transcription factors (LETFs) in both domains A (-4120 to -3756 bp) and B (-3492 to -3300 bp) of the gene. These sites included: one hepatocyte nuclear factor (HNF)-1 and HNF-4, two HNF-3, and two C/EBP binding sites in domain A. An adjacent domain B contained one HNF-3 site and three C/EBP sites plus a previously identified HNF-1 site. Each of these elements alone has the ability to stimulate heterogeneous promoter activity in a dose-dependent manner when transfected into AFP producing cells. A comparative study showed that the presence of two HNF-1 and one HNF-4 site is a characteristic feature of human but not rodent AFP enhancer. The mRNA levels of the liver-enriched transcription factors (LETFs) were variable in individual HCC cell lines and together with silencer activities may underlie differential expression of the AFP gene.

Regulation of alpha-fetoprotein expression by Nkx2.8

The alpha-fetoprotein (AFP) gene is an important model of developmental gene silencing and neoplastic gene reactivation. Nkx2.8 is a divergent homeodomain factor originally cloned through its binding to the promoter-coupling element (PCE), a regulatory region upstream of the AFP promoter that mediates stimulation by distant enhancers. Nkx2.8 is the only developmentally regulated factor that has been associated with AFP gene expression. Fetoprotein transcription factor, an orphan nuclear receptor, has also been shown to bind the PCE but is not developmentally regulated. The binding specificities of both families of transcription factor were determined, and overlapping sites for each were defined in the PCE. After modification of nuclear extract and gel shift analysis procedures, Nkx2.8 was identified in six AFP-positive cell lines. Transient-transfection analysis did not show transcriptional stimulation by Nkx2.8 or other active NK2 factors, which only interfered with gene expression. However, two sets of analysis demonstrated the relationship of Nkx2.8 to AFP expression: chromatin immunoprecipitation demonstrated that Nkx2.8 bound to the active AFP promoter, and antisense inhibition of Nkx2.8 mRNA translation selectively reduced expression of both the endogenous human AFP gene and transfected reporters containing the rat AFP promoter.

Conserved sequences in a tissue-specific regulatory region of the pdx-1 gene mediate transcription in Pancreatic beta cells: role for hepatocyte nuclear factor 3 beta and Pax6

Pancreas duodenum homeobox 1 (PDX-1) is absolutely required for pancreas development and the maintenance of islet beta-cell function. Temporal and cell-type-specific transcription of the pdx-1 gene is controlled by factors acting upon sequences found within its 5'-flanking region. Critical cis-acting transcriptional control elements are located within a nuclease hypersensitive site that contains three conserved subdomains, termed areas I, II, and III. We show that area II acts as a tissue-specific regulatory region of the pdx-1 gene, directing transgene expression to a subpopulation of islet cells. Mutation of the area II hepatocyte nuclear factor 3 (HNF3) binding element in the larger area I- and area II- containing PstBst fragment also decreases PB(hsplacZ) transgene penetrance. These two results indicate possible ontogenetic and/or functional heterogeneity of the beta-cell population. Several other potential positive- and negative-acting control elements were identified in area II after mutation of the highly conserved sequence blocks within this subdomain. Pax6, a factor essential for islet alpha-cell development and islet hormone gene expression, was shown to bind in area II in vitro. Pax6 and HNF3 beta were also found to bind to this region in vivo by using the chromatin immunoprecipitation assay. Collectively, these data suggest an important role for both HNF3 beta and Pax6 in regulating pdx-1 expression in beta cells.

Gene therapy vectors harboring AFP regulatory sequences. Preparation of an adenoviral vector

Gene therapy for hepatocellular carcinoma (HCC) may be achieved by introducing a therapeutic gene under the control of transcriptional regulatory sequences of the alpha-fetoprotein (AFP) gene. Transcription of the human AFP gene is controlled positively by the promoter and the enhancer and negatively by the silencer. The AFP promoter is a 200-bp region immediately upstream of the AFP gene, and the enhancer is present between 3 and 4.9 kb upstream of the transcription initiation site. Two silencer regions have been identified upstream of the gene, one at -0.31 kb and the other at -1.75 kb. To achieve specific killing of HCC, adenoviral vectors carrying AFP regulatory sequences have been constructed. In this article, we describe the details of the preparation of an adenoviral vector designed to express the herpes simplex virus thymidine kinase gene under the control of the 4.9-kb AFP 5'-regulatory sequence. Treatment with this viral vector followed by ganciclovir resulted in specific killing of AFP-positive HCC transplanted in nude mice. Other viral vectors containing AFP-regulatory sequences are also discussed.

Distant enhancers stimulate the albumin promoter through complex proximal binding sites

The albumin-alpha-fetoprotein locus epitomizes the main features of transcriptional regulation of fetal and adult hepatocyte-specific genes: developmentally regulated promoters and strong distant enhancers. Full enhancer activity required only a proximal albumin-promoter region containing the TATA box, hepatic nuclear factor 1 (HNF1), and nuclear factor Y (NF-Y) sites. Deletion of the HNF1 site abrogated enhancer and promoter activity, whereas methylation of the site reduced all activity by about 3-fold. Deletion of the NF-Y site attenuated activity by about half, but much of the activity could be replaced by juxtaposition of an upstream region (designated distal element IV). Gel shift and competition analysis demonstrated that binding of architectural factors overlapped NF-Y binding. Moreover, a mutation that eliminated NF-Y binding but only minimally perturbed the surrounding region did not affect enhancer function. In plasmids with a second promoter, the enhancers simultaneously stimulated both albumin and alpha-fetoprotein promoters with minimal competition, but surprisingly some mutations in the albumin promoter attenuated expression from both promoters, whereas another uncoupled their expression. With single promoters, the function of the proximal promoter region was controlled by three parameters in the following hierarchy: HNF1 binding > local architecture > NF-Y binding, but integrated two-promoter function had a much greater dependence on NF-Y.

Hepatitis B viral transactivator HBx alleviates p53-mediated repression of alpha-fetoprotein gene expression

Chronic infection with hepatitis B virus (HBV) is associated with development of hepatocellular carcinoma (HCC). The exact mechanism by which chronic infection with HBV contributes to onset of HCC is unknown. However, previous studies have implicated the HBV transactivator protein, HBx, in progression of HCC through its ability to bind the human tumor suppressor protein, p53. In this study, we have examined the ability of HBx to modify p53 regulation of the HCC tumor marker gene, alpha-fetoprotein (AFP). By utilizing in vitro chromatin assembly of DNA templates prior to transcription analysis, we have demonstrated that HBx functionally disrupts p53-mediated repression of AFP transcription through protein-protein interaction. HBx modification of p53 gene regulation is both tissue-specific and dependent upon the p53 binding element. Our data suggest that the mechanism by which HBx alleviates p53 repression of AFP transcription is through an association with DNA-bound p53, resulting in a loss of p53 interaction with liver-specific transcriptional co-repressors.

Human alpha-fetoprotein transcriptional regulatory sequences. Application to gene therapy

The AFP regulatory sequences are among the best known tumor-specific transcriptional regulators. A number of groups have demonstrated that a variety of genes can be expressed in an HCC-specific manner under the control of the AFP regulatory sequences in vitro and in vivo. It would appear that, with the development of a suitable delivery system, HCC-directed gene therapy using the AFP regulatory sequences holds a promising future.

p53-mediated repression of alpha-fetoprotein gene expression by specific DNA binding

Aberrant expression of the alpha-fetoprotein (AFP) gene is characteristic of a majority of hepatocellular carcinoma cases and serves as a diagnostic tumor-specific marker. By dissecting regulatory mechanisms through electromobility gel shift, transient-transfection, Western blot, and in vitro transcription analyses, we find that AFP gene expression is controlled in part by mutually exclusive binding of two trans-acting factors, p53 and hepatic nuclear factor 3 (HNF-3). HNF-3 protein activates while p53 represses AFP transcription through sequence-specific binding within the previously identified AFP developmental repressor domain. A single mutation within the DNA binding domain of p53 protein or a mutation of the p53 DNA binding element within the AFP developmental repressor eliminates p53-repressive effects in both transient-transfection and cell-free expression systems. Coexpression of p300 histone acetyltransferase, which has been shown to acetylate p53 and increase specific DNA binding, amplifies the p53-mediated repression. Western blot analysis of proteins present in developmentally staged, liver nuclear extracts reveal a one-to-one correlation between activation of p53 protein and repression of AFP during hepatic development. Induction of p53 in response to actinomycin D or hypoxic stress decreases AFP expression. Studies in fibroblast cells lacking HNF-3 further support a model for p53-mediated repression that is both passive through displacement of a tissue-specific activating factor and active in the presence of tissue-specific corepressors. This mechanism for p53-mediated repression of AFP gene expression may be active during hepatic differentiation and lost in the process of tumorigenesis.

Identification of a cis-acting element in the rat alpha-fetoprotein gene and its specific binding proteins in F9 cells during retinoic acid-induced differentiation

Mouse F9 embryonic teratocarcinoma stem cells can be induced to differentiate into visceral endoderm. Following retinoic acid (RA) treatment, alpha-fetoprotein (AFP), a differentiation marker, is expressed and secreted. The mechanism by which RA regulates AFP expression during differentiation is not clear. The relatively late induction of AFP indicates that the AFP gene may not be a primary target of RA activity during F9 cell differentiation. In this study, a CAT reporter plasmid containing the rat AFP 5'-regulatory region (-7040 to +7) adjacent to the CAT gene (pAFPCAT) was stably transfected into F9 cells and used to delineate a cis-acting element which associates with AFP gene activation. Similar spatial and temporal expression patterns between the transcriptional activity of the recombinant AFP gene and the endogenous AFP gene demonstrate that this stably transfected F9 system can be used to dissect both cis-elements and trans-acting factors responsible for RA-induced AFP expression. Using a series of deletion mutants of the pAFPCAT, the region between -2611 to -1855 was found to be important in AFP-induction. Subsequent analysis identified a functional sequence (-1905 to -1891, 5'-ACTAAAATGGAGACT-3') that differentially binds nuclear proteins from undifferentiated and differentiated F9 cells. This sequence, designed as differentiation-associated sequence (DAS) for its unique binding of a nuclear protein (DAP-II) that appears during RA-induced F9 differentiation, acts as a regulatory protein factor in AFP gene activation.

Retinoic acid mediates down-regulation of the alpha-fetoprotein gene through decreased expression of hepatocyte nuclear factors

alpha-Fetoprotein (AFP), a protein highly induced during fetal liver development, is down-regulated by retinoids in the human hepatoma cell line Hep3B, in contrast to up-regulation observed in other cell types. Previously, we have documented that such up-regulation involves direct effects through cis-retinoid X receptor-binding sites in the AFP enhancer. In this report, we show a distinctive effect of all-trans-retinoic acid (RA) in Hep3B cells. RA caused a marked decrease in AFP transcripts. Deletion analysis of the upstream regulatory region of the AFP gene revealed that cis-acting sites required for down-regulation resided near the promoter. Gel mobility shift assays for factors binding to key elements in the AFP promoter region demonstrated that hepatocyte nuclear factor (HNF) 1 binding was diminished in nuclear extracts from RA-treated cells. In addition, HNF4, which is not known to bind to the AFP promoter but does regulate HNF1, was also diminished. The levels of HNF1 and HNF4 mRNA were also decreased following RA treatment. AFP promoter-chloramphenicol acetyltransferase transient transfection assays demonstrated that the level of HNF1 had a direct impact on basal transcription as well as RA-mediated down-regulation of the AFP gene, and that co-transfection of HNF1 and HNF4, but not transfection of either factor alone, reversed the RA-mediated inhibition. Taken together these data point to an interaction among the RA, HNF1, and HNF4 signals, which is reflected in decreased expression of AFP.

A novel nk-2-related transcription factor associated with human fetal liver and hepatocellular carcinoma

A novel cDNA was partially isolated from a HepG2 cell expression library by screening with the promoter-linked coupling element (PCE), a site from the alpha-fetoprotein (AFP) gene promoter. The remainder of the cDNA was cloned from fetal liver RNA using random amplification of cDNA ends. The cDNA encodes a 239-amino acid peptide with domains closely related to the Drosophila factor nk-2. The new factor is the eighth vertebrate factor related to nk-2, hence nkx-2.8. Northern blot and reverse transcriptase polymerase chain reaction analysis demonstrated mRNA in HepG2, two other AFP-expressing human cell lines, and human fetal liver. Transcripts were not detected in adult liver. Cell-free translation produced DNA binding activity that gel shifted a PCE oligonucleotide. Cotransfection of nkx-2.8 expression and PCE reporter plasmids into HeLa cells demonstrated transcriptional activation; NH2-terminal deletion eliminated this activity. Cotransfection into AFP-producing hepatocytic cells repressed AFP reporter expression, suggesting that endogenous activity was already present in these cells. In contrast, cotransfection into an AFP-negative hepatocytic line produced moderate activation of the AFP gene. The cardiac developmental factor nkx-2.5 could substitute for nkx-2.8 in all transfection assays, whereas another related factor, thyroid transcription factor 1, showed a more limited range of substitution. Although the studies have yet to establish definitively that nkx-2.8 is the AFP gene regulator PCF, the two factors share a common DNA binding site, gel shift behavior, migration on SDS-acrylamide gels, and cellular distribution. Moreover, the nk-2-related genes are developmental regulators, and nkx-2.8 is the first such factor associated with liver development.

Chicken ovalbumin upstream promoter-transcription factor, hepatocyte nuclear factor 3, and CCAAT/enhancer binding protein control the far-upstream enhancer of the rat alpha-fetoprotein gene

We have further characterized the most distal of the three alpha-fetoprotein (AFP) enhancers required for expression of the AFP gene in fetal hepatocytes and yolk sac endodermal cells. Almost total rat AFP enhancer 3 (E3) activity is driven by a 160-bp fragment at -6 kb containing three target regions for nuclear proteins that cooperate to stimulate transcription from the AFP and the thymidine kinase promoters in HepG2 hepatoma cells. Region 1, recently shown to be crucial for correct function of the enhancer in liver of transgenic mice, is recognized by two sets of transcription factors that bind to partly overlapping sites, 1a and 1b, in a noncooperative and nonexclusive manner. Site 1a contains a motif, AGGTCA, which is recognized by chicken ovalbumin upstream promoter transcription factors (COUP-TFs), but not by hepatocyte nuclear factor 4. Hepatocyte nuclear factor 3 (HNF3) and CCAAT/enhancer binding protein (C/EBP), which bind to regions 2 and 3, respectively, are likely responsible for the liver-specific E3 action. They play a key role by acting in synergy. The participation of nuclear receptors such as COUP-TFs, with C/EBP and HNF3, in the tight control of the distal AFP enhancer is a new, and perhaps key, step toward understanding the regulation and function of this enhancer, which may remain active throughout development.

RXR-mediated regulation of the alpha-fetoprotein gene through an upstream element

Retinoic acid (RA) is known to have potent effects on development and differentiation. RA exerts its effects on transcription through two distinct classes of nuclear receptors, the retinoic acid receptor (RAR) and the retinoid X receptor (RXR), that bind to specific RA-responsive elements (RARE) in target genes. alpha-Fetoprotein (AFP), a hepatocyte differentiation, maturation, and carcinogenesis marker, is transcriptionally upregulated by RA in McA-RH8994 hepatoma cells. Using deletion mapping analysis, we have identified a RARE-like sequence that is located between -2406 and -2378 of the transcription initiation site of the rat AFP gene. Sequence analysis demonstrated that this cis-acting element consists of three direct repeats and one inverted repeat of a GGGTCA-like half-site. The putative RARE can specifically bind to both RXR homodimers and RAR/RXR heterodimers as determined by gel mobility shift assays. A DR1 direct repeat was more efficient than a DR5 direct repeat oligonucleotide in competition for binding of the putative RARE to RXR and RAR/RXR. A mutagenesis study indicated that to have a full-strength induction, all the repeats were required. To further analyze the function of this element in vivo, a reporter gene construct of the putative RARE combined with the thymidine kinase promoter was cotransfected with RAR and RXR expression plasmids in CV1 cells. CAT assays demonstrated that overexpression of RXRalpha conferred the best RA response, consistent with our previous observation that 9-cis-RA is more potent than all-trans-RA for inducing the expression of the AFP gene. In addition, the RXR selective ligand LG100153 alone can stimulate the expression of the AFP gene. Our data suggest that an RXR-mediated pathway exists for modulation of AFP gene expression through a specific element.

Individual mouse alpha-fetoprotein enhancer elements exhibit different patterns of tissue-specific and hepatic position-dependent activities

Transcription of the mouse alpha-fetoprotein (AFP) gene, which is expressed at high levels in the visceral endoderm of the yolk sac and fetal liver and at low levels in the fetal gut, is regulated by three distinct upstream enhancer regions. To investigate the activities of these regions, each enhancer was individually linked to a heterologous human beta-globin promoter fused to the mouse class I H-2Dd structural gene. When tested in transgenic mice, the beta-globin promoter alone has minimal activity. We find that all three enhancers activate the beta-globin promoter in an AFP-like pattern; i.e., activity is detected in the yolk sac, fetal liver, and fetal gut. The enhancers remain active in the livers and guts of adult mice, consistent with previous studies showing that postnatal AFP repression is due not to the loss of enhancer activity but to a dominant repressor region. Enhancer III also functions in the brain. In addition, these studies reveal that the three enhancers exhibit different position-dependent activities in the adult liver. Enhancers I and II are most active in hepatocytes surrounding the central vein, with a gradual decrease in activity along the hepatic plates toward the portal triad. Enhancer III is active exclusively in hepatocytes surrounding the central vein. These data represent the first examples of individual control elements exhibiting positionally regulated activity in adult liver.

Enhancer sharing in a plasmid model containing the alpha-fetoprotein and albumin promoters

It has been proposed that the alpha-fetoprotein (AFP) enhancers also regulate the adjacent albumin gene, since the -10 kbp albumin enhancer is inactive in a number of cell lines that express albumin. In transfection experiments, the AFP enhancers strongly stimulate the albumin promoter in cells that silence the AFP promoter. These observations led us to develop a plasmid model of AFP-albumin gene switching, in which the albumin and AFP promoters would compete for the three AFP enhancers. However, when AFPCAT + ALBgal genes were combined with the AFP enhancers in one plasmid, both genes were driven at full activity. There was no change in the relative promoter expression over a wide range of transfected DNA concentrations, demonstrating that relative promoter activity was independent of DNA concentration and of promoter concentration, and that neither promoter was limiting the expression of the other. In contrast, a control plasmid containing two albumin promoters showed mutual inhibition, indicating the expected promoter competition. The albumin and AFP promoters noncompetitively shared the three enhancers on this plasmid, resulting in high levels of transcription from both promoters.

Mouse alpha-fetoprotein gene 5' regulatory elements are required for postnatal regulation by raf and Rif

The mouse alpha-fetoprotein (AFP) gene is expressed at high levels in the yolk sac and fetal liver and at low levels in the fetal gut. AFP synthesis decreases dramatically shortly after birth to low levels that are maintained in the adult liver and gut. AFP expression can be reactivated in the adult liver upon renewed cell proliferation such as during liver regeneration or in hepatocellular carcinomas. Previously, two unlinked genetic loci that modulate postnatal AFP levels were identified. The raf locus controls, at least in part, basal steady-state AFP mRNA levels in adult liver. Rif influences the extent of AFP mRNA induction during liver regeneration. Transgenic mice were used to examine the role of 5' AFP regulatory regions in raf- and Rif-mediated control. A fragment of the AFP 5' region containing enhancer element I, the repressor, and the promoter was linked to the mouse class I H-2Dd structural gene. We demonstrate that this hybrid AFP-Dd transgene is expressed in the appropriate tissues. In addition, it is postnatally repressed and reactivated during liver regeneration in parallel with the endogenous AFP gene. Therefore, proper transcriptional control does not require the AFP structural gene. Furthermore, the AFP 5' control region is sufficient to confer raf and Rif responsiveness to the linked H-2Dd structural gene, suggesting that raf and Rif act at the level of transcriptional initiation.

A novel hepatocytic transcription factor that binds the alpha-fetoprotein promoter-linked coupling element

We recently characterized a promoter-linked coupling element (PCE) in the rat alpha-fetoprotein (AFP) gene required for strong transcriptional stimulation by distant enhancers (P. Wen, N. Crawford, and J. Locker, Nucleic Acids Res. 21:1911-1918, 1993). In this study, oligonucleotide gel retardation and competition experiments defined the PCE as a 12-bp binding site, TGTCCTTGAACA, an imperfect inverted repeat from -166 to -155 near the AFP promoter. A factor that bound this site (PCF) was abundant in HepG2 nuclear extracts and detectable in extracts from several other AFP-producing hepatocarcinoma cell lines and fetal liver. Hepatocytic cell lines that did not express AFP, nonhepatocytic cell lines, adult liver, and fetal brain did not show the factor. Experiments excluded the possibility that PCF activity was due to binding of glucocorticoid receptor or an AP1-like factor that bound overlapping sites. Competition experiments with several mutant oligonucleotides determined that the optimum PCF binding site was TGTCCTTGAAC(A/T). Mutations decreased binding or totally abolished binding activity. In expression plasmids, PCE mutations strongly reduced gene expression. UV cross-linking to a PCE probe identified peptide bands near 34 kDa. PCF was purified by heparin-Sepharose chromatography followed by affinity binding to oligomerized PCE DNA. The product resolved as a complex of three peptides (PCF alpha 1, PCF alpha 2, and PCF beta, 32 to 34 kDa) on sodium dodecyl sulfate-acrylamide gels. The peptide sizes and gel patterns are unlike those of any of the well-described hepatic transcription factors, and the binding site has not been previously reported. PCF thus appears to be a novel transcription factor.

Mouse alpha-fetoprotein gene 5' regulatory elements are required for postnatal regulation by raf and Rif

The mouse alpha-fetoprotein (AFP) gene is expressed at high levels in the yolk sac and fetal liver and at low levels in the fetal gut. AFP synthesis decreases dramatically shortly after birth to low levels that are maintained in the adult liver and gut. AFP expression can be reactivated in the adult liver upon renewed cell proliferation such as during liver regeneration or in hepatocellular carcinomas. Previously, two unlinked genetic loci that modulate postnatal AFP levels were identified. The raf locus controls, at least in part, basal steady-state AFP mRNA levels in adult liver. Rif influences the extent of AFP mRNA induction during liver regeneration. Transgenic mice were used to examine the role of 5' AFP regulatory regions in raf- and Rif-mediated control. A fragment of the AFP 5' region containing enhancer element I, the repressor, and the promoter was linked to the mouse class I H-2Dd structural gene. We demonstrate that this hybrid AFP-Dd transgene is expressed in the appropriate tissues. In addition, it is postnatally repressed and reactivated during liver regeneration in parallel with the endogenous AFP gene. Therefore, proper transcriptional control does not require the AFP structural gene. Furthermore, the AFP 5' control region is sufficient to confer raf and Rif responsiveness to the linked H-2Dd structural gene, suggesting that raf and Rif act at the level of transcriptional initiation.

A novel hepatocytic transcription factor that binds the alpha-fetoprotein promoter-linked coupling element

We recently characterized a promoter-linked coupling element (PCE) in the rat alpha-fetoprotein (AFP) gene required for strong transcriptional stimulation by distant enhancers (P. Wen, N. Crawford, and J. Locker, Nucleic Acids Res. 21:1911-1918, 1993). In this study, oligonucleotide gel retardation and competition experiments defined the PCE as a 12-bp binding site, TGTCCTTGAACA, an imperfect inverted repeat from -166 to -155 near the AFP promoter. A factor that bound this site (PCF) was abundant in HepG2 nuclear extracts and detectable in extracts from several other AFP-producing hepatocarcinoma cell lines and fetal liver. Hepatocytic cell lines that did not express AFP, nonhepatocytic cell lines, adult liver, and fetal brain did not show the factor. Experiments excluded the possibility that PCF activity was due to binding of glucocorticoid receptor or an AP1-like factor that bound overlapping sites. Competition experiments with several mutant oligonucleotides determined that the optimum PCF binding site was TGTCCTTGAAC(A/T). Mutations decreased binding or totally abolished binding activity. In expression plasmids, PCE mutations strongly reduced gene expression. UV cross-linking to a PCE probe identified peptide bands near 34 kDa. PCF was purified by heparin-Sepharose chromatography followed by affinity binding to oligomerized PCE DNA. The product resolved as a complex of three peptides (PCF alpha 1, PCF alpha 2, and PCF beta, 32 to 34 kDa) on sodium dodecyl sulfate-acrylamide gels. The peptide sizes and gel patterns are unlike those of any of the well-described hepatic transcription factors, and the binding site has not been previously reported. PCF thus appears to be a novel transcription factor.

Members of the CAAT/enhancer-binding protein, hepatocyte nuclear factor-1 and nuclear factor-1 families can differentially modulate the activities of the rat alpha-fetoprotein promoter and enhancer

The promoter of the rat alpha-fetoprotein (AFP) gene, which makes the expression of the developmentally regulated AFP gene specific to the liver, is a putative target for transcription factors of the CAAT/enhancer-binding protein (C/EBP), hepatocyte nuclear factor-1 (HNF-1) and nuclear factor-1 (NF-1) families. We have evaluated the influence of these factors on the activity of the AFP promoter by transfection of HepG2 hepatoma cells with the appropriate expression vector plus a CAT plasmid under the control of the AFP promoter. A similar plasmid bearing the rat albumin promoter was used as a control. C/EBP alpha, C/EBP beta and D-binding protein (DBP) acted as trans-activators on the AFP promoter, whereas liver inhibitory protein (LIP), a truncated form of C/EBP beta, was a potent negative regulator of the promoter. C/EBP alpha also bound to and stimulated the activity of the AFP enhancer at -2.5 kb. Interestingly, HNF-1 beta was found to be more potent than HNF-1 alpha in activating the AFP promoter. This effect was specific, as it did not occur with the rat albumin promoter. HNF-1 beta, which is produced earlier than HNF-1 alpha during liver development, would thus have the greater influence on the AFP promoter in early development. Both HNF-1s allowed expression of the AFP promoter in cells of nonhepatic origin. Overexpression of NF-1 induced a specific decrease in the activity of the AFP promoter. This strongly suggests that competition between NF-1 and HNF-1 for binding to their overlapping binding sites on the AFP promoter is critical for modulating its activity. Thus changing combinations of these trans-acting factors may tightly modulate the AFP promoter activity in the course of liver development and carcinogenesis.

A promoter-linked coupling region required for stimulation of alpha-fetoprotein transcription by distant enhancers

We previously demonstrated that the rat alpha-fetoprotein (AFP) gene has three upstream enhancers that stimulate the AFP promoter additively in HepG2 cells (1). In this paper, deletion analysis demonstrated that a promoter-linked segment from -178 to -155 was required for full activity when the enhancers were distant from the promoter, even at less than their normal genomic distances, but dispensable when the enhancers were moved close to the promoter. This 'promoter-coupling element' appears to interact simultaneously with all three enhancers. Deletion analysis also localized a transcription stimulatory and a negative region in the promoter. Though these latter regions controlled the strength of the isolated promoter, they did not affect 'coupling' to the distant enhancers, and transcription stimulation by these distal promoter elements was small compared to the distant enhancers. Overall, the distant enhancers, acting through the promoter-coupling element, accounted for 70% of the activity of the transfected AFP gene. Footprint analysis with HepG2 nuclear extracts demonstrated protein binding at two sites near the promoter-coupling element. The data indicate a positive transcription control mechanism by which distant enhancers stimulate the AFP promoter through a specific promoter-linked element.

Functional analysis of developmentally regulated chromatin-hypersensitive domains carrying the alpha 1-fetoprotein gene promoter and the albumin/alpha 1-fetoprotein intergenic enhancer

During liver development, the tandem alpha 1-fetoprotein (AFP)/albumin locus is triggered at the AFP end and then asymmetrically enhanced; this is followed by autonomous repression of the AFP-encoding gene. To understand this regulation better, we characterized the two early developmental stage-specific DNase I-hypersensitive (DH) sites so far identified in rat liver AFP/albumin chromatin: an intergenic DH-enhancer site and the AFP DH-promoter site. Mutation-transfection analyses circumscribed the DH-enhancer domain to a 200-bp DNA segment stringently conserved among species. Targeted mutations, DNA-protein-binding assays, and coexpression experiments pinpointed C/EBP as the major activatory component of the intergenic enhancer. Structure-function relationships at the AFP DH-promoter site defined a discrete glucocorticoid-regulated domain activated cooperatively by HNF1 and a highly specific AFP transcription factor, FTF, which binds to a steroid receptor recognition motif. The HNF1/FTF/DNA complex is deactivated by glucocorticoid receptors or by the ubiquitous factor NF1, which eliminates HNF1 by competition at an overlapping, high-affinity binding site. We propose that the HNF1-NF1 site might serve as a developmental switch to direct autonomous AFP gene repression in late liver development. We also conclude that the intergenic enhancer is driven by C/EBP alpha primarily to fulfill albumin gene activation functions at early developmental stages. Factor FTF seems to be the key regulator of AFP gene-specific functions in carcinoembryonic states.

Functional analysis of developmentally regulated chromatin-hypersensitive domains carrying the alpha 1-fetoprotein gene promoter and the albumin/alpha 1-fetoprotein intergenic enhancer

During liver development, the tandem alpha 1-fetoprotein (AFP)/albumin locus is triggered at the AFP end and then asymmetrically enhanced; this is followed by autonomous repression of the AFP-encoding gene. To understand this regulation better, we characterized the two early developmental stage-specific DNase I-hypersensitive (DH) sites so far identified in rat liver AFP/albumin chromatin: an intergenic DH-enhancer site and the AFP DH-promoter site. Mutation-transfection analyses circumscribed the DH-enhancer domain to a 200-bp DNA segment stringently conserved among species. Targeted mutations, DNA-protein-binding assays, and coexpression experiments pinpointed C/EBP as the major activatory component of the intergenic enhancer. Structure-function relationships at the AFP DH-promoter site defined a discrete glucocorticoid-regulated domain activated cooperatively by HNF1 and a highly specific AFP transcription factor, FTF, which binds to a steroid receptor recognition motif. The HNF1/FTF/DNA complex is deactivated by glucocorticoid receptors or by the ubiquitous factor NF1, which eliminates HNF1 by competition at an overlapping, high-affinity binding site. We propose that the HNF1-NF1 site might serve as a developmental switch to direct autonomous AFP gene repression in late liver development. We also conclude that the intergenic enhancer is driven by C/EBP alpha primarily to fulfill albumin gene activation functions at early developmental stages. Factor FTF seems to be the key regulator of AFP gene-specific functions in carcinoembryonic states.

An upstream activating sequence from the Aspergillus nidulans gpdA gene

Introduction of a previously identified promoter element of the Aspergillus nidulans gpdA gene (encoding glyceraldehyde-3-phosphate dehydrogenase), the so-called gpd box, into the upstream region of the highly regulated A. nidulans amdS gene (encoding acetamidase), significantly increased (up to 30-fold) the expression of the lacZ reporter gene fused to these expression signals. This increase was dependent on the orientation of the gpd box and on the site of introduction into the amdS upstream region. The presence of additional gpdA sequences which flank the gpd box reduced or even extinguished positive effects of the gpd box. omega-Amino acid and carbon catabolite regulation of the amdS promoter were retained after introduction of the gpd box, indicating that the gpd box does not abolish interactions of the regulatory proteins, AmdR and CreA, with the amdS transcription control sequences. Based on the results, it is suggested that the gpd box comprises at least two separate activities: one being orientation dependent, but relatively independent of position of the gpd box in the upstream region, and the other is only functional near other sites of transcriptional control. Most likely, both activities are not involved in regulation of the amdS promoter.