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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The A2 vitellogenin gene of Xenopus laevis, which is expressed liver specifically, contains an A-activator-binding site (AABS) that mediates high in vitro transcriptional activity in rat liver nuclear extracts. Footprint experiments with DNase I and gel retardation assays revealed the binding of several proteins to AABS. Using binding sites of known DNA-binding proteins as competitors in the gel retardation assay, we found that the transcription factor C/EBP and/or one of its "iso-binders" as well as LFB1/HNF1 bound AABS. These interactions were confirmed by in vitro transcription experiments using various oligonucleotides as competitors. However, saturating amounts of C/EBP- and LFB1/HNF1-binding sites as competitors only partially blocked AABS-mediated transcriptional activity. This finding implies that at least a third distinct transcription factor interacts with AABS. In vitro transcription experiments revealed that AABS was present not only in the closely related Xenopus A1 vitellogenin gene but also in acute-phase genes as a liver-specific regulatory element known to confer the interleukin-6 response. Both AABS and the interleukin-6 response element are promoter modules interacting with at least three distinct transcription factors, including C/EBP and LFB1/HNF1.
Mol Cell Biol 1991 Jan
PMID:Liver-specific gene expression: A-activator-binding site, a promoter module present in vitellogenin and acute-phase genes. 170 15

The hepatic transcription of the angiotensinogen gene is regulated by both glucocorticoids and cytokines generated as products of the acute phase reaction. We have identified a multimodular enhancer in the 5'-flanking region of the rat angiotensinogen gene that mediates these responses and consists of an acute phase response element (APRE) flanked on both sides by adjacent glucocorticoid response element consensus motifs (GREs). Induction of transcription by the cytokine interleukin-1 (IL-1) is glucocorticoid dependent and mediated through the APRE. The APRE binds in a mutually exclusive manner a cytokine/phorbol ester-inducible protein (BPi), indistinguishable from nuclear factor kB, and a family of constitutive liver proteins (BPcs) related to the heat-stable transcription factor C/EBP. Using mutated 5'-flanking sequences of the angiotensinogen gene fused to a firefly luciferase reporter gene transfected into hepatoblastoma (HepG2) cells, we have mapped enhanson sequences required for the transcriptional response to glucocorticoids. Two functionally distinct GREs are identified by deletion and site-directed mutagenesis, both of which mediate glucocorticoid-stimulated transcription in vivo. Glucocorticoid-induced transcription mediated by the angiotensinogen gene enhancer is, furthermore, dependent on the occupancy of the APRE by either the BPi or a member of the BPc family because a mutant APRE that binds neither BPi nor BPc exhibits an attenuated glucocorticoid responsiveness. Mutant APREs that permit exclusive binding of either BPi or BPc synergistically transmit the glucocorticoid response mediated by one or the other of the adjacent GREs. Thus, the induction of angiotensinogen gene transcription involves interaction between the glucocorticoid receptor and either one of the APRE-binding proteins: either the cytokine-inducible NFkB or the constitutive family of C/EBP-like proteins, bound to adjacent enhansons in a mutually synergistic enhancer complex.
Mol Endocrinol 1990 Dec
PMID:Synergistic enhansons located within an acute phase responsive enhancer modulate glucocorticoid induction of angiotensinogen gene transcription. 170 27

A complex cell culture environment has been shown to maintain the differentiated state of hepatocytes, yet the mechanisms by which environmental cues selectively maintain liver-specific gene transcription have been unknown. In this paper we show that the hepatic environment regulates the activities of at least three liver-enriched transcription factors, eE-TF, eG-TF/HNF3, and eH-TF, that activate the mouse serum albumin enhancer. eE-TF is a heat-stable factor that has a DNA-binding specificity similar to that of the liver transcription factor C/EBP, but is a distinct protein. eG-TF/HNF3 contributes to the liver-specific transcription of several other serum protein genes. eH-TF binds to a TGTTTGC sequence that occurs at regulatory sites of the albumin promoter, the hepatitis B virus enhancer, and other hepatic genes. eE-TF, eG-TF/HNF3, and eH-TF are regulated by different combinations of the following cell culture conditions: a hormonally defined serum-free medium; an extracellular matrix gel; and a transformation-competent simian virus 40 large T antigen. We propose a regulatory network model to explain how cues from the cell lineage and the extracellular environment coordinately help maintain the activities of transcription factors involved in hepatocyte differentiation.
Mol Cell Biol 1991 Feb
PMID:Extracellular signals that regulate liver transcription factors during hepatic differentiation in vitro. 199 Feb 82

The far-upstream mouse albumin enhancer (-10.5 to -8.43 kilobases) has both positive and negative regulatory domains which contribute to the rate and tissue specificity of albumin gene transcription. (R. S. Herbst, N. Friedman, J. E. Darnell, Jr., and L. E. Babiss, Proc. Natl. Acad. Sci. USA 86:1553-1557). In this work, the negative regulatory region has been functionally localized to sequences -8.7 to -8.43 kilobases upstream of the albumin gene cap site. In the absence of the albumin-modulating region (in which there are binding sites for the transcription factor C/EBP), the negative region can suppress a neighboring positive-acting element, thereby interfering with albumin enhancer function. The negative region is also capable of negating the positive action of the heterologous transthyretin enhancer in an orientation-independent fashion. Within this negative-acting region we can detect two DNA-binding sites, both of which are recognized by a protein present in all cell types tested. This DNA-binding activity is not competed for by any of a series of known DNA-binding sites, and hence this new protein is a candidate for a role in suppressing the albumin gene in nonhepatic cells.
Mol Cell Biol 1990 Aug
PMID:The mouse albumin enhancer contains a negative regulatory element that interacts with a novel DNA-binding protein. 237 Aug 57

Among the various factors binding to DNA elements within the mouse albumin promoter, NF-Y is the only one present at identical concentrations in the nuclei of all examined tissues. NF-Y binds to albumin promoter element C, which contains the sequence CCAAT. To determine whether this factor augments in vitro transcription from the albumin promoter, an extensive point-mutation analysis was performed within the promoter element C. In liver extracts, six out of the ten mutations result in a strong inhibition of NF-Y binding and in a concomitant decrease in promoter activity. Two mutations that increase the affinity of the C-element for NF-Y also augment the transcription efficiency from the albumin promoter. A similarly strong correlation of NF-Y-binding with transcription efficiency has also been observed in spleen nuclear extracts. The liver-enriched CCAAT and enhancer binding factor C/EBP also recognizes the C element. In contrast to NF-Y, no correlation between the affinity of mutant C-elements for C/EBP and transcriptional activity could be observed in liver nuclear extracts.
J Mol Biol 1990 Aug 20
PMID:A ubiquitous CCAAT factor is required for efficient in vitro transcription from the mouse albumin promoter. 238 72

Similar to tRNA genes and the VAI gene, the Alu family repeats are transcribed by RNA polymerase III and contain a split intragenic promoter. Results of our previous studies have shown that when the anterior, box A-containing promoter element (5'-Pu-Pu-Py-N-N-Pu-Pu-Py-G-G-3' in which Pu is any purine, Py is any pyrimidine, and N is any nucleotide) of a human Alu family repeat is deleted, the remaining box B-containing promoter element (5'-G-A/T-T-C-Pu-A-N-N-C-3') is still capable of directing weak transcriptional initiation at approximately 70 base pairs (bp) upstream from the box B sequence. This is different from the tRNA genes in which the box A-containing promoter element plays the major role in the positioning of the transcriptional initiation site(s). To account for this difference, we first carried out competition experiments in which we show that the posterior element of the Alu repeat competes with the VAI gene effectively for the transcription factor C in HeLa cell extracts. We then constructed a series of contraction and expansion mutants of the Alu repeat promoter in which the spacing between boxes A and B was systematically varied by molecular cloning. In vitro transcription of these clones in HeLa cell extracts was analyzed by RNA gel electrophoresis and primer extension mapping. We show that when the box A and box B promoter sequences are separated by 47 to 298 bp, the transcriptional initiation sites remain 4 to 5 bp upstream from box A. However, this positioning function by the box A-containing promoter element was lost when the spacing was shortened to only 26 bp or increased to longer than 600 bp. Instead, transcriptional initiation occurred approximately 70 bp upstream from box B, similar to that in the clones containing only the box B promoter element. All the mutant clones were transcribed less efficiently than was the wild type. An increase in the distance between boxes A and B also activated a second box A-like element within the Alu family repeat. We compare these results with the results of tRNA gene studies. We also discuss this comparison in terms of the positioning function of the split class III promoter elements and the evolutionary conservation of the spacing between the two promoter elements for optimum transcriptional efficiency.
Mol Cell Biol 1986 Jun
PMID:Competitive and cooperative functioning of the anterior and posterior promoter elements of an Alu family repeat. 302 16

The nucleoprotein structure of single-copy tRNA genes in yeast nuclei was examined by DNase I footprinting and compared with that of complexes formed in vitro between the same genes and transcription factor C. Transcription factor C bound to both the 5' and 3' intragenic promoters of the tRNA(SUP53Leu) gene in vitro, protecting approximately 30 base pairs at the 3' promoter (B block) and 40 base pairs at the 5' promoter (A block) and causing enhanced DNase I cleavages between the protected regions. Binding to the two sites was independent of the relative orientation of the two sites on the helix and was eliminated by a single point mutation in the 3' promoter. The chromosomal tRNA(SUP53Leu) and tRNA(UCGSer) genes showed a pattern of protection and enhanced cleavages similar to that observed in vitro, indicating that the stable complexes formed in vitro accurately reflect at least some aspects of the nucleoprotein structure of the genes in chromatin.
Mol Cell Biol 1987 Sep
PMID:Comparison of tRNA gene transcription complexes formed in vitro and in nuclei. 331 9

We have studied the protein components and nucleic acid sequences involved in stably activating the ribosomal DNA (rDNA) template and in directing accurate transcription of mammalian rRNA genes. Two protein components are necessary to catalyze rDNA transcription, and these have been extensively purified. The first, factor D, can stably associate by itself with the rDNA promoter region and is responsible for template commitment. The second component, factor C, which appears to be an activated subset of polymerase I, can stably bind to the factor D-rDNA complex but not to the rDNA in the absence of factor D. A third component which had been previously identified as a rDNA transcription factor is shown to be a RNase inhibitor. Extending our earlier observation that the approximately 150-base-pair mouse rDNA promoter consists of a minimal essential region (residues approximately -35 to approximately +9) and additional upstream stimulatory domains, we now report that each of these promoter domains acts to augment the binding of the polymerase I transcription factors. A minimum core region (residues approximately -35 to approximately -15) is capable of stable complex formation and of binding transcription factor D. Factor C can also bind to this D-core region complex.
Mol Cell Biol 1986 Oct
PMID:Factors and nucleotide sequences that direct ribosomal DNA transcription and their relationship to the stable transcription complex. 379 88

Replication factor C (RFC) is a five-subunit DNA polymerase accessory protein that functions as a structure-specific, DNA-dependent ATPase. The ATPase function of RFC is activated by proliferating cell nuclear antigen. RFC was originally purified from human cells on the basis of its requirement for simian virus 40 DNA replication in vitro. A functionally homologous protein complex from Saccharomyces cerevisiae, called ScRFC, has been identified. Here we report the cloning, by either peptide sequencing or by sequence similarity to the human cDNAs, of the S. cerevisiae genes RFC1, RFC2, RFC3, RFC4, and RFC5. The amino acid sequences are highly similar to the sequences of the homologous human RFC 140-, 37-, 36-, 40-, and 38-kDa subunits, respectively, and also show amino acid sequence similarity to functionally homologous proteins from Escherichia coli and the phage T4 replication apparatus. All five subunits show conserved regions characteristic of ATP/GTP-binding proteins and also have a significant degree of similarity among each other. We have identified eight segments of conserved amino acid sequences that define a family of related proteins. Despite their high degree of sequence similarity, all five RFC genes are essential for cell proliferation in S. cerevisiae. RFC1 is identical to CDC44, a gene identified as a cell division cycle gene encoding a protein involved in DNA metabolism. CDC44/RFC1 is known to interact genetically with the gene encoding proliferating cell nuclear antigen, confirming previous biochemical evidence of their functional interaction in DNA replication.
Mol Cell Biol 1995 Sep
PMID:Characterization of the five replication factor C genes of Saccharomyces cerevisiae. 765 83

To study the transcriptional regulation of the liver gluconeogenic phenotype, the underdifferentiated mouse Hepa-1c1c7 (Hepa) hepatoma cell line was used. These cells mimicked the fetal liver by appreciably expressing the alpha-fetoprotein and albumin genes but not the phosphoenolpyruvate carboxykinase (PEPCK) gene. Unlike the fetal liver, however, Hepa cells failed to express the early-expressed factors hepatocyte nuclear factor 1 alpha (HNF-1 alpha) and HNF-4 and the late-expressed factor C/EBP alpha, thereby providing a suitable system for examining possible cooperation between these factors in the transcriptional regulation of the PEPCK gene. Transient transfection assays of a chimeric PEPCK-chloramphenicol acetyltransferase construct showed a residual PEPCK promoter activity in the Hepa cell line, which was slightly stimulated by cotransfection with a single transcription factor from either the C/EBP family or HNF-1 alpha but not at all affected by cotransfection of HNF-4. In contrast, cotransfection of the PEPCK construct with members from the C/EBP family plus HNF-1 alpha resulted in a synergistic stimulation of the PEPCK promoter activity. This synergistic effect depended on the presence in the PEPCK promoter region of the HNF-1 recognition sequence and on the presence of two C/EBP recognition sequences. The results demonstrate a requirement for coexistence and cooperation between early and late liver-enriched transcription factors in the transcriptional regulation of the PEPCK gene. In addition, the results suggest redundancy between members of the C/EBP family of transcription factors in the regulation of PEPCK gene expression.
Mol Cell Biol 1994 Nov
PMID:Transcriptional regulation of the phosphoenolpyruvate carboxykinase gene by cooperation between hepatic nuclear factors. 793 27


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