NGF‐dependent and tissue‐specific transcription of vgf is regulated by a CREB–p300 and bHLH factor interaction
Georgia MandolesiSilvia GarganoMaria PennutoBarbara IlliRosa MolfettaLaura SoucekLaura MoscaAndrea LeviRichard JuckerSergio Nasi
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Abstract:
Neurotrophins support neuronal survival, development, and plasticity through processes requiring gene expression. We studied how vgf target gene transcription is mediated by a critical promoter region containing E‐box, CCAAT and cAMP response element (CRE) sites. The p300 acetylase was present in two distinct protein complexes bound to this region. One complex, containing HEB (ubiquitous basic helix–loop–helix (bHLH)), bound the promoter in non‐neuronal cells and was involved in repressing vgf expression. Neurotrophin‐dependent transcription was mediated by the second complex, specific for neuronal cells, which included CRE binding protein and MASH1 (neuro‐specific bHLH), bound the CCAAT motif, and was target of neurotrophin signalling. The interaction, mediated by p300, of different transcription factors may add specificity to the neurotrophin response.Keywords:
Basic helix-loop-helix
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Tumor suppressor p53 plays a pivotal role in the regulation of cell fate determination in response to a variety of cellular stress including carbon source depletion. In this study, we found that cAMP-responsive element-binding protein (CREB) collaborates with AMP-activated protein kinase alpha (AMPKalpha) to regulate the transcription of p53. Luciferase reporter assays showed that the genomic fragment spanning from -531 to -239 of human p53 gene is required for the transactivation of p53 in response to glucose deprivation. Within this region, we found out a putative CREB-binding site. siRNA-mediated knockdown of CREB resulted in a significant inhibition of the up-regulation of p53 and apoptosis under glucose deprivation. Consistent with these observations, glucose deprivation induced the transcription of p53 and CREB. Additionally, glucose deprivation led to an efficient recruitment of CREB onto the promoter region of p53 gene carrying the canonical CREB-binding site, indicating that CREB has an ability to bind to the promoter region of p53 gene and transactivate p53. Furthermore, the amounts of CREB/phospo-AMPKalpha complex increased in response to glucose deprivation. Taken together, our present findings suggest that p53 is transcriptionally regulated by CREB/phospho-AMPKalpha complex and thereby contributing to the induction of apoptosis under carbon source depletion.
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In general, DNA-binding factors that activate gene transcription are thought to do so via reversible interaction with DNA. However, most studies, largely performed in vitro, suggest that the transcriptional activator, cAMP response element-binding protein (CREB), is exceptional in that it is constitutively bound to the promoter, where its phosphorylation leads to the recruitment of CREB-binding protein (CBP) to form a CREB/CBP/promoter complex. We have studied how CREB interacts with DNA in vivo to regulate the cAMP-responsive gene encoding human CRH (hCRH). Protein-DNA complexes were cross-linked in cells expressing the endogenous hCRH gene by exposure to a 10 nsec pulse of high-energy UV-laser light, followed by immunoaffinity purification of CREB-DNA complexes. Binding of CREB to a fragment of the hCRH promoter containing a canonical, functional cAMP response element was absent in untreated cells, but was specifically induced after activation of the protein kinase A pathway with forskolin. These data indicate that, in vivo, CREB, like the majority of other DNA-binding transcriptional activators, undergoes signal-mediated promoter interaction.
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We have studied the regulation of protooncogene fos following serum induction. We show that un- or hypo-phosphorylated form of transcription factor cyclic AMP response element binding (CREB) protein represses the transcription of fos promoter. The negative regulation by CREB is alleviated if it is phosphorylated at serine 133 by the catalytic subunit of protein kinase A (PKA). A DNA binding mutant of CREB is unable to suppress transcription of the fos promoter. However, mutation in the cyclic AMP responsive element (CRE) at -60 or AP-1 binding site at -290, known to bind to CREB, does not appear to be involved in repression. Serum induction of dyad symmetry element (DSE) linked reporter gene is also repressed by unmodified CREB, which can be relieved following phosphorylation by PKA. We propose that posttranslational modification of CREB regulates serum inducibility of fos promoter.
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The transcription factors CREB (cAMP response element binding protein) and ATF (activating transcription factor) recognize DNA containing the consensus sequence TGACGTCA. We compared the neuropeptide somatostatin promoter, which binds CREB and is activated by cAMP, to the adenovirus E2A promoter, which binds ATF but is not activated by cAMP, to determine which specific nucleotides within a CREB/ATF recognition sequence confer cAMP responsiveness. Several mutant somatostatin promoters were generated containing part of all of the E2A ATF binding site. Some of the hybrid CREB/ATF binding sites competed for factor binding to a wild-type somatostatin promoter probe. However, only the wild-type CREB binding site promoter could confer cAMP activation on a linked CAT plasmid. Furthermore, this wild-type CREB binding site could confer cAMP activation on the CAT plasmid only if it was adjacent to a wild-type somatostatin TATA box and cap site. These results suggest that slight deviation from a wild-type CREB recognition sequence might be tolerated by factor(s) binding to cAMP response element-like sequences. However, transcription activation may require a particular CREB recognition sequence, as well as additional promoter elements that bind proteins that interact with CREB.
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The transcriptional transactivational activities of the phosphoprotein cAMP-response element-binding protein (CREB) are activated by the cAMP-dependent protein kinase A signaling pathway. Dimers of CREB bind to the palindromic DNA element 5'-TGACGTCA-3' (or similar motifs) called cAMP-responsive enhancers (CREs) found in the control regions of many genes, and activate transcription in response to phosphorylation of CREB by protein kinase A. Earlier we reported on the cyclical expression of the CREB gene in the Sertoli cells of the rat testis that occurred concomitant with the FSH-induced rise in cellular cAMP levels and suggested that transcription of the CREB gene may be autoregulated by cAMP-dependent transcriptional proteins. We now report the structure of the 5'-flanking sequence of the human CREB gene containing promoter activity. The promoter has a high content of guanosines and cytosines and lacks canonical TATA and CCAAT boxes typically found in the promoters of genes in eukaryotes. Notably, the promoter contains three CREs and transcriptional activities of a promoter-luciferase reporter plasmid transfected to placental JEG-3 cells are increased 3- to 5-fold over basal activities in response to either cAMP or 12-O-tetradecanoyl phorbol-14-acetate, and give 6- to 7-fold responses when both agents are added. The CREs bind recombinant CREB and endogenous CREB or CREB-like proteins contained in placental JEG-3 cells and also confer cAMP-inducible transcriptional activation to a heterologous minimal promoter. Our studies suggest that the expression of the CREB gene is positively autoregulated in trans.
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Cyclic AMP response element binding protein (CREB) activates transcription of cAMP response element (CRE)-contalnlng promoters following an elevation of Intracellular cAMP. Here we show that CREB and the highly related protein ATF-1 are also potent transcription inhibitors. Strikingly, CREB inhibits transcription of multiple activators, whose DNA-binding domains and activation regions are unrelated to one another. Inhibition requires that the CREB dimerization and DNA-binding domains are intact. However, inhibition is not dependent upon the presence of a CRE in the promoter, and does not Involve heterodlmer formation between CREB and the activator. The ability of an activator protein to inhibit transcription In such a promiscuous fashion has not been previously reported.
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The transcriptional transactivational activities of the phosphoprotein cAMP-response element-binding protein (CREB) are activated by the cAMP-dependent protein kinase A signaling pathway. Dimers of CREB bind to the palindromic DNA element 5'-TGACGTCA-3' (or similar motifs) called cAMP-responsive enhancers (CREs) found in the control regions of many genes, and activate transcription in response to phosphorylation of CREB by protein kinase A. Earlier we reported on the cyclical expression of the CREB gene in the Sertoli cells of the rat testis that occurred concomitant with the FSH-induced rise in cellular cAMP levels and suggested that transcription of the CREB gene may be autoregulated by cAMP-dependent transcriptional proteins. We now report the structure of the 5'-flanking sequence of the human CREB gene containing promoter activity. The promoter has a high content of guanosines and cytosines and lacks canonical TATA and CCAAT boxes typically found in the promoters of genes in eukaryotes. Notably, the promoter contains three CREs and transcriptional activities of a promoter-luciferase reporter plasmid transfected to placental JEG-3 cells are increased 3- to 5-fold over basal activities in response to either cAMP or 12-O-tetradecanoyl phorbol-14-acetate, and give 6- to 7-fold responses when both agents are added. The CREs bind recombinant CREB and endogenous CREB or CREB-like proteins contained in placental JEG-3 cells and also confer cAMP-inducible transcriptional activation to a heterologous minimal promoter. Our studies suggest that the expression of the CREB gene is positively autoregulated in trans.
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The cAMP signaling pathway stimulates cholecystokinin (CCK) gene transcription via CREB binding to a cAMP response element (CRE). In the present study we examined the function of glycogen synthase kinase-3β (GSK-3β) on cAMP-induced CCK gene transcription. Co-transfection of GSK-3β reduced the cAMP-induced CCK promoter activity with ∼80% and ∼60% in SK-N-MC and PC12 cells, respectively. Binding of in vitro translated CREB to the CCK CRE(-80) promoter element was reduced following incubation with recombinant GSK-3β. Finally, mutation of serine-129, which is a phosphorylation site for GSK-3β, did not abolish cAMP-induced CREB-dependent transcription, and cAMP-mediated GAL4-CREB transcription was unaffected by co-transfection with GSK-3β. We conclude that GSK-3β regulates cAMP-induced CCK transcription by reducing CREB binding to the CRE(-80) element in the CCK promoter.
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