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Recent studies have detailed the ability of activating transcription factor-2 (ATF-2) to mediate adenoviral E1a stimulation of gene expression; however, an endogenous regulator for the transcriptional activity of this protein has not been described. To characterize the regulation of ATF-2 activity, we have expressed full-length and truncated peptides corresponding to various regions of the ATF-2 protein in bacteria and the baculovirus insect cell system. Bacterially expressed truncated (350-505) but not full-length ATF-2, was able to bind a consensus cAMP response element-containing oligonucleotide, suggesting the N-terminal moiety may serve as a negative regulator of DNA-binding activity. In contrast, the full-length ATF-2 protein expressed in Spodoptera frugiperda (Sf9) cells using a recombinant baculovirus was fully competent to bind DNA. Protein phosphatase 2A reversed the DNA-binding activity by dephosphorylating the ATF-2 polypeptide. Microtubule-associated protein kinase catalyzed the phosphorylation and stimulated the DNA-binding activity of bacterially expressed full-length ATF-2. Phosphopeptide mapping of phosphorylated ATF-2 proteins identified a single peptide in the N-terminal moiety of ATF-2 phosphorylated by p42 or p54 microtubule-associated protein kinase. Therefore, we propose that phosphorylation of this regulatory site is sufficient to induce an allosteric structural change in the ATF-2 protein, which allows dimerization and subsequent DNA binding.
Mol Endocrinol 1992 Dec
PMID:Activating transcription factor-2 DNA-binding activity is stimulated by phosphorylation catalyzed by p42 and p54 microtubule-associated protein kinases. 133 44

The ubiquitously expressed transcription factor Oct-1 and several other members of the POU domain protein family bind to a site, termed the octamer motif, that functions in the promoter and enhancer regions of a variety of genes expressed under diverse conditions. An octamer motif present in a conserved histone H2B-specific promoter element is required for S-phase-specific transcription of mammalian histone H2B genes in cultured cells. We have previously shown that the octamer motif in a Xenopus histone H2B gene promoter was inactive in nondividing frog oocytes. Here we show that the octamer motif, in addition to regulatory elements (TATAA, CCAAT, and ATF motifs) that are active in oocytes, is required for maximal H2B gene transcription in developing frog embryos. Factors binding to each of the H2B upstream promoter elements are present in oocytes and increase slightly in abundance during early development. The activity of the H2B octamer motif in embryos is not specifically associated with increased binding by Oct-1 or the appearance of novel octamer-binding proteins but requires the presence of an intact CCAAT motif. Our results indicate that synergistic interactions among promoter-bound factors are important for octamer-dependent H2B transcription. We suggest that the activity of the H2B promoter is regulated primarily by changes in the interactions between proteins already bound to the promoter rather than by alterations in their intrinsic abilities to bind DNA.
Mol Cell Biol 1992 Oct
PMID:Histone H2B gene transcription during Xenopus early development requires functional cooperation between proteins bound to the CCAAT and octamer motifs. 140 29

In regenerating liver, a physiologically normal model of cell growth, LRF-1, JunB, c-Jun, and c-Fos among Jun/Fos/LRF-1 family members are induced posthepatectomy. In liver cells, high levels of c-Fos/c-Jun, c-Fos/JunB, LRF-1/c-Jun, and LRF-1/JunB complexes are present for several hours after the G0/G1 transition, and the relative level of LRF-1/JunB complexes increases during G1. We provide evidence for dramatic differences in promoter-specific activation by LRF-1- and c-Fos-containing complexes. LRF-1 in combination with either Jun protein strongly activates a cyclic AMP response element-containing promoter which c-Fos/Jun does not activate. LRF-1/c-Jun, c-Fos/c-Jun, and c-Fos/JunB activate specific AP-1 and ATF site-containing promoters, and in contrast, LRF-1/JunB potently represses c-Fos- and c-Jun-mediated activation of these promoters. Repression is dependent on a region in LRF-1 that includes amino acids 40 to 84 (domain R) and the basic/leucine zipper domain. As the relative level of LRF-1/JunB complexes increases posthepatectomy, c-Fos/Jun-mediated ATF and AP-1 site activation is likely to decrease with simultaneous transcriptional activation of the many liver-specific genes whose promoters contain cyclic AMP response element sites. Thus, through complex interactions among LRF-1, JunB, c-Jun, and c-Fos, control of delayed gene expression may be established for extended times during the G1 phase of hepatic growth.
Mol Cell Biol 1992 Oct
PMID:Interactions among LRF-1, JunB, c-Jun, and c-Fos define a regulatory program in the G1 phase of liver regeneration. 140 55

Members of the mammalian ATF/CREB family of transcription factors, which are associated with regulation by cyclic AMP and viral oncogenes, bind common DNA sequences (consensus TGACGTCA) via a bZIP domain. In the yeast Saccharomyces cerevisiae, ATF/CREB-like sequences confer either repression or activation of transcription, depending on the promoter context. By isolating mutations that alleviate the repression mediated by ATF/CREB sites, we define a new yeast gene, ACR1, which encodes an ATF/CREB transcriptional repressor. ACR1 contains a bZIP domain that is necessary for homodimer formation and specific DNA binding to an ATF/CREB site. Within the bZIP domain, ACR1 most strongly resembles the mammalian cyclic AMP-responsive transcriptional regulators CREB and CREM; it is less similar to GCN4 and YAP1, two previously described yeast bZIP transcriptional activators that recognize the related AP-1 sequence (consensus TGACTCA). Interestingly, deletion of the ACR1 gene causes increased transcription through ATF/CREB sites that does not depend on GCN4 or YAP1. Moreover, extracts from acr1 deletion strains contain one or more ATF/CREB-like DNA-binding activities. These genetic and biochemical observations suggest that S. cerevisiae contains a family of ATF/CREB proteins that function as transcriptional repressors or activators.
Mol Cell Biol 1992 Dec
PMID:ACR1, a yeast ATF/CREB repressor. 144 73

The adenovirus protein E1a stimulates transcription of both viral and cellular genes. Unlike most other transcription factors, it induces transactivation through several different promoter elements. The mechanism by which elements of diverse sequence mediate the effect of E1a is the focus of this study. Three E1a-responsive elements (an ATF site, an Sp1 site, and a TATA box containing the sequence TATAA) were studied to determine whether their interaction with a common factor is necessary for transactivation. In transfection assays, each element was used as a competitor against promoter constructs containing the other elements. The elements as competitors had no effect on basal transcription, but each competitor completely inhibited transactivation by E1a. Competitors that were not E1a responsive failed to inhibit transactivation. Therefore, either E1a itself or an E1a-inducible factor interacts with each of the elements to cause transactivation, most likely though an association with each element's specific binding protein.
Mol Cell Biol 1992 Feb
PMID:Interaction of a common factor with ATF, Sp1, or TATAA promoter elements is required for these sequences to mediate transactivation by the adenoviral oncogene E1a. 153 Oct 85

Understanding the nature and importance of protein-protein interactions in the mechanisms of eukaryotic gene expression is essential to understanding the normal and aberrant regulation of gene transcription. Using 125I-labeled cAMP response element-binding protein (CREB) and activating transcription factor-2 (ATF-2) recombinant peptides to probe Western blots of HeLa nuclear extracts, we have identified multiple separate nuclear factors that form specific protein-protein interactions with these leucine zipper-containing transcriptional regulatory proteins. The interaction is specific because preincubation of blots with cold homologous protein blocks the binding of labeled protein, whereas preincubation of blots with cold heterologous protein has no effect on labeled protein interactions. Although these studies focus on two specific transactivators, CREB and ATF-2, the approach is of general use for the study of other leucine zipper-containing mammalian transcription factors. Furthermore, in addition to allowing the detection of protein-protein interactions of CREB and ATF-2 with nuclear factors, we have used this strategy to isolate cDNA clones expressing these nuclear proteins. We demonstrate that CREB will form heterodimers with ATF-1, but not ATF-2, Jun, Fos, or C/EBP whereas, ATF-2 will form heterodimers with Jun and Fos, but not with C/EBP or ATF-1. This strategy, therefore, allows a systematic approach to identifying, characterizing, and cloning proteins involved in the control of eukaryotic transcriptional regulation. The identification and characterization of the components of eukaryotic transcription complexes will allow studies that address the molecular mechanisms of normal and abnormal control of cellular gene expression.
Mol Endocrinol 1991 Feb
PMID:Identification of multiple nuclear factors that interact with cyclic adenosine 3',5'-monophosphate response element-binding protein and activating transcription factor-2 by protein-protein interactions. 182 7

To elucidate how methylation of specific sites in plant DNA might control transcription, we examined the effect of DNA methylation at CpG sequences on the binding of plant nuclear factors to an oligonucleotide duplex containing the consensus sequence for mammalian CREB (cAMP response element binding protein). CREB is part of the ATF (activating transcription factor) family of mammalian proteins specifically binding to 5'-TGACGTCA-3' and related sequences. Proteins recognizing the CREB-specific ligand were identified in nuclear extracts of pea seeds, wheat germ, cauliflower, and soybean leaves using electrophoretic mobility shift assays. Cytosine methylation inhibited binding of this protein in all these extracts, and so this sequence-specific DNA-binding activity is referred to as methylation-inhibited binding protein 1 (MIB-1). Sites somewhat similar to that of the CREB ligand are found in the upstream regions of a wheat histone H3 gene and tomato and pea ribulose 1,5-bisphosphate carboxylase genes. These sites were bound preferentially by distinct proteins that may be related to the previously described plant proteins HBP-1, HSBF, ASF-1, or GBF. Methylation of cytosine residues at these sites and at a site for MIB-1 located upstream of a soybean proline-rich protein gene also reduced specific binding with all the nuclear extracts tested. Similarly, substitution of the central CpG dinucleotide with TpG decreased binding.
Plant Mol Biol 1991 Jul
PMID:CpG methylation inhibits binding of several sequence-specific DNA-binding proteins from pea, wheat, soybean and cauliflower. 183 Oct 56

The cellular factors E4F and ATF-2 (a member of the activating transcription factor [ATF] family) bind to common sites in the adenovirus E4 promoter and have both been suggested to mediate transcriptional activation by the viral E1A protein. To assess the role of E4F, we have introduced mutations into the E4F/ATF binding sites of the E4 promoter and monitored promoter activity in HeLa cells. We find that the core motif (TGACG) of the E4F/ATF binding site is important for E4 promoter activity. However, a point mutation adjacent to the core motif that reduces E4F binding (but has no effect on ATF binding) has no effect on E4 promoter activity. Together with previous results, these findings indicate that there are at least two cellular factors (a member of the ATF family and E4F) that can function with E1A to induce transcription of the E4 promoter. We also find that certain mutations strongly reduce E4 transcription in vivo but have no effect on ATF-2 binding in vitro. These results are therefore incompatible with the possibility that (with respect to members of the ATF family) ATF-2 alone can function with E1A to transactivate the E4 promoter in HeLa cells.
Mol Cell Biol 1991 Sep
PMID:E1A-mediated activation of the adenovirus E4 promoter can occur independently of the cellular transcription factor E4F. 183 36

F9 embryonal carcinoma (EC) stem cells contain an E1a-like activity that is absent from differentiated derivatives. We have previously characterized proteins present in F9 EC cell extracts that bind to the E1a-dependent E2A promoter and have shown that two of them, TF68 and DRTF1, are required for efficient transcription in vitro (N. B. La Thangue, B. Thimmapaya, and P. W. J. Rigby, Nucleic Acids Res. 18:2929-2938, 1990). We now show that the E1a-like activity is detectable in transient transfection assays. Deletion mutations show that a distal sequence element, which includes the ATF/CREB consensus, is required for expression in both cell types, although it does not mediate the down-regulation of promoter activity that accompanies differentiation. A series of point mutations generated by in vitro mutagenesis confirm this and show that sequences around -60 are necessary for efficient expression in stem cells but not in differentiated derivatives. These sequences bind DRTF1, the activity of which is strongly down-regulated during differentiation. Surprisingly, mutations in a previously uncharacterized region of the promoter restore activity to a promoter carrying the -60 mutation and lead to the formation of a new DNA-protein complex.
Mol Cell Biol 1991 Nov
PMID:Sequences and factors required for the F9 embryonal carcinoma stem cell E1a-like activity. 183 34

To investigate the synergism or cooperative interaction between transcription elements, we have designed and constructed a series of synthetic polymerase II promoters with different combinations of elements. These include three different CCAAT boxes, which correspond to the binding sites for CP1, CP2, and NFI, a GC box, a CACCC box, and an ATF/CREB-binding site. The synthetic promoters containing these elements in proximal positions were linked to a test gene (CAT). Tandem repeats of AP1- and AP2-binding sites, the simian virus 40 enhancer, and DNA-binding sites for GAL-estrogen receptor were cloned downstream of the test gene. The strength of these promoters was then tested in transient-expression assays in HeLa TK- cells. In the context of the adenovirus major late promoter TATA box, the promoters containing only certain combinations of elements are active in this assay. Some elements appear to cooperate nearly universally, but others exhibit strong selectivity. These results indicate strongly selective synergistic interactions between elements and suggest that levels of promoter strength may be determined by the extent of compatibility between factors bound to proximal and enhancer sites.
Mol Cell Biol 1991 Sep
PMID:Differential ability of proximal and remote element pairs to cooperate in activating RNA polymerase II transcription. 187 39

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