Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P51532 (transcriptional activator)
6,546 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The myb gene family has three members, c-myb, A-myb, and B-myb. A-myb mRNA is mainly expressed in testis and peripheral blood leukocytes. A-Myb can activate transcription from the promoter containing Myb-binding sites in all cells examined. In addition to the two domains (a DNA-binding domain and a transcriptional activation domain), two negative regulatory domains have been identified in A-Myb. These results indicate that A-Myb functions as a transcriptional activator mainly in testis and peripheral blood cells, and the regulatory mechanism of A-Myb activity is similar to that of c-Myb.
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PMID:Human A-myb gene encodes a transcriptional activator containing the negative regulatory domains. 782 37

The Escherichia coli CadC protein is required for activation of cadBA transcription under conditions of low external pH and exogenous lysine. cadBA encodes proteins involved in the decarboxylation of lysine to cadaverine, and cadaverine excretion. Sequence analysis suggested that CadC contains a single transmembrane segment separating a DNA-binding domain in the amino terminus from a periplasmic domain. Western analysis of subcellular fractions demonstrated that CadC is expressed and concentrated in the cytoplasmic membrane in cells grown either at an inducing pH (pH 5.8) or at a non-inducing pH (pH 7.6). Eight cadC mutants were isolated based on their ability to confer expression of a cadA-lacZ fusion independent of low external pH or exogenous lysine. Five of these mutants expressed the cadA-lacZ fusion at both pH 5.8 and pH 7.6, but retained the requirement for the lysine signal while the other three mutants displayed pH independence at pH 5.8 but not at pH 7.6. These results support a model in which CadC is a membrane-bound transcriptional activator of the cadBA operon capable of sensing (directly or indirectly) signals generated outside the cytoplasmic membrane as a consequence of acidic pH and lysine.
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PMID:Altered pH and lysine signalling mutants of cadC, a gene encoding a membrane-bound transcriptional activator of the Escherichia coli cadBA operon. 783 May 62

The SRY gene functions as a genetic switch in gonadal ridge initiating testis determination. The mouse Sry and human SRY open reading frames (ORFs) share a conserved DNA-binding domain (the HMG-box) yet exhibit no additional homology outside this region. As judged by the accumulation of lacZ-SRY hybrid proteins in the nucleus, both the human and mouse SRY ORFs contain a nuclear localization signal. The mouse Sry HMG-box domain selectively binds the sequence NACAAT in vitro when challenged with a random pool of oligonucleotides and binds AACAAT with the highest affinity. When put under the control of a heterologous promotor, the mouse Sry gene activated transcription of a reporter gene containing multiple copies of the AACAAT binding site. Activation was likewise observed for a GAL4-responsive reporter gene, when the mouse Sry gene was linked to the DNA-binding domain of GAL4. Using this system, the activation function was mapped to a glutamine/histidine-rich domain. In addition, LexA-mouse Sry fusion genes activated a LexA-responsive reporter gene in yeast. In contrast, a GAL4-human SRY fusion gene did not cause transcriptional activation. These studies suggest that both the human and the mouse SRY ORFs encode nuclear, DNA-binding proteins and that the mouse Sry ORF can function as a transcriptional activator with separable DNA-binding and activator domains.
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PMID:Sry is a transcriptional activator. 783 51

Alveolar rhabdomyosarcomas are pediatric solid tumors with a hallmark cytogenetic abnormality: translocation of chromosomes 2 and 13 [t(2;13) (q35;q14)]. The genes on each chromosome involved in this translocation have been identified as the transcription factor-encoding genes PAX3 and FKHR. The NH2-terminal paired box and homeodomain DNA-binding domains of PAX3 are fused in frame to COOH-terminal regions of the chromosome 13-derived FKHR gene, a novel member of the forkhead DNA-binding domain family. To determine the role of the fusion protein in transcriptional regulation and oncogenesis, we identified the PAX3-FKHR fusion protein and characterized its function(s) as a transcription factor relative to wild-type PAX3. Antisera specific to PAX3 and FKHR were developed and used to examine PAX3 and PAX3-FKHR expression in tumor cell lines. Sequential immunoprecipitations with anti-PAX3 and anti-FKHR sera demonstrated expression of a 97-kDa PAX3-FKHR fusion protein in the t(2;13)-positive rhabdomyosarcoma Rh30 cell line and verified that a single polypeptide contains epitopes derived from each protein. The PAX3-FKHR protein was localized to the nucleus in Rh30 cells, as was wild-type PAX3, in t(2;13)-negative A673 cells. In gel shift assays using a canonical PAX binding site (e5 sequence), we found that DNA binding of PAX3-FKHR was significantly impaired relative to that of PAX3 despite the two proteins having identical PAX DNA-binding domains. However, the PAX3-FKHR fusion protein was a much more potent transcriptional activator than PAX3 as determined by transient cotransfection assays using e5-CAT reporter plasmids. The PAX3-FKHR protein may function as an oncogenic transcription factor by enhanced activation of normal PAX3 target genes.
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PMID:The PAX3-FKHR fusion protein created by the t(2;13) translocation in alveolar rhabdomyosarcomas is a more potent transcriptional activator than PAX3. 786 45

The timing of asexual fruiting body formation during Aspergillus nidulans colony development is precisely regulated so that conidiophores are typically produced 1-2 mm behind the growing edge of the colony. Mutations in any of four A. nidulans genes, flbB, flbC, flbD, or flbE, result in colonies that are delayed at least 24 hr in their ability to initiate conidiophore development resulting in fluffy colonies with conidiophores forming in the center, at least 12-15 mm behind the growing edge. The requirement for each of these four genes in determining the timing of developmental initiation precedes transcriptional activation of the primary developmental regulatory gene brlA, indicating a possible role for each gene in developmentally regulated activation of brlA expression. The wild-type flbD gene was isolated and shown to encode an approximately 1.6-kb mRNA that is present throughout the A. nidulans life cycle. The deduced FlbD protein sequence predicts a 314-amino-acid polypeptide with significant identity at its amino terminus to the DNA-binding domain of the Myb family of transcription factors indicating that FlbD probably functions as a sequence-specific transcriptional activator. Although conidiophore development does not normally occur in submerged culture, forced overexpression of flbD in submerged hyphae caused inappropriate activation of brlA expression and resulted in production of complex conidiophores that produced all of the distinct cell types observed in wild-type conidiophores including viable spores. This ability of flbD overexpression to activate conidiation requires brlA, flbB, and flbA (another early developmental regulator) but does not require flbC or flbE. We propose that FlbD functions during normal development by activating transcription of other genes required for development (such as brlA) and that FlbD activity is normally controlled post-transcriptionally by an unknown mechanism.
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PMID:flbD encodes a Myb-like DNA-binding protein that coordinates initiation of Aspergillus nidulans conidiophore development. 788 70

The product of the LYS14 gene of Saccharomyces cerevisiae activates the transcription of at least four genes involved in lysine biosynthesis. Physiological and genetic studies indicate that this activation is dependent on the inducer alpha-aminoadipate semialdehyde, an intermediate of the pathway. The gene LYS14 was sequenced and, from its nucleotide sequence, predicted to encode a 790-amino-acid protein carrying a cysteine-rich DNA-binding motif of the Zn(II)2Cys6 type in its N-terminal portion. Deletion of this N-terminal portion including the cysteine-rich domain resulted in the loss of LYS14 function. To test the function of Lys14 as a transcriptional activator, this protein without its DNA-binding motif was fused to the DNA-binding domain of the Escherichia coli LexA protein. The resulting LexA-Lys14 hybrid protein was capable of activating transcription from a promoter containing a lexA operator, thus confirming the transcriptional activation function of Lys14. Furthermore, evidence that this function, which is dependent on the presence of alpha-aminoadipate semialdehyde, is antagonized by lysine was obtained. Such findings suggest that activation by alpha-aminoadipate semialdehyde and the apparent repression by lysine are related mechanisms. Lysine possibly acts by limiting the supply of the coinducer, alpha-aminoadipate semialdehyde.
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PMID:Repression of the genes for lysine biosynthesis in Saccharomyces cerevisiae is caused by limitation of Lys14-dependent transcriptional activation. 793 67

The mammalian transcriptional activator CREB binds as a dimer to a broad spectrum of inducible promoters. CREB activity is modulated by several signalling agents (protein kinase A [PKA], Ca2+, and transforming growth factor beta) and via functional interactions with cell-specific transcription factors. In addition, CREB can activate transcription constitutively and repress the activity of several other transcriptional activators. The mechanisms that allow CREB to act in such a malleable manner and the role that CREB dimerization might play in this are poorly understood. To probe the latter issue, we have created monomeric forms of CREB by fusing CREB to the DNA-binding domain of a protein (B-cell specific activator protein [BSAP]) that binds to DNA as a monomer. Remarkably, monomeric CREB acts as a potent, constitutive activator under conditions in which native CREB is inducible by PKA. Thus, CREB contains constitutive activation regions that are unable to function in native CREB. Two glutamine-rich domains that are important for native, PKA-inducible CREB activity are required for the constitutive activity of monomeric CREB. In contrast, two elements within the kinase-inducible domain of CREB are dispensable for constitutive activity. We discuss our results in relation to inducible and constitutive CREB activity and the potential modes of action of other activators that directly interact with CREB.
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PMID:A monomeric derivative of the cellular transcription factor CREB functions as a constitutive activator. 793 35

The rat neu protooncogene encodes a 185 kD transmembrane protein (p185neu), which is a member of the epidermal growth factor receptor (EGFr) family. In searching for the signaling transducer of p185neu by using a two-hybrid selection system, we found, surprisingly, that the cytoplasmic domain of p185neu, when fused to the DNA-binding domain of GAL4 (amino acids 1-147), functioned as a transcriptional activator. We subsequently observed nuclear localization of p185neu. Interestingly, nuclear p185neu has a much higher extent of tyrosine phosphorylation than its nonnuclear counterpart. Our results suggest that a transmembrane receptor tyrosine kinase may enter the nucleus and be involved in transcriptional activation. This novel finding unveils a clue in the understanding of the mechanism of receptor tyrosine kinase-mediated signal transduction.
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PMID:Nuclear localization of p185neu tyrosine kinase and its association with transcriptional transactivation. 794 9

Various fragments of the N-terminal, DNA-binding domain of the yeast Saccharomyces cerevisiae transcriptional activator CYP1(HAP1) have been cloned and expressed in Escherichia coli. The corresponding polypeptides have been analysed biochemically and we have undertaken a more extensive physical study of a fragment consisting of amino acids 49-126 [CYP1(49-126)]. We show that this CYP1(49-126) peptide requires zinc or cadmium in the growth medium in order to maintain a stable structure. A method to purify CYP1(49-126) is presented. We demonstrate that the purified CYP1(49-126) fragment contains two zinc ions/fragment or two cadmium ions/fragment, which are necessary for DNA binding. 113Cd one-dimensional NMR data suggest that CYP1(HAP1) has a tetrahedral coordination, and that it forms a zinc-cluster complex like GAL4.
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PMID:The DNA-binding domain of the yeast Saccharomyces cerevisiae CYP1(HAP1) transcription factor possesses two zinc ions which are complexed in a zinc cluster. 795 73

The yeast transcriptional activator HAP1 contains a DNA-binding domain homologous to GAL4, PPR1, and related factors. By selecting random HAP1-binding sites, we found that HAP1, like GAL4, binds to two CGG triplets. Unlike GAL4, the CGGs in the HAP1 consensus are in a direct and not inverted orientation. Sites with inverted CGGs were not recovered, and mutations converting the direct repeat of CGGs to an inverted repeat greatly reduce HAP1-binding affinity. Also, the 6-bp spacer between the CGGs contains a consensus TA that is positioned asymmetrically. Dimethylsulfate protection patterns on six of these sites show protections and enhancements that also lie in a directly repeated orientation, suggesting that the two HAP1 DNA recognition domains of a HAP1 homodimer are oriented in a directly repeated configuration on the DNA. Moreover, substitution of the HAP1 dimerization domain with that of PPR1, which forms coiled-coils and dimerizes symmetrically, did not diminish the ability of the protein to bind selectively to a direct repeat. This result suggests that one DNA-binding domain of the HAP1 homodimer must be able to swivel 180 degrees relative to the dimerization domain to make specific contacts with the second CGG triplet. Our results present a novel example of domain swiveling in one of the two identical subunits of a homodimer to accommodate specific DNA contacts to both CGG triplets of a direct repeat.
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PMID:The yeast activator HAP1--a GAL4 family member--binds DNA in a directly repeated orientation. 795 82


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