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

The ETS-domain transcription factor Elk-1 is a MAP kinase-inducible transcriptional activator protein. However, in the basal state, its activity is repressed by SUMO-dependent histone deacetylase (HDAC) recruitment. Relief of this repression accompanies the activation process. Here, we demonstrate that PIASx(alpha) acts to facilitate this derepression process. Members of the PIAS family of proteins can act as E3 enzymes that enhance the sumoylation status of a variety of substrates. However, PIASx-mediated coactivation of Elk-1 occurs in an E3 activity-independent manner. PIASx(alpha) binds to Elk-1 in vivo and enhances its transcriptional activity. The coactivating properties of PIASx(alpha) require Elk-1 to be modified with SUMO and the integrity of the SUMO binding motif in PIASx(alpha). PIASx(alpha) activates Elk-1 through alterations in the HAT/HDAC activities associated with Elk-1. In particular, PIASx(alpha) facilitates the loss of the repressive HDAC-2 from sumoylated Elk-1, a key event in the activation of Elk-1 in response to signalling through the ERK MAP kinase pathway. Our data therefore reveal a novel coactivator function for PIASx(alpha) through reversing SUMO-mediated repression of transcription factor activity.
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PMID:PIASx acts as an Elk-1 coactivator by facilitating derepression. 1592 Apr 81

The Arabidopsis GCN5, ADA2a and ADA2b proteins are homologs of components of several yeast and animal transcriptional coactivator complexes. Previous work has implicated these plant coactivator proteins in the stimulation of cold-regulated gene expression by the transcriptional activator protein CBF1. Surprisingly, protein interaction studies demonstrate that the DNA-binding domain of CBF1 (and of a related protein, TINY), rather than its transcriptional activation domain, can bind directly to the Arabidopsis ADA2 proteins. The ADA2a and ADA2b proteins can also bind directly to GCN5 through their N-terminal regions (comparable to a region previously defined in yeast Ada2) and through previously unmapped regions in the middle of the ADA2 proteins, which bind to the HAT domain of GCN5. The ADA2 proteins enhance the ability of GCN5 to acetylate histones in vitro and enable GCN5 to acetylate nucleosomal histones. Moreover, GCN5 can acetylate the ADA2 proteins at a motif unique to the plant homologs and absent from fungal and animal homologs. We speculate that this modification may represent a novel autoregulatory mechanism for the plant SAGA-like transcriptional coactivator complexes.
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PMID:Physical and functional interactions of Arabidopsis ADA2 transcriptional coactivator proteins with the acetyltransferase GCN5 and with the cold-induced transcription factor CBF1. 1660 59

The molting during Drosophila development is tightly regulated by the ecdysone hormone. Several steps of the ecdysone biosynthesis have been already identified but the regulation of the entire process has not been clarified yet. We have previously reported that dATAC histone acetyltransferase complex is necessary for the steroid hormone biosynthesis process. To reveal possible mechanisms controlled by dATAC we made assumptions that either dATAC may influence directly the transcription of Halloween genes involved in steroid hormone biosynthesis or it may exert an indirect effect on it by acetylating the Ftz-F1 transcription factor which regulates the transcription of steroid converting genes. Here we show that the lack of dATAC complex results in increased mRNA level and decreased protein level of Ftz-F1. In this context, decreased mRNA and increased protein levels of Ftz-F1 were detected upon treatment of Drosophila S2 cells with histone deacetylase inhibitor trichostatin A. We showed that Ftz-F1, the transcriptional activator of Halloween genes, is acetylated in S2 cells. In addition, we found that ecdysone biosynthetic Halloween genes are transcribed in S2 cells and their expression can be influenced by deacetylase inhibitors. Furthermore, we could detect H4K5 acetylation at the regulatory regions of disembodied and shade Halloween genes, while H3K9 acetylation is absent on these genes. Based on our findings we conclude that the dATAC HAT complex might play a dual regulatory role in Drosophila steroid hormone biosynthesis through the acetylation of Ftz-F1 protein and the regulation of the H4K5 acetylation at the promoters of Halloween genes.
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PMID:Acetylations of Ftz-F1 and histone H4K5 are required for the fine-tuning of ecdysone biosynthesis during Drosophila metamorphosis. 2595 39