Annika E. Wallberg

p300 and PCAF act cooperatively to mediate transcriptional activation from chromatin templates by notch intracellular domains in vitro.

ABSTRACT Ligand activation of Notch receptors leads to release of the intracellular receptor domain (Notch IC), which translocates to the nucleus and interacts with the DNA-binding protein RBP-Jκ to control expression of specific target genes. A number of proteins have been shown to interact with Notch ICs and to modulate target gene activation, but the precise function of and interplay between these factors is not known. This report investigates the Notch IC-interacting proteins, p300, PCAF, and Mastermind-like 1 (MAML1), in an in vitro transcription system with purified factors and naked DNA or chromatin templates. MAML1, RBP-Jκ, and Notch IC are all required for optimal transcription from DNA, whereas transcription from chromatin requires, in addition, p300, which interacts with MAML1. The transcriptional activity of p300 requires acetyl coenzyme A, indicating that it functions as a histone acetyltransferase when mediating Notch IC function. PCAF is unable to promote transcription on its own but enhances Notch IC-mediated transcription from chromatin in conjunction with p300. These data define a critical role for p300 in the potentiation of Notch IC function by MAML1 and PCAF, provide the first evidence for cooperativity between PCAF and p300 in Notch IC function, and also indicate direct effects of RBP-Jκ, Notch IC, and MAML1 on the general transcription machinery.

Recruitment of the SWI-SNF Chromatin Remodeling Complex as a Mechanism of Gene Activation by the Glucocorticoid Receptor τ1 Activation Domain

ABSTRACT The SWI-SNF complex has been shown to alter nucleosome conformation in an ATP-dependent manner, leading to increased accessibility of nucleosomal DNA to transcription factors. In this study, we show that the SWI-SNF complex can potentiate the activity of the glucocorticoid receptor (GR) through the N-terminal transactivation domain, τ1, in both yeast and mammalian cells. GR-τ1 can directly interact with purified SWI-SNF complex, and mutations in τ1 that affect the transactivation activity in vivo also directly affect τ1 interaction with SWI-SNF. Furthermore, the SWI-SNF complex can stimulate τ1-driven transcription from chromatin templates in vitro. Taken together, these results support a model in which the GR can directly recruit the SWI-SNF complex to target promoters during glucocorticoid-dependent gene activation. We also provide evidence that the SWI-SNF and SAGA complexes represent independent pathways of τ1-mediated activation but play overlapping roles that are able to compensate for one another under some conditions.

TRAP/SMCC/mediator-dependent transcriptional activation from DNA and chromatin templates by orphan nuclear receptor hepatocyte nuclear factor 4.

ABSTRACT The orphan nuclear receptor hepatocyte nuclear factor 4 (HNF-4) regulates the expression of many liver-specific genes both during development and in the adult animal. Towards understanding the molecular mechanisms by which HNF-4 functions, we have established in vitro transcription systems that faithfully recapitulate HNF-4 activity. Here we have focused on the coactivator requirements for HNF-4, especially for the multicomponent TRAP/SMCC/Mediator complex that has emerged as the central regulatory module of the transcription apparatus. Using a system that has been reconstituted from purified transcription factors, as well as one consisting of unfractionated nuclear extract from which TRAP/SMCC/Mediator has been depleted by specific antibodies, we demonstrate a strong dependence of HNF-4 function on this coactivator. Importantly, we further show a TRAP/SMCC/Mediator-dependence for HNF-4 transcriptional activation from chromatin templates. The latter involves cooperation with the histone acetyltransferase-containing coactivator p300, in accord with a synergistic mode of action of the two divergent coactivators. We also show that HNF-4 and TRAP/SMCC/Mediator can interact physically. This interaction likely involves primary HNF-4 activation function 2 (AF-2)-dependent interactions with the TRAP220 subunit of TRAP/SMCC/Mediator and secondary (AF-2-independent) interactions with TRAP170/RGR1. Finally, recruitment experiments using immobilized templates strongly suggest that the functional consequences of the physical interaction probably are manifested at a postrecruitment step in the activation pathway.

Histone acetyltransferase complexes can mediate transcriptional activation by the major glucocorticoid receptor activation domain.

ABSTRACT Previous studies have shown that the Ada adapter proteins are important for glucocorticoid receptor (GR)-mediated gene activation in yeast. The N-terminal transactivation domain of GR, τ1, is dependent upon Ada2, Ada3, and Gcn5 for transactivation in vitro and in vivo. Using in vitro techniques, we demonstrate that the GR-τ1 interacts directly with the native Ada containing histone acetyltransferase (HAT) complex SAGA but not the related Ada complex. Mutations in τ1 that reduce τ1 transactivation activity in vivo lead to a reduced binding of τ1 to the SAGA complex and conversely, mutations increasing the transactivation activity of τ1 lead to an increased binding of τ1 to SAGA. In addition, the Ada-independent NuA4 HAT complex also interacts with τ1. GAL4-τ1-driven transcription from chromatin templates is stimulated by SAGA and NuA4 in an acetyl coenzyme A-dependent manner. Low-activity τ1 mutants reduce SAGA- and NuA4-stimulated transcription while high-activity τ1 mutants increase transcriptional activation, specifically from chromatin templates. Our results demonstrate that the targeting of native HAT complexes by the GR-τ1 activation domain mediates transcriptional stimulation from chromatin templates.

A proline repeat domain in the Notch co-activator MAML1 is important for the p300-mediated acetylation of MAML1

Ligand activation of Notch leads to the release of Notch IC (the intracellular receptor domain), which translocates to the nucleus and interacts with the DNA-binding protein CSL to control expression of specific target genes. In addition to ligand-mediated activation, Notch signalling can be further modulated by interactions of Notch IC with a number of other proteins. MAML1 has previously been shown to act co-operatively with the histone acetyltransferase p300 in Notch IC-mediated transcription. In the present study we show that the N-terminal domain of MAML1 directly interacts with both p300 and histones, and the p300-MAML1 complex specifically acetylates histone H3 and H4 tails in chromatin. Furthermore, p300 acetylates MAML1 and evolutionarily conserved lysine residues in the MAML1 N-terminus are direct substrates for p300-mediated acetylation. The N-terminal domain of MAML1 contains a proline repeat motif (PXPAAPAP) that was previously shown to be present in p53 and important for the p300-p53 interaction. We show that the MAML1 proline repeat motif interacts with p300 and enhances the activity of the MAML1 N-terminus in vivo. These findings suggest that the N-terminal domain of MAML1 plays an important role in Notch-regulated transcription, by direct interactions with Notch, p300 and histones.

GSK3β is a negative regulator of the transcriptional coactivator MAML1

Glycogen synthase kinase 3β (GSK3β) is involved in several cellular signaling systems through regulation of the activity of diverse transcription factors such as Notch, p53 and β-catenin. Mastermind-like 1 (MAML1) was originally identified as a Notch coactivator, but has also been reported to function as a transcriptional coregulator of p53, β-catenin and MEF2C. In this report, we show that active GSK3β directly interacts with the MAML1 N-terminus and decreases MAML1 transcriptional activity, suggesting that GSK3β might target a coactivator in its regulation of gene expression. We have previously shown that MAML1 increases global acetylation of histones, and here we show that the GSK3 inhibitor SB41, further enhances MAML1-dependent histone acetylation in cells. Finally, MAML1 translocates GSK3β to nuclear bodies; this function requires full-length MAML1 protein.

Ubiquitination of Notch1 is regulated by MAML1-mediated p300 acetylation of Notch1.

Earlier studies demonstrated the involvement of the p300 histone acetyltransferase in Notch signaling but the precise mechanisms by which p300 might modulate Notch function remains to be investigated. In this study, we show that p300 acetylates Notch1 ICD in cell culture assay and in vitro, and conserved lysines located within the Notch C-terminal nuclear localization signal are essential for Notch acetylation. MAML1 and CSL, which are components of the Notch transcription complex, enhance Notch acetylation and we suggest that MAML1 increases Notch acetylation by potentiating p300 autoacetylation. Furthermore, MAML1-dependent acetylation of Notch1 ICD by p300 decreases the ubiquitination of Notch1 ICD in cellular assays. CDK8 has been shown to target Notch1 for ubiquitination and proteosomal degradation. We show that CDK8 inhibits Notch acetylation and Notch transcription enhanced by p300. Therefore, we speculate that acetylation of Notch1 might be a mechanism to regulate Notch activity by interfering with ubiquitin-dependent pathways.

SUMO modification regulates the transcriptional activity of MAML1

The Mastermindlike (MAML) family, comprising human MAML1, MAML2, and MAML3, are transcriptional regulators in Notch signaling. MAML proteins contain two consensus sites for SUMOylation at Lysine217 and Lysine299 that are conserved in humans, mice, and Xenopus. In this report, we show that MAML1 is SUMOylated at both sites. The E2‐conjugating enzyme UBC9 is essential for MAML1 SUMOylation, and the E3 ligase PIAS1 stimulates this activity. Mutation of the lysines abolishes SUMOylation of MAML1 and strongly increases MAML1‐activated transcription in cell culture assays. The protease SENP1 reverses SUMOylation of MAML1 and potentiates the transcription factor activity of MAML1. Furthermore, SUMOylation enhances MAML1 interaction with HDAC7, which decreases MAML1 transcriptional activity. Taken together, our data indicate that SUMOylation of MAML1 is a mechanism for repressing MAML1 activity by influencing its interaction with HDAC7.—Lindberg, M. J., Popko‐Scibor, A. E., Hansson, M. L., Wallberg, A. E. SUMO modification regulates the transcriptional activity of MAML1. FASEBJ. 24, 2396–2404 (2010). www.fasebj.org

Chromatin-remodeling complexes involved in gene activation by the glucocorticoid receptor

Publisher Summary This chapter provides an overview of the glucocorticoid receptor (GR) and general mechanisms of gene regulation and also describes the selected aspects of the molecular mechanisms by which the GR, once bound to DNA, activates the expression of genes through its N-terminal transactivation domain τ1. GR belongs to a large family of ligand-inducible nuclear receptors and consists of a ligand-binding domain, a DNA-binding domain, and transactivation domains. The main transcriptional activation domain, τ1, is located in the N terminus of the receptor. Current models for many nuclear receptors suggest that gene activation involves both derepression of a repressive chromatin structure within promoters and subsequent activation of transcription, involving recruitment of the transcriptional machinery. Activators can modulate chromatin structure by interacting with histone acetyltransferases (HATs) and/or adenosine triphosphate (ATP)-dependent chromatin remodeling complexes. Preinitiation complex formation can be influenced by direct interactions of activators with basal transcription factors or indirect interactions by coactivators.

MAML1 acts cooperatively with EGR1 to activate EGR1-regulated promoters: implications for nephrogenesis and the development of renal cancer.

Mastermind-like 1 (MAML1) is a transcriptional coregulator of activators in various signaling pathways, such as Notch, p53, myocyte enhancer factor 2C (MEF2C) and beta-catenin. In earlier studies, we demonstrated that MAML1 enhanced p300 acetyltransferase activity, which increased the acetylation of Notch by p300. In this study, we show that MAML1 strongly induced acetylation of the transcription factor early growth response-1 (EGR1) by p300, and increased EGR1 protein expression in embryonic kidney cells. EGR1 mRNA transcripts were also upregulated in the presence of MAML1. We show that MAML1 physically interacted with, and acted cooperatively with EGR1 to increase transcriptional activity of the EGR1 and p300 promoters, which both contain EGR1 binding sites. Bioinformatics assessment revealed a correlation between p300, EGR1 and MAML1 copy number and mRNA alterations in renal clear cell carcinoma and p300, EGR1 and MAML1 gene alterations were associated with increased overall survival. Our findings suggest MAML1 may be a component of the transcriptional networks which regulate EGR1 target genes during nephrogenesis and could also have implications for the development of renal cell carcinoma.