Alex Vassilev scite author profile

Activation of p53-mediated transcription is a critical cellular response to DNA damage. p53 stability and site-specific DNA-binding activity and, therefore, transcriptional activity, are modulated by post-translational modifications including phosphorylation and acetylation. Here we show that p53 is acetylated in vitro at separate sites by two different histone acetyltransferases (HATs), the coactivators p300 and PCAF. p300 acetylates Lys-382 in the carboxy-terminal region of p53, whereas PCAF acetylates Lys-320 in the nuclear localization signal. Acetylations at either site enhance sequence-specific DNA binding. Using a polyclonal antisera specific for p53 that is phosphorylated or acetylated at specific residues, we show that Lys-382 of human p53 becomes acetylated and Ser-33 and Ser-37 become phosphorylated in vivo after exposing cells to UV light or ionizing radiation. In vitro, amino-terminal p53 peptides phosphorylated at Ser-33 and/or at Ser-37 differentially inhibited p53 acetylation by each HAT. These results suggest that DNA damage enhances p53 activity as a transcription factor in part through carboxy-terminal acetylation that, in turn, is directed by amino-terminal phosphorylation.

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TEAD/TEF transcription factors utilize the activation domain of YAP65, a Src/Yes-associated protein localized in the cytoplasm

Vassilev¹,

Kaneko²,

Shu³

et al. 2001

Genes Dev.

632

571

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Mammals express four highly conserved TEAD/TEF transcription factors that bind the same DNA sequence, but serve different functions during development. TEAD-2/TEF-4 protein purified from mouse cells was associated predominantly with a novel TEAD-binding domain at the amino terminus of YAP65, a powerful transcriptional coactivator. YAP65 interacted specifically with the carboxyl terminus of all four TEAD proteins. Both this interaction and sequence-specific DNA binding by TEAD were required for transcriptional activation in mouse cells. Expression of YAP in lymphocytic cells that normally do not support TEAD-dependent transcription (e.g., MPC11) resulted in up to 300-fold induction of TEAD activity. Conversely, TEAD overexpression squelched YAP activity. Therefore, the carboxy-terminal acidic activation domain in YAP is the transcriptional activation domain for TEAD transcription factors. However, whereas TEAD was concentrated in the nucleus, excess YAP65 accumulated in the cytoplasm as a complex with the cytoplasmic localization protein, 14-3-3. Because TEAD-dependent transcription was limited by YAP65, and YAP65 also binds Src/Yes protein tyrosine kinases, we propose that YAP65 regulates TEAD-dependent transcription in response to mitogenic signals.

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Overlapping but Distinct Patterns of Histone Acetylation by the Human Coactivators p300 and PCAF within Nucleosomal Substrates

Schiltz

Mizzen

Vassilev

et al. 1999

Journal of Biological Chemistry

385

310

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A number of transcriptional coactivators possess intrinsic histone acetylase activity, providing a direct link between hyperacetylated chromatin and transcriptional activation. We have determined the core histone residues acetylated in vitro by recombinant p300 and PCAF within mononucleosomes. p300 specifically acetylates all sites of histones H2A and H2B known to be acetylated in bulk chromatin in vivo but preferentially acetylates lysines 14 and 18 of histone H3 and lysines 5 and 8 of histone H4. PCAF primarily acetylates lysine 14 of H3 but also less efficiently acetylates lysine 8 of H4. PCAF in its native form, which is present in a stable multimeric protein complex lacking p300/CBP, primarily acetylates H3 to a monoacetylated form, suggesting that PCAF-associated polypeptides do not alter the substrate specificity. These distinct patterns of acetylation by the p300 and PCAF may contribute to their differential roles in transcriptional regulation.The association of DNA with histones in chromatin antagonizes transcription in vitro (1, 2) and molecular genetic analyses in yeast have demonstrated roles for specific, evolutionarily conserved lysine residues within the N termini of the core histones in transcriptional regulation in vivo (for review see Ref.3). Several studies have demonstrated an enrichment of hyperacetylated histones within transcriptionally active/competent chromatin in vivo (for review see Refs. 4 -7). Strong support for the notion that histone acetylation facilitates transcription is supported by the discovery that transcriptional regulatory proteins, including GCN5 (8, 9), PCAF (10), p300 (11), CBP (12), TAF II 250 (13), and the nuclear hormone receptor coactivators ACTR (14) and SRC-1 (15), possess intrinsic histone acetyltransferase (HAT) 1 activity (for review see Refs. 16 and 17). Moreover, mutational analyses of yeast GCN5 indicate that GCN5 HAT activity in vitro is correlated with histone acetylation at promoter regions and transcriptional activation of target genes in vivo (18,19). These results are further supported by in vitro transcription experiments from nucleosomal templates showing acetylCoA-dependent activation by the GCN5-containing SAGA complex (20). These lines of evidence demonstrate the requirement of the HAT activity of GCN5 for transcriptional activation in a nucleosomal context.

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An Exposed KID-Like Domain in Human T-Cell Lymphotropic Virus Type 1 Tax Is Responsible for the Recruitment of Coactivators CBP/p300

Harrod

Tang

Nicot

et al. 1998

Molecular and Cellular Biology

170

236

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Alex Vassilev

DNA damage activates p53 through a phosphorylation–acetylation cascade

TEAD/TEF transcription factors utilize the activation domain of YAP65, a Src/Yes-associated protein localized in the cytoplasm

Overlapping but Distinct Patterns of Histone Acetylation by the Human Coactivators p300 and PCAF within Nucleosomal Substrates

An Exposed KID-Like Domain in Human T-Cell Lymphotropic Virus Type 1 Tax Is Responsible for the Recruitment of Coactivators CBP/p300

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