UCSC Genome Browser Gene Interaction Graph

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Gene interactions and pathways from curated databases and text-mining

Genes Dev 2002, PMID: 12050117

Mastermind mediates chromatin-specific transcription and turnover of the Notch enhancer complex.

Fryer, Christy J; Lamar, Elise; Turbachova, Ivana; Kintner, Chris; Jones, Katherine A

Signaling through the Notch pathway activates the proteolytic release of the Notch intracellular domain (ICD), a dedicated transcriptional coactivator of CSL enhancer-binding proteins. Here we show that chromatin-dependent transactivation by the recombinant Notch ICD-CBF1 enhancer complex in vitro requires an additional coactivator, Mastermind (MAM). MAM provides two activation domains necessary for Notch signaling in mammalian cells and in Xenopus embryos. We show that the central MAM activation domain (TAD1) recruits CBP/p300 to promote nucleosome acetylation at Notch enhancers and activate transcription in vitro. We also find that MAM expression induces phosphorylation and relocalization of endogenous CBP/p300 proteins to nuclear foci in vivo. Moreover, we show that coexpression with MAM and CBF1 strongly enhances phosphorylation and proteolytic turnover of the Notch ICD in vivo. Enhanced phosphorylation of the ICD and p300 requires a glutamine-rich region of MAM (TAD2) that is essential for Notch transcription in vivo. Thus MAM may function as a timer to couple transcription activation with disassembly of the Notch enhancer complex on chromatin.

Document information provided by NCBI PubMed

Text Mining Data

MAM → CBP/p300: " We also find that MAM expression induces phosphorylation and relocalization of endogenous CBP/p300 proteins to nuclear foci in vivo "

Manually curated Databases

IRef Biogrid Interaction: MAML1 — CREBBP (physical association, affinity chromatography technology)
IRef Biogrid Interaction: EP300 — MAML1 (physical association, affinity chromatography technology)
IRef Hprd Interaction: MAML1 — CREBBP (in vitro)
IRef Hprd Interaction: EP300 — MAML1 (in vitro)
IRef Ophid Interaction: MAML1 — CREBBP (aggregation, confirmational text mining)
Reactome Reaction: CREBBP → MAML3 (reaction)
Reactome Reaction: NOTCH1 → MAML1 (reaction)
Reactome Reaction: NOTCH1 → MAML2 (reaction)
Reactome Reaction: CREBBP → RBPJ (indirect_complex)
Reactome Reaction: NOTCH1 → EP300 (indirect_complex)
Reactome Reaction: KAT2B → RBPJ (reaction)
Reactome Reaction: NOTCH1 → MAML3 (reaction)
Reactome Reaction: MAML1 → RBPJ (reaction)
Reactome Reaction: CREBBP → SNW1 (indirect_complex)
Reactome Reaction: CREBBP → NOTCH1 (reaction)
Reactome Reaction: KAT2B → SNW1 (indirect_complex)
Reactome Reaction: KAT2B → MAML2 (reaction)
Reactome Reaction: NOTCH1 → MAML2 (indirect_complex)
Reactome Reaction: KAT2B → MAML3 (reaction)
Reactome Reaction: EP300 → MAML1 (reaction)
Reactome Reaction: MAML3 → RBPJ (indirect_complex)
Reactome Reaction: NOTCH1 → MAML1 (indirect_complex)
Reactome Reaction: CREBBP → SNW1 (reaction)
Reactome Reaction: NOTCH1 → KAT2B (reaction)
Reactome Reaction: MAML2 → RBPJ (reaction)
Reactome Reaction: EP300 → MAML2 (reaction)
Reactome Reaction: NOTCH1 → MAML3 (indirect_complex)
Reactome Reaction: CREBBP → MAML3 (direct_complex)
Reactome Reaction: CREBBP → MAML2 (reaction)
Reactome Reaction: NOTCH1 → KAT2B (indirect_complex)
Reactome Reaction: EP300 → RBPJ (reaction)
Reactome Reaction: EP300 → KAT2B (direct_complex)
Reactome Reaction: EP300 → MAML2 (direct_complex)
Reactome Reaction: CREBBP → KAT2B (direct_complex)
Reactome Reaction: SNW1 → MAML1 (reaction)
Reactome Reaction: MAML2 → RBPJ (indirect_complex)
Reactome Reaction: CREBBP → EP300 (reaction)
Reactome Reaction: EP300 → MAML3 (direct_complex)
Reactome Reaction: EP300 → MAML1 (direct_complex)
Reactome Reaction: SNW1 → MAML3 (reaction)
Reactome Reaction: SNW1 → MAML3 (indirect_complex)
Reactome Reaction: CREBBP → MAML1 (direct_complex)
Reactome Reaction: CREBBP → NOTCH1 (indirect_complex)
Reactome Reaction: CREBBP → RBPJ (reaction)
Reactome Reaction: CREBBP → MAML2 (direct_complex)
Reactome Reaction: CREBBP → KAT2B (reaction)
Reactome Reaction: KAT2B → SNW1 (reaction)
Reactome Reaction: EP300 → RBPJ (indirect_complex)
Reactome Reaction: MAML3 → RBPJ (reaction)
Reactome Reaction: CREBBP → MAML1 (reaction)
Reactome Reaction: MAML1 → RBPJ (indirect_complex)
Reactome Reaction: KAT2B → MAML2 (direct_complex)
Reactome Reaction: SNW1 → MAML1 (indirect_complex)
Reactome Reaction: SNW1 → MAML2 (reaction)
Reactome Reaction: SNW1 → MAML2 (indirect_complex)
Reactome Reaction: EP300 → MAML3 (reaction)
Reactome Reaction: KAT2B → MAML1 (reaction)
Reactome Reaction: EP300 → SNW1 (indirect_complex)
Reactome Reaction: KAT2B → RBPJ (indirect_complex)
Reactome Reaction: KAT2B → MAML1 (direct_complex)
Reactome Reaction: EP300 → KAT2B (reaction)
Reactome Reaction: EP300 → SNW1 (reaction)
Reactome Reaction: KAT2B → MAML3 (direct_complex)
Reactome Reaction: NOTCH1 → EP300 (reaction)
Reactome Reaction: CREBBP → EP300 (direct_complex)

In total, 30 gene pairs are associated to this article in curated databases