Ping Yi scite author profile

Although several lines of evidence have indicated that the activity of SRC-3/AIB1/ACTR/pCIP/RAC3/TRAM1 could be regulated by phosphorylation, an important question remained as to how different signaling pathways can act through limiting concentrations of the same SRC-3 molecule to exert different physiological functions. Herein, we report the successful identification of six functional in vivo SRC-3 phosphorylation sites. Interestingly, all phosphorylation sites are required for coactivation of estrogen and androgen receptors, but not all sites are required for coactivation of NF-kappaB. Different combinations of site-specific phosphorylations of SRC-3 are required for induction of IL-6 gene expression by TNF-alpha as compared to oncogenic transformation of MEFs. Mechanisms of pathway selectivity involve protein-protein interactions of differentially phosphorylated SRC-3 with downstream transcriptional activators and coactivators. Our results uncovered an additional level of transcriptional regulation whereby specific modulations of SRC-3 phosphorylation allow this coactivator to function as a regulatable integrator for diverse signaling pathways in cells.

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Metabolic enzyme PFKFB4 activates transcriptional coactivator SRC-3 to drive breast cancer

Dasgupta

Rajapakshe

Zhu

et al. 2018

Nature

185

193

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Altered re-wiring of cell metabolism and transcriptional programs are both hallmarks of cancer that sustain rapid proliferation and metastasis1. However mechanisms controlling the interplay between metabolic reprogramming and transcriptional regulation remain elusive. Here we show that metabolic enzyme 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase 4 (PFKFB4) regulates transcriptional reprogramming by activating the oncogenic steroid receptor coactivator-3 (SRC-3). We employed a method for identifying potential kinases that modulate coactivator functions by integrating kinome-wide RNA interference (RNAi)-based screening coupled to intrinsic SRC-3-transcriptional response. PFKFB4, a regulatory enzyme that synthesizes an allosteric stimulator of glycolysis2, was found to be a robust stimulator of SRC-3 that co-activates estrogen receptor (ER). PFKFB4 phosphorylates SRC-3 at serine 857 (S857) enhancing its transcriptional activity, whereas either suppression of PFKFB4 or ectopic expression of a phosphorylation-deficient SRC-3 mutant S857A (SRC-3S857A) significantly abolishes SRC-3-mediated transcriptional output. Functionally, PFKFB4-driven SRC-3 activation drives glucose flux towards the pentose phosphate pathway enabling purine synthesis by transcriptionally upregulating the expression of enzyme transketolase (TKT). In addition, two enzymes adenosine monophosphate deaminase-1 (AMPD1) and xanthine dehydrogenase (XDH) involved in purine metabolism were identified as SRC-3 targets which may or may not be directly involved in purine synthesis. Mechanistically, phosphorylation at S857 increases coactivator interaction with the transcription factor ATF4 stabilizing SRC-3/ATF4 recruitment to target gene promoters. Ablation of SRC-3 or PFKFB4 suppresses in vivo breast tumor growth and prevents metastasis to the lung from an orthotopic setting as does an SRC-3S857A mutant. PFKFB4 and pSRC-3-S857 levels are elevated and significantly correlate in ER positive tumors whereas, in patients with basal subtype, PFKFB4-SRC-3 drives a common protein signature that positively correlates with the poor survival of breast cancer patients. These findings suggest that the Warburg-pathway enzyme PFKFB4 acts as a molecular fulcrum coupling sugar metabolism to transcriptional activation by stimulating SRC-3 critical to promote aggressive metastatic tumors.

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Structure of a Biologically Active Estrogen Receptor-Coactivator Complex on DNA

et al. 2015

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SUMMARY Estrogen receptor (ER) is a transcription factor critical for development, reproduction, metabolism and cancer. ER function hinges on its ability to recruit primary and secondary coactivators, yet structural information on the full-length receptor-coactivator complex to complement pre-existing and sometimes controversial biochemical information is lacking. Here we use cryo-EM to determine the quaternary structure of an active complex of DNA-bound ERα, steroid receptor coactivator 3 (SRC-3) and a secondary coactivator (p300). Our structural model suggests the following assembly mechanism for the complex: each of the two ligand-bound ERα monomers independently recruits one SRC-3 protein via the transactivation domain of ERα; the two SRC-3s in turn bind to different regions of one p300 protein through multiple contacts. We also present structural evidence for the location of activation function 1 (AF-1) in a full-length nuclear receptor, which supports a role for AF-1 in SRC-3 recruitment.

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GATA2 facilitates steroid receptor coactivator recruitment to the androgen receptor complex

Lanz

Fiskus

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

106

159

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The androgen receptor (AR) is a key driver of prostate cancer (PC), even in the state of castration-resistant PC (CRPC) and frequently even after treatment with second-line hormonal therapies such as abiraterone and enzalutamide. The persistence of AR activity via both ligand-dependent and ligand-independent mechanisms (including constitutively active AR splice variants) highlights the unmet need for alternative approaches to block AR signaling in CRPC. We investigated the transcription factor GATA-binding protein 2 (GATA2) as a regulator of AR signaling and an actionable therapeutic target in PC. We demonstrate that GATA2 directly promotes expression of both full-length and splice-variant AR, resulting in a strong positive correlation between GATA2 and AR expression in both PC cell lines and patient specimens. Conversely, GATA2 expression is repressed by androgen and AR, suggesting a negative feedback regulatory loop that, upon androgen deprivation, derepresses GATA2 to contribute to AR overexpression in CRPC. Simultaneously, GATA2 is necessary for optimal transcriptional activity of both fulllength and splice-variant AR. GATA2 colocalizes with AR and Forkhead box protein A1 on chromatin to enhance recruitment of steroid receptor coactivators and formation of the transcriptional holocomplex. In agreement with these important functions, high GATA2 expression and transcriptional activity predicted worse clinical outcome in PC patients. A GATA2 small molecule inhibitor suppressed the expression and transcriptional function of both full-length and splice-variant AR and exerted potent anticancer activity against PC cell lines. We propose pharmacological inhibition of GATA2 as a firstin-field approach to target AR expression and function and improve outcomes in CRPC.prostate cancer | small molecule inhibitor | AR signaling | GATA2 | steroid receptor coactivator

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Signaling within a Coactivator Complex: Methylation of SRC-3/AIB1 Is a Molecular Switch for Complex Disassembly

Feng

Wong

et al. 2006

Molecular and Cellular Biology

149

126

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Recent studies indicate that steroid receptor-mediated transcriptional initiation is a cyclical process involving multiple rounds of coactivator assembly and disassembly. Steroid receptor coactivator 3 (SRC-3) coactivator phosphorylation has been shown to regulate coactivator complex assembly, but the mechanisms by which coactivator disassembly is triggered are not well understood. In this study, we provide in vitro and in vivo evidence that members of the SRC coactivator family serve as substrates for the enzymatic coactivator coactivator-associated arginine methyltransferase 1 (CARM1). Methylation of SRC-3 was localized to an arginine in its CARM1 binding region and correlated with decreased estrogen receptor alpha-mediated transcription, as seen with both cell-based and in vitro transcription assays. Consistent with this finding, we demonstrated that methylation promotes dissociation of the SRC-3/CARM1 coactivator complex. Methylation of SRC-3 is regulated by estrogen signaling in MCF7 cells and serves as a molecular switch for disassembly of the SRC-3 transcriptional coactivator complex. We propose that CARM1 is a dual-function coactivator, as it not only activates transcription by modifying core histone tails but also terminates hormone signaling by disassembly of the coactivator complex.

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Ping Yi

Selective Phosphorylations of the SRC-3/AIB1 Coactivator Integrate Genomic Reponses to Multiple Cellular Signaling Pathways

Metabolic enzyme PFKFB4 activates transcriptional coactivator SRC-3 to drive breast cancer

Structure of a Biologically Active Estrogen Receptor-Coactivator Complex on DNA

GATA2 facilitates steroid receptor coactivator recruitment to the androgen receptor complex

Signaling within a Coactivator Complex: Methylation of SRC-3/AIB1 Is a Molecular Switch for Complex Disassembly

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