BET Bromodomain Inhibitors with One-Step Synthesis Discovered from Virtual Screen

Ayoub, Alex; Hawk, Laura M. L.; Herzig, Ryan J.; Jiang, Jiewei; Wisniewski, Andrea; Gee, Clifford T.; Zhao, Pei‐Liang; Zhu, Jin; Berndt, Norbert; Offei-Addo, Nana K.; Scott, Thomas G.; Qi, Jun; Bradner, James E.; Ward, Timothy R.; Schönbrunn, E.; Georg, Gunda I.; Pomerantz, William C. K.

doi:10.1021/acs.jmedchem.6b01336

Cited by 38 publications

(26 citation statements)

References 64 publications

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“…This method of assay readout is less prone to compound interference compared to other displacement assays,s uch as FP or the AlphaScreen. Label-free methods based on DSF, [32, 47b,d,49] ITC, [32,47b] NMR spectroscopy (water-LOGSY, 19 F-observed, and STD) [50] have also been established to assess binding to bromodomains. These label-free methods do not rely on the availability of previously identified ligands,w hich can be especially useful when studying bromodomains for which an endogenous binding partner is not known, or for which only low affinity ligands have been identified.…”

Section: Functional Genomics:c Orrelating Proteins To Aspecific Phenomentioning

confidence: 99%

Chemical Epigenetics: The Impact of Chemical and Chemical Biology Techniques on Bromodomain Target Validation

et al. 2019

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Epigenetics is currently the focus of intense research interest across a broad range of disciplines due to its importance in a multitude of biological processes and disease states. Epigenetic functions result partly from modification of the nucleobases in DNA and RNA, and/or post‐translational modifications of histone proteins. These modifications are dynamic, with cellular machinery identified to modulate and interpret the marks. Our focus is on bromodomains, which bind to acetylated lysine residues. Progress in the study of bromodomains, and the development of bromodomain ligands, has been rapid. These advances have been underpinned by many disciplines, but chemistry and chemical biology have undoubtedly played a significant role. Herein, we review the key chemistry and chemical biology approaches that have furthered our study of bromodomains, enabled the development of bromodomain ligands, and played a critical role in the validation of bromodomains as therapeutic targets.

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Section: Functional Genomics:c Orrelating Proteins To Aspecific Phenomentioning

confidence: 99%

Chemical Epigenetics: The Impact of Chemical and Chemical Biology Techniques on Bromodomain Target Validation

et al. 2019

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“…82 William's group disclosed dihydropyridopyrimidine derivative 79 as a novel Brd4 inhibitor, which was facilely generated in a single step from commercially available starting materials. 83 Through a midthroughput screen, a xanthine derivative compound 81 was identified as a Brd4 inhibitor with a K d of 2.1 μM determined by ITC. Despite compound 81 showing weak cellular activity against Jurkat T cells with an EC 50 of 27 μM, impressive selectivity for Brd4(1) (IC 50 = 5.0 μM) over Brd2/3(1) (IC 50 > 50 μM) and BrdT(1) (IC 50 > 100 μM) was observed; more unexpectedly, compound 81 showed no detectable inhibition against the BD2 counterparts of all BET proteins tested.…”

Section: Brd4 Inhibitorsmentioning

confidence: 99%

Targeting Brd4 for cancer therapy: inhibitors and degraders

et al. 2018

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“…Among them, crystal structure of compound NSC127133 (compound 61 in Figure 4 ) in complex with BRD2(2) was resolved, which displayed distinct structural features. In 2017, Ayoub et al performed high throughput virtual screen with 6,000,000 compounds in ZINC database using the crystal structure of BRDT(1) (Ayoub et al, 2017 ). A dihydropyridopyrimidine scaffold (compound 62 in Figure 4 ) was identified with highly selectivity for BET family and submicromolar affinity for BRD4(1) and BRDT(1), which could be easily synthesized in one step.…”

Section: Readermentioning

confidence: 99%

Computer-Aided Drug Design in Epigenetics

Zhang

Jiang

et al. 2018

Front. Chem.

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Epigenetic dysfunction has been widely implicated in several diseases especially cancers thus highlights the therapeutic potential for chemical interventions in this field. With rapid development of computational methodologies and high-performance computational resources, computer-aided drug design has emerged as a promising strategy to speed up epigenetic drug discovery. Herein, we make a brief overview of major computational methods reported in the literature including druggability prediction, virtual screening, homology modeling, scaffold hopping, pharmacophore modeling, molecular dynamics simulations, quantum chemistry calculation, and 3D quantitative structure activity relationship that have been successfully applied in the design and discovery of epi-drugs and epi-probes. Finally, we discuss about major limitations of current virtual drug design strategies in epigenetics drug discovery and future directions in this field.

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BET Bromodomain Inhibitors with One-Step Synthesis Discovered from Virtual Screen

Cited by 38 publications

References 64 publications

Chemical Epigenetics: The Impact of Chemical and Chemical Biology Techniques on Bromodomain Target Validation

Chemical Epigenetics: The Impact of Chemical and Chemical Biology Techniques on Bromodomain Target Validation

Targeting Brd4 for cancer therapy: inhibitors and degraders

Computer-Aided Drug Design in Epigenetics

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