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PDBsum entry 3huc
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References listed in PDB file
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Key reference
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Title
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Fluorophore labeling of the glycine-Rich loop as a method of identifying inhibitors that bind to active and inactive kinase conformations.
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Authors
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J.R.Simard,
M.Getlik,
C.Grütter,
R.Schneider,
S.Wulfert,
D.Rauh.
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Ref.
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J Am Chem Soc, 2010,
132,
4152-4160.
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PubMed id
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Abstract
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Targeting protein kinases with small organic molecules is a promising strategy
to regulate unwanted kinase activity in both chemical biology and medicinal
chemistry research. Traditionally, kinase inhibitors are identified in
activity-based screening assays using enzymatically active kinase preparations
to measure the perturbation of substrate phosphorylation, often resulting in the
enrichment of classical ATP competitive (Type I) inhibitors. However, addressing
enzymatically incompetent kinase conformations offers new opportunities for
targeted therapies and is moving to the forefront of kinase inhibitor research.
Here we report the development of a new FLiK (Fluorescent Labels in Kinases)
binding assay to detect small molecules that induce changes in the conformation
of the glycine-rich loop. Due to cross-talk between the glycine-rich loop and
the activation loop in kinases, this alternative labeling approach can also
detect ligands that stabilize inactive kinase conformations, including
slow-binding Type II and Type III kinase inhibitors. Protein X-ray
crystallography validated the assay results and identified a novel DFG-out
binding mode for a quinazoline-based inhibitor in p38alpha kinase. We also
detected the high-affinity binding of a clinically relevant and specific VEGFR2
inhibitor, and we provide structural details of its binding mode in p38alpha, in
which it stabilizes the DFG-out conformation. Last, we demonstrate the power of
this new FLiK labeling strategy to detect the binding of Type I ligands that
induce conformational changes in the glycine-rich loop as a means of gaining
affinity for the target kinase. This approach may be a useful alternative to
develop direct binding assays for kinases that do not adopt the DFG-out
conformation while also avoiding the use of expensive kits, detection reagents,
or radioactivity frequently employed with activity-based assays.
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