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PDBsum entry 4rwj
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Transferase/transferase inhibitor
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PDB id
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4rwj
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References listed in PDB file
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Key reference
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Title
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Illuminating the molecular mechanisms of tyrosine kinase inhibitor resistance for the fgfr1 gatekeeper mutation: the achilles' Heel of targeted therapy.
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Authors
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C.D.Sohl,
M.R.Ryan,
B.Luo,
K.M.Frey,
K.S.Anderson.
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Ref.
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Acs Chem Biol, 2015,
10,
1319-1329.
[DOI no: ]
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PubMed id
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Abstract
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Human fibroblast growth factor receptors (FGFRs) 1-4 are a family of receptor
tyrosine kinases that can serve as drivers of tumorigenesis. In particular,
FGFR1 gene amplification has been implicated in squamous cell lung and breast
cancers. Tyrosine kinase inhibitors (TKIs) targeting FGFR1, including AZD4547
and E3810 (Lucitanib), are currently in early phase clinical trials.
Unfortunately, drug resistance limits the long-term success of TKIs, with
mutations at the "gatekeeper" residue leading to tumor progression.
Here we show the first structural and kinetic characterization of the FGFR1
gatekeeper mutation, V561M FGFR1. The V561M mutation confers a 38-fold increase
in autophosphorylation achieved at least in part by a network of interacting
residues forming a hydrophobic spine to stabilize the active conformation.
Moreover, kinetic assays established that the V561M mutation confers significant
resistance to E3810, while retaining affinity for AZD4547. Structural analyses
of these TKIs with wild type (WT) and gatekeeper mutant forms of FGFR1 offer
clues to developing inhibitors that maintain potency against gatekeeper
mutations. We show that AZD4547 affinity is preserved by V561M FGFR1 due to a
flexible linker that allows multiple inhibitor binding modes. This is the first
example of a TKI binding in distinct conformations to WT and gatekeeper mutant
forms of FGFR, highlighting adaptable regions in both the inhibitor and binding
pocket crucial for drug design. Exploiting inhibitor flexibility to overcome
drug resistance has been a successful strategy for combatting diseases such as
AIDS and may be an important approach for designing inhibitors effective against
kinase gatekeeper mutations.
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