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PDBsum entry 4ase
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References listed in PDB file
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Key reference
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Title
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Molecular conformations, Interactions, And properties associated with drug efficiency and clinical performance among vegfr tk inhibitors.
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Authors
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M.Mctigue,
B.W.Murray,
J.H.Chen,
Y.L.Deng,
J.Solowiej,
R.S.Kania.
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Ref.
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Proc Natl Acad Sci U S A, 2012,
109,
18281-18289.
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PubMed id
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Abstract
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Analyses of compounds in clinical development have shown that ligand
efficient-molecules with privileged physical properties and low dose are less
likely to fail in the various stages of clinical testing, have fewer
postapproval withdrawals, and are less likely to receive black box safety
warnings. However, detailed side-by-side examination of molecular interactions
and properties within single drug classes are lacking. As a class, VEGF receptor
tyrosine kinase inhibitors (VEGFR TKIs) have changed the landscape of how cancer
is treated, particularly in clear cell renal cell carcinoma, which is
molecularly linked to the VEGF signaling axis. Despite the clear role of the
molecular target, member molecules of this validated drug class exhibit distinct
clinical efficacy and safety profiles in comparable renal cell carcinoma
clinical studies. The first head-to-head randomized phase III comparative study
between active VEGFR TKIs has confirmed significant differences in clinical
performance [Rini BI, et al. (2011) Lancet 378:193-1939]. To elucidate how
fundamental drug potency-efficiency is achieved and impacts differentiation
within the VEGFR TKI class, we determined potencies, time dependence,
selectivities, and X-ray structures of the drug-kinase complexes using a VEGFR2
TK construct inclusive of the important juxtamembrane domain. Collectively, the
studies elucidate unique drug-kinase interactions that are dependent on distinct
juxtamembrane domain conformations, resulting in significant potency and ligand
efficiency differences. The identified structural trends are consistent with in
vitro measurements, which translate well to clinical performance, underscoring a
principle that may be broadly applicable to prospective drug design for optimal
in vivo performance.
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