Because
of the success of imatinib, the first type-II kinase inhibitor
approved by the FDA in 2001, sustained efforts have been made by the
pharmaceutical industry to discover novel compounds stabilizing the
inactive conformation of protein kinases. On the seven type-II inhibitors
having reached the market, four were released in 2012, suggesting
an acceleration of the research of such a class of compounds. Still,
they represent less than a third of the protein kinase inhibitors
available to patients today. The identification of key residues involved
in the binding of this type of ligands in the kinase active site might
ease the design of potent and selective type-II inhibitors. In order
to identify those discriminant residues, we have developed a proteometric
approach combining residue descriptors of protein kinase sequences
and biological activities of various type-II kinase inhibitors. We
applied Partial Least Squares (PLS) regression to identify 29 key
residues that influence the binding of four type-II inhibitors to
most proteins of the kinome. The gatekeeper residue was found to be
the most relevant, confirming an essential role in ligand binding
as well as in protein kinase conformational changes. Using the newly
developed proteometric model, we predicted the propensity of each
protein kinase to be inhibited by type-II ligands. The model was further
validated using an external data set of protein/ligand activity pairs.
Other residues present in the kinase domain, and more specifically
in the binding site, have been highlighted by this approach, but their
role in biological mechanisms is still unknown.