BACKGROUND: Reliable prediction of multiple ligand-receptor interactions for a given bioactive compound helps recognize and understand off-target effects, and enables drug re-purposing and scaffold-hopping in lead discovery. We developed a ligand-based computational method for drug-target prediction that is independent from protein structural analysis. METHOD: The idea is to infer drug targets from the pharmacophoric feature similarity of known ligands, and define functional target similarity from a ligand perspective, which also provides access to targets with unknown structures. First, known ligands were represented by topological pharmacophoric features. Then, the self-organizing map technique was used to generate fingerprint patterns for similarity analysis, where each resulting fingerprint represents a drug target. Target fingerprints were clustered and analyzed for correlations. Well-structured dendrograms were obtained presenting interpretable and meaningful relationships between drug targets. CONCLUSION: Self-organization of fingerprints reduces noise from molecular pharmacophore descriptors, captures their essential features, and reveals potential cross-activities of ligand classes and off-target effects of bioactive compounds.
BACKGROUND: Reliable prediction of multiple ligand-receptor interactions for a given bioactive compound helps recognize and understand off-target effects, and enables drug re-purposing and scaffold-hopping in lead discovery. We developed a ligand-based computational method for drug-target prediction that is independent from protein structural analysis. METHOD: The idea is to infer drug targets from the pharmacophoric feature similarity of known ligands, and define functional target similarity from a ligand perspective, which also provides access to targets with unknown structures. First, known ligands were represented by topological pharmacophoric features. Then, the self-organizing map technique was used to generate fingerprint patterns for similarity analysis, where each resulting fingerprint represents a drug target. Target fingerprints were clustered and analyzed for correlations. Well-structured dendrograms were obtained presenting interpretable and meaningful relationships between drug targets. CONCLUSION: Self-organization of fingerprints reduces noise from molecular pharmacophore descriptors, captures their essential features, and reveals potential cross-activities of ligand classes and off-target effects of bioactive compounds.
Authors: Michael Reutlinger; Christian P Koch; Daniel Reker; Nickolay Todoroff; Petra Schneider; Tiago Rodrigues; Gisbert Schneider Journal: Mol Inform Date: 2013-02-07 Impact factor: 3.353
Authors: Yen-Chu Lin; Jan A Hiss; Petra Schneider; Peter Thelesklaf; Yi Fan Lim; Max Pillong; Fabian M Koehler; Petra S Dittrich; Cornelia Halin; Silja Wessler; Gisbert Schneider Journal: Chembiochem Date: 2014-09-09 Impact factor: 3.164