Experimental and Computational Active Site Mapping as a Starting Point to Fragment-Based Lead Discovery

• Published in: ChemMedChem Vol. 7; no. 2; pp. 248 - 261
• Main Authors: Behnen, Jürgen, Köster, Helene, Neudert, Gerd, Craan, Tobias, Heine, Andreas, Klebe, Gerhard
• Format: Journal Article
• Language: English; German
• Published: Weinheim WILEY-VCH Verlag 06.02.2012; WILEY‐VCH Verlag; Wiley Subscription Services, Inc
• Subjects: active site mapping; Aldose-Ketose Isomerases - chemistry; Aldose-Ketose Isomerases - metabolism; Aspartic Acid Endopeptidases - chemistry; Aspartic Acid Endopeptidases - metabolism; Binding Sites; Catalytic Domain; computational chemistry; crystal structure analysis; Crystallography, X-Ray; Drug Design; Escherichia coli Proteins - chemistry; Escherichia coli Proteins - metabolism; Hydrogen Bonding; Ligands; Models, Molecular; Multienzyme Complexes - chemistry; Multienzyme Complexes - metabolism; Oxidoreductases - chemistry; Oxidoreductases - metabolism; Protein Binding; protein-ligand complexes; Proteins - chemistry; Proteins - metabolism; Small Molecule Libraries - chemistry; small-molecule probes; Software; Thermolysin - chemistry; Thermolysin - metabolism
• ISSN: 1860-7179; 1860-7187
• DOI: 10.1002/cmdc.201100490

Small highly soluble probe molecules such as aniline, urea, N‐methylurea, 2‐bromoacetate, 1,2‐propanediol, nitrous oxide, benzamidine, and phenol were soaked into crystals of various proteins to map their binding pockets and to detect hot spots of binding with respect to hydrophobic and hydrophilic properties. The selected probe molecules were first tested at the zinc protease thermolysin. They were then applied to a wider range of proteins such as protein kinase A, D‐xylose isomerase, 4‐diphosphocytidyl‐2C‐methyl‐D‐erythritol synthase, endothiapepsin, and secreted aspartic protease 2. The crystal structures obtained clearly show that the probe molecules populate the protein binding pockets in an ordered fashion. The thus characterized, experimentally observed hot spots of binding were subjected to computational active site mapping using HotspotsX. This approach uses knowledge‐based pair potentials to detect favorable binding positions for various atom types. Good agreement between the in silico hot spot predictions and the experimentally observed positions of the polar hydrogen bond forming functional groups and hydrophobic portions was obtained. Finally, we compared the observed poses of the small‐molecule probes with those of much larger structurally related ligands. They coincide remarkably well with the larger ligands, considering their spatial orientation and the experienced interaction patterns. This observation confirms the fundamental hypothesis of fragment‐based lead discovery: that binding poses, even of very small molecular probes, do not significantly deviate or move once a ligand is grown further into the binding site. This underscores the fact that these probes populate given hot spots and can be regarded as relevant seeds for further design. Small highly soluble molecules were soaked into various protein crystals to detect binding hot spots with respect to hydrophobic and hydrophilic properties. These hot spots were subjected to computational active site mapping with an approach using knowledge‐based pair potentials to detect favorable binding positions for various atom types. Our findings confirm the central hypothesis of fragment‐based lead discovery: binding poses, even of small probes, do not strongly deviate once a ligand is grown further into a binding site.