Functionality maps of the ATP binding site of DNA gyrase B: generation of a consensus model of ligand binding.

The Multiple Copy Simultaneous Search method (MCSS) was used to construct consensus functionality maps for functional group binding in the ATP binding site of DNA gyrase B. To account for the conformational flexibility of the protein active site, which involves small side chain fluctuations as well as large-scale loop motions, the calculations were done for three different conformations of the 24 kDa subdomain of DNA gyrase B. A postprocessing procedure that employs a continuum dielectric model to include solvent effects was used to calculate the binding free energy for every functional group. These results were ranked according to their affinity for DNA gyrase B and clustered using a new procedure based on van der Waals contacts that is better adapted for cases where multiple conformations are being considered. A total of 23 different functional groups were tested. The results gave consensus maps that indicate those functional group binding sites that are insensitive to the specific protein conformation. The maps also demonstrate that functional groups other than those found in the known ligands may bind competitively in the binding sites of known ligands. This suggests numerous scaffolds that can be used in the development of new ligands for the ATP and coumarinic binding sites in DNA gyrase B. Finally, the calculations show the existence of alternative binding sites near the known binding sites that could be targeted in the rational design for new inhibitors.

Critical role of desolvation in the binding of 20-hydroxyecdysone to the ecdysone receptor.

The insect steroid hormone 20-hydroxyecdysone (20E) binds to its cognate nuclear receptor composed of the ecdysone receptor (EcR) and Ultraspiracle (USP) and triggers the main developmental transitions, in particular molting and metamorphosis. We present the crystal structure of the ligand-binding domains of EcR/USP in complex with 20E at 2.4A resolution and compare it with published structures of EcR/USP bound to ponasterone A (ponA). ponA is essentially identical to 20E but lacks the 25-OH group of 20E. The structure of 20E-bound EcR indicates that an additional hydrogen bond is formed compared with the ponA-bound receptor, yet, paradoxically, ponA has a significantly higher affinity for EcR than 20E. Theoretical studies based on docking and free energy methods lead to a rationale for understanding the difference in binding affinities between 20E and ponA. Results of the calculations indicate that the favorable contribution from the extra H-bond made by 25-OH of 20E is counterbalanced by its larger desolvation cost compared with that of ponA. The contribution of 25-OH to the binding affinity is further compared with those of 20- and 22-OH groups. Ligands that lack the 20- or 22-OH group are indeed known to bind less favorably to EcR than 20E, an effect opposite to that observed for ponA. The results indicate that their respective contributions to receptor-ligand complex stability reside mostly in their different contributions to solvation/desolvation. Together, the data demonstrate the critical role of ligand desolvation in determining binding affinity, with general implications for the binding of hormones to their cognate nuclear receptors.