The glucocorticoid mometasone furoate is a novel FXR ligand that decreases inflammatory but not metabolic gene expression.

The Farnesoid X receptor (FXR) regulates bile salt, glucose and cholesterol homeostasis by binding to DNA response elements, thereby activating gene expression (direct transactivation). FXR also inhibits the immune response via tethering to NF-κB (tethering transrepression). FXR activation therefore has therapeutic potential for liver and intestinal inflammatory diseases. We aim to identify and develop gene-selective FXR modulators, which repress inflammation, but do not interfere with its metabolic capacity. In a high-throughput reporter-based screen, mometasone furoate (MF) was identified as a compound that reduced NF-κB reporter activity in an FXR-dependent manner. MF reduced mRNA expression of pro-inflammatory cytokines, and induction of direct FXR target genes in HepG2-GFP-FXR cells and intestinal organoids was minor. Computational studies disclosed three putative binding modes of the compound within the ligand binding domain of the receptor. Interestingly, mutation of W469A residue within the FXR ligand binding domain abrogated the decrease in NF-κB activity. Finally, we show that MF-bound FXR inhibits NF-κB subunit p65 recruitment to the DNA of pro-inflammatory genes CXCL2 and IL8. Although MF is not suitable as selective anti-inflammatory FXR ligand due to nanomolar affinity for the glucocorticoid receptor, we show that separation between metabolic and anti-inflammatory functions of FXR can be achieved.

Bile acid derivatives as ligands of the farnesoid x receptor: molecular determinants for bile acid binding and receptor modulation.

Bile acids are a peculiar class of steroidal compounds that never cease to amaze. From being simple detergents with a primary role in aiding the absorption of fats and fat-soluble vitamins, bile acids are now widely considered as crucial hormones endowed with genomic and non-genomic functions that are mediated by their interaction with several proteins including the nuclear receptor Farnesoid X Receptor (FXR). Taking advantages of the peculiar properties of bile acids in interacting with the FXR receptor, several biliary derivatives have been synthesized and tested as FXR ligands. The availability of these compounds has contributed to characterize the receptor from a structural, patho-physiological and therapeutic standpoint. Among these, obeticholic acid is a first-in-class FXR agonist that is demonstrating hepatoprotective effects upon FXR activation in patients with liver diseases such as primary biliary cirrhosis and nonalcoholic steatohepatitis. This review provides an historical overview of the rationale behind the discovery of obeticholic acid and chemical tools generated to depict the molecular features and bio-pharmacological relevance of the FXR receptor, as well as to summarize structure-activity relationships of bile acid-based FXR ligands so far reported.

Accounting for target flexibility and water molecules by docking to ensembles of target structures: the HCV NS5B palm site I inhibitors case study.

The introduction of new anti-HCV drugs in therapy is an imperative need and is necessary with a view to develop an interferon-free therapy. Thus, the discovery and development of novel small molecule inhibitors of the viral NS5B polymerase represent an exciting area of research for many pharmaceutical companies and academic groups. This study represents a contribution to this field and relies on the identification of the best NS5B model(s) to be used in structure-based computational approaches aimed at identifying novel non-nucleoside inhibitors of one of the protein allosteric sites, namely, palm site I. First, the NS5B inhibitors at palm site I were classified as water-mediated or nonwater-mediated ligands depending on their ability to interact with or displace a specific water molecule. Then, we took advantage of the available X-ray structures of the NS5B/ligand complexes to build different models of protein/water combinations, which were used to investigate the influence on docking studies of solvent sites as well as of the influence of the protein conformations. As the overall trend, we observed improved performance in the docking results of the water-mediated inhibitors by inclusion of explicit water molecules, with an opposite behavior generally happening for the nonwater-mediated inhibitors. The best performing target structures for the two ligand sets were then used for virtual screening simulations of a library containing the known NS5B inhibitors along with related decoys to assess the best performing targets ensembles on the basis of their ability to discriminate active and inactive compounds as well as to generate the correct binding modes. The parallel use of different protein structures/water sets outperformed the use of a single target structure, with the two-protein 3H98/2W-2FVC/7W and 3HKY/NoW-3SKE/NoW models resulting in the best performing ensembles for water-mediated inhibitors and nonwater-mediated inhibitors, respectively. The information gathered from this work confirms the primary role of water molecules and protein flexibility in docking-based studies and can be exploited to aid NS5B-directed HCV drug discovery efforts.