The role of residue C410 on activation of the human vitamin D receptor by various ligands.

Nuclear receptors (NRs) are ligand-activated transcription factors that regulate the expression of genes involved in biologically important processes. The human vitamin D receptor (hVDR) is a member of the NR superfamily and is responsible for maintaining calcium and phosphate homeostasis. This receptor is activated by its natural ligand, 1α, 25-dihydroxyvitamin D(3) (1α, 25(OH)(2)D(3)), as well as bile acids such as lithocholic acid (LCA). Disruption of molecular interactions between the hVDR and its natural ligand result in adverse diseases, such as rickets, making this receptor a good target for drug discovery. Previous mutational analyses of the hVDR have mainly focused on residues lining the receptor's ligand binding pocket (LBP) and techniques such as alanine scanning mutagenesis and site-directed mutagenesis. In this work, a rationally designed hVDR library using randomized codons at selected positions provides insight into the role of residue C410, particularly on activation of the receptor by various ligands. A variant, C410Y, was engineered to bind LCA with increased sensitivity (EC(50) value of 3 µM and a 34-fold activation) in mammalian cell culture assays. Furthermore, this variant displayed activation with a novel small molecule, cholecalciferol (chole) which does not activate the wild-type receptor, with an EC(50) value of 4 µM and a 25-fold activation. The presence of a bulky residue at this position, such as a tyrosine or phenylalanine, may contribute towards molecular interactions that allow for the enhanced activation with LCA and novel activation with chole. Additional bulk at the same end of the pocket, such as in the case of the variant H305F; C410Y enhances the receptor's sensitivity for these ligands further, perhaps due to the filling of a cavity. The effects of residue C410 on specificity and activation with the different ligands studied were unforeseen, as this residue does not line the hVDR's LBP. Further investigating of the structure-function relationships between the hVDR and its ligands, including the mutational tolerance of residues within as well as outside the LBP, is needed for a comprehensive understanding of the functionality and interactions of the receptor with these ligands and for development of new small molecules as potential therapeutic drugs.

A human vitamin D receptor mutant activated by cholecalciferol.

The human vitamin D receptor (hVDR) is a member of the nuclear receptor superfamily, involved in calcium and phosphate homeostasis; hence implicated in a number of diseases, such as Rickets and Osteoporosis. This receptor binds 1α,25-dihydroxyvitamin D(3) (also referred to as 1,25(OH)(2)D(3)) and other known ligands, such as lithocholic acid. Specific interactions between the receptor and ligand are crucial for the function and activation of this receptor, as implied by the single point mutation, H305Q, causing symptoms of Type II Rickets. In this work, further understanding of the significant and essential interactions between the ligand and the receptor was deciphered, through a combination of rational and random mutagenesis. A hVDR mutant, H305F, was engineered with increased sensitivity towards lithocholic acid, with an EC(50) value of 10 µM and 40±14 fold activation in mammalian cell assays, while maintaining wild-type activity with 1,25(OH)(2)D(3). Furthermore, via random mutagenesis, a hVDR mutant, H305F/H397Y, was discovered to bind a novel small molecule, cholecalciferol, a precursor in the 1α,25-dihydroxyvitamin D(3) biosynthetic pathway, which does not activate wild-type hVDR. This variant, H305F/H397Y, binds and activates in response to cholecalciferol concentrations as low as 100 nM, with an EC(50) value of 300 nM and 70±11 fold activation in mammalian cell assays. In silico docking analysis of the variant displays a dramatic conformational shift of cholecalciferol in the ligand binding pocket in comparison to the docked analysis of cholecalciferol with wild-type hVDR. This shift is hypothesized to be due to the introduction of two bulkier residues, suggesting that the addition of these bulkier residues introduces molecular interactions between the ligand and receptor, leading to activation with cholecalciferol.