To obtain novel transrepression-selective liver X receptor (LXR) ligands, we adopted a strategy of reducing the transactivational agonistic activity of the 5,11-dihydro-5-methyl-11-methylene-6H-dibenz Show more
To obtain novel transrepression-selective liver X receptor (LXR) ligands, we adopted a strategy of reducing the transactivational agonistic activity of the 5,11-dihydro-5-methyl-11-methylene-6H-dibenz[b,e]azepin-6-one derivative 10, which exhibits LXR-mediated transrepressional and transactivational activity. Structural modification of 10 based on the reported X-ray crystal structure of the LXR ligand-binding domain led to a series of compounds, of which almost all exhibited transrepressional activity at 1 or 10 μM but showed no transactivational activity even at 30 μM. Among the compounds obtained, 18 and 22 were confirmed to have LXR-dependent transrepressional activity by using peritoneal macrophages from wild-type and LXR-null mice. A newly developed fluorescence polarization assay indicated that they bind directly to LXRα. Next, further structural modification was performed with the guidance of docking simulations with LXRα, focusing on enhancing the binding of the ligands with LXRα through the introduction of substituents or heteroatom(s). Among the compounds synthesized, compound 48, bearing a hydroxyl group, showed potent, selective, and dose-dependent transrepressional activity. Show less
Liver X receptor (LXR) alpha/beta dual agonists are candidate medicaments for the treatment of metabolic syndrome, because their biological actions include increasing cholesterol efflux mediated by LX Show more
Liver X receptor (LXR) alpha/beta dual agonists are candidate medicaments for the treatment of metabolic syndrome, because their biological actions include increasing cholesterol efflux mediated by LXRbeta. However, their clinical application is currently limited by their enhancing effect on triglyceride (TG) synthesis mediated by LXRalpha. Combination of an LXRalpha-selective antagonist with an LXRalpha/beta dual agonist may overcome this disadvantage. In the present work, structural development studies of phenethylphenyl phthalimide 9, which possesses LXRalpha/beta dual-antagonistic activity and alpha-glucosidase-inhibitory activity, led to the LXRalpha-selective antagonist 23f. Specific alpha-glucosidase inhibitors were also obtained. Show less
Liver X receptors (LXR), which were originally reported as oxysterol-activated nuclear receptors, were recently found to recognize glucose as a physiological ligand. On this basis, we have already dev Show more
Liver X receptors (LXR), which were originally reported as oxysterol-activated nuclear receptors, were recently found to recognize glucose as a physiological ligand. On this basis, we have already developed novel LXR antagonists based upon alpha-glucosidase inhibitors derived from thalidomide. Here, to clarify the relationship between alpha-glucosidase inhibition and LXR modulation, we investigate the alpha-glucosidase-inhibitory activity of typical LXR ligands and the LXR-modulating activity of typical alpha-glucosidase inhibitors. Although there were some exceptions, co-existence of LXR-regulatory and alpha-glucosidase-inhibitory activities seemed to be rather general among the examined compounds. The LXR ligands were found to be non-competitive alpha-glucosidase inhibitors, suggesting that it might be possible to separate the two activities. To test this idea, we focused on riccardin C, a naturally occurring LXR ligand, which we found here to be a potent alpha-glucosidase inhibitor as well. Structural development of riccardin C afforded novel LXR antagonists lacking alpha-glucosidase-inhibitory activity, 19c and 19f, and a LXRalpha-selective antagonist, 22. Show less
Following our previous discovery of LXR antagonistic activity of 2'-substituted phenylphthalimides derived from thalidomide-related glucosidase inhibitors, structure-activity studies and further struc Show more
Following our previous discovery of LXR antagonistic activity of 2'-substituted phenylphthalimides derived from thalidomide-related glucosidase inhibitors, structure-activity studies and further structural development led to 5-chloro-N-2'-n-pentylphenyl-1,3-dithiophthalimide (5CPPSS-50), with IC50 values of about 10 and 13 microM for LXRalpha and LXRbeta, respectively. Show less