Mathias Färnegårdh

The orphan nuclear receptor SHP utilizes conserved LXXLL-related motifs for interactions with ligand-activated estrogen receptors.

ABSTRACT SHP (short heterodimer partner) is an unusual orphan nuclear receptor consisting only of a ligand-binding domain, and it exhibits unique features of interaction with conventional nuclear receptors. While the mechanistic basis of these interactions has remained enigmatic, SHP has been suggested to inhibit nuclear receptor activation by at least three alternatives; inhibition of DNA binding via dimerization, direct antagonism of coactivator function via competition, and possibly transrepression via recruitment of putative corepressors. We now show that SHP binds directly to estrogen receptors via LXXLL-related motifs. Similar motifs, referred to as NR (nuclear receptor) boxes, are usually critical for the binding of coactivators to the ligand-regulated activation domain AF-2 within nuclear receptors. In concordance with the NR box dependency, SHP requires the intact AF-2 domain of agonist-bound estrogen receptors for interaction. Mutations within the ligand-binding domain helix 12, or binding of antagonistic ligands, which are known to result in an incomplete AF-2 surface, abolish interactions with SHP. Supporting the idea that SHP directly antagonizes receptor activation via AF-2 binding, we demonstrate that SHP variants, carrying either interaction-defective NR box mutations or a deletion of the repressor domain, have lost the capacity to inhibit agonist-dependent transcriptional estrogen receptor activation. Furthermore, our studies indicate that SHP may function as a cofactor via the formation of ternary complexes with dimeric receptors on DNA. These novel insights provide a mechanistic explanation for the inhibitory role of SHP in nuclear receptor signaling, and they may explain how SHP functions as a negative coregulator or corepressor for ligand-activated receptors, a novel and unique function for an orphan nuclear receptor.

The three-dimensional structure of the liver X receptor beta reveals a flexible ligand-binding pocket that can accommodate fundamentally different ligands.

The structures of the liver X receptor LXRβ (NR1H2) have been determined in complexes with two synthetic ligands, T0901317 and GW3965, to 2.1 and 2.4 Å, respectively. Together with its isoform LXRα (NR1H3) it regulates target genes involved in metabolism and transport of cholesterol and fatty acids. The two LXRβ structures reveal a flexible ligand-binding pocket that can adjust to accommodate fundamentally different ligands. The ligand-binding pocket is hydrophobic but with polar or charged residues at the two ends of the cavity. T0901317 takes advantage of this by binding to His-435 close to H12 while GW3965 orients itself with its charged group in the opposite direction. Both ligands induce a fixed “agonist conformation” of helix H12 (also called the AF-2 domain), resulting in a transcriptionally active receptor.

Indazole-based liver X receptor (LXR) modulators with maintained atherosclerotic lesion reduction activity but diminished stimulation of hepatic triglyceride synthesis.

A series of substituted 2-benzyl-3-aryl-7-trifluoromethylindazoles were prepared as LXR modulators. These compounds were partial agonists in transactivation assays when compared to 1 (T0901317) and were slightly weaker with respect to potency and efficacy on LXRalpha than on LXRbeta. Lead compounds in this series 12 (WAY-252623) and 13 (WAY-214950) showed less lipid accumulation in HepG2 cells than potent full agonists 1 and 3 (WAY-254011) but were comparable in efficacy to 1 and 3 with respect to cholesterol efflux in THP-1 foam cells, albeit weaker in potency. Compound 13 reduced aortic lesion area in LDLR knockout mice equivalently to 3 or positive control 2 (GW3965). In a 7-day hamster model, compound 13 showed a lesser propensity for plasma TG elevation than 3, when the compounds were compared at doses in which they elevated ABCA1 and ABCG1 gene expression in duodenum and liver at equal levels. In contrast to results previously published for 2, the lack of TG effect of 13 correlated with its inability to increase liver fatty acid synthase (FAS) gene expression, which was up-regulated 4-fold by 3. These results suggest indazoles such as 13 may have an improved profile for potential use as a therapeutic agent.

Convergence of lipid homeostasis through liver X and thyroid hormone receptors

Members of the nuclear receptor gene family act as biological rheostats to maintain metabolic homeostasis in response to endocrine and nutritional changes. The liver X (LXR) and thyroid hormone (TR) receptors have been shown to regulate overlapping but distinct metabolic pathways important for overall lipid homeostasis. Dyslipidemia is one out of four key determinants for cardiovascular risk and both LXRs and TRs may provide attractive targets for intervention of cardiovascular disease. In this review we will compare the two receptor systems to highlight similarities and differences in structure and function with implications for development of novel treatments for dyslipidemia and atherosclerosis.

Biarylether amide quinolines as liver X receptor agonists.

A series of 4-(amido-biarylether)-quinolines was prepared as potential LXR agonists. Appropriate substitution with amide groups provided high affinity LXR ligands, some with excellent potency and efficacy in functional assays of LXR activity. Novel amide 4g had a binding IC(50)=1.9 nM for LXRbeta and EC(50)=34 nM (96% efficacy relative to T0901317) in an ABCA1 gene expression assay in mouse J774 cells, demonstrating that 4-(biarylether)-quinolines with appropriate amide substitution are potent LXR agonists.