Yuka Inaba

Vitamin D3 Derivatives with Adamantane or Lactone Ring Side Chains are Cell Type-Selective Vitamin D Receptor Modulators

The vitamin D receptor (VDR) mediates the biological actions of 1,25-dihydroxyvitamin D3 [1,25(OH)2D3], the active form of vitamin D, which regulates calcium homeostasis, immunity, cellular differentiation, and other physiological processes. We investigated the effects of three 1,25(OH)2D3 derivatives on VDR function. AD47 has an adamantane ring and LAC67a and LAC67b have lactone ring substituents at the side chain position. These vitamin D derivatives bind to VDR but do not stabilize an active cofactor conformation. In a VDR transfection assay, AD47 and LAC67b act as partial agonists and all three compounds inhibit VDR activation by 1,25(OH)2D3. The derivatives enhanced the heterodimerization of VDR with the retinoid X receptor, an effect unrelated to agonist/antagonist activity. AD47 and LAC67b weakly induced recruitment of the SRC-1 cofactor to VDR, and all three derivatives inhibited the recruitment of p160 family cofactors to VDR induced by 1,25(OH)2D3. It is noteworthy that AD47 induced DRIP205 recruitment as effectively as 1,25(OH)2D3, whereas LAC67a and LAC67b were not effective. We examined the expression of endogenous VDR target genes and the nuclear protein levels of VDR and cofactors in several cell lines, including cells derived from intestine, bone, and monocytes, and found that the vitamin D3 derivatives act as cell type-selective VDR modulators. The data indicate that side chain modification is useful in the development of VDR antagonists and tissue-selective modulators. Further elucidation of the molecular mechanisms of action of selective VDR modulators will be essential for their clinical application.

A New Class of Vitamin D Analogues that Induce Structural Rearrangement of the Ligand-Binding Pocket of the Receptor

To identify novel vitamin D receptor (VDR) ligands that induce a novel architecture within the ligand-binding pocket (LBP), we have investigated eight 22-butyl-1alpha,24-dihydroxyvitamin D(3) derivatives (3-10), all having a butyl group as the branched alkyl side chain. We found that the 22S-butyl-20-epi-25,26,27-trinorvitamin D derivative 5 was a potent VDR agonist, whereas the corresponding compound 4 with the natural configuration at C(20) was a potent VDR antagonist. Analogues with the full vitamin D(3) side chain were less potent agonist, and whether they were agonists or antagonists depended on the 24-configuration. X-ray crystal structures demonstrated that the VDR-LBD accommodating the potent agonist 5 has an architecture wherein the lower side and the helix 11 side of the LBP is simply expanded relative to the canonical active-VDR situation; in contrast, the potent antagonist 4 induces an extra cavity to accommodate the branched moiety. This is the first report of a VDR antagonist that generates a new cavity to alter the canonical pocket structure of the ligand occupied VDR.

Structural basis for the activation of PPAR|[gamma]| by oxidized fatty acids

The nuclear receptor peroxisome proliferator–activated receptor-γ (PPARγ) has important roles in adipogenesis and immune response as well as roles in both lipid and carbohydrate metabolism. Although synthetic agonists for PPARγ are widely used as insulin sensitizers, the identity of the natural ligand(s) for PPARγ is still not clear. Suggested natural ligands include 15-deoxy-Δ12,14-prostaglandin J2 and oxidized fatty acids such as 9-HODE and 13-HODE. Crystal structures of PPARγ have revealed the mode of recognition for synthetic compounds. Here we report structures of PPARγ bound to oxidized fatty acids that are likely to be natural ligands for this receptor. These structures reveal that the receptor can (i) simultaneously bind two fatty acids and (ii) couple covalently with conjugated oxo fatty acids. Thermal stability and gene expression analyses suggest that such covalent ligands are particularly effective activators of PPARγ and thus may serve as potent and biologically relevant ligands.

Potent antagonist for the vitamin D receptor: vitamin D analogues with simple side chain structure.

We previously reported that 22S-butyl-25,26,27-trinor-1alpha,24-dihydroxyvitamin D(3) 2 was a potent VDR antagonist. The X-ray crystal structure of the ligand binding domain of VDR complexed with 2 indicated that this ligand induces an extra cavity within the ligand-binding pocket. The structure also showed that the ligand forms only poor hydrophobic interactions with helix 12 of the protein. Here, to study the effects of the induction of the extra cavity and of insufficient interactions with helix 12 on antagonism, we designed and synthesized a series of vitamin D(3) analogues with or without a 22-alkyl substituent and evaluated their biological potency. We found that the 22-butyl analogues 3c and 5c act as full antagonists, the 22-ethyl analogues 3b, 4b, 5b, and 22-butyl analogue 4c act as partial agonists, and the others (3a, 4a, 5a, 6a, 6b, and 6c) act as full agonists for VDR. It is intriguing that 6c is a potent agonist for VDR, whereas its 26,27-dinor analogue 5c is a potent antagonist. Analogue 6c recruited coactivator SRC-1 well, but 5c did not. These results indicate that a combination of induction of the extra cavity and insufficient hydrophobic interactions with helix 12 is important for VDR antagonism in this class of ligands.

Butyl pocket formation in the vitamin d receptor strongly affects the agonistic or antagonistic behavior of ligands

Previously, we reported that 22S-butyl-25,26,27-trinor-1α,24-dihydroxyvitamin D(3)2 represents a new class of antagonist for the vitamin D receptor (VDR). The crystal structure of the ligand-binding domain (LBD) of VDR complexed with 2 showed the formation of a butyl pocket to accommodate the 22-butyl group and insufficient interactions between ligand 2 and the C-terminus of VDR. Here, we designed and synthesized new analogues 5a-c and evaluated their biological activities to probe whether agonistic activity is recovered when the analogue restores interactions with the C-terminus of VDR. Analogues 5a-c exhibited full agonistic activity in transactivation. Interestingly, 5c, which bears a 24-diethyl group, completely recovered agonistic activity, although 3c and 4c act as an antagonist and a weak agonist, respectively. The crystal structures of VDR-LBD complexed with 3a, 4a, 5a, and 5c were solved, and the results confirmed that butyl pocket formation in VDR strongly affects the agonistic or antagonistic behaviors of ligands.

22S-Butyl-1α,24R-dihydroxyvitamin D3: Recovery of vitamin D receptor agonistic activity

We recently reported that 22S-butyl-1alpha,24R-dihydroxyvitamin D(3)3 recovers the agonistic activity for vitamin D receptor (VDR), although its 25,26,27-trinor analog 2 is a potent VDR antagonist. To investigate the structural features involved in the recovery of agonism, we crystallized the ternary complex of VDR-ligand-binding domain, ligand 3 and coactivator peptide, and conducted X-ray crystallographic analysis of the complex. Compared with the complex with 2, the complex with 3 recovered the following structural features: a pincer-type hydrogen bond between the 24-hydroxyl group and VDR, the conformation of Leu305, the positioning of His301 and His393, the stability of the complex, and intimate hydrophobic interactions between the ligand and helix 12. In addition, we evaluated the potency of both compounds for recruiting RXR and coactivator. The results indicate that the complex with 3 generates a suitable surface for coactivator recruitment. These studies suggest that the action of 2 as an antagonist is caused by the generation of a surface not suitable for coactivator recruitment due to the lack of hydrophobic interactions with helix 12 as well as insufficient hydrogen bond formation between the 24-hydroxyl group and VDR. We concluded that the action of 3 as an agonist is based on the elimination of these structural defects in the complex with 2.

Structural basis for inhibition of carboxypeptidase B by selenium-containing inhibitor: selenium coordinates to zinc in enzyme.

Activated thrombin-activatable fibrinolysis inhibitor (TAFIa) is a zinc-containing carboxypeptidase and significantly inhibits fibrinolysis. TAFIa inhibitors are thus expected to act as profibrinolytic agents. We recently reported the design and synthesis of selenium-containing inhibitors of TAFIa and their inhibitory activity. Here we report the crystal structures of potent selenium-, sulfur-, and phosphinic acid-containing inhibitors bound to porcine pancreatic carboxypeptidase B (ppCPB). ppCPB is a TAFIa homologue and is surrogate TAFIa for crystallographic analysis. Crystal structures of ppCPB complexed with selenium compound 1a, its sulfur analogue 2, and phosphinic acid derivative EF6265 were determined at 1.70, 2.15, and 1.90 Å resolution, respectively. Each inhibitor binds to the active site of ppCPB in a similar manner to that observed for previously reported inhibitors. Thus, in complexes, selenium, sulfur, and phosphinic acid oxygen coordinate to zinc in ppCPB. This is the first observation and report of selenium coordinating to zinc in CPB.

Fine tuning of agonistic/antagonistic activity for vitamin D receptor by 22-alkyl chain length of ligands: 22S-Hexyl compound unexpectedly restored agonistic activity.

1α,25-Dihydroxyvitamin D3 exerts its actions by binding to vitamin D receptor (VDR). We are continuing the study related to the alteration of pocket structure of VDR by 22-alkyl substituent of ligands and the relationships between the alteration and agonistic/antagonistic activity. Previously we reported that compounds 2 (22-H), 3 (22S-Et), and 4 (22S-Bu) are VDR agonist, partial agonist and antagonist, respectively. Here, we describe the synthesis and biological evaluation of 22S-hexyl analog 5 (22S-Hex), which was designed to be a stronger VDR antagonist than 4. Unexpectedly, 5 showed partial agonistic but not antagonistic activity when bound to VDR, indicating that it is not necessarily true that the bulkier the side chain is, the stronger the antagonistic activity will be. X-ray crystallographic analysis of the VDR-ligand-binding domain (VDR-LBD) accommodating compound 5 indicated that the partial agonist activity of 5 is dependent on the mixed population of the agonistic and antagonistic conformations. Binding of compound 5 may not bring the complex into the only antagonistic conformation due to the large conformational change of the VDR-LBD. From this study it was found that fine tuning of agonistic/antagonistic activity for VDR is possible by 22-alkyl chain length of ligands.

Structural basis for the activation of PPARγ by oxidized fatty acids

The nuclear receptor peroxisome proliferator–activated receptor-γ (PPARγ) has important roles in adipogenesis and immune response as well as roles in both lipid and carbohydrate metabolism. Although synthetic agonists for PPARγ are widely used as insulin sensitizers, the identity of the natural ligand(s) for PPARγ is still not clear. Suggested natural ligands include 15-deoxy-Δ12,14-prostaglandin J2 and oxidized fatty acids such as 9-HODE and 13-HODE. Crystal structures of PPARγ have revealed the mode of recognition for synthetic compounds. Here we report structures of PPARγ bound to oxidized fatty acids that are likely to be natural ligands for this receptor. These structures reveal that the receptor can (i) simultaneously bind two fatty acids and (ii) couple covalently with conjugated oxo fatty acids. Thermal stability and gene expression analyses suggest that such covalent ligands are particularly effective activators of PPARγ and thus may serve as potent and biologically relevant ligands.