Yoshitaka Yoshizawa

Antipruritic activity of the κ-opioid receptor agonist, TRK-820

The effects of the κ-opioid receptor agonist, TRK-820, (−)-17-(cyclopropylmethyl)-3, 14β-dihydroxy-4, 5α-epoxy-6β-[N-methyl-trans-3-(3-furyl) acrylamido] morphinan hydrochloride, on the itch sensation were compared with those of histamine H1 receptor antagonists, using the mouse pruritogen-induced scratching model. Peroral administration of TRK-820 reduced the numbers of substance P- or histamine-induced scratches dose dependently. No obvious suppression of the spontaneous locomotor activity was observed at the doses used for the experiments, indicating that the inhibition of scratches was not due to the effect on general behavior. Furthermore, the scratching inhibitory activity of TRK-820 was dose dependently antagonized by the specific κ-opioid receptor antagonist, nor-binaltorphimine, suggesting that the inhibitory activity was mediated via κ-opioid receptors. Histamine H1 receptor antagonists, chlorpheniramine and ketotifen, did not inhibit substance P-induced scratches, or did so only partially. Both antihistamines inhibited the histamine-induced scratches completely. These results suggest that TRK-820 has antipruritic activity which is mediated by κ-opioid receptors, and is effective in both antihistamine-sensitive and -resistant pruritus.

Nrf2 Activators Attenuate the Progression of Nonalcoholic Steatohepatitis–Related Fibrosis in a Dietary Rat Model

Oxidative stress is considered to be a key mechanism of hepatocellular injury and disease progression in patients with nonalcoholic steatohepatitis (NASH). The transcription factor Nrf2 (nuclear factor-erythroid-2-related factor 2) plays a central role in stimulating expression of various antioxidant-associated genes in the cellular defense against oxidative stress. As the cytosolic repressor kelch-like ECH-associated protein 1 (Keap1) negatively regulates Nrf2, activation of Nrf2 facilitated by its release from Keap1 may represent a promising strategy in the treatment of NASH. To test this hypothesis, we used two chemically distinct types of Nrf2 activator. One is the thiol-reactive agent oltipraz (OPZ), a typical Nrf2 activator, and the other is a novel biaryl urea compound, termed NK-252 (1-(5-(furan-2-yl)-1,3,4-oxadiazol-2-yl)-3-(pyridin-2-ylmethyl)urea). NK-252 exhibits a greater Nrf2-activating potential than OPZ. Furthermore, in vitro binding studies revealed that NK-252 interacts with the domain containing the Nrf2-binding site of Keap1, whereas OPZ does not. This finding indicates that NK-252 is more potent than OPZ due to its unique mechanism of action. For in vivo animal model studies, we used rats on a choline-deficient L-amino acid–defined (CDAA) diet, which demonstrate pathologic findings similar to those seen in human NASH. The administration of OPZ or NK-252 significantly attenuated the progression of histologic abnormalities in rats on a CDAA diet, especially hepatic fibrosis. In conclusion, by using Nrf2 activators with independent mechanisms of action, we show that, in a rat model of NASH, the activation of Nrf2 is responsible for the antifibrotic effects of these drugs. This strategy of Nrf2 activation presents new opportunities for treatment of NASH patients with hepatic fibrosis.

Multiple binding modes of a small molecule to human Keap1 revealed by X-ray crystallography and molecular dynamics simulation

Keap1 protein acts as a cellular sensor for oxidative stresses and regulates the transcription level of antioxidant genes through the ubiquitination of a corresponding transcription factor, Nrf2. A small molecule capable of binding to the Nrf2 interaction site of Keap1 could be a useful medicine. Here, we report two crystal structures, referred to as the soaking and the cocrystallization forms, of the Kelch domain of Keap1 with a small molecule, Ligand1. In these two forms, the Ligand1 molecule occupied the binding site of Keap1 so as to mimic the ETGE motif of Nrf2, although the mode of binding differed in the two forms. Because the Ligand1 molecule mediated the crystal packing in both the forms, the influence of crystal packing on the ligand binding was examined using a molecular dynamics (MD) simulation in aqueous conditions. In the MD structures from the soaking form, the ligand remained bound to Keap1 for over 20 ns, whereas the ligand tended to dissociate in the cocrystallization form. The MD structures could be classified into a few clusters that were related to but distinct from the crystal structures, indicating that the binding modes observed in crystals might be atypical of those in solution. However, the dominant ligand recognition residues in the crystal structures were commonly used in the MD structures to anchor the ligand. Therefore, the present structural information together with the MD simulation will be a useful basis for pharmaceutical drug development.

Structural and Interaction Analysis of Glycoprotein VI-binding Peptide Selected from a Phage Display Library

Glycoprotein VI (GPVI) is a major collagen receptor on the platelet surface that recognizes the glycine-proline-hydroxyproline (GPO) sequence in the collagen molecule and plays a crucial role in thrombus formation. Inhibitors that block the interaction of GPVI with collagen have potential for use as antithrombotic drugs. For low molecular weight drug design for GPVI, it is essential to obtain precise structural and interaction information about GPVI-binding ligands. However, experimentally obtained structural and interaction information of small ligands, such as peptides, in the GPVI-bound state has not been reported. In this study, by screening a phage-displayed peptide library, we discovered a novel peptide ligand (pep-10L; YSDTDWLYFSTS) without any similarities to the sequence of collagen that inhibits GPVI-GPO binding. Systematic Ala scanning in surface plasmon resonance experiments and a saturation transfer difference NMR experiment revealed that Trp6, Leu7, Phe9, and Ser10 residues in the pep-10L peptide interacted with GPVI. Furthermore, the GPVI-bound conformation of the pep-10L peptide was determined using transferred nuclear Overhauser effect analysis. The obtained structure has revealed that the central part of pep-10L (Asp5–Phe9) has a helical conformation, the side chains of Trp6, Leu7, and Phe9 form a hydrophobic side in the helix, and the Tyr8 side chain faces the opposite direction from the hydrophobic side. Computational docking prediction has shown that the hydrophobic side of pep-10L sticks in the hydrophobic groove on the GPVI surface, which corresponds to the putative collagen-related peptide binding groove. These data could enable the structure-guided development of a small molecule GPVI antagonist.

Discovery of potent α1L-adrenoceptor agonists: Design and synthesis of bicyclic derivatives

We aimed to create a novel and potent α(1L)-adrenoceptor agonist because such agonists are possible drug candidates for stress urinary incontinence. We used ligand-based drug design and evaluated the α(1L)-adrenoceptor agonist activity of the designed compounds. Among them, tetrahydroquinoline derivative 50 showed the most potent activity (ratio of noradrenaline half maximal effective concentration, 0.0028) and effectively induced contraction of rat bladder neck.