Design,synthesis, and structure–activity relationship of novel opioid κ receptor selective agonists: α-Iminoamide derivatives with an azabicyclo[2.2.2]octene skeleton

The α-iminoamide derivative, 4b was designed and synthesized as a novel agonist selective for the opioid κ receptor. The amide was constrained to an orientation horizontal to the F-ring of the azabicyclo[2.2.2]octane skeleton, which remarkably improved its affinity, selectivity, and agonistic activity for the κ receptor. This finding was newly established by chemical modification of the nitrogen atom at the 8-position in the azabicyclo[2.2.2]octane skeleton. This modification would never have been found with KNT-63, a derivation of oxabicyclo[2.2.2]octane. These results may provide valuable information for the future development of novel κ selective agonists.     

Design and synthesis of novel opioid ligands with an azabicyclo[2.2.2]octane skeleton having a 7-amide side chain and their pharmacologies

Several derivatives with an azabicyclo[2.2.2]octane skeleton having a 7-amide side chain were synthesized. Compounds that had an electron-donating group exhibited high affinity for the μ opioid receptor while those with a bulky substituent at the 8-nitrogen atom had low affinities for all receptor types. High affinities and selectivities for the κ receptor resulted from the introduction of the longer amide side chain at the 7α-position. Our studies indicate that the orientation of the amide side chain at the 7-position within the azabicyclo[2.2.2]octane skeleton is related to selectivity for the κ receptor.     

Discovery of attenuation effect of orexin 1 receptor to aversion of nalfurafine: Synthesis and evaluation of D-nor-nalfurafine derivatives and analyses of the three active conformations of nalfurafine

The D-nor-nalfurafine derivatives, which were synthesized by contraction of the six-membered D-ring in nalfurafine (1), had no affinity for orexin 1 receptors (OX₁Rs). The 17N-lone electron pair in 1 oriented toward the axial direction, while that of D-nor-derivatives was directed in the equatorial configuration. The axial lone electron pair can form a hydrogen bond with the 14-hydroxy group, which could push the 6-amide side chain toward the downward direction with respect to the C-ring. The resulting conformation would be an active conformation for binding with OX₁R. The dual affinities of 1 for OX₁R and κ opioid receptor (KOR) led us to elucidate the mechanism by which only 1 showed no aversion but U-50488H. Actually, 1 selectively induced severe aversion in OX₁R knockout mice, but not in wild-type mice. These results well support that OX₁R suppresses the aversion of 1. This is the elucidation of long period puzzle which 1 showed no aversion in KOR.     

Essential structure of orexin 1 receptor antagonist YNT-707, Part I: Role of the 4,5-epoxy ring for binding with orexin 1 receptor

The essential structure of the orexin 1 receptor (OX₁R) antagonist YNT-707 (2) was clarified, particularly the roles to OX₁R antagonist activities of the 3-OMe, the 4,5-epoxy ring, the 14-hydroxy group, and the orientation of the 6-amide side chain.The 3-OMe and 17-sulfonamide group were shown to be essential for the OX₁R antagonistic activity. The 4,5-epoxy ring plays an important role for the active orientation of the 6-amide group. The 14-hydroxy group could lower the activity of the 6β-amide isomer by the interaction of the 14-hydroxy group with the 6-amide group, which could orient the 6-amide group toward the upper side of the C-ring.Finally, we proposed the difference in the active conformation between OX₁R and κ opioid receptor (KOR), especially in the orientation of the 6-amide group which is expected to be a useful guide for medicinal chemists to design OX₁R ligands.     

Essential structure of orexin 1 receptor antagonist YNT-707, Part IV: The role of D-ring in 4,5-epoxymorphinan on the orexin 1 receptor antagonistic activity

The orexin 1 receptor (OX₁R) antagonists carrying a morphinan skeleton such as YNT-707 (2) and YNT-1310 (3) showed potent and extremely high selective antagonistic activity against OX₁R. In the course of our study of the essential structure of YNT-707 for high binding affinity against OX₁R, we prepared derivatives of 2 without the D- and 4,5-epoxy rings to clarify the roles of these structural determinants toward OX₁R antagonistic activity. The D- and 4,5-epoxy rings played important roles for the active orientation of the 17-sulfonamide and 6-amide side chains. Finally, we identified the simple structure required for selective OX₁R antagonistic activity in the complex morphinan skeleton, which is expected to be a useful scaffold for further design of OX₁R ligands.     

Essential structure of orexin 1 receptor antagonist YNT-707, part V: Structure-activity relationship study of the substituents on the 17-amino group

The morphinan-type orexin 1 receptor (OX₁R) antagonists such as YNT-707 (2) and YNT-1310 (3) show potent and extremely high selective antagonistic activity against OX₁R. In the course of our studies of the essential structure of 2, we identified new scaffolds by simplification of the morphinan skeleton. However, the new chemical entities carrying the D-ring removed scaffold showed insufficient activity. To improve the activity of these derivatives, we investigated the effect of substituents mainly focused on the 17-nitrogen group. The 17-N-substituted derivatives, as well as the cyclic derivatives, were synthesized and examined the OX₁R antagonistic activity. The assay results showed the interesting relationship between the OX₁R antagonistic activity and the substituents on the 17-nitrogen: the antagonistic activity was increased as the bulkiness of 17-substituents increased. Finally, the 17-N-Boc derivative 14a showed the most potent OX₁R antagonistic activity (K_i = 14.8 nM).