Second generation "peptoid" CCK-B receptor antagonists: identification and development of N-(adamantyloxycarbonyl)-alpha-methyl-(R)-tryptophan derivative (CI-1015) with an improved pharmacokinetic profile.

We have previously described the design and development of CI-988, a peptoid analogue of CCK-4 with excellent binding affinity and selectivity for the CCK-B receptor. Due to its anxiolytic profile in animal models of anxiety, this compound was developed as a clinical candidate. However, during its development, it was determined that CI-988 had low bioavailability in both rodent and nonrodent species. In the clinic, it was further established that CI-988 had poor bioavailability. Thus, there was a need to identify an analogue with an improved pharmacokinetic (PK) profile. The poor bioavailability was attributed to poor absorption and efficient hepatic extraction. We envisaged that reducing the molecular weight of the parent compound (5, MW = 614) would lead to better absorption. Thus, we synthesized a series of analogues in which the key alpha-methyltryptophan and adamantyloxycarbonyl moieties, required for receptor binding, were kept intact and the C-terminus was extensively modified. This SAR study led to the identification of tricyclo[3.3.1.1(3,7)]dec-2-yl [1S-[1 alpha(S*)2 beta]-[2-[(2-hydroxycyclohexyl)amino]-1-(1H-indol-3- ylmethyl)-1-methyl-2-oxoethyl]carbamate (CI-1015, 31) with binding affinities of 3.0 and 2900 nM for the CCK-B and CCK-A receptors, respectively. The compound showed CCK-B antagonist profile in the rat ventromedial hypothalamus assay with a Ke of 34 nM. It also showed an anxiolytic like profile orally in a standard anxiety paradigm (X-maze) with a minimum effective dose (MED) of 0.1 microgram/kg. Although the compound is less water soluble than CI-988, oral bioavailability in rat was improved nearly 10 times relative to CI-988 when dosed in HP beta CD. The blood-brain permeability of CI-1015 (31) was also enhanced relative to CI-988 (5). On the basis of the overall improved pharmacokinetic profile as well as enhanced brain penetration, CI-1015 (31) was chosen as a development candidate.

Use of a dipeptide chemical library in the development of non-peptide tachykinin NK3 receptor selective antagonists.

The use of a dipeptide library as the source of a micromolar chemical lead compound for the human tachykinin NK3 receptor is described. The screening of a dipeptide library through a cloned human NK3 receptor binding assay resulted in the identification of Boc(S)Phe(S)PheNH2 (1), which has subsequently been developed, following a 'peptoid' design strategy, into a series of high-affinity NK3 receptor selective antagonists. The structure-activity relationship of the C-terminal portion of this dipeptide lead was first explored and led to the identification of the urea derivative Boc(S)Phe(R)alphaMePheNH(CH2)7NHCONH2 (41, PD157672). This modified dipeptide has a Ke of 7 nM in blocking senktide-induced increases in intracellular calcium levels in human NK3 receptors stably expressed in CHO cells. Subsequent optimization of the N-terminal BocPhe group and the alphaMePhe residue side chain of 41 led to the identification of [S-(R*,S*)]-[2-(2,3-difluorophenyl)-1-methyl-1-[(7-ureidoheptyl)ca r bamoyl]ethyl]carbamic acid 2-methyl-1-phenylpropyl ester (60, PD161182), a non-peptide NK3 receptor selective antagonist. Compound 60 blocks the senktide-evoked increases in intracellular calcium levels in cloned human NK3 receptors stably expressed in CHO cells with Ke of 0.9 nM.