RESUMO
With an objective to improve the profiles of the 1st generation non-basic MCHR1 antagonists, a lean design approach of replacing the bicyclic thienopyrimidine core with a monocyclic pyrrol-2-one chemotype was examined in the context of reducing aromatic ring count, while also contemplating enhanced flexibility as a means of decreasing flat character. The new compounds exhibited potent antagonism up to the sub-nanomolar range, thereby implying that the monocyclic ring could effectively serve as an effective bioisostere of the bicyclic system. The prototype compound 2m offered benefits like improved potency, reduced half-life, and enhanced solubility, while also demonstrating >5% reduction in weight gain in rats, thereby providing proof-of-concept for this new class of compounds as anti-obesity agents.
RESUMO
Adaptor protein 2-associated kinase 1 (AAK1) is a serine/threonine kinase that was identified as a therapeutic target for the potential treatment of neuropathic pain. Inhibition of AAK1 in the central nervous system, particularly within the spinal cord, was found to be the relevant site for achieving an antinociceptive effect. We previously reported that compound 7 is a brain-penetrant, AAK1 inhibitor that showed efficacy in animal models for neuropathic pain. One approach we took to improve upon the potency of 7 involved tying the amide back into the neighboring phenyl ring to form a bicyclic heterocycle. Investigation of the structure-activity relationships (SARs) of substituents on the resultant quinazoline and quinoline ring systems led to the identification of (S)-31, a brain-penetrant, AAK1-selective inhibitor with improved enzyme and cellular potency compared to 7. The synthesis, SAR, and in vivo evaluation of a series of quinazoline and quinoline-based AAK1 inhibitors are described herein.