Abstract
The discovery of small molecule melanin concentrating hormone receptor (MCHr1) antagonists as novel therapeutic agents for the treatment of obesity has been actively pursued across the pharmaceutical industry. While multiple chemotypes of small molecule MCHr1 antagonists have been identified and shown to deliver weight loss in animal models of obesity, many of these lead compounds have been found to cross-react with the hERG channel and/or demonstrate deleterious effects on cardiovascular hemodynamic parameters. This review describes an approach to rapidly identifying safer MCHr1 antagonists by placing assays to assess cardiovascular safety early in the lead optimization compound prioritization process. Ultimately, despite putting significant effort toward the discovery of a MCHr1 antagonist for the treatment of obesity, we were unable to deliver a candidate compound that attained an acceptable therapeutic index (TI = 30-100) in our in vivo models. Our inability to identify a compound with an acceptable therapeutic index was driven by two primary factors: 1) high levels of sustained drug exposure in the brain was required to achieve efficacy; and 2) many small molecule MCHR1 receptor antagonists suffer from receptor cross-reactivity that leads to cardiovascular toxicity at low multiples of their therapeutic plasma concentration.
Keywords: 4-Aminoquinoline, Indazoles, MCHr1 potency, Coumarin, Rat Cardiovascular Assay, hERG channel
Current Topics in Medicinal Chemistry
Title: Lead Optimization Strategies and Tactics Applied to the Discovery of Melanin Concentrating Hormone Receptor 1 Antagonists
Volume: 7 Issue: 15
Author(s): Philip R. Kym, Andrew S. Judd, John K. Lynch, Rajesh Iyengar, Anil Vasudevan and Andrew J. Souers
Affiliation:
Keywords: 4-Aminoquinoline, Indazoles, MCHr1 potency, Coumarin, Rat Cardiovascular Assay, hERG channel
Abstract: The discovery of small molecule melanin concentrating hormone receptor (MCHr1) antagonists as novel therapeutic agents for the treatment of obesity has been actively pursued across the pharmaceutical industry. While multiple chemotypes of small molecule MCHr1 antagonists have been identified and shown to deliver weight loss in animal models of obesity, many of these lead compounds have been found to cross-react with the hERG channel and/or demonstrate deleterious effects on cardiovascular hemodynamic parameters. This review describes an approach to rapidly identifying safer MCHr1 antagonists by placing assays to assess cardiovascular safety early in the lead optimization compound prioritization process. Ultimately, despite putting significant effort toward the discovery of a MCHr1 antagonist for the treatment of obesity, we were unable to deliver a candidate compound that attained an acceptable therapeutic index (TI = 30-100) in our in vivo models. Our inability to identify a compound with an acceptable therapeutic index was driven by two primary factors: 1) high levels of sustained drug exposure in the brain was required to achieve efficacy; and 2) many small molecule MCHR1 receptor antagonists suffer from receptor cross-reactivity that leads to cardiovascular toxicity at low multiples of their therapeutic plasma concentration.
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Cite this article as:
Kym R. Philip, Judd S. Andrew, Lynch K. John, Iyengar Rajesh, Vasudevan Anil and Souers J. Andrew, Lead Optimization Strategies and Tactics Applied to the Discovery of Melanin Concentrating Hormone Receptor 1 Antagonists, Current Topics in Medicinal Chemistry 2007; 7 (15) . https://dx.doi.org/10.2174/156802607782194699
DOI https://dx.doi.org/10.2174/156802607782194699 |
Print ISSN 1568-0266 |
Publisher Name Bentham Science Publisher |
Online ISSN 1873-4294 |
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