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Discovery of 'molecular switches' within a GIRK activator scaffold that afford selective GIRK inhibitors.


AUTHORS

Wen WWandong , Wu W Wenjun , Romaine IM Ian M , Kaufmann K Kristian , Du Y Yu , Sulikowski GA Gary A , Weaver CD C David , Lindsley CW Craig W . Bioorganic & medicinal chemistry letters. 2013 8 15; 23(16). 4562-6

ABSTRACT

This letter describes a multi-dimensional SAR campaign based on a potent, efficacious and selective GIRK1/2 activator (~10-fold versus GIRK1/4 and inactive on nonGIRK 1-containing GIRKs, GIRK 2 or GIRK2/3). Further chemical optimization through an iterative parallel synthesis effort identified multiple ‘molecular switches’ that modulated the mode of pharmacology from activator to inhibitor, as well as engendering varying selectivity profiles for GIRK1/2 and GIRK1/4. Importantly, these compounds were all inactive on nonGIRK1 containing GIRK channels. However, SAR was challenging as subtle structural modifications had large effects on both mode of pharmacology and GIRK1/2 and GIRK1/4 channel selectivity.

Copyright © 2013 Elsevier Ltd. All rights reserved.


This letter describes a multi-dimensional SAR campaign based on a potent, efficacious and selective GIRK1/2 activator (~10-fold versus GIRK1/4 and inactive on nonGIRK 1-containing GIRKs, GIRK 2 or GIRK2/3). Further chemical optimization through an iterative parallel synthesis effort identified multiple ‘molecular switches’ that modulated the mode of pharmacology from activator to inhibitor, as well as engendering varying selectivity profiles for GIRK1/2 and GIRK1/4. Importantly, these compounds were all inactive on nonGIRK1 containing GIRK channels. However, SAR was challenging as subtle structural modifications had large effects on both mode of pharmacology and GIRK1/2 and GIRK1/4 channel selectivity.

Copyright © 2013 Elsevier Ltd. All rights reserved.