Structure-Based Drug Design of Novel, Potent, and Selective Azabenzimidazoles (ABI) as ATR Inhibitors

Paul A Barsanti; Yue Pan; Yipin Lu; Rama Jain; Matthew Cox; Robert J Aversa; Michael P Dillon; Robert Elling; Cheng Hu; Xianming Jin; Mark Knapp; Jiong Lan; Savithri Ramurthy; Patrick Rudewicz; Lina Setti; Sharadha Subramanian; Michelle Mathur; Lorena Taricani; George Thomas; Linda Xiao; Qin Yue

doi:10.1021/ml500352s

Structure-Based Drug Design of Novel, Potent, and Selective Azabenzimidazoles (ABI) as ATR Inhibitors

ACS Med Chem Lett. 2014 Oct 30;6(1):42-6. doi: 10.1021/ml500352s. eCollection 2015 Jan 8.

Authors

Paul A Barsanti¹, Yue Pan¹, Yipin Lu¹, Rama Jain¹, Matthew Cox¹, Robert J Aversa¹, Michael P Dillon¹, Robert Elling¹, Cheng Hu¹, Xianming Jin¹, Mark Knapp¹, Jiong Lan¹, Savithri Ramurthy¹, Patrick Rudewicz¹, Lina Setti¹, Sharadha Subramanian¹, Michelle Mathur¹, Lorena Taricani¹, George Thomas¹, Linda Xiao¹, Qin Yue¹

Affiliation

¹ Global Discovery Chemistry/Oncology, Novartis Institutes for Biomedical Research , 5300 Chiron Way, Emeryville, California 94608, United States.

Abstract

Compound 13 was discovered through morphing of the ATR biochemical HTS hit 1. The ABI series was potent and selective for ATR. Incorporation of a 6-azaindole afforded a marked increase in cellular potency but was associated with poor PK and hERG ion channel inhibition. DMPK experiments established that CYP P450 and AO metabolism in conjunction with Pgp and BCRP efflux were major causative mechanisms for the observed PK. The series also harbored the CYP3A4 TDI liability driven by the presence of both a morpholine and an indole moiety. Incorporation of an adjacent fluorine or nitrogen into the 6-azaindole addressed many of the various medicinal chemistry issues encountered.

Keywords: ATR; CYP3A4 TDI; aldehyde oxidase; structure-based drug design.