Discovery of Indoles as Potent and Selective Inhibitors of the Deacetylase SIRT1

Andrew D. Napper; Jeffrey Hixon; Thomas McDonagh; Kenneth Keavey; Jean‐François Pons; Jonathan Barker; Wei Tsung Yau; Patricia Amouzegh; Adam Flegg; Estelle Hamelin; Russell J. Thomas; Michael J. Kates; Stephen P. Jones; Manuel A. Navia; Jeffrey O. Saunders; Peter S. DiStefano; Rory Curtis

doi:10.1021/jm050522v

Discovery of Indoles as Potent and Selective Inhibitors of the Deacetylase SIRT1

Andrew D. Napper(Evotec (United Kingdom)), Jeffrey Hixon(Evotec (United Kingdom)), Thomas McDonagh(Evotec (United Kingdom)), Kenneth Keavey(Evotec (United Kingdom)), Jean‐François Pons(Evotec (United Kingdom)), Jonathan Barker(Evotec (United Kingdom)), Wei Tsung Yau(Evotec (United Kingdom)), Patricia Amouzegh(Evotec (United Kingdom)), Adam Flegg(Evotec (United Kingdom)), Estelle Hamelin(Evotec (United Kingdom)), Russell J. Thomas(Evotec (United Kingdom)), Michael J. Kates(Evotec (United Kingdom)), Stephen P. Jones(Evotec (United Kingdom)), Manuel A. Navia(Evotec (United Kingdom)), Jeffrey O. Saunders(Evotec (United Kingdom)), Peter S. DiStefano(Evotec (United Kingdom)), Rory Curtis(Evotec (United Kingdom))

Journal of Medicinal Chemistry

November 9, 2005

10.1021/jm050522v

Cited by 524Open Access

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Abstract

High-throughput screening against the human sirtuin SIRT1 led to the discovery of a series of indoles as potent inhibitors that are selective for SIRT1 over other deacetylases and NAD-processing enzymes. The most potent compounds described herein inhibit SIRT1 with IC50 values of 60-100 nM, representing a 500-fold improvement over previously reported SIRT inhibitors. Preparation of enantiomerically pure indole derivatives allowed for their characterization in vitro and in vivo. Kinetic analyses suggest that these inhibitors bind after the release of nicotinamide from the enzyme and prevent the release of deacetylated peptide and O-acetyl-ADP-ribose, the products of enzyme-catalyzed deacetylation. These SIRT1 inhibitors are low molecular weight, cell-permeable, orally bioavailable, and metabolically stable. These compounds provide chemical tools to study the biology of SIRT1 and to explore therapeutic uses for SIRT1 inhibitors.

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