Fragment-based structure-guided drug discovery: strategy, process, and lessons from human protein kinases

doi:10.1017/CBO9780511730412.005

3 - Fragment-based structure-guided drug discovery: strategy, process, and lessons from human protein kinases

from PART I - STRUCTURAL BIOLOGY

Published online by Cambridge University Press: 06 July 2010

Stephen K. Burley ,

Gavin Hirst ,

Paul Sprengeler and

Siegfried Reich

Edited by

Kenneth M. Merz, Jr ,

Dagmar Ringe and

Charles H. Reynolds

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Kenneth M. Merz, Jr: Affiliation:
University of Florida
Dagmar Ringe: Affiliation:
Brandeis University, Massachusetts
Charles H. Reynolds: Affiliation:
Johnson & Johnson Pharmaceutical Research & Development

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Summary

INTRODUCTION

The experimental roots of fragment-based drug discovery can be found in the work of Petsko, Ringe, and coworkers, who were the first to report flooding of protein crystals with small organic solutes (e.g., compounds such as benzene with ten or fewer nonhydrogen atoms) to identify bound functional groups that might ultimately be transformed into targeted ligands. The concept of linking fragments together to increase binding affinity was described as early as 1992 by Verlinde et al. Computational screening of fragments, using tools such as DOCK or MCSS, was also described in the early 1990s. Pharmaceutical industry application of fragment screening began at Abbott Laboratories, where Fesik and coworkers pioneered “SAR by NMR” (structure/activity relationship by nuclear magnetic resonance). In this spectroscopic approach, bound fragments are detected by NMR screening and subsequently linked together to increase affinity, as envisaged by Verlinde and coworkers. Application of x-ray crystallography to detect and identify fragment hits was also pursued at Abbott.

Fragment-based drug discovery has now been under way for more than a decade. Although Fesik and coworkers popularized the notion of linking fragments (as in their highly successful BCL-2 program), tactical emphasis appears to have largely shifted from fragment condensation to fragment engineering (or growing the fragment) to increase binding affinity and selectivity. Various biotechnology companies, including SGX Pharmaceuticals, Astex, and Plexxikon, have recently demonstrated that fragment-based approaches can indeed produce development candidates suitable for Phase I studies of safety and tolerability in patients (www.clinicaltrials.gov).

Type: Chapter
Information: Drug Design
Structure- and Ligand-Based Approaches
, pp. 30 - 40

DOI: https://doi.org/10.1017/CBO9780511730412.005 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2010

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