AI Article Synopsis
- Protein kinases are crucial drug targets due to their connection to various diseases, but finding selective inhibitors is challenging because of their closely related structure.
- Fragment-based drug discovery involves using small, simple compounds to identify potential drug hits, which are then enhanced through medicinal chemistry and structural biology assistance.
- The discussion will cover recent examples of this approach for kinase inhibitors, including the creation of screening libraries, validation of hits, optimization strategies, and insights gained from both personal and broader research experiences.
Article Abstract
Protein kinases are one of the most important families of drug targets, and aberrant kinase activity has been linked to a large number of disease areas. Although eminently targetable using small molecules, kinases present a number of challenges as drug targets, not least obtaining selectivity across such a large and relatively closely related target family. Fragment-based drug discovery involves screening simple, low-molecular weight compounds to generate initial hits against a target. These hits are then optimized to more potent compounds via medicinal chemistry, usually facilitated by structural biology. Here, we will present a number of recent examples of fragment-based approaches to the discovery of kinase inhibitors, detailing the construction of fragment-screening libraries, the identification and validation of fragment hits, and their optimization into potent and selective lead compounds. The advantages of fragment-based methodologies will be discussed, along with some of the challenges associated with using this route. Finally, we will present a number of key lessons derived both from our own experience running fragment screens against kinases and from a large number of published studies.
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