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A covalent fragment-based strategy targeting a novel cysteine to inhibit activity of mutant EGFR kinase.

Naoki KukiDavid Lee WalmsleyKazuo KanaiSho TakechiMasao YoshidaRyo MurakamiKohei TakanoYuichi TominagaMizuki TakahashiShuichiro ItoNaoki NakaoHayley AngoveLisa M BakerEdward CarterPawel DokurnoLoic Le StratAlba T MaciasCarrie-Anne MolyneauxJames B MurrayAllan E SurgenorTomoaki HamadaRoderick Eliot Hubbard
Published in: RSC medicinal chemistry (2023)
Several generations of ATP-competitive anti-cancer drugs that inhibit the activity of the intracellular kinase domain of the epidermal growth factor receptor (EGFR) have been developed over the past twenty years. The first-generation of drugs such as gefitinib bind reversibly and were followed by a second-generation such as dacomitinib that harbor an acrylamide moiety that forms a covalent bond with C797 in the ATP binding pocket. Resistance emerges through mutation of the T790 gatekeeper residue to methionine, which introduces steric hindrance to drug binding and increases the K m for ATP. A third generation of drugs, such as osimertinib were developed which were effective against T790M EGFR in which an acrylamide moiety forms a covalent bond with C797, although resistance has emerged by mutation to S797. A fragment-based screen to identify new starting points for an EGFR inhibitor serendipitously identified a fragment that reacted with C775, a previously unexploited residue in the ATP binding pocket for a covalent inhibitor to target. A number of acrylamide containing fragments were identified that selectively reacted with C775. One of these acrylamides was optimized to a highly selective inhibitor with sub-1 μM activity, that is active against T790M, C797S mutant EGFR independent of ATP concentration, providing a potential new strategy for pan-EGFR mutant inhibition.
Keyphrases
  • epidermal growth factor receptor
  • tyrosine kinase
  • small cell lung cancer
  • advanced non small cell lung cancer
  • emergency department
  • wild type
  • risk assessment
  • single molecule
  • dna binding
  • single cell