变构调节
化学
结合位点
药物发现
合理设计
生物物理学
变构酶
血浆蛋白结合
机制(生物学)
药物设计
分子模型
计算生物学
生物化学
结构生物学
装订袋
酶
活动站点
立体化学
蛋白质结构
激酶
结构-活动关系
小分子
化学生物学
分子动力学
构象变化
蛋白质-蛋白质相互作用
细胞生物学
作者
Noah B. Herrington,Susmita Khamrui,Yihan Zhao,Carisse Lansiquot,Ruoxi Wu,Gaurav Pandey,Michael B. Lazarus,Avner Schlessinger
摘要
, exhibits selectivity and enhanced potency and engages PKMYT1 in cells. Surprisingly, however, it binds in the ATP binding pocket, demonstrating that subtle chemical modifications can shift binding mode and mechanism of inhibition. Furthermore, computational analysis using structural modeling methods, including AlphaFold2, AlphaFold3, Boltz-2, as well as unbiased MD simulations, indicates that these approaches are limited in their ability to capture this inhibitor-induced cryptic binding site and conformational change. Our study identifies an underexplored allosteric site in PKMYT1 and establishes a new avenue for the rational design of selective kinase inhibitors targeting a cryptic binding site in this emerging drug target. These findings also reveal intrinsic challenges in the computational discovery of noncanonical kinase binding sites and underscore the necessity of integrating computational modeling with experimental testing using structural and functional approaches.
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