Justin J Kim, Ilse K Schaeffner, David E. Heppner, Ciric To, Pasi A Jänne, Tyler S Beyett, Michael J Eck
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引用次数: 0
摘要
肺癌通常是由表皮生长因子受体(EGFR)的激活突变引起的。异位激酶抑制剂不受常见 ATP 位点耐药突变的影响,是针对耐药表皮生长因子受体变体的一种很有前景的治疗策略。然而,异位激酶抑制剂会被激酶二聚化所拮抗,对这一现象的理解仅限于细胞实验。为了促进对异位抑制剂药理学的研究,我们设计并纯化了含有临床相关 L858R/T790M 突变的组成型表皮生长因子受体激酶二聚体。动力学表征显示,表皮生长因子受体激酶二聚体比单体表皮生长因子受体(L858R/T790M)激酶更活跃,并且具有相同的Km,ATP。对大量 ATP 竞争性和异构表皮生长因子受体抑制剂进行的生化分析表明,与单体相比,异构抑制剂在激酶二聚体中的效力降低了 500 倍,其 IC50 值与 Ba/F3 细胞效力密切相关。因此,这种易于纯化的组成型不对称表皮生长因子受体激酶二聚体是对表皮生长因子受体抑制剂药理学进行生化评估,特别是对异位抑制剂进行评估的一种极具吸引力的工具。
A Constitutive EGFR Kinase Dimer to Study Inhibitor Pharmacology
Lung cancer is commonly caused by activating mutations in the epidermal growth factor receptor (EGFR). Allosteric kinase inhibitors are unaffected by common ATP-site resistance mutations and represent a promising therapeutic strategy for targeting drug-resistant EGFR variants. However, allosteric inhibitors are antagonized by kinase dimerization, and understanding this phenomenon has been limited to cellular experiments. To facilitate the study of allosteric inhibitor pharmacology, we designed and purified a constitutive EGFR kinase dimer harboring the clinically relevant L858R/T790M mutations. Kinetic characterization revealed that the EGFR kinase dimer is more active than monomeric EGFR(L858R/T790M) kinase and has the same Km,ATP. Biochemical profiling of a large panel of ATP-competitive and allosteric EGFR inhibitors showed that allosteric inhibitor potency decreased by >500-fold in the kinase dimer compared to monomer, yielding IC50 values that correlate well with Ba/F3 cellular potencies. Thus, this readily purifiable constitutive asymmetric EGFR kinase dimer represents an attractive tool for biochemical evaluation of EGFR inhibitor pharmacology, in particular for allosteric inhibitors.
期刊介绍:
Molecular Pharmacology publishes findings derived from the application of innovative structural biology, biochemistry, biophysics, physiology, genetics, and molecular biology to basic pharmacological problems that provide mechanistic insights that are broadly important for the fields of pharmacology and toxicology. Relevant topics include:
Molecular Signaling / Mechanism of Drug Action
Chemical Biology / Drug Discovery
Structure of Drug-Receptor Complex
Systems Analysis of Drug Action
Drug Transport / Metabolism
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