Mutation in Abl kinase with altered drug-binding kinetics indicates a novel mechanism of imatinib resistance

Agatha Lyczek, B. Berger, Aziz M. Rangwala, YiTing Paung, Jessica Tom, Hannah Philipose, Jiaye Guo, Steven K. Albanese, M. Robers, S. Knapp, J. Chodera, M. Seeliger
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引用次数: 21

Abstract

Significance We performed an in-cell screen of imatinib binding against a library of Abl kinase mutants derived from patients with imatinib-resistant chronic myeloid leukemia. The majority of mutations readily bind imatinib, posing the question of how these mutations cause resistance in patients. We identified several kinetic mutants, one of which binds imatinib with wild-type affinity but dissociates considerably faster from the mutant kinase. Using NMR and molecular dynamics, we found that this mutation increases the conformational dynamics of the mutant protein, linking conformational dynamics of the protein to drug dissociation. The results underline the importance of drug dissociation kinetics for drug efficacy and propose a kinetic resistance mechanism that may be targetable by altering drug treatment schedules. Protein kinase inhibitors are potent anticancer therapeutics. For example, the Bcr-Abl kinase inhibitor imatinib decreases mortality for chronic myeloid leukemia by 80%, but 22 to 41% of patients acquire resistance to imatinib. About 70% of relapsed patients harbor mutations in the Bcr-Abl kinase domain, where more than a hundred different mutations have been identified. Some mutations are located near the imatinib-binding site and cause resistance through altered interactions with the drug. However, many resistance mutations are located far from the drug-binding site, and it remains unclear how these mutations confer resistance. Additionally, earlier studies on small sets of patient-derived imatinib resistance mutations indicated that some of these mutant proteins were in fact sensitive to imatinib in cellular and biochemical studies. Here, we surveyed the resistance of 94 patient-derived Abl kinase domain mutations annotated as disease relevant or resistance causing using an engagement assay in live cells. We found that only two-thirds of mutations weaken imatinib affinity by more than twofold compared to Abl wild type. Surprisingly, one-third of mutations in the Abl kinase domain still remain sensitive to imatinib and bind with similar or higher affinity than wild type. Intriguingly, we identified three clinical Abl mutations that bind imatinib with wild type–like affinity but dissociate from imatinib considerably faster. Given the relevance of residence time for drug efficacy, mutations that alter binding kinetics could cause resistance in the nonequilibrium environment of the body where drug export and clearance play critical roles.
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Abl激酶突变与药物结合动力学改变表明了一种新的伊马替尼耐药机制
我们对来自伊马替尼耐药慢性髓性白血病患者的Abl激酶突变文库进行了伊马替尼结合的细胞内筛选。大多数突变很容易结合伊马替尼,这就提出了这些突变如何引起患者耐药的问题。我们发现了几个动态突变体,其中一个以野生型亲和力结合伊马替尼,但与突变激酶的解离速度相当快。利用核磁共振和分子动力学,我们发现这种突变增加了突变蛋白的构象动力学,将蛋白质的构象动力学与药物解离联系起来。这些结果强调了药物解离动力学对药物疗效的重要性,并提出了一种可能通过改变药物治疗计划来靶向的动力学耐药机制。蛋白激酶抑制剂是有效的抗癌药物。例如,Bcr-Abl激酶抑制剂伊马替尼可使慢性髓系白血病的死亡率降低80%,但仍有22%至41%的患者对伊马替尼产生耐药性。大约70%的复发患者在Bcr-Abl激酶结构域有突变,在那里已经发现了一百多种不同的突变。一些突变位于伊马替尼结合位点附近,通过改变与药物的相互作用引起耐药性。然而,许多耐药突变位于远离药物结合位点的地方,目前尚不清楚这些突变如何赋予耐药性。此外,早期对一小部分患者源性伊马替尼耐药突变的研究表明,在细胞和生化研究中,这些突变蛋白中的一些实际上对伊马替尼敏感。在这里,我们调查了94例患者来源的Abl激酶结构域突变的耐药性,这些突变被标记为与疾病相关或在活细胞中使用接合试验引起耐药性。我们发现,与Abl野生型相比,只有三分之二的突变使伊马替尼的亲和力减弱了两倍以上。令人惊讶的是,三分之一的Abl激酶结构域突变仍然对伊马替尼敏感,并且与野生型的结合具有相似或更高的亲和力。有趣的是,我们发现了三个临床Abl突变,它们以野生型亲和力结合伊马替尼,但与伊马替尼分离的速度要快得多。鉴于停留时间与药物疗效的相关性,改变结合动力学的突变可能在体内的非平衡环境中引起耐药性,而药物的输出和清除起着关键作用。
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