全面的结构-功能分析揭示了影响致癌性KRAS活性的功能获得和功能丧失机制。

Comprehensive structure-function analysis reveals gain- and loss-of-function mechanisms impacting oncogenic KRAS activity.

作者信息

Kwon Jason J, Dilly Julien, Liu Shengwu, Kim Eejung, Bian Yuemin, Dharmaiah Srisathiyanarayanan, Tran Timothy H, Kapner Kevin S, Ly Seav Huong, Yang Xiaoping, Rabara Dana, Waybright Timothy J, Giacomelli Andrew O, Hong Andrew L, Misek Sean, Wang Belinda, Ravi Arvind, Doench John G, Beroukhim Rameen, Lemke Christopher T, Haigis Kevin M, Esposito Dominic, Root David E, Nissley Dwight V, Stephen Andrew G, McCormick Frank, Simanshu Dhirendra K, Hahn William C, Aguirre Andrew J

机构信息

Department of Medical Oncology, Dana Farber Cancer Institute, Boston, MA, 02115, USA.

Harvard Medical School, Boston, MA, 02115, USA.

出版信息

bioRxiv. 2024 Oct 25:2024.10.22.618529. doi: 10.1101/2024.10.22.618529.

DOI:10.1101/2024.10.22.618529

PMID:39484452

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11526993/

Abstract

To dissect variant-function relationships in the KRAS oncoprotein, we performed deep mutational scanning (DMS) screens for both wild-type and KRAS mutant alleles. We defined the spectrum of oncogenic potential for nearly all possible variants, identifying several novel transforming alleles and elucidating a model to describe the frequency of mutations in human cancer as a function of transforming potential, mutational probability, and tissue-specific mutational signatures. Biochemical and structural analyses of variants identified in a KRAS second-site suppressor DMS screen revealed that attenuation of oncogenic KRAS can be mediated by protein instability and conformational rigidity, resulting in reduced binding affinity to effector proteins, such as RAF and PI3-kinases, or reduced SOS-mediated nucleotide exchange activity. These studies define the landscape of single amino acid alterations that modulate the function of KRAS, providing a resource for the clinical interpretation of KRAS variants and elucidating mechanisms of oncogenic KRAS inactivation for therapeutic exploitation.

摘要

为了剖析KRAS癌蛋白中的变异-功能关系，我们对野生型和KRAS突变等位基因都进行了深度突变扫描（DMS）筛选。我们定义了几乎所有可能变异的致癌潜力谱，鉴定出了几个新的转化等位基因，并阐明了一个模型，该模型将人类癌症中的突变频率描述为转化潜力、突变概率和组织特异性突变特征的函数。在KRAS第二位点抑制DMS筛选中鉴定出的变异的生化和结构分析表明，致癌性KRAS的减弱可由蛋白质不稳定性和构象刚性介导，导致与效应蛋白（如RAF和PI3激酶）的结合亲和力降低，或SOS介导的核苷酸交换活性降低。这些研究定义了调节KRAS功能的单氨基酸改变的格局，为KRAS变异的临床解释提供了资源，并阐明了致癌性KRAS失活的机制以供治疗利用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2228/11526993/d6dec7295c2a/nihpp-2024.10.22.618529v1-f0001.jpg

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全面的结构-功能分析揭示了影响致癌性KRAS活性的功能获得和功能丧失机制。

Comprehensive structure-function analysis reveals gain- and loss-of-function mechanisms impacting oncogenic KRAS activity.

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