Tomer Meirson, David Bomze, Ora Schueler-Furman, Salomon M Stemmer, Gal Markel
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引用次数: 0
摘要
癌症研究的一项主要工作是将复杂的疾病组织成基本特征。尽管过去几十年在概念上取得了进展,并总结出了一些标志性特征,但除了细胞特征之外,还不存在任何管理癌症的组织原则。我们分析了人类癌症中最重要、最普遍的驱动性错义突变的实验测定结构,涵盖了《癌症中的体细胞突变目录》(COSMIC)中 73% 的肿瘤样本(n = 168178)。结果显示,单一结构元素--κ-螺旋(多脯氨酸 II 螺旋)--是驱动点突变的核心,在所有主要解剖部位都有显著的富集,这表明大多数甚至所有类型的癌症都具有少量的分子特征。因此,我们发现了在蛋白质水平上发生癌变的最低可能组织水平。这一框架为从机理上理解肿瘤的发展提供了一个初步方案,并指出了关键的薄弱环节。
Systemic structural analysis of alterations reveals a common structural basis of driver mutations in cancer.
A major effort in cancer research is to organize the complexities of the disease into fundamental traits. Despite conceptual progress in the last decades and the synthesis of hallmark features, no organizing principles governing cancer beyond cellular features exist. We analyzed experimentally determined structures harboring the most significant and prevalent driver missense mutations in human cancer, covering 73% (n = 168178) of the Catalog of Somatic Mutation in Cancer tumor samples (COSMIC). The results reveal that a single structural element-κ-helix (polyproline II helix)-lies at the core of driver point mutations, with significant enrichment in all major anatomical sites, suggesting that a small number of molecular traits are shared by most and perhaps all types of cancer. Thus, we uncovered the lowest possible level of organization at which carcinogenesis takes place at the protein level. This framework provides an initial scheme for a mechanistic understanding underlying the development of tumors and pinpoints key vulnerabilities.
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