摘要
c-MYC基因(以下简称MYC)表达失调普遍存在于人类肿瘤中。MYC转基因小鼠模型能产生多种肿瘤。 MYC基因是肿瘤生成的强大推动力,也是肿瘤存在所必需的。因此 MYC是癌症治疗的一个活性靶点。然而研究表明,用于治疗MYC基因过度表达肿瘤的MYC基因靶向失活的基因学和药理学方法不尽人意。MYC基因表达在转录、转录后和翻译阶段由不同机制调节。MYC蛋白的翻转是影响MYC基因表达和起作用的重要步骤。MYC翻转主要由糖原合成激酶-3和泛素连接酶(GSK3β/FBW7)中枢控制,这一中枢由多个因素调节。小分子抑制剂(SMIs)能通过针对中枢及其调节因素来影响MYC蛋白的稳定性和活性。王等人(2004年)首先引入了由TRAIL和DR5受体激动剂诱导的MYC-介导合成致死(MYC-SL)概念。研究人员已经把合成致死作为MYC过度表达肿瘤的一个治疗策略。MYC基因的功能与MYC水平密切相关。现已发展出通过上调或下调MYC水平来治疗MYC过度表达肿瘤的两种方法。小分子抑制剂可通过糖原合成激酶-3和泛素连接酶中枢和酪蛋白激酶的灭活来诱导MYC-SL增加MYC表达。Myc水平升高会导致DNA损伤、衰老和凋亡。小分子抑制剂也可以通过激活GSK3β/FBW7中枢、PP2A抑制剂灭活和抑制ARK5、AUK-A、Brd4、CDK1、CDK2、 CHK1和 SAE1/2来诱导MYC-SL 减少MYC基因表达。减少MYC 水平会导致肿瘤退化。有些小分子抑制剂已进入I期和II期临床试验。在不久的将来,小分子抑制剂可能会用来治疗癌症共同过度表达的MYC和相应的MYC-SL 基因。
关键词: c-MYC, 癌基因成瘾性,小分子抑制剂,合成致死,靶向治疗,肿瘤,肿瘤发生。
图形摘要
Current Cancer Drug Targets
Title:MYC-Mediated Synthetic Lethality for Treating Tumors
Volume: 15 Issue: 2
Author(s): Xin Li, Xin A. Zhang, Xiaoqing Li, Wei Xie and Shiang Huang
Affiliation:
关键词: c-MYC, 癌基因成瘾性,小分子抑制剂,合成致死,靶向治疗,肿瘤,肿瘤发生。
摘要: Deregulated c-MYC (hereafter MYC) is widely expressed in many human tumors. Myctransgenic mouse models produce diverse tumors. MYC is a strong driver of tumorigenesis and is required for tumor maintenance. MYC is therefore an attractive target for cancer treatment. However, genetic and pharmacological approaches for the targeted inactivation of MYC for the treatment of MYC-overexpressing tumors have been shown to be unsatisfactory. MYC expression is regulated by different mechanisms at transcriptional, post-transcriptional, and post-translational levels. Turnover of MYC protein is an important step that influences the expression and function of MYC. MYC turnover is predominantly controlled by the GSK3/FBW7 axis that is regulated by multiple elements. Small molecule inhibitors (SMIs) can influence the stability and activity of MYC protein by targeting the axis and its regulator elements. Wang et al. (2004) first introduced the concept of MYC-mediated synthetic lethality (MYC-SL) induced by TRAIL and DR5-agonists. Researchers have turned to synthetic lethality as a treatment strategy for MYC-overexpressing tumors. MYC function is closely associated with MYC levels. Two strategies have been developed to treat MYC-overexpressing tumors by upregulating or downregulating MYC. An SMI can induce MYC-SL by increasing MYC expression through the inactivation of the GSK3β/FBW7 axis and CK1. Elevated MYC levels lead to DNA damage, senescence, and apoptosis. An SMI can also induce MYC-SL by decreasing MYC expression through the activation of the GSK3β/FBW7 axis, the inactivation of PP2A inhibitors, and the inhibition of ARK5, AUK-A, Brd4, CDK1, CDK2, CHK1, and SAE1/2. Reduced MYC levels cause tumor regression. Some SMIs have entered phase I and II clinical trials. SMIs may be used in the near future to treat cancers co-overexpressing MYC and the corresponding MYC-SL genes.
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Cite this article as:
Xin Li, Xin A. Zhang, Xiaoqing Li, Wei Xie and Shiang Huang , MYC-Mediated Synthetic Lethality for Treating Tumors, Current Cancer Drug Targets 2015; 15 (2) . https://dx.doi.org/10.2174/1568009615666150121162921
DOI https://dx.doi.org/10.2174/1568009615666150121162921 |
Print ISSN 1568-0096 |
Publisher Name Bentham Science Publisher |
Online ISSN 1873-5576 |
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