Maya-Mendoza Apolinar, Ostrakova Jitka, Kosar Martin, Hall Arnaldur, Duskova Pavlina, Mistrik Martin, Merchut-Maya Joanna Maria, Hodny Zdenek, Bartkova Jirina, Christensen Claus, Bartek Jiri
Danish Cancer Society Research Center, DK-2100 Copenhagen, Denmark.
Danish Cancer Society Research Center, DK-2100 Copenhagen, Denmark.
Mol Oncol. 2015 Mar;9(3):601-16. doi: 10.1016/j.molonc.2014.11.001. Epub 2014 Nov 15.
Both Myc and Ras oncogenes impact cellular metabolism, deregulate redox homeostasis and trigger DNA replication stress (RS) that compromises genomic integrity. However, how are such oncogene-induced effects evoked and temporally related, to what extent are these kinetic parameters shared by Myc and Ras, and how are these cellular changes linked with oncogene-induced cellular senescence in different cell context(s) remain poorly understood. Here, we addressed the above-mentioned open questions by multifaceted comparative analyses of human cellular models with inducible expression of c-Myc and H-RasV12 (Ras), two commonly deregulated oncoproteins operating in a functionally connected signaling network. Our study of DNA replication parameters using the DNA fiber approach and time-course assessment of perturbations in glycolytic flux, oxygen consumption and production of reactive oxygen species (ROS) revealed the following results. First, overabundance of nuclear Myc triggered RS promptly, already after one day of Myc induction, causing slow replication fork progression and fork asymmetry, even before any metabolic changes occurred. In contrast, Ras overexpression initially induced a burst of cell proliferation and increased the speed of replication fork progression. However, after several days of induction Ras caused bioenergetic metabolic changes that correlated with slower DNA replication fork progression and the ensuing cell cycle arrest, gradually leading to senescence. Second, the observed oncogene-induced RS and metabolic alterations were cell-type/context dependent, as shown by comparative analyses of normal human BJ fibroblasts versus U2-OS sarcoma cells. Third, the energy metabolic reprogramming triggered by Ras was more robust compared to impact of Myc. Fourth, the detected oncogene-induced oxidative stress was due to ROS (superoxide) of non-mitochondrial origin and mitochondrial OXPHOS was reduced (Crabtree effect). Overall, our study provides novel insights into oncogene-evoked metabolic reprogramming, replication and oxidative stress, with implications for mechanisms of tumorigenesis and potential targeting of oncogene addiction.
Myc和Ras癌基因均会影响细胞代谢、破坏氧化还原稳态并引发DNA复制应激(RS),进而损害基因组完整性。然而,这些癌基因诱导的效应是如何诱发的以及在时间上有何关联,Myc和Ras在多大程度上共享这些动力学参数,以及在不同细胞环境中这些细胞变化如何与癌基因诱导的细胞衰老相关联,目前仍知之甚少。在这里,我们通过对具有c-Myc和H-RasV12(Ras)诱导表达的人类细胞模型进行多方面的比较分析,解决了上述开放性问题,c-Myc和H-RasV12是两种在功能连接的信号网络中常见的失调癌蛋白。我们使用DNA纤维方法对DNA复制参数进行研究,并对糖酵解通量、氧消耗和活性氧(ROS)产生的扰动进行时间进程评估,得出了以下结果。首先,核Myc的过量表达在Myc诱导一天后就迅速引发了RS,导致复制叉进展缓慢和叉不对称,甚至在任何代谢变化发生之前。相比之下,Ras过表达最初诱导了细胞增殖的爆发并提高了复制叉进展的速度。然而,诱导几天后,Ras引起了生物能量代谢变化,这与较慢的DNA复制叉进展和随后的细胞周期停滞相关,逐渐导致衰老。其次,如对正常人BJ成纤维细胞与U2-OS肉瘤细胞的比较分析所示,观察到的癌基因诱导的RS和代谢改变是细胞类型/环境依赖性的。第三,与Myc的影响相比,Ras触发的能量代谢重编程更为强烈。第四,检测到的癌基因诱导的氧化应激是由于非线粒体来源的ROS(超氧化物),并且线粒体氧化磷酸化减少(Crabtree效应)。总体而言
