P53 协调癌症代谢:揭示逆转沃伯格效应的策略

Roba Abukwaik, Elias Vera-Siguenza, Daniel Tennant, Fabian Spill
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摘要

癌细胞的新陈代谢发生了重大变化,其特点是氧化磷酸化(OXPHOS)减少,对糖酵解的依赖性增加,即使在有氧的情况下也是如此。这种被称为沃伯格效应的新陈代谢转变,是助长癌症控制生长、侵袭和抗药性的关键因素。虽然许多基因的失调都会导致这种新陈代谢的转变,但肿瘤抑制基因ep53却是其中的主要角色。本研究引入了一个全面的数学模型,整合了 p53 的重要靶点,让人们深入了解 p53 如何协调其靶点将癌症代谢导向 OXPHOS 主导状态。模拟结果与比较具有野生型和突变型 p53 的结肠癌细胞葡萄糖代谢的实验数据非常吻合。此外,我们的研究结果还揭示了 p53 激活水平升高完全逆转沃伯格效应的动态能力,凸显了其活性水平不仅在化疗后触发细胞凋亡(程序性细胞死亡)方面,而且在改变与耐药性有关的代谢途径方面的重要意义。在 p53 突变的情况下,我们的分析表明,以促进糖酵解的信号通路为靶点是一种替代策略,在这种情况下,仅以细胞色素 c 氧化酶 2 (SCO2) 的合成为靶点确实能支持软骨呼吸,但可能无法有效抑制糖酵解通路,从而有可能提高能量产生和癌细胞活力。
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P53 Orchestrates Cancer Metabolism: Unveiling Strategies to Reverse the Warburg Effect
Cancer cells exhibit significant alterations in their metabolism, characterised by a reduction in oxidative phosphorylation (OXPHOS) and an increased reliance on glycolysis, even in the presence of oxygen. This metabolic shift, known as the Warburg effect, is pivotal in fuelling cancer's uncontrolled growth, invasion, and therapeutic resistance. While dysregulation of many genes contributes to this metabolic shift, the tumour suppressor gene p53 emerges as a master player. Yet, the molecular mechanisms remain elusive. This study introduces a comprehensive mathematical model, integrating essential p53 targets, offering insights into how p53 orchestrates its targets to redirect cancer metabolism towards an OXPHOS-dominant state. Simulation outcomes align closely with experimental data comparing glucose metabolism in colon cancer cells with wild-type and mutated p53. Additionally, our findings reveal the dynamic capability of elevated p53 activation to fully reverse the Warburg effect, highlighting the significance of its activity levels not just in triggering apoptosis (programmed cell death) post-chemotherapy but also in modifying the metabolic pathways implicated in treatment resistance. In scenarios of p53 mutations, our analysis suggests targeting glycolysis-instigating signalling pathways as an alternative strategy, whereas targeting solely synthesis of cytochrome c oxidase 2 (SCO2) does support mitochondrial respiration but may not effectively suppress the glycolysis pathway, potentially boosting the energy production and cancer cell viability.
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