Chair of Medical Biochemistry, Faculty of Medicine, Jagiellonian University Medical College, Kraków, Poland.
Faculty of Chemistry, Jagiellonian University, Kraków, Poland.
Pharmacol Rep. 2023 Aug;75(4):876-890. doi: 10.1007/s43440-023-00504-1. Epub 2023 Jun 19.
Although Warburg's discovery of intensive glucose uptake by tumors, followed by lactate fermentation in oxygen presence of oxygen was made a century ago, it is still an area of intense research and development of new hypotheses that, layer by layer, unravel the complexities of neoplastic transformation. This seemingly simple metabolic reprogramming of cancer cells reveals an intriguing, multi-faceted nature that may link various phenomena including cell signaling, cell proliferation, ROS generation, energy supply, macromolecules synthesis/biosynthetic precursor supply, immunosuppression, or cooperation of cancerous cells with cancer-associated fibroblasts (CAFs), known as reversed Warburg effect. According to the current perception of the causes and consequences of the Warburg effect, PI3K/Akt/mTOR are the main signaling pathways that, in concert with the transcription factors HIF-1, p53, and c-Myc, modulate the activity/expression of key regulatory enzymes, including PKM2, and PDK1 to tune in the most optimal metabolic setting for the cancer cell. This in turn secures adequate levels of biosynthetic precursors, NADPH, NAD, and rapid ATP production to meet the increased demands of intensively proliferating tumor cells. The end-product of "aerobic glycolysis", lactate, an oncometabolite, may provide fuel to neighboring cancer cells, and facilitate metastasis and immunosuppression together enabling cancer progression. The importance and possible applicability of the presented issue are best illustrated by numerous trials with various agents targeting the Warburg effect, constituting a promising strategy in future anti-cancer regimens. In this review, we present the key aspects of this multifactorial phenomenon, depicting the mechanisms and benefits behind the Warburg effect, and also pointing to selected aspects in the field of anticancer therapy.
尽管沃伯格(Warburg)一个世纪前就发现了肿瘤细胞对葡萄糖的摄取增加,随后在有氧条件下进行乳酸发酵,但这仍然是一个研究和开发新假说的热点领域,这些假说逐层揭示了肿瘤转化的复杂性。这种看似简单的癌细胞代谢重编程揭示了一种有趣的、多方面的性质,它可能将各种现象联系起来,包括细胞信号转导、细胞增殖、ROS 生成、能量供应、大分子合成/生物合成前体供应、免疫抑制,或癌细胞与癌症相关成纤维细胞(CAFs)的合作,这被称为逆转沃伯格效应。根据目前对沃伯格效应的原因和后果的认识,PI3K/Akt/mTOR 是主要的信号通路,与转录因子 HIF-1、p53 和 c-Myc 一起,调节关键调节酶的活性/表达,包括 PKM2 和 PDK1,以调整最适合癌细胞的代谢状态。这反过来又确保了生物合成前体、NADPH、NAD 和快速 ATP 产生的足够水平,以满足高度增殖的肿瘤细胞的需求。“有氧糖酵解”的终产物乳酸是一种致癌代谢物,可为邻近的癌细胞提供燃料,并促进转移和免疫抑制,共同促进癌症进展。针对沃伯格效应的各种药物的大量试验最能说明所提出问题的重要性和可能的适用性,这构成了未来抗癌方案中的一种有前途的策略。在这篇综述中,我们介绍了这一多因素现象的关键方面,描述了沃伯格效应背后的机制和益处,并指出了抗癌治疗领域的一些选定方面。
