Sumiyoshi Akira, Shibata Sayaka, Zhelev Zhivko, Miller Thomas, Lazarova Dessislava, Aoki Ichio, Obata Takayuki, Higashi Tatsuya, Bakalova Rumiana
Department of Molecular Imaging and Theranostics, National Institutes for Quantum and Radiological Science and Technology (QST), 4-9-1 Anagawa, Chiba 263-8555, Inage-ku, Japan.
Faculty of Medicine, Trakia University, 6000 Stara Zagora, Bulgaria.
Cancers (Basel). 2022 Jan 19;14(3):485. doi: 10.3390/cancers14030485.
Glioblastoma is one of the most aggressive brain tumors, characterized by a pronounced redox imbalance, expressed in a high oxidative capacity of cancer cells due to their elevated glycolytic and mitochondrial oxidative metabolism. The assessment and modulation of the redox state of glioblastoma are crucial factors that can provide highly specific targeting and treatment. Our study describes a pharmacological strategy for targeting glioblastoma using a redox-active combination drug. The experiments were conducted in vivo on glioblastoma mice (intracranial model) and in vitro on cell lines (cancer and normal) treated with the redox cycling pair menadione/ascorbate (M/A). The following parameters were analyzed in vivo using MRI or ex vivo on tissue and blood specimens: tumor growth, survival, cerebral perfusion, cellular density, tissue redox state, expression of tumor-associated NADH oxidase (tNOX) and transforming growth factor-beta 1 (TGF-β1). Dose-dependent effects of M/A on cell viability, mitochondrial functionality, and redox homeostasis were evaluated in vitro. M/A treatment suppressed tumor growth and significantly increased survival without adverse side effects. This was accompanied by increased oxidative stress, decreased reducing capacity, and decreased cellular density in the tumor only, as well as increased cerebral perfusion and down-regulation of tNOX and TGF-β1. M/A induced selective cytotoxicity and overproduction of mitochondrial superoxide in isolated glioblastoma cells, but not in normal microglial cells. This was accompanied by a significant decrease in the over-reduced state of cancer cells and impairment of their "pro-oncogenic" functionality, assessed by dose-dependent decreases in: NADH, NAD, succinate, glutathione, cellular reducing capacity, mitochondrial potential, steady-state ATP, and tNOX expression. The safety of M/A on normal cells was compromised by treatment with cerivastatin, a non-specific prenyltransferase inhibitor. In conclusion, M/A differentiates glioblastoma cells and tissues from normal cells and tissues by redox targeting, causing severe oxidative stress only in the tumor. The mechanism is complex and most likely involves prenylation of menadione in normal cells, but not in cancer cells, modulation of the immune response, a decrease in drug resistance, and a potential role in sensitizing glioblastoma to conventional chemotherapy.
胶质母细胞瘤是最具侵袭性的脑肿瘤之一,其特征是明显的氧化还原失衡,表现为癌细胞由于糖酵解和线粒体氧化代谢增强而具有较高的氧化能力。评估和调节胶质母细胞瘤的氧化还原状态是能够提供高度特异性靶向和治疗的关键因素。我们的研究描述了一种使用氧化还原活性联合药物靶向胶质母细胞瘤的药理学策略。实验在胶质母细胞瘤小鼠体内(颅内模型)以及用氧化还原循环对甲萘醌/抗坏血酸盐(M/A)处理的细胞系(癌细胞和正常细胞)体外进行。使用MRI在体内或在组织和血液标本上进行体外分析以下参数:肿瘤生长、存活、脑灌注、细胞密度、组织氧化还原状态、肿瘤相关NADH氧化酶(tNOX)和转化生长因子-β1(TGF-β1)的表达。在体外评估了M/A对细胞活力、线粒体功能和氧化还原稳态的剂量依赖性影响。M/A治疗抑制了肿瘤生长并显著提高了存活率,且无不良副作用。这伴随着氧化应激增加、还原能力降低、仅肿瘤中的细胞密度降低,以及脑灌注增加和tNOX及TGF-β1的下调。M/A在分离的胶质母细胞瘤细胞中诱导了选择性细胞毒性和线粒体超氧化物的过量产生,但在正常小胶质细胞中未诱导。这伴随着癌细胞过度还原状态的显著降低及其“促癌”功能的受损,通过以下剂量依赖性降低来评估:NADH、NAD、琥珀酸盐、谷胱甘肽、细胞还原能力、线粒体电位、稳态ATP和tNOX表达。非特异性异戊二烯基转移酶抑制剂西立伐他汀的处理损害了M/A对正常细胞的安全性。总之,M/A通过氧化还原靶向将胶质母细胞瘤细胞和组织与正常细胞和组织区分开来,仅在肿瘤中引起严重的氧化应激。其机制复杂,很可能涉及甲萘醌在正常细胞而非癌细胞中的异戊二烯化、免疫反应的调节、耐药性的降低以及在使胶质母细胞瘤对传统化疗敏感化方面的潜在作用。
