Quayle Lewis A, Pereira Maria G, Scheper Gerjan, Wiltshire Tammy, Peake Ria E, Hussain Issam, Rea Carol A, Bates Timothy E
School of Life Sciences, Joseph Banks Laboratories, University of Lincoln, Lincoln, LN6 7DL, U.K.
Department of Oncology and Metabolism, Medical School, University of Sheffield, Sheffield, S10 2RX, U.K.
Oncotarget. 2017 Sep 13;8(51):88670-88688. doi: 10.18632/oncotarget.20858. eCollection 2017 Oct 24.
Components of the mitochondrial electron transport chain have recently gained much interest as potential therapeutic targets. Since mitochondria are essential for the supply of energy that is required for both angiogenic and tumourigenic activity, targeting the mitochondria represents a promising potential therapeutic approach for treating cancer. Here we investigate the established anti-angiogenesis drugs combretastatin A4, thalidomide, OGT 2115 and tranilast that we hypothesise are able to exert a direct anti-cancer effect in the absence of vasculature by targeting the mitochondria. Drug cytotoxicity was measured using the MTT assay. Mitochondrial function was measured in intact isolated mitochondria using polarography, fluorimetry and enzymatic assays to measure mitochondrial oxygen consumption, membrane potential and complex I-IV activities respectively. Combretastatin A4, OGT 2115 and tranilast were both shown to decrease mitochondrial oxygen consumption. OGT 2115 and tranilast decreased mitochondrial membrane potential and reduced complex I activity while combretastatin A4 and thalidomide did not. OGT 2115 inhibited mitochondrial complex II-III activity while combretastatin A4, thalidomide and tranilast did not. Combretastatin A4, thalidomide and OGT 2115 induced bi-phasic concentration-dependent increases and decreases in mitochondrial complex IV activity while tranilast had no evident effect. These data demonstrate that combretastatin A4, thalidomide, OGT 2115 and tranilast are all mitochondrial modulators. OGT 2115 and tranilast are both mitochondrial inhibitors capable of eliciting concentration-dependent reductions in cell viability by decreasing mitochondrial membrane potential and oxygen consumption.
线粒体电子传递链的组成部分最近作为潜在的治疗靶点引起了广泛关注。由于线粒体对于血管生成和肿瘤发生活动所需的能量供应至关重要,因此靶向线粒体代表了一种有前景的癌症治疗潜在方法。在此,我们研究了已确立的抗血管生成药物康普瑞他汀A4、沙利度胺、OGT 2115和曲尼司特,我们推测这些药物能够通过靶向线粒体在无脉管系统的情况下发挥直接抗癌作用。使用MTT法测量药物细胞毒性。使用极谱法、荧光法和酶法分别测量完整分离线粒体中的线粒体功能,以测量线粒体氧消耗、膜电位和复合体I-IV活性。结果表明,康普瑞他汀A4、OGT 2115和曲尼司特均能降低线粒体氧消耗。OGT 2115和曲尼司特降低了线粒体膜电位并降低了复合体I活性,而康普瑞他汀A4和沙利度胺则没有。OGT 2115抑制线粒体复合体II-III活性,而康普瑞他汀A4、沙利度胺和曲尼司特则没有。康普瑞他汀A4、沙利度胺和OGT 2115诱导线粒体复合体IV活性呈双相浓度依赖性增加和降低,而曲尼司特没有明显作用。这些数据表明,康普瑞他汀A4、沙利度胺、OGT 2115和曲尼司特都是线粒体调节剂。OGT 2115和曲尼司特都是线粒体抑制剂,能够通过降低线粒体膜电位和氧消耗引起细胞活力的浓度依赖性降低。