氧化磷酸化为目标以阻止恶性肿瘤。

Oxidative phosphorylation as a target to arrest malignant neoplasias.

机构信息

Departamento de Bioquímica, Instituto Nacional de Cardiología Ignacio Chávez, México.

出版信息

Curr Med Chem. 2011;18(21):3156-67. doi: 10.2174/092986711796391561.

Abstract

Since Warburg proposed in 1956 that cancer cells exhibit increased glycolysis due to mitochondrial damage, numerous researchers have assumed that glycolysis is the predominant ATP supplier for cancer cell energy-dependent processes. However, chemotherapeutic strategies using glycolytic inhibitors have been unsuccessful in arresting tumor proliferation indicating that the Warburg hypothesis may not be applicable to all existing neoplasias. This review analyzes recent information on mitochondrial metabolism in several malignant neoplasias emphasizing that, although tumor cells maintain a high glycolytic rate, the principal ATP production may derive from active oxidative phosphorylation. Thus, anti-mitochondrial drug therapy may be an adequate adjuvant strategy to arrest proliferation of oxidative phosphorylation-dependent neoplasias.

摘要

自 1956 年 Warburg 提出癌细胞由于线粒体损伤而表现出增强的糖酵解以来，许多研究人员假设糖酵解是癌细胞能量依赖性过程的主要 ATP 供应者。然而，使用糖酵解抑制剂的化疗策略在阻止肿瘤增殖方面并不成功，这表明 Warburg 假说可能不适用于所有现有的肿瘤。这篇综述分析了几种恶性肿瘤中线粒体代谢的最新信息，强调尽管肿瘤细胞保持高糖酵解率，但主要的 ATP 产生可能来自活跃的氧化磷酸化。因此，抗线粒体药物治疗可能是一种有效的辅助策略，可以阻止依赖氧化磷酸化的肿瘤的增殖。

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氧化磷酸化为目标以阻止恶性肿瘤。

Oxidative phosphorylation as a target to arrest malignant neoplasias.

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