Scientific Research Center for Translational Medicine, Department of Biotechnology, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian, China.
CAS Key Laboratory of Separation Science for Analytical Chemistry, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian, China.
Clin Cancer Res. 2018 Jan 15;24(2):474-485. doi: 10.1158/1078-0432.CCR-17-1707. Epub 2017 Oct 30.
Metabolic reprogramming is frequently identified in hepatocellular carcinoma (HCC), which is the most common type of liver malignancy. The reprogrammed cellular metabolisms promote tumor cell survival, proliferation, angiogenesis, and metastasis. However, the mechanisms of this process remain unclear in HCC. The global nontargeted metabolic study in 69 paired hepatic carcinomas and adjacent tissue specimens was performed using capillary electrophoresis-time of flight mass spectrometry-based approach. Key findings were validated by targeted metabolomic approach. Biological studies were also performed to investigate the role of proline biosynthesis in HCC pathogenesis. Proline metabolism was markedly changed in HCC tumor tissue, characterized with accelerated consumption of proline and accumulation of hydroxyproline, which significantly correlated with α-fetoprotein levels and poor prognosis in HCC. In addition, we found that hydroxyproline promoted hypoxia- and HIF-dependent phenotype in HCC. Moreover, we demonstrated that hypoxia activated proline biosynthesis via upregulation of , subsequently leading to accumulation of hydroxyproline via attenuated activity. More importantly, we showed that glutamine, proline, and hydroxyproline metabolic axis supported HCC cell survival through modulating HIF1α stability in response to hypoxia. Finally, inhibition of proline biosynthesis significantly enhanced cytotoxicity of sorafenib and Our results demonstrate that hypoxic microenvironment activates proline metabolism, resulting in accumulation of hydroxyproline that promotes HCC tumor progression and sorafenib resistance through modulating HIF1α. These findings provide the proof of concept for targeting proline metabolism as a potential therapeutic strategy for HCC. .
代谢重编程在肝细胞癌(HCC)中经常被发现,这是最常见的肝脏恶性肿瘤类型。重编程的细胞代谢促进肿瘤细胞存活、增殖、血管生成和转移。然而,这一过程的机制在 HCC 中仍不清楚。我们使用毛细管电泳-飞行时间质谱为基础的方法对 69 对肝癌和相邻组织标本进行了全球非靶向代谢组学研究。关键发现通过靶向代谢组学方法进行了验证。还进行了生物学研究以调查脯氨酸生物合成在 HCC 发病机制中的作用。脯氨酸代谢在 HCC 肿瘤组织中明显改变,其特征是脯氨酸消耗加速和羟基脯氨酸积累,这与 HCC 中的甲胎蛋白水平和预后不良显著相关。此外,我们发现羟基脯氨酸促进 HCC 中的缺氧和 HIF 依赖性表型。此外,我们证明缺氧通过上调 来激活脯氨酸生物合成,从而导致通过减弱 活性积累羟基脯氨酸。更重要的是,我们表明谷氨酰胺、脯氨酸和羟基脯氨酸代谢轴通过调节 HIF1α 稳定性来响应缺氧从而支持 HCC 细胞存活。最后,脯氨酸生物合成的抑制显著增强了索拉非尼的细胞毒性 和 我们的结果表明,缺氧微环境激活脯氨酸代谢,导致羟基脯氨酸的积累,从而促进 HCC 肿瘤进展和索拉非尼耐药通过调节 HIF1α。这些发现为靶向脯氨酸代谢作为 HCC 的潜在治疗策略提供了概念验证。
