Apigenin inhibits lipid metabolism of hepatocellular carcinoma cells by targeting the histone demethylase KDM1A.

ABSTRACT

BACKGROUND: The development of cancer is accompanied by metabolic reprogramming, and the liver serves as a central hub for lipid transportation. Apigenin, a plant-derived flavonoid, demonstrates potent anticancer properties across various cancer types and exhibits promising potential as a therapeutic agent for cancer treatment. However, there are limited studies focusing on the downstream targets of apigenin. Moreover, there are few reports on the impact of apigenin in lipid metabolism within liver cancer cells. PURPOSE: The objective is to elucidate the metabolic mechanism underlying the inhibitory effect of apigenin on liver cancer progression, search for downstream targets and provide reliable data support for the clinical trials of apigenin. METHODS: Anticancer effects of apigenin were detected at cellular and molecular levels in vitro, and downstream targets of apigenin, especially metabolic pathway genes, were analyzed by transcriptome. Next, the downstream target of apigenin was verified and the biological function of the downstream target was examined. Finally, the downstream target of apigenin was further verified by restoring target gene expression. RESULTS: Cellular molecular experiments showed that Apigenin inhibited the proliferation, migration, invasion and lipid metabolism of hepatocellular carcinoma (HCC) cells. Transcriptome analysis showed apigenin widely regulates histone demethylase, particularly histone H3K4 lysine demethylase 1A (KDM1A). Apigenin treatment inhibited the expression of KDM1A protein and mRNA levels in liver cancer cells, molecular docking predicted the interaction between apigenin and KDM1A. Furthermore, downregulation KDM1A inhibited the proliferation and lipid metabolism of HCC cells, in the same way, overexpressing KDM1A promoted proliferation of HCC cells. Finally, restoring KDM1A expression partially attenuated the effects of apigenin on lipid metabolism in HCC cells. CONCLUSION: In conclusion, our study provides compelling evidence that apigenin inhibits liver cancer progression and elucidates its mechanism of action in regulating lipid metabolism. Specifically, we find that apigenin suppresses the progression of HCC cells by downregulating genes involved in lipid metabolism. Additionally, our results indicate that KDM1A acts as a downstream target of apigenin in the inhibition of lipid metabolism in HCC. These findings offer experimental support for the potential use of apigenin as a therapeutic agent for liver cancer, highlighting its relevance in future clinical applications.