Signaling metabolite succinylacetone activates HIF-1α and promotes angiogenesis in GSTZ1-deficient hepatocellular carcinoma
Huating Luo, Qiujie Wang, Fan Yang, Rui Liu, Qingzhu Gao, Bin Cheng, Xue Lin, Luyi Huang, Chang Chen, Jin Xiang, Kai Wang, Bo Qin, Ni Tang
Huating Luo, Qiujie Wang, Fan Yang, Rui Liu, Qingzhu Gao, Bin Cheng, Xue Lin, Luyi Huang, Chang Chen, Jin Xiang, Kai Wang, Bo Qin, Ni Tang
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Research Article Oncology

Signaling metabolite succinylacetone activates HIF-1α and promotes angiogenesis in GSTZ1-deficient hepatocellular carcinoma

Abstract

Aberrant angiogenesis in hepatocellular carcinoma (HCC) is associated with tumor growth, progression, and local or distant metastasis. Hypoxia-inducible factor 1α (HIF-1α) is a transcription factor that plays a major role in regulating angiogenesis during adaptation of tumor cells to nutrient-deprived microenvironments. Genetic defects in Krebs cycle enzymes, such as succinate dehydrogenase and fumarate hydratase, result in elevation of oncometabolites succinate and fumarate, thereby increasing HIF-1α stability and activating the HIF-1α signaling pathway. However, whether other metabolites regulate HIF-1α stability remains unclear. Here, we reported that deficiency of the enzyme in phenylalanine/tyrosine catabolism, glutathione S-transferase zeta 1 (GSTZ1), led to accumulation of succinylacetone, which was structurally similar to α-ketoglutarate. Succinylacetone competed with α-ketoglutarate for prolyl hydroxylase domain 2 (PHD2) binding and inhibited PHD2 activity, preventing hydroxylation of HIF-1α, thus resulting in its stabilization and consequent expression of vascular endothelial growth factor (VEGF). Our findings suggest that GSTZ1 may serve as an important tumor suppressor owing to its ability to inhibit the HIF-1α/VEGFA axis in HCC. Moreover, we explored the therapeutic potential of HIF-1α inhibitor combined with anti–programmed cell death ligand 1 therapy to effectively prevent HCC angiogenesis and tumorigenesis in Gstz1-knockout mice, suggesting a potentially actionable strategy for HCC treatment.

Authors

Huating Luo, Qiujie Wang, Fan Yang, Rui Liu, Qingzhu Gao, Bin Cheng, Xue Lin, Luyi Huang, Chang Chen, Jin Xiang, Kai Wang, Bo Qin, Ni Tang

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Figure 8

Clinical evidence that GSTZ1/SA/HIF-1α is activated in tumors isolated from patients with HCC.

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Clinical evidence that GSTZ1/SA/HIF-1α is activated in tumors isolated f...
(A) Representative images of IHC staining of GSTZ1 and HIF-1α in HCC tissue. Scores are calculated based on the intensity and percentage of the stained cells (scale bar = 20 μm). The original magnification of the top row is 10×. (B) GSTZ1 and HIF-1α protein expression in 36 HCC and paired nontumor tissues. (C) Correlation analysis of GSTZ1 and HIF-1α mRNA expression levels is conducted using data from 373 patients with HCC included in TCGA LIHC data set. (D) Relative SA levels of metabolites in HCC and paired nontumor tissues as measured using mass spectrometry. Data are shown as mean ± SEM (n = 40 in each group). (E) Overall survival in HCC patients with high (> 25th percentile) or low (≤ 25th percentile) mRNA expression levels of GSTZ1 and HIF-1α, based on TCGA data. (F) A proposed model of how SA/HIF-1α/VEGFA axis activation promotes angiogenesis in GSTZ1-deficient cells. Statistical analysis was performed using Pearson’s r test (B and C), 2-tailed unpaired Student’s t test (D), or Gehan-Breslow-Wilcoxon test (E); **P < 0.01. N, nontumor; T, tumor; TCGA, The Cancer Genome Atlas. MAA, maleylacetoacetate; FAA, fumarylacetoacetate; SAA, succinylacetoacetate; OH, hydroxyl; DMOG, dimethyloxalylglycine; 2-ME2, 2-methoxyestradiol; HRE, hypoxia-responsive element.