Ceramide-mediated gut dysbiosis enhances cholesterol esterification and promotes colorectal tumorigenesis in mice
Yahui Zhu, Li Gu, Xi Lin, Jinmiao Zhang, Yi Tang, Xinyi Zhou, Bingjun Lu, Xingrong Lin, Cheng Liu, Edward V. Prochownik, Youjun Li
Yahui Zhu, Li Gu, Xi Lin, Jinmiao Zhang, Yi Tang, Xinyi Zhou, Bingjun Lu, Xingrong Lin, Cheng Liu, Edward V. Prochownik, Youjun Li
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Research Article Gastroenterology Metabolism

Ceramide-mediated gut dysbiosis enhances cholesterol esterification and promotes colorectal tumorigenesis in mice

Abstract

Colorectal cancer (CRC) severely threatens human health and life span. An effective therapeutic strategy has not been established because we do not clearly know its pathogenesis. Here, we report that ceramide and sterol O-acyltransferase 1 (SOAT1) have roles in both spontaneous and chemical-induced intestinal cancers. We first found that miRNA-148a deficiency dramatically increased mouse gut dysbiosis through upregulating ceramide synthase 5 (Cers5) expression, which promoted ceramide synthesis afterward. The newly generated ceramide further promoted both azoxymethane/dextran sodium sulfate–induced (AOM/DSS-induced) and ApcMin/+ spontaneous intestinal tumorigenesis via increasing mouse gut dysbiosis. Meanwhile, increased level of ceramide correlated with the significant enhancements of both β-catenin activity and colorectal tumorigenesis in a TLR4-dependent fashion. Next, we found a direct binding of β-catenin to SOAT1 promoter to activate transcriptional expression of SOAT1, which further induced cholesterol esterification and colorectal tumorigenesis. In human patients with CRC, the same CERS5/TLR4/β-catenin/SOAT1 axis was also found to be dysregulated. Finally, the SOAT1 inhibitor (avasimibe) showed significant levels of therapeutic effects on both AOM/DSS-induced and ApcMin/+ spontaneous intestinal cancer. Our study clarified that ceramide promoted CRC development through increasing gut dysbiosis, further resulting in the increase of cholesterol esterification in a SOAT1-dependent way. Treatment with avasimibe to specifically decrease cholesterol esterification could be considered as a clinical strategy for effective CRC therapy in a future study.

Authors

Yahui Zhu, Li Gu, Xi Lin, Jinmiao Zhang, Yi Tang, Xinyi Zhou, Bingjun Lu, Xingrong Lin, Cheng Liu, Edward V. Prochownik, Youjun Li

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Figure 5

SOAT1 is transcriptionally activated by β-catenin/TCF1 complex.

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SOAT1 is transcriptionally activated by β-catenin/TCF1 complex. (A) qPCR...
(A) qPCR analyzed lipid metabolism genes’ expression on CRCs from AOM/DSS-treated vehicle + control, ceramide + control, and ceramide + antibiotics mice (n = 3/group). (B and C) The mRNA (B) (n = 5/group) and protein (C) (n = 3/group) levels of SOAT1 in CRCs of WT and Tlr4–/– mice with indicated treatment. (D) Results of Western blot assay for both β-catenin and SOAT1 protein levels in CRC from indicated mice (n = 3/group). (E) Schematic representation of the SOAT1 promoter (–5 kb to +5 kb of the transcription start site [TSS]). At the top, β-catenin binding sites are indicated. (F) Western blot detected β-catenin protein levels in CRCs of mouse with indicated treatment (n = 3/group). (G and H) The mRNA (G) and protein (H) levels of SOAT1 in HCT116 cells treated with different concentrations of β-catenin inhibitor (iCRT14). (I and J) Depletion of β-catenin repressed the mRNA (I) and protein (J) levels of SOAT1 in HCT116 cells. (K) ChIP qPCR analyses on the SOAT1 promoter with IgG and β-catenin antibodies in HCT116 cells. (L) Luciferase activity of SOAT1 promoter in HCT116 and SW480 cells in response to shRNA-mediated suppression of β-catenin. (Data were presented as mean ± SEM in B, G, I, K, and L.) *P < 0.05, **P < 0.01, ***P < 0.001. Statistical significance was calculated by using 1-way ANOVA (B) or 2-tailed unpaired t test (G, I, K, and L). Data shown in GL are representatives of 3 independent experiments.