Altered fatty acid metabolism continues to be an attractive target for therapeutic intervention in cancer. We previously found that colorectal cancer (CRC) cells with a higher metastatic potential express a higher level of fatty acid translocase (CD36). However, the role of CD36 in CRC metastasis has not been studied. Here, we demonstrate that high expression of CD36 promotes invasion of CRC cells. Consistently, CD36 promoted lung metastasis in the tail vein model and GI metastasis in the cecum injection model. RNA-Seq analysis of CRC cells with altered expression of CD36 revealed an association between high expression of CD36 and upregulation of MMP28, a novel member of the metallopeptidase family of proteins. Using shRNA-mediated knockdown and overexpression of CD36, we confirmed that CD36 regulates MMP28 expression in CRC cells. siRNA-mediated knockdown of MMP28 decreases invasion of CRC cells, suggesting that MMP28 regulates the metastatic properties of cells downstream of CD36. Importantly, high expression of MMP28 leads to a significant decrease in active E-cadherin and an increase in the products of E-cadherin cleavage, CTF1 and CTF2. In summary, upregulation of CD36 expression promotes the metastatic properties of CRC via upregulation of MMP28 and an increase in E-cadherin cleavage, suggesting that targeting the CD36–MMP28 axis may be an effective therapeutic strategy for CRC metastasis.
Background: Aberrant lipid metabolism is associated with poor prognosis in colorectal cancer (CRC). Fatty acid synthase (FASN), a key enzyme of lipogenesis, is overexpressed and a therapeutic target in CRC. Overexpression of CD36, a fatty acid translocase, plays a pro-tumorigenic role in CRC. BRAFV600E is the mutation occurring in about 10-15% of CRC cases. BRAF-targeted therapy is effective, but quickly developed resistance is an issue. Our preliminary data show that development of resistance to BRAF-targeted therapy is associated with an increase in expression of FASN, CD36, accumulation of triglycerides (TGs), and mitochondrial respiration. Therefore, our central hypothesis is that inhibition of lipid metabolism will sensitize CRC cells to BRAF inhibitors and overcome acquired resistance. Methods: We established HT29 cells and primary PT130 and PT2449pt cells resistant to PLX8394, a novel BRAF inhibitor. IC50 curves, PrestoBlue viability, CytoSelect™ 24-Well Cell Invasion, and Triglyceride Assays, Seahorse XF analysis, western blot, and confocal microscopy were used to evaluate differences between parental and resistant cells. RNA-seq and lipid analysis were used to evaluate changes in gene expression and lipids levels. Combination of PLX8394 and TVB3664 (FASN inhibitor) was tested on cell viability in parental and resistant cells. Results: PLX8394 resistant cells have a higher IC50, an increased proliferation, and invasion compared to parental cells. An increase in invasion of resistant cells is associated with a decrease in E-cadherin. RNA sequencing shows a significant increase in FASN expression. Western blot on resistant cells confirms upregulation of FASN, CD36, and other lipogenic markers. Consistently, resistant cells have an increase in levels of triglycerides as compared to parental cells. Seahorse XF Cell Mito Stress Test shows that resistant cells forgo the Warburg effect and instead rely more heavily on oxidative phosphorylation. To further support our hypothesis, FASN shRNA knockdown of FASN in parental HT29 cells is more susceptible to PLX8394 treatment compared to control. We also observed the synergetic effect of PLX8394 and TVB3664 treatment on cell viability in parental cells, but not in resistant cells. Conclusion: Our study demonstrates that resistance to BRAF inhibitors is associated with a significant increase in proliferation, metastasis, and upregulation of lipid metabolism. We show that combination of FASN and BRAF inhibitors has a combinational effect on inhibiting cell viability in parental but not resistant cells, suggesting that the addition of FASN inhibitor to the standard regimen for BRAFV600E mutation positive patients can improve efficacy of these therapies. Additional screening of lipid metabolism-targeted therapies in combination with standard BRAF regimens are needed to develop novel and more efficacious strategies for CRC patients with BRAF mutations. Citation Format: Mariah E. Geisen, Dang he, Chi Wang, Jill M. Kolesar, Yekaterina Zaytseva. Targeting lipid metabolism to improve efficacy of braf-targeted therapy in colorectal cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 414.
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