| Literature DB >> 29861385 |
Hideki Iwamoto1, Mitsuhiko Abe1, Yunlong Yang2, Dongmei Cui3, Takahiro Seki4, Masaki Nakamura4, Kayoko Hosaka4, Sharon Lim4, Jieyu Wu4, Xingkang He4, Xiaoting Sun5, Yongtian Lu6, Qingjun Zhou7, Weiyun Shi7, Takuji Torimura8, Guohui Nie9, Qi Li10, Yihai Cao11.
Abstract
Intrinsic and evasive antiangiogenic drug (AAD) resistance is frequently developed in cancer patients, and molecular mechanisms underlying AAD resistance remain largely unknown. Here we describe AAD-triggered, lipid-dependent metabolic reprogramming as an alternative mechanism of AAD resistance. Unexpectedly, tumor angiogenesis in adipose and non-adipose environments is equally sensitive to AAD treatment. AAD-treated tumors in adipose environment show accelerated growth rates in the presence of a minimal number of microvessels. Mechanistically, AAD-induced tumor hypoxia initiates the fatty acid oxidation metabolic reprogramming and increases uptake of free fatty acid (FFA) that stimulates cancer cell proliferation. Inhibition of carnitine palmitoyl transferase 1A (CPT1) significantly compromises the FFA-induced cell proliferation. Genetic and pharmacological loss of CPT1 function sensitizes AAD therapeutic efficacy and enhances its anti-tumor effects. Together, we propose an effective cancer therapy concept by combining drugs that target angiogenesis and lipid metabolism.Entities:
Keywords: VEGF; angiogenesis; antiangiogenic therapy; cancer; drug resistance; hypoxia; lipid metabolism; metastasis; tumor microenvironment; β-oxidation
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Year: 2018 PMID: 29861385 DOI: 10.1016/j.cmet.2018.05.005
Source DB: PubMed Journal: Cell Metab ISSN: 1550-4131 Impact factor: 27.287