| Literature DB >> 27135739 |
Tomoya Fukawa1,2,3, Benjamin Chua Yan-Jiang4, Jason Chua Min-Wen4, Elwin Tan Jun-Hao4, Dan Huang2, Chao-Nan Qian5, Pauline Ong1,2, Zhimei Li2, Shuwen Chen6, Shi Ya Mak6, Wan Jun Lim7, Hiro-Omi Kanayama3, Rosmin Elsa Mohan8, Ruiqi Rachel Wang8, Jiunn Herng Lai9, Clarinda Chua4,7, Hock Soo Ong10, Ker-Kan Tan11, Ying Swan Ho6, Iain Beehuat Tan4,7,12, Bin Tean Teh1,2,7,13,14,15, Ng Shyh-Chang4.
Abstract
Cachexia is a devastating muscle-wasting syndrome that occurs in patients who have chronic diseases. It is most commonly observed in individuals with advanced cancer, presenting in 80% of these patients, and it is one of the primary causes of morbidity and mortality associated with cancer. Additionally, although many people with cachexia show hypermetabolism, the causative role of metabolism in muscle atrophy has been unclear. To understand the molecular basis of cachexia-associated muscle atrophy, it is necessary to develop accurate models of the condition. By using transcriptomics and cytokine profiling of human muscle stem cell-based models and human cancer-induced cachexia models in mice, we found that cachectic cancer cells secreted many inflammatory factors that rapidly led to high levels of fatty acid metabolism and to the activation of a p38 stress-response signature in skeletal muscles, before manifestation of cachectic muscle atrophy occurred. Metabolomics profiling revealed that factors secreted by cachectic cancer cells rapidly induce excessive fatty acid oxidation in human myotubes, which leads to oxidative stress, p38 activation and impaired muscle growth. Pharmacological blockade of fatty acid oxidation not only rescued human myotubes, but also improved muscle mass and body weight in cancer cachexia models in vivo. Therefore, fatty acid-induced oxidative stress could be targeted to prevent cancer-induced cachexia.Entities:
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Year: 2016 PMID: 27135739 DOI: 10.1038/nm.4093
Source DB: PubMed Journal: Nat Med ISSN: 1078-8956 Impact factor: 53.440