|
|||||
|
|
In-depth Profiling and Quantification of the Lysine Acetylome in Hepatocellular Carcinoma with a Trapped Ion Mobility Mass Spectrometer |
|
| Authors: | Jia Xu Xinyu Guan Xiaodong Jia Hongyan Li Ruibing Chen Yinying Lu |
| Affiliation: | 1. School of Pharmaceutical Science and Technology, Tianjin University, Tianjin, China;2. Department of Hepatology, Comprehensive Liver Cancer Center, The Fifth Medical Center of General Hospital of PLA, Beijing, China;3. General surgery Department, Xuanwu Hospital, National Clinical Research Center for Geriatric Diseases, Beijing, China;4. Guangdong Key Laboratory of Epigenetics, College of Life Sciences and Oceanography, Shenzhen University, Shenzhen, Guangdong, China |
| Abstract: | Hepatocellular carcinoma (HCC) is the third most common cause of cancer-related death worldwide with limited therapeutic options. Comprehensive investigation of protein posttranslational modifications in HCC is still limited. Lysine acetylation is one of the most common types of posttranslational modification involved in many cellular processes and plays crucial roles in the regulation of cancer. In this study, we analyzed the proteome and K-acetylome in eight pairs of HCC tumors and normal adjacent tissues using a timsTOF Pro instrument. As a result, we identified 9219 K-acetylation sites in 2625 proteins, of which 1003 sites exhibited differential acetylation levels between tumors and normal adjacent tissues. Interestingly, many novel tumor-specific K-acetylation sites were characterized, for example, filamin A (K865), filamin B (K697), and cofilin (K19), suggesting altered activities of these cytoskeleton-modulating molecules, which may contribute to tumor metastasis. In addition, we observed an overall suppression of protein K-acetylation in HCC tumors, especially for enzymes from various metabolic pathways, for example, glycolysis, tricarboxylic acid cycle, and fatty acid metabolism. Moreover, the expression of deacetylase sirtuin 2 (SIRT2) was upregulated in HCC tumors, and its role of deacetylation in HCC cells was further explored by examining the impact of SIRT2 overexpression on the proteome and K-acetylome in Huh7 HCC cells. SIRT2 overexpression reduced K-acetylation of proteins involved in a wide range of cellular processes, including energy metabolism. Furthermore, cellular assays showed that overexpression of SIRT2 in HCC cells inhibited both glycolysis and oxidative phosphorylation. Taken together, our findings provide valuable information to better understand the roles of K-acetylation in HCC and to treat this disease by correcting the aberrant acetylation patterns. |
| Keywords: | acetyl-proteomics cellular metabolism hepatocellular carcinoma nonhistone PASEF proteomics SIRT2 timsTOF Pro 2-DG"} {"#name":"keyword" "$":{"id":"kwrd0055"} "$$":[{"#name":"text" "_":"2-deoxy-glucose ACN"} {"#name":"keyword" "$":{"id":"kwrd0065"} "$$":[{"#name":"text" "_":"acetonitrile CC"} {"#name":"keyword" "$":{"id":"kwrd0075"} "$$":[{"#name":"text" "_":"cellular component ECAR"} {"#name":"keyword" "$":{"id":"kwrd0085"} "$$":[{"#name":"text" "_":"extracellular acidification rate FA"} {"#name":"keyword" "$":{"id":"kwrd0095"} "$$":[{"#name":"text" "_":"formic acid FASN"} {"#name":"keyword" "$":{"id":"kwrd0105"} "$$":[{"#name":"text" "_":"fatty acid synthase FC"} {"#name":"keyword" "$":{"id":"kwrd0115"} "$$":[{"#name":"text" "_":"fold change FCCP"} {"#name":"keyword" "$":{"id":"kwrd0125"} "$$":[{"#name":"text" "_":"carbonyl cyanide 4-trifluoromethoxyphenylhydrazone GO"} {"#name":"keyword" "$":{"id":"kwrd0135"} "$$":[{"#name":"text" "_":"gene ontology GPI"} {"#name":"keyword" "$":{"id":"kwrd0145"} "$$":[{"#name":"text" "_":"glucose-6-phosphate isomerase HCC"} {"#name":"keyword" "$":{"id":"kwrd0155"} "$$":[{"#name":"text" "_":"hepatocellular carcinoma KDAC"} {"#name":"keyword" "$":{"id":"kwrd0165"} "$$":[{"#name":"text" "_":"lysine deacetylase MDH2"} {"#name":"keyword" "$":{"id":"kwrd0175"} "$$":[{"#name":"text" "_":"malate dehydrogenase NAM"} {"#name":"keyword" "$":{"id":"kwrd0185"} "$$":[{"#name":"text" "_":"Nicotinamide NAT"} {"#name":"keyword" "$":{"id":"kwrd0195"} "$$":[{"#name":"text" "_":"normal adjacent tissue OCR"} {"#name":"keyword" "$":{"id":"kwrd0205"} "$$":[{"#name":"text" "_":"oxygen consumption rate PASEF"} {"#name":"keyword" "$":{"id":"kwrd0215"} "$$":[{"#name":"text" "_":"parallel accumulation serial fragmentation PCA"} {"#name":"keyword" "$":{"id":"kwrd0225"} "$$":[{"#name":"text" "_":"principal component analysis PGK1"} {"#name":"keyword" "$":{"id":"kwrd0235"} "$$":[{"#name":"text" "_":"phosphoglycerate kinase PTM"} {"#name":"keyword" "$":{"id":"kwrd0245"} "$$":[{"#name":"text" "_":"posttranslational modification R/A"} {"#name":"keyword" "$":{"id":"kwrd0255"} "$$":[{"#name":"text" "_":"rotenone/antimycin A TCA"} {"#name":"keyword" "$":{"id":"kwrd0265"} "$$":[{"#name":"text" "_":"trichloroacetic acid TIMS"} {"#name":"keyword" "$":{"id":"kwrd0275"} "$$":[{"#name":"text" "_":"trapped ion mobility spectrometry TSA"} {"#name":"keyword" "$":{"id":"kwrd0285"} "$$":[{"#name":"text" "_":"Trichostatin A |
| 本文献已被 ScienceDirect 等数据库收录! | |
