Yu Wang Chang scite author profile

In an effort to identify tumor-associated proteins from plasma of tumor-bearing mice that may be used as diagnostic biomarkers, we developed a strategy that combines a tumor xenotransplantation model in nude mice with comparative proteomic technology. Five human cancer cell lines (SC-M1, HONE-1, CC-M1, OECM1, GBM 8401) derived from stomach, nasopharyngeal, colon, oral and brain cancers were subcutaneously inoculated into nude mice and compared to control nude mice injected with phosphate-buffered saline. One month later, plasma from mice inoculated with cancer cells was collected for proteomic analysis using two-dimensional gel electrophoresis (2-DE) and mass spectrometry (MS). Comparison of plasma 2-DE maps from tumor-bearing mice with those produced from control mice revealed the overexpression of several mouse acute phase proteins (APPs) such as haptoglobin. Another APP, serum amyloid A (SAA), was found only in mice bearing tumors induced by the stomach cancer cell line SC-M1, which has not previously been demonstrated in xenotransplatation experiment. Furthermore, by using immunohistochemistry, SAA and haptoglobin were found to originate from the mouse hosts and not from the human cancer cell line donors. The protein alterations were further confirmed on patients with stomach cancers where up-regulated levels of SAA were also observed. These results indicate that APPs may be used as nonspecific tumor-associated serum markers. SAA in particular may serve as a potential marker for detecting stomach cancer. Taken together, the combination of the xenotransplatation model in nude mice and proteomics analysis provided a valuable impact for clinical applications in cancer diagnostics. In addition, our findings demonstrate that a panel of APPs might serve as screening biomarkers for early cancer detection.

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Quantitative Phosphoproteomic Study of Pressure-Overloaded Mouse Heart Reveals Dynamin-Related Protein 1 as a Modulator of Cardiac Hypertrophy

Chang

Wang

et al. 2013

Molecular & Cellular Proteomics

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Pressure-overload stress to the heart causes pathological cardiac hypertrophy, which increases the risk of cardiac morbidity and mortality. However, the detailed signaling pathways induced by pressure overload remain unclear. Here we used phosphoproteomics to delineate signaling pathways in the myocardium responding to acute pressure overload and chronic hypertrophy in mice. Myocardial samples at 4 time points (10, 30, 60 min and 2 weeks) after transverse aortic banding (TAB) in mice underwent quantitative phosphoproteomics assay. Temporal phosphoproteomics profiles showed 360 phosphorylation sites with significant regulation after TAB. Multiple mechanical stress sensors were activated after acute pressure overload. Gene ontology analysis revealed differential phosphorylation between hearts with acute pressure overload and chronic hypertrophy. Most interestingly, analysis of the cardiac hypertrophy pathway revealed phosphorylation of the mitochondrial fission protein dynamin-related protein 1 (DRP1) by prohypertrophic kinases. Phosphorylation of DRP1 S622 was confirmed in TAB-treated mouse hearts and phenylephrine (PE)-treated rat neonatal cardiomyocytes. TAB-treated mouse hearts showed phosphorylation-mediated mitochondrial translocation of DRP1. Inhibition of DRP1 with the small-molecule inhibitor mdivi-1 reduced the TAB-induced hypertrophic responses. Mdivi-1 also prevented PE-induced hypertrophic growth and oxygen consumption in rat neonatal cardiomyocytes. We reveal the signaling responses of the heart to pressure stress in vivo and in vitro. Hypertension or acute aortic stenosis causes pressure overload in the left ventricle (LV) 1 , and prolonged pressure overload leads to pathological cardiac hypertrophy. Although beneficial initially, hypertrophy in the heart signals metabolic, structural and functional abnormalities and might lead to abnormal cardiac function (1). Patients with LV hypertrophy have increased risk of heart failure, arrhythmia and death (2, 3). Therefore, inhibition of the hypertrophic heart is proposed as a therapeutic target (1, 4). However, one of the major challenges but also the prerequisite to preventing cardiac hypertrophy is a comprehensive understanding of the mechanism to precisely prevent pathologic cardiac growth without affecting homeostasis (1).The signaling pathways leading to cardiac hypertrophy with chronic pressure overload have been extensively studied by genetic and pharmacological means (1). Proteomic and transcriptomic approaches have been used to study global changes in protein and mRNA expression in hypertrophic hearts (5-7). Acute pressure overload of the heart leads to altered myocardial energy metabolism (8 -10) and contractile function (9,11,12). However, the signaling pathways contributing to early changes in cardiomyocytes remain unclear.Protein phosphorylation allows cells to quickly respond to stimuli and transmit signals by regulating enzymatic activity, protein subcellular localization, protein interaction partners, and protein stability (13). Protein pho...

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Yu Wang Chang

Identification of tumor‐associated plasma biomarkers using proteomic techniques: From mouse to human

Quantitative Phosphoproteomic Study of Pressure-Overloaded Mouse Heart Reveals Dynamin-Related Protein 1 as a Modulator of Cardiac Hypertrophy

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