Project description:The aim of this project was to profile the proteome of mouse-derived serum in order to identify those that showed significant quantitative different proteins among leptin-deficient (db/db) mouse, the genetic non-alcoholic fatty liver disease (NAFLD) mouse model and their lean bks mouse group.

Project description:The aim of this project was to profile the proteome of mouse-derived liver in order to identify those that showed significant quantitative different proteins among leptin-deficient (db/db) mouse, the genetic non-alcoholic fatty liver disease (NAFLD) mouse model and their lean BKS mouse group.

Project description:Purpose: The purpose of present study is to characterize the Idiopathic epiretinal membrane (iERM) through phosphoproteomics to facilitate its diagnosis and treatment. Experimental design: The vitreous of 25 patients with iERM and 15 patients with idiopathic macular hole were analyzed by proteomic and phosphoproteomic analysis based on tandem mass tag. PRM was used to verify differential proteins. Results: Proteomic analysis identified a total of 878 proteins, including 50 differential proteins. Phosphoproteomic analysis identified a total of 401 phosphorylation sites on 213 proteins, including 27 differential phosphorylation sites on 24 proteins. Twenty six proteins of these differential proteins and phosphorylated proteins may be closely related to fibrosis in iERM. MAPKAPK3 and MAPKAPK5 are predicted as the major kinases in vitreous of iERM. Conclusion and clinical relevance: Our results screened candidate proteins for the treatment of fibrosis in iERM, among which tenascin-C, galectin-3-binding protein, glucose-6-phosphate isomerase, neuroserpin, collagen alpha-1(XI) chain and collagen alpha-1(II) chain are expected to become potential biomarkers or therapeutic targets for iERM. In addition, this article expand the data of vitreous phosphoproteome, and provide a reference resource and new enlightenment for studying the pathogenic mechanisms of retinal diseases.

Project description:We used label-free based mass spectrometry-based quantitative proteomics to quantify dynamic changes of protein acetylation between gliomas with seizure (CA1 group) and gliomas without seizure (CA2 group).We further classified acetylated proteins into groups according to cell component, molecular function and biological process. In addition, metabolic pathways and protein interaction networks were analyzed.

Project description:Long term chest blast exposure can lead to mental disorders, brain inflammation and oxidative stress in soldiers. However, the underlying mechanism of brain injury caused indirectly by chest blast remains unclear. It is urgent to find more potential biomarkers to reveal the deeper pathogenesis of this phenomenon. We used iTRAQ labeling combined with LC-MS/MS to screen potential differentially expressed proteins in rat brain after chest blast at different time points. Meanwhile, we also used Go, KEGG, David and Cytoscape to analyze the proteomic profile and explore its pathogenesis. Moreover, Western blotting was used to verify the target proteins. Our data showed that, a total of 6,931 proteins were identified. A total of 255 differentially expressed proteins were identified, of which 43, 84, 52, 97 and 49 proteins were identified from brain tissues at 12h, 24h, 48h, 72h, and 1w after chest blast exposure. Bioinformatics analysis, including GO, COG, KEGG and STRING, further proved that brain damage caused by chest blast exposure was involved in many important biological processes and signal pathways, such as inflammation, cell adhesion, phagocytosis, neuronal and synaptic damage, oxidative stress and apoptosis. Moreover, Western blotting further confirmed that these differentially expressed proteins and signaling pathways were associated with brain damage caused by chest blast exposure. For the first time, we screened and verified the potential protein biomarkers of brain damage caused indirectly by chest blast, and provided a new target for the treatment of this disease.

Project description:Hemorrhagic transformation (HT), which occurs with or without reperfusion treatments (thrombolysis and/or thrombectomy), deteriorates the outcomes of ischemic stroke patients. It is essential to find clinically reliable biomarkers that can predict HT. In this study, we screened for potential serum biomarkers from an existing blood bank and database with 243 suspected acute ischemic stroke (AIS) patients. A total of 37 patients were enrolled, who were diagnosed as AIS but did not receive reperfusion treatment. They were divided into two groups based on whether they accompanied with HT or not (5 HT and 32 non-HT). Serum samples were labeled by isobaric tags for relative and absolute quantitation (iTRAQ) and analyzed by liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS) and compared under NCBInr database. A total of 647 proteins in sera samples were captured and the levels of 17 proteins (12 up-regulated and 5 down-regulated) were significantly different. These differentially expressed proteins were further categorized with Gene Ontology functional classification annotation and Kyoto Encyclopedia of Genes and Genomes metabolic pathway analysis into biological processes. Further protein-protein interaction analysis using String database discovered that, among the differential expressed proteins, 10 pairs of proteins were found to have crosstalk connections, which may have direct (physical) and indirect (functional) interactions for the development of HT. Our findings suggest that these differentially expressed proteins could serve as potential biomarkers for predicting HT after ischemic stroke.

Project description:HUVECs of ischemia for 3 h, ischemia for 3 h/reperfusion for 24 h, and control group for 3 h were collected to identify respiratory and metabolic status under lethal ischemic condition. The results showed that HUVECs depend on ischemic TCA cycle rather than glycolysis to keep cells alive under lethal ischemia condition.

Project description:Quantitative acetyl-proteomics, a newly identified post-translational modification, is known to regulate transcriptional activity in different organisms. Neurospora crassa is a model ascomycete fungus maintained for biochemistry and molecular biology research; however, extensive studies of the functions of its acylation proteins have yet to be performed. In this study, using LC-MS/MS qualitative proteomics strategies, we identified 1909 modification sites on 940 proteins in N. crassa and analysed the functions of these proteins using GO enrichment, KEGG pathway, and subcellular location experiments. We classified the acetylation protein involvement in diverse pathways, and protein-protein interaction (PPI) network analysis further demonstrated that these proteins participate in diverse biological processes. In summary, our study comprehensively profiles the crosstalk of modified sites, and PPI among these proteins may form a complex network with both similar and distinct regulatory mechanisms, providing improved understanding of their biological functions in N. crassa.

Project description:Low-oxygen stress associated with natural phenomena such as waterlogging, results in widespread transcriptome changes and a metabolic switch from aerobic respiration to anaerobic fermentation. High-throughput sequencing of small RNA libraries obtained from low-oxygen stressed and control root tissue identified a total of 65 unique microRNA (miRNA) sequences from 46 families, and 14 trans-acting small interfering RNA (tasiRNA) from 3 families. Low-oxygen stress resulted in changes to the abundance of 46 miRNAs from 19 families, and all 3 tasiRNA families. Chemical inhibition of mitochondrial respiration caused similar changes in expression in a majority of the low-oxygen responsive small RNAs analysed. Our data indicate that miRNAs and tasiRNAs play a role in gene regulation and possibly developmental responses to low oxygen, and that a major signal for these responses is likely to be dependent on mitochondrial function. Keywords: Small RNA transcriptome analysis Examination of root tissue under 2 different environments, control and low oxygen

Project description:Background: Sanghuangporus sanghuang is a well-known traditional medicinal mushroom associated with mulberry, which has enormous economic and medical value. Despite being known for many years, the regulatory mechanisms of bioactive compounds biosynthesis in this medicinal mushroom are still unclear.Lysine malonylation is one of a post-translational modifications that has many critical functions in various aspects of cell metabolism. However, at present we do not know its role in S. sanghuang. In this study, a global investigation of lysine malonylome in S. sanghuang was therefore carried out. Results: In total, 714 malonyl modification sites were matched to 255 different proteins. The analysis indicated that malonyl modifications were involved in a wide range of acellular functions and displayed a distinct subcellular localization. Bioinformatics analysis indicated that malonylated proteins were engaged in different metabolic pathways, including glyoxylate and dicarboxylate metabolism, glycolysis/gluconeogenesis, and the tricarboxylic acid (TCA) cycle. Notably, a total of 26 enzymes related to triterpene and polysaccharide biosynthesis were found to be malonylated, indicating an indispensable role of lysine malonylation in bioactive compounds biosynthesis in S. sanghuang. Conclusions: These findings suggest that malonylation is associated with many metabolic pathways, particularly the metabolism of bioactive compounds triterpene and polysaccharide. This paper represents the first comprehensive survey of malonylation in S. sanghuang and provides an important data for further study on the physiological function of lysine malonylation in S. sanghuang and other medicinal mushrooms.