Quantification of cysteinyl S-nitrosylation by fluorescence in unbiased proteomic studies

Keyphrases

• Proteomic Study 100%
• S-nitrosylation 100%
• Unbiased Proteomics 100%
• Electrophoretic Mobility 40%
• Antimicrobial 40%
• Hypoxia-ischemia 40%
• S-nitrosylated Proteins 40%
• Cell Development 20%
• Apoptosis 20%
• Physiologic 20%
• Functional Analysis 20%
• Host Response 20%
• Neurogenesis 20%
• Post-translational Modification 20%
• Protein Function 20%
• Glia 20%
• Ischemia-reperfusion Injury 20%
• Axon 20%
• Change of Measure 20%
• Neurite 20%
• Ingenuity Pathway Analysis 20%
• Protein Abundance 20%
• Cortical Neurons 20%
• S-nitrosoglutathione 20%
• Calcium Signaling 20%
• Biological Applications 20%
• Stress-responsive 20%
• Cysteine S-nitrosylation 20%
• Altered Proteins 20%
• In Vivo Rat 20%
• Abundance Change 20%
• Microbial Pathogens 20%
• Transnitrosation 20%
• Fibrillar Proteins 20%
• Developmental Networks 20%
• Branching Morphogenesis 20%
• Nervous System Development 20%
• Sample Loss 20%
• Ischemia-reperfusion Model 20%

Neuroscience

• Neurogenesis 100%
• Proteomics 100%
• In Vivo 50%
• Posttranslational Modification 50%
• Glia 50%
• Reperfusion Injury 50%
• Neurite 50%
• Axon 50%
• Cysteine 50%
• S Nitrosoglutathione 50%
• Calcium Signaling 50%
• Protein Function 50%
• Cell Maturation 50%
• Ischemia 50%
• Morphogenesis 50%

Biochemistry, Genetics and Molecular Biology

• Proteomics 100%
• S-Nitrosylation 100%
• Nervous System Development 33%
• Reperfusion 33%
• Electrophoretic Mobility 33%
• Infectious Agent 16%
• Posttranslational Modification 16%
• Protein Function 16%
• Cell Maturation 16%
• Immune Response 16%
• Axon 16%
• S-Nitrosoglutathione 16%
• Branching Morphogenesis 16%
• Calcium Signaling 16%
• Cysteine 16%