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FAT-switch-based quantitative S-nitrosoproteomics reveals a key role of GSNOR1 in regulating ER functions

Guochen Qin, Menghuan Qu, Bei Jia, Wei Wang, Zhuojun Luo, Chun‐Peng Song, W. Andy Tao, Pengcheng Wang

2023Nature Communications26 citationsDOIOpen Access PDF

Abstract

Reversible protein S-nitrosylation regulates a wide range of biological functions and physiological activities in plants. However, it is challenging to quantitively determine the S-nitrosylation targets and dynamics in vivo. In this study, we develop a highly sensitive and efficient fluorous affinity tag-switch (FAT-switch) chemical proteomics approach for S-nitrosylation peptide enrichment and detection. We quantitatively compare the global S-nitrosylation profiles in wild-type Arabidopsis and gsnor1/hot5/par2 mutant using this approach, and identify 2,121 S-nitrosylation peptides in 1,595 protein groups, including many previously unrevealed S-nitrosylated proteins. These are 408 S-nitrosylated sites in 360 protein groups showing an accumulation in hot5-4 mutant when compared to wild type. Biochemical and genetic validation reveal that S-nitrosylation at Cys337 in ER OXIDOREDUCTASE 1 (ERO1) causes the rearrangement of disulfide, resulting in enhanced ERO1 activity. This study offers a powerful and applicable tool for S-nitrosylation research, which provides valuable resources for studies on S-nitrosylation-regulated ER functions in plants.

Topics & Concepts

S-NitrosylationMutantArabidopsis thalianaArabidopsisCell biologyNitrosylationPeptideComputational biologyProteomicsChemistryWild typeBiologyCysteineBiochemistryGeneEnzymeNitric oxideOrganic chemistryRedox biology and oxidative stressNitric Oxide and Endothelin EffectsPolyamine Metabolism and Applications
FAT-switch-based quantitative S-nitrosoproteomics reveals a key role of GSNOR1 in regulating ER functions | Litcius