A simple isotopic labeling method to study cysteine oxidation in Alzheimer’s disease: oxidized cysteine-selective dimethylation (OxcysDML)

Gu, Liqing; Robinson, Renã A. S.

doi:10.1007/s00216-016-9307-4

Cited by 15 publications

(19 citation statements)

References 56 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For example, in a redox proteomic study using duplex ICAT reagents, because there are no more channels available for protein quantification, a separate experiment using isotopic dimethyl labeling is employed to provide protein abundance data 48 . Even in our OxcysDML approach, two experiments were performed to obtain total cysteine oxidation levels and protein abundance information based on cysteine-containing peptides 27 . Two, there is a large difference (roughly two to three orders of magnitude 49 ) between total peptide and SNO-modified peptide abundance.…”

Section: Resultsmentioning

confidence: 99%

“…Isobaric tagging methods such as iodoTMT, TMT, or the inclusion of iTRAQ 22 allow greater sample multiplexing capabilities (i.e., up to eight samples can be analyzed simultaneously). We recently developed a simple, straightforward, and robust approach to measure oxidized cysteine in global proteome experiments, through coupling on-resin capture of cysteines and isotopic dimethylation reactions 27 . This approach, called OxcysDML, could be readily modified to study SNO by exchanging the dithiothreitol reducing agent with ascorbate.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

High-throughput endogenous measurement of S-nitrosylation in Alzheimer's disease using oxidized cysteine-selective cPILOT

Robinson

2016

Analyst

Self Cite

View full text Add to dashboard Cite

Reversible cysteine modifications play important physiological roles such as modulating enzymatic catalysis, maintaining redox homeostasis and conducting cellular signaling. These roles can be critical in the context of disease. Oxidative modifications such as S-nitrosylation (SNO) are signatures of neurodestruction in conditions of oxidative stress however are also indicators of neuroprotection and normal signaling in cellular environments with low concentrations of reactive oxygen and nitrogen species. SNO is a dynamic and low abundance modification and requires sensitive and selective analytical methods for its detection in biological tissues. Here we present an enhanced multiplexing strategy to study SNO in complex mixtures arising from tissues. This method, termed oxidized cysteine-selective cPILOT (OxcyscPILOT), allows simultaneous analysis of SNO-modified peptides in 12 samples. OxcyscPILOT has three primary steps: (1) blocking of free thiols by a cysteine-reactive reagent, (2) enrichment of peptides containing SNO on a solid phase resin, and (3) isotopic labeling and isobaric tagging of enriched peptides on the solid phase resin. This approach offers the advantage of allowing total protein abundance levels to be measured simultaneously with endogenous SNO levels and measurement of SNO levels across four biological replicates in a single analysis. Furthermore, the relative amount of SNO on a specific cysteine site can also be determined. A well-known model of Alzheimer’s disease, the APP/PS-1 transgenic mouse model, was selected for demonstration of the method as several SNO-modified proteins have previously been reported in brain and synaptosomes from AD subjects. OxcyscPILOT analysis resulted in identification of 138 SNO-modified cysteines in brain homogenates that corresponds to 135 proteins. Many of these SNO-modified proteins were only present in wild-type or AD mice, whereas 93 proteins had SNO signals in both WT and AD. Pathway analysis links SNO-modified proteins to various biological pathways especially metabolism and signal transduction, consistent with previous reports in the literature. The OxcyscPILOT strategy provides enhanced multiplexing capability to current redox proteomics methods to study oxidative modifications of cysteine.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

High-throughput endogenous measurement of S-nitrosylation in Alzheimer's disease using oxidized cysteine-selective cPILOT

Robinson

2016

Analyst

Self Cite

View full text Add to dashboard Cite

show abstract

“…To date, numerous approaches have been developed and applied in biological studies, e.g. oxidized isotopecoded affinity tag [37], oxidized isobaric tag for relative and absolute quantitation [45], SNO analysis by resin-assisted capture [36], oxidized multiple reaction monitoring [40], cysteine tandem mass tags and isobaric tag for relative and absolute quantification [48], and two approaches developed by our laboratory: oxidized cysteine-selective dimethylation (OxcysDML) [76] and oxidized cysteine-selective cPILOT (OxcyscPILOT) [77]. Compared with global protein quantification, more variables have to be considered for cysteine redox quantification, such as the modification type investigated, the number of sample multiplexing channels required, the incorporation of chemical mass tags, the enrichment method, amount of starting material, and method for stoichiometric quantitation.…”

Section: Redox Proteomic Approaches To Quantify Cysteine Reversible Mmentioning

confidence: 99%

“…This simple method is suitable for comparing cysteine modifications from two samples with desirable proteome coverage, and can reach up to 5-plex comparison using other formaldehyde/cyanoborohydride isotopomers [96]. Ox-cysDML has been applied to study the redox proteome of liver tissues from an AD mouse model [76], as discussed below.…”

Section: Thiol-affinity Solid Phase Resinmentioning

confidence: 99%

See 1 more Smart Citation

Proteomic approaches to quantify cysteine reversible modifications in aging and neurodegenerative diseases

Robinson

2016

Proteomics Clinical Apps

Self Cite

View full text Add to dashboard Cite

Cysteine is a highly reactive amino acid and is subject to a variety of reversible post-translational modifications (PTMs), including nitrosylation, glutathionylation, palmitoylation, as well as formation of sulfenic acid and disulfides. These modifications are not only involved in normal biological activities, such as enzymatic catalysis, redox signaling and cellular homeostasis, but can also be the result of oxidative damage. Especially in aging and neurodegenerative diseases, oxidative stress leads to aberrant cysteine oxidations that affect protein structure and function leading to neurodegeneration as well as other detrimental effects. Methods that can identify cysteine modifications by type, including the site of modification, as well as the relative stoichiometry of the modification can be very helpful for understanding the role of the thiol proteome and redox homeostasis in the context of disease. Cysteine reversible modifications however, are challenging to investigate as they are low abundant, diverse, and labile especially under endogenous conditions. Thanks to the development of redox proteomic approaches, large-scale quantification of cysteine reversible modifications is possible. These approaches cover a range of strategies to enrich, identify, and quantify cysteine reversible modifications from biological samples. This review will focus on nongel-based redox proteomics workflows that give quantitative information about cysteine PTMs and highlight how these strategies have been useful for investigating the redox thiol proteome in aging and neurodegenerative diseases.

show abstract

Investigating protein thiol chemistry associated with dehydroascorbate, homocysteine and glutathione using mass spectrometry

Ahuie

Gagnon

Pace

et al. 2020

Rapid Comm Mass Spectrometry

View full text Add to dashboard Cite

Rationale:Oxidative stress is an imbalance between reactive free radical oxygen species and antioxidant defenses. Its consequences can lead to numerous pathologies. Regulating oxidative stress is the complex interplay between antioxidant recycling and thiol-containing regulatory proteins. Understanding these regulatory mechanisms is important for preventing onset of oxidative stress. The aim of this study was to investigate S-thiol protein chemistry associated with oxidized vitamin C (dehydroascorbate, DHA), homocysteine (HcySH) and glutathione (GSH) using mass spectrometry. Methods:Glutaredoxin-1 (Grx-1) was incubated with DHA, with and without GSH and HcySH. Disulfide formation was followed by electrospray ionization mass spectrometry (ESI-MS) of intact proteins and by LC/ESI-MS/MS of peptides from protein tryptic digestions. The mechanism of DHA-mediated S-thiolation was investigated using two synthetic peptides: AcFHACAAK and AcFHACE. Three proteins, i.e. human hemoglobin (HHb), recombinant peroxiredoxin 2 (Prdx2) andGrx-1, were S-homocysteinylated followed by S-transthiolyation with GSH and investigated by ESI-MS and ESI-MS/MS. Results: ESI-MS analysis reveals that DHA mediates disulfide formation andS-thiolation by HcySH as well as GSH of Grx-1. LC/ESI-MS/MS analysis allows identification of Grx-1 S-thiolated cysteine adducts. The mechanism by which DHA mediates S-thiolation of heptapeptide AcFHACAAK is shown to be via initial formation of a thiohemiketal adduct. In addition, ESI-MS of intact proteins shows that GSH can S-transthiolate S-homocysteinylated Grx-1, HHb and Prdx2.The GS-S-protein adducts over time dominate the ESI-MS spectrum profile. Conclusions:Mass spectrometry is a unique analytical technique for probing complex reaction mechanisms associated with oxidative stress. Using model proteins, ESI-MS reveals the mechanism of DHA-facilitated S-thiolation, which consists of thiohemiketal formation, disulfide formation or S-thiolation. Furthermore, protein S-thiolation by HcySH can be reversed by reversible GSH thiol exchange. The use of mass spectrometry with in vitro models of protein S-thiolation in oxidative stress may provide significant insight into possible mechanisms of action occurring in vivo.

show abstract

A simple isotopic labeling method to study cysteine oxidation in Alzheimer’s disease: oxidized cysteine-selective dimethylation (OxcysDML)

Cited by 15 publications

References 56 publications

High-throughput endogenous measurement of S-nitrosylation in Alzheimer's disease using oxidized cysteine-selective cPILOT

High-throughput endogenous measurement of S-nitrosylation in Alzheimer's disease using oxidized cysteine-selective cPILOT

Proteomic approaches to quantify cysteine reversible modifications in aging and neurodegenerative diseases

Investigating protein thiol chemistry associated with dehydroascorbate, homocysteine and glutathione using mass spectrometry

Contact Info

Product

Resources

About