Chemical proteomics reveals new targets of cysteine sulfinic acid reductase

Akter, Salma; Fu, Ling; Jung, Young-Eun; Conte, Mauro Lo; Lawson, J. Reed; Lowther, W. Todd; Sun, Rui; Liu, Keke; Yang, Jing; Carroll, Kate S.

doi:10.1038/s41589-018-0116-2

Cited by 195 publications

(215 citation statements)

References 59 publications

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“…Therefore, the potential implications of these new redox PTMs in histones specially, in histone H3, should be investigated in the near future. Further, other oxidative modifications of the Cys residues (Cys96 and Cys110) of histone H3 such as (S-sulfhydryl persulfide, sulfonamide, sulfonamide, thiosulfinate, or thiosulfate), 59 which account in other proteins should be explored not only by their ability to change the redox state of the thiol group but also by their biological implication in the secondary structure of histone H3 and the quaternary structure of the nucleosome.…”

Section: Resultsmentioning

confidence: 99%

“…Lee et al described the susceptibility to form sulfenic, sulfinic, and sulfonic acids in Cys96 and Cys110 in the histone variant H3.1, and the formation of sulfonic acid in Cys110 in the histone variant H3.2 in HEK293T cells after oxidative stress . Importantly, Atker et al revealed a striking difference between S‐sulfenylation and S‐sulfinylation dynamic response to oxidative stress, therefore suggesting different roles for these OxiPTMs in redox regulation and signaling . Particularly, S‐sulfinylated proteins appear enriched in diverse biological processes and cellular pathways, including oxidation–reduction, cell–cell adhesion, RNA processing, glycolysis, fatty acids beta‐oxidation, and importantly, protein import into the nucleus .…”

Section: Redox Post‐translational Modifications In Histonesmentioning

confidence: 99%

“…59 Particularly, S-sulfinylated proteins appear enriched in diverse biological processes and cellular pathways, including oxidation-reduction, cell-cell adhesion, RNA processing, glycolysis, fatty acids beta-oxidation, and importantly, protein import into the nucleus. 59 This is of special relevance, since it was proposed that histone H3 is transported to the nucleus and positioned at specific chromatin regions by chaperones which recognize the Cys residues of histone H3 variants. 60 For example, the histone cell cycle regulator (HIRA), a histone chaperone, recognizes H3.3; and CAF-1 (chromatin assembly factor-1), another histone chaperone, binds to H3.1.…”

Section: Histone H3 Sulfe- Sulfi- and Sulfonylationmentioning

confidence: 99%

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Oxidative post‐translational modifications in histones

2019

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Epigenetic regulation is attracting much attention because it explains many of the effects that the external environment induces in organisms. Changes in the cellular redox status and even more specifically in its nuclear redox compartment is one of these examples. Redox changes can induce modulation of the epigenetic regulation in cells. Here we present a few cases where reactive oxygen or nitrogen species induces epigenetic marks in histones. Posttranslational modification of these proteins like histone nitrosylation, carbonylation, or glutathionylation together with other mechanisms not reviewed here are the cornerstones of redox‐related epigenetic regulation. We currently face a new field of research with potential important consequences for the treatment of many pathologies.

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Section: Resultsmentioning

confidence: 99%

Section: Redox Post‐translational Modifications In Histonesmentioning

confidence: 99%

Section: Histone H3 Sulfe- Sulfi- and Sulfonylationmentioning

confidence: 99%

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Oxidative post‐translational modifications in histones

2019

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“…Recent proteomics experiments have demonstrated that a significant number of proteins exhibit reversible formation of cysteine sulfinic acids, indicating that cysteine sulfinic acid is a widely distributed protein posttranslational modification responsive to oxidative conditions or signaling . Oxidation of cysteine to the sulfinic acid can induce activating or inhibiting functional changes to proteins .…”

Section: Introductionmentioning

confidence: 99%

“…Given the broad range of proteins whose functions might be regulated by Cys oxidation to the sulfinic acid, we and others have sought to develop new ways to interrogate this oxidation state of cysteine. Recently, a number of molecular probes that react specifically with Cys sulfinic acid have been developed . These bioconjugation reagents take advantage of the nucleophilic character of Cys sulfinic acid.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of peptides with cysteine sulfinic acid via the cysteine methoxybenzyl sulfone

Urmey

Zondlo

2019

Peptide Science

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Cysteine sulfinic acid is a protein posttranslational modification that is formed under oxidative conditions and is regulated both enzymatically and nonenzymatically. Cysteine oxidation to the sulfinic acid has been observed broadly throughout the proteome and can induce activation or inhibition of function in proteins. Recently, wide‐scale, reversible regulation of the sulfinic acid state of cysteine within proteins was identified, posing new questions in cysteine sulfinic acid biology. Existing methods to synthesize peptides with cysteine sulfinic acid can suffer from low yield, due to the formation of side products in the disulfide, sulfenic acid, and/or sulfonic acid oxidation states. Herein, a method for the synthesis of peptides with cysteine sulfinic acids was developed, via protection of cysteine sulfinic acid as the methoxybenzyl (Mob) sulfone. Cysteine Mob sulfone was synthesized as an Fmoc amino acid in one step from the commercially available Mob‐protected Fmoc‐cysteine (Fmoc‐Cys(Mob)‐OH). This amino acid was directly incorporated into peptides via solid‐phase peptide synthesis. Alternatively, peptides were synthesized using Fmoc‐Cys(Mob)‐OH, followed by subsequent oxidation within peptides of the thioether to the Mob sulfone via H2O2 and catalytic niobium carbide. Deprotection of peptides under strongly acidic conditions (50% triflic acid, 45% trifluoroacetic acid, 5% water) generated peptides with cysteine sulfinic acid. This approach was applied to the synthesis of peptides containing cysteine sulfinic acid within diverse peptide sequence contexts.

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Chemical Tagging of Protein Lipoylation

et al. 2020

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Protein lipoylation is a post‐translational modification of emerging importance in both prokaryotes and eukaryotes. However, labeling and large‐scale profiling of protein lipoylation remain challenging. Here, we report the development of iLCL (iodoacetamide‐assisted lipoate‐cyclooctyne ligation), a chemoselective reaction that enables chemical tagging of protein lipoylation. We demonstrate that the cyclic disulfide of lipoamide but not linear disulfides can selectively react with iodoacetamide to produce sulfenic acid, which can be conjugated with cyclooctyne probes. iLCL enables tagging of lipoylated proteins for gel‐based detection and cellular imaging. Furthermore, we apply iLCL for proteomic profiling of lipoylated proteins in both bacteria and mammalian cells. In addition to all of the eight known lipoylated proteins, we identified seven candidates for novel lipoylated proteins. The iLCL strategy should facilitate uncovering the biological function of protein lipoylation.

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Chemical proteomics reveals new targets of cysteine sulfinic acid reductase

Cited by 195 publications

References 59 publications

Oxidative post‐translational modifications in histones

Oxidative post‐translational modifications in histones

Synthesis of peptides with cysteine sulfinic acid via the cysteine methoxybenzyl sulfone

Chemical Tagging of Protein Lipoylation

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