Redox Proteomics Uncovers Peroxynitrite-sensitive Proteins That Help Escherichia coli to Overcome Nitrosative Stress

Claudia Lindemann,Nataliya Lupilova,Alexandra Müller,Bettina Warscheid,Helmut E Meyer,Katja Kuhlmann,Martin Eisenacher,Lars I Leichert

doi:10.1074/jbc.m113.457556

Claudia Lindemann, Nataliya Lupilova + Show 6 more

Open Access

https://doi.org/10.1074/jbc.m113.457556

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Abstract

Peroxynitrite is a highly reactive chemical species with antibacterial properties that are synthesized in immune cells. In a proteomic approach, we identified specific target proteins of peroxynitrite-induced modifications in Escherichia coli. Although peroxynitrite caused a fairly indiscriminate nitration of tyrosine residues, reversible modifications of protein thiols were highly specific. We used a quantitative redox proteomic method based on isotope-coded affinity tag chemistry and identified four proteins consistently thiol-modified in cells treated with peroxynitrite as follows: AsnB, FrmA, MaeB, and RidA. All four were required for peroxynitrite stress tolerance in vivo. Three of the identified proteins were modified at highly conserved cysteines, and MaeB and FrmA are known to be directly involved in the oxidative and nitrosative stress response in E. coli. In in vitro studies, we could show that the activity of RidA, a recently discovered enamine/imine deaminase, is regulated in a specific manner by the modification of its single conserved cysteine. Mutation of this cysteine 107 to serine generated a constitutively active protein that was not susceptible to peroxynitrite.

Highlights

Oxidative thiol modifications are thought to be one of the major effects of peroxynitrite on proteins
We used a quantitative redox proteomic method based on isotope-coded affinity tag chemistry and identified four proteins consistently thiol-modified in cells treated with peroxynitrite as follows: AsnB, FrmA, MaeB, and RidA
Peroxynitrite Nitrosates Tyrosine Residues in E. coli Proteins— To analyze the molecular cause of the growth stop, we focused on specific protein modifications

Summary

Background

Oxidative thiol modifications are thought to be one of the major effects of peroxynitrite on proteins. We could show that the activity of RidA, a recently discovered enamine/imine deaminase, is regulated in a specific manner by the modification of its single conserved cysteine. Mutation of this cysteine 107 to serine generated a constitutively active protein that was not susceptible to peroxynitrite. RidA was recently discovered to act as enamine/imine deaminase [15] and has not yet been implicated in nitrosative stress It contains a single cysteine (Cys-107) that is conserved in many species. Cys-107 is not directly involved in the catalytic function of RidA, and a mutation to serine results in a fully active but “redox-dead” enzyme

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DISCUSSION