Literature DB >> 22411989

Mononuclear iron enzymes are primary targets of hydrogen peroxide stress.

Adil Anjem1, James A Imlay.   

Abstract

This study tested whether nonredox metalloenzymes are commonly charged with iron in vivo and are primary targets of oxidative stress because of it. Indeed, three sample mononuclear enzymes, peptide deformylase, threonine dehydrogenase, and cytosine deaminase, were rapidly damaged by micromolar hydrogen peroxide in vitro and in live Escherichia coli. The first two enzymes use a cysteine residue to coordinate the catalytic metal atom; it was quantitatively oxidized by the radical generated by the Fenton reaction. Because oxidized cysteine can be repaired by cellular reductants, the effect was to avoid irreversible damage to other active-site residues. Nevertheless, protracted H(2)O(2) exposure gradually inactivated these enzymes, consistent with the overoxidation of the cysteine residue to sulfinic or sulfonic forms. During H(2)O(2) stress, E. coli defended all three proteins by inducing MntH, a manganese importer, and Dps, an iron-sequestration protein. These proteins appeared to collaborate in replacing the iron atom with nonoxidizable manganese. The implication is that mononuclear metalloproteins are common targets of H(2)O(2) and that both structural and metabolic arrangements exist to protect them.

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Year:  2012        PMID: 22411989      PMCID: PMC3346116          DOI: 10.1074/jbc.M111.330365

Source DB:  PubMed          Journal:  J Biol Chem        ISSN: 0021-9258            Impact factor:   5.157


  58 in total

1.  Crystal structure of the Escherichia coli peptide deformylase.

Authors:  M K Chan; W Gong; P T Rajagopalan; B Hao; C M Tsai; D Pei
Journal:  Biochemistry       Date:  1997-11-11       Impact factor: 3.162

2.  A thiol peroxidase is an H2O2 receptor and redox-transducer in gene activation.

Authors:  Agnès Delaunay; Delphine Pflieger; Marie Bénédicte Barrault; Joelle Vinh; Michel B Toledano
Journal:  Cell       Date:  2002-11-15       Impact factor: 41.582

3.  Three-dimensional structure and catalytic mechanism of cytosine deaminase.

Authors:  Richard S Hall; Alexander A Fedorov; Chengfu Xu; Elena V Fedorov; Steven C Almo; Frank M Raushel
Journal:  Biochemistry       Date:  2011-05-12       Impact factor: 3.162

4.  Small-molecule antioxidant proteome-shields in Deinococcus radiodurans.

Authors:  Michael J Daly; Elena K Gaidamakova; Vera Y Matrosova; Juliann G Kiang; Risaku Fukumoto; Duck-Yeon Lee; Nancy B Wehr; Gabriela A Viteri; Barbara S Berlett; Rodney L Levine
Journal:  PLoS One       Date:  2010-09-03       Impact factor: 3.240

5.  Manganese and defenses against oxygen toxicity in Lactobacillus plantarum.

Authors:  F S Archibald; I Fridovich
Journal:  J Bacteriol       Date:  1981-01       Impact factor: 3.490

6.  Cytosine deaminase. The roles of divalent metal ions in catalysis.

Authors:  D J Porter; E A Austin
Journal:  J Biol Chem       Date:  1993-11-15       Impact factor: 5.157

7.  Accumulation of Mn(II) in Deinococcus radiodurans facilitates gamma-radiation resistance.

Authors:  M J Daly; E K Gaidamakova; V Y Matrosova; A Vasilenko; M Zhai; A Venkateswaran; M Hess; M V Omelchenko; H M Kostandarithes; K S Makarova; L P Wackett; J K Fredrickson; D Ghosal
Journal:  Science       Date:  2004-09-30       Impact factor: 47.728

8.  Manganese import is a key element of the OxyR response to hydrogen peroxide in Escherichia coli.

Authors:  Adil Anjem; Shery Varghese; James A Imlay
Journal:  Mol Microbiol       Date:  2009-04-21       Impact factor: 3.501

9.  The PerR transcription factor senses H2O2 by metal-catalysed histidine oxidation.

Authors:  Jin-Won Lee; John D Helmann
Journal:  Nature       Date:  2006-03-16       Impact factor: 49.962

Review 10.  Redox signaling: thiol chemistry defines which reactive oxygen and nitrogen species can act as second messengers.

Authors:  Henry Jay Forman; Jon M Fukuto; Martine Torres
Journal:  Am J Physiol Cell Physiol       Date:  2004-08       Impact factor: 4.249
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  96 in total

1.  Overlapping and complementary oxidative stress defense mechanisms in nontypeable Haemophilus influenzae.

Authors:  Alistair Harrison; Beth D Baker; Robert S Munson
Journal:  J Bacteriol       Date:  2014-11-03       Impact factor: 3.490

2.  Genome-wide analysis on Chlamydomonas reinhardtii reveals the impact of hydrogen peroxide on protein stress responses and overlap with other stress transcriptomes.

Authors:  Ian K Blaby; Crysten E Blaby-Haas; María Esther Pérez-Pérez; Stefan Schmollinger; Sorel Fitz-Gibbon; Stéphane D Lemaire; Sabeeha S Merchant
Journal:  Plant J       Date:  2015-12       Impact factor: 6.417

3.  The induction of two biosynthetic enzymes helps Escherichia coli sustain heme synthesis and activate catalase during hydrogen peroxide stress.

Authors:  Stefano Mancini; James A Imlay
Journal:  Mol Microbiol       Date:  2015-03-16       Impact factor: 3.501

4.  Intracellular hydrogen peroxide and superoxide poison 3-deoxy-D-arabinoheptulosonate 7-phosphate synthase, the first committed enzyme in the aromatic biosynthetic pathway of Escherichia coli.

Authors:  Jason M Sobota; Mianzhi Gu; James A Imlay
Journal:  J Bacteriol       Date:  2014-03-21       Impact factor: 3.490

5.  During Oxidative Stress the Clp Proteins of Escherichia coli Ensure that Iron Pools Remain Sufficient To Reactivate Oxidized Metalloenzymes.

Authors:  Ananya Sen; Yidan Zhou; James A Imlay
Journal:  J Bacteriol       Date:  2020-08-25       Impact factor: 3.490

Review 6.  Manganese uptake and streptococcal virulence.

Authors:  Bart A Eijkelkamp; Christopher A McDevitt; Todd Kitten
Journal:  Biometals       Date:  2015-02-05       Impact factor: 2.949

7.  Endogenous superoxide is a key effector of the oxygen sensitivity of a model obligate anaerobe.

Authors:  Zheng Lu; Ramakrishnan Sethu; James A Imlay
Journal:  Proc Natl Acad Sci U S A       Date:  2018-03-20       Impact factor: 11.205

8.  Improved measurements of scant hydrogen peroxide enable experiments that define its threshold of toxicity for Escherichia coli.

Authors:  Xin Li; James A Imlay
Journal:  Free Radic Biol Med       Date:  2018-03-14       Impact factor: 7.376

9.  Protection from oxidative stress relies mainly on derepression of OxyR-dependent KatB and Dps in Shewanella oneidensis.

Authors:  Yaoming Jiang; Yangyang Dong; Qixia Luo; Ning Li; Genfu Wu; Haichun Gao
Journal:  J Bacteriol       Date:  2013-11-08       Impact factor: 3.490

Review 10.  Manganese complexes: diverse metabolic routes to oxidative stress resistance in prokaryotes and yeast.

Authors:  Valeria C Culotta; Michael J Daly
Journal:  Antioxid Redox Signal       Date:  2013-02-06       Impact factor: 8.401
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