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Literature DB >> 30735836

Evolutionary adaptations that enable enzymes to tolerate oxidative stress.

James A Imlay¹, Ramakrishnan Sethu², Sanjay Kumar Rohaun².

Abstract

Biochemical mechanisms emerged and were integrated into the metabolic plan of cellular life long before molecular oxygen accumulated in the biosphere. When oxygen levels finaly rose, they threatened specific types of enzymes: those that use organic radicals as catalysts, and those that depend upon iron centers. Nature has found ways to ensure that such enzymes are still used by contemporary organisms. In some cases they are restricted to microbes that reside in anoxic habitats, but in others they manage to function inside aerobic cells. In the latter case, it is frequently true that the ancestral enzyme has been modified to fend off poisoning. In this review we survey a range of protein adaptations that permit radical-based and low-potential iron chemistry to succeed in oxic environments. In many cases, accessory domains shield the vulnerable radical or metal center from oxygen. In others, the structures of iron cofactors evolved to less oxidizable forms, or alternative metals replaced iron altogether. The overarching view is that some classes of biochemical mechanism are intrinsically incompatible with the presence of oxygen. The structural modification of target enzymes is an under-recognized response to this problem.

Entities: Chemical Disease Gene Species

Keywords: Hydrogen peroxide; Iron-sulfur clusters; Obligate anaerobiosis; Radical enzymes; Superoxide

Mesh：

Substances：
Free Radicals
Iron
Oxygen

Year: 2019 PMID： 30735836 PMCID： PMC6684875 DOI： 10.1016/j.freeradbiomed.2019.01.048

Source DB: PubMed Journal: Free Radic Biol Med ISSN： 0891-5849 Impact factor: 7.376

74 in total

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8. Crystal structure of type II peptide deformylase from Staphylococcus aureus.

Authors: Eric T Baldwin; Melissa S Harris; Anthony W Yem; Cindy L Wolfe; Anne F Vosters; Kimberly A Curry; Robert W Murray; Jeffrey H Bock; Vincent P Marshall; Joyce I Cialdella; Mahesh H Merchant; Gil Choi; Martin R Deibel
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9. Regulation of Salmonella enterica serovar Typhimurium mntH transcription by H(2)O(2), Fe(2+), and Mn(2+).

Authors: David G Kehres; Anu Janakiraman; James M Slauch; Michael E Maguire
Journal: J Bacteriol Date: 2002-06 Impact factor: 3.490

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Journal: Nat Struct Biol Date: 1999-02

14 in total

1. Anaerobic Transcription by OxyR: A Novel Paradigm for Nitrosative Stress.

Authors: Divya Seth; Alfred Hausladen; Jonathan S Stamler
Journal: Antioxid Redox Signal Date: 2019-12-03 Impact factor: 8.401

2. Do reactive oxygen species or does oxygen itself confer obligate anaerobiosis? The case of Bacteroides thetaiotaomicron.

Authors: Maryam Khademian; James A Imlay
Journal: Mol Microbiol Date: 2020-05-19 Impact factor: 3.501

3. Cellular responses to reactive oxygen species are predicted from molecular mechanisms.

Authors: Laurence Yang; Nathan Mih; Amitesh Anand; Joon Ho Park; Justin Tan; James T Yurkovich; Jonathan M Monk; Colton J Lloyd; Troy E Sandberg; Sang Woo Seo; Donghyuk Kim; Anand V Sastry; Patrick Phaneuf; Ye Gao; Jared T Broddrick; Ke Chen; David Heckmann; Richard Szubin; Ying Hefner; Adam M Feist; Bernhard O Palsson
Journal: Proc Natl Acad Sci U S A Date: 2019-07-03 Impact factor: 11.205

Review 4. The ArcAB Two-Component System: Function in Metabolism, Redox Control, and Infection.

Authors: Aric N Brown; Mark T Anderson; Michael A Bachman; Harry L T Mobley
Journal: Microbiol Mol Biol Rev Date: 2022-04-20 Impact factor: 13.044

5. A conserved motif liganding the [4Fe-4S] cluster in [4Fe-4S] fumarases prevents irreversible inactivation of the enzyme during hydrogen peroxide stress.

Authors: Zheng Lu; James A Imlay
Journal: Redox Biol Date: 2019-08-23 Impact factor: 11.799