Goedele Roos scite author profile

Many cellular functions involve cysteine chemistry via thiol-disulfide exchange pathways. The nucleophilic cysteines of the enzymes involved are activated as thiolate. A thiolate is much more reactive than a neutral thiol. Therefore, determining and understanding the pK(a)s of functional cysteines are important aspects of biochemistry and molecular biology with direct implications for redox signaling. Here, we describe the experimental and theoretical methods to determine cysteine pK(a) values, and we examine the factors that control these pK(a)s. Drawing largely on experience gained with the thioredoxin superfamily, we examine the roles of solvation, charge-charge, helix macrodipole, and hydrogen bonding interactions as pK(a)-modulating factors. The contributions of these factors in influencing cysteine pK(a)s and the associated chemistry, including the relevance for the reaction kinetics and thermodynamics, are discussed. This analysis highlights the critical role of direct hydrogen bonding to the cysteine sulfur as a key factor modulating the equilibrium between thiol S-H and thiolate S(-). This role is easily understood intuitively and provides a framework for biochemical functional insights.

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Protein sulfenic acid formation: From cellular damage to redox regulation

Roos

Messens

2011

Free Radical Biology and Medicine

242

204

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Mycoredoxin‐1 is one of the missing links in the oxidative stress defence mechanism of Mycobacteria

Laer

Buts

Foloppe

et al. 2012

Molecular Microbiology

118

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SummaryTo survive hostile conditions, the bacterial pathogen Mycobacterium tuberculosis produces millimolar concentrations of mycothiol as a redox buffer against oxidative stress. The reductases that couple the reducing power of mycothiol to redox active proteins in the cell are not known. We report a novel mycothiol-dependent reductase (mycoredoxin-1) with a CGYC catalytic motif. With mycoredoxin-1 and mycothiol deletion strains of Mycobacterium smegmatis, we show that mycoredoxin-1 and mycothiol are involved in the protection against oxidative stress. Mycoredoxin-1 acts as an oxidoreductase exclusively linked to the mycothiol electron transfer pathway and it can reduce S-mycothiolated mixed disulphides. Moreover, we solved the solution structures of oxidized and reduced mycoredoxin-1, revealing a thioredoxin fold with a putative mycothiol-binding site.With HSQC snapshots during electron transport, we visualize the reduction of oxidized mycoredoxin-1 as a function of time and find that mycoredoxin-1 gets S-mycothiolated on its N-terminal nucleophilic cysteine. Mycoredoxin-1 has a redox potential of -218 mV and hydrogen bonding with neighbouring residues lowers the pK a of its N-terminal nucleophilic cysteine. Determination of the oxidized and reduced structures of mycoredoxin-1, better understanding of mycothiol-dependent reactions in general, will likely give new insights in how M. tuberculosis survives oxidative stress in human macrophages.

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Goedele Roos

Understanding the pK_aof Redox Cysteines: The Key Role of Hydrogen Bonding

Protein sulfenic acid formation: From cellular damage to redox regulation

Mycoredoxin‐1 is one of the missing links in the oxidative stress defence mechanism of Mycobacteria

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Goedele Roos

Understanding the pKaof Redox Cysteines: The Key Role of Hydrogen Bonding

Protein sulfenic acid formation: From cellular damage to redox regulation

Mycoredoxin‐1 is one of the missing links in the oxidative stress defence mechanism of Mycobacteria

Contact Info

Product

Resources

About

Understanding the pK_aof Redox Cysteines: The Key Role of Hydrogen Bonding