Theoretical and Electrochemical Analysis of Dissociative Electron Transfers Proceeding through Formation of Loose Radical Anion Species:  Reduction of Symmetrical and Unsymmetrical Disulfides

Antonello, Sabrina; Benassi, Rois; Gavioli, G. Battistuzzi; Taddei, F.; Maran, Flavio

doi:10.1021/ja012545e

Cited by 127 publications

(114 citation statements)

References 88 publications

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“…Equilibrium constants for this association reaction are in the range 10 2 -10 4 M -1 (Mezyk and Armstrong, 1999). Direct evidence for the reaction of the thiyl radical and thiolate to the disulfide radical anion was recognized by EPR in the enzymatic process, at least for the E441Q R1 mutant (Lawrence et al, 1999 Figure 13 Step (4) as suggested by Cerqueira et al (2004b) and by Pelmenschikov et al (2004). of disulfides are in the range of -1.9 to -2.3 V SCE for dialkyl derivatives (Mezyk and Armstrong, 1999;Antonello et al, 2002); hence, disulfide radical anions are strong reducing agents that can reduce carbonyl derivatives, in particular if these are involved in hydrogen bonding (Oelgemö ller et al, 2002).…”

Section: Bereitgestellt Von | Universitaetsbibliothek Der Lmu Muenchenmentioning

confidence: 99%

Spectroscopic and theoretical approaches for studying radical reactions in class I ribonucleotide reductase

Bennati

Lendzian²,

Schmittel³

et al. 2005

Biological Chemistry

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Ribonucleotide reductases (RNRs) catalyze the production of deoxyribonucleotides, which are essential for DNA synthesis and repair in all organisms. The three currently known classes of RNRs are postulated to utilize a similar mechanism for ribonucleotide reduction via a transient thiyl radical, but they differ in the way this radical is generated. Class I RNR, found in all eukaryotic organisms and in some eubacteria and viruses, employs a diferric iron center and a stable tyrosyl radical in a second protein subunit, R2, to drive thiyl radical generation near the substrate binding site in subunit R1. From extensive experimental and theoretical research during the last decades, a general mechanistic model for class I RNR has emerged, showing three major mechanistic steps: generation of the tyrosyl radical by the diiron center in subunit R2, radical transfer to generate the proposed thiyl radical near the substrate bound in subunit R1, and finally catalytic reduction of the bound ribonucleotide. Amino acid-or substrate-derived radicals are involved in all three major reactions. This article summarizes the present mechanistic picture of class I RNR and highlights experimental and theoretical approaches that have contributed to our current understanding of this important class of radical enzymes.

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Section: Bereitgestellt Von | Universitaetsbibliothek Der Lmu Muenchenmentioning

confidence: 99%

Spectroscopic and theoretical approaches for studying radical reactions in class I ribonucleotide reductase

Bennati

Lendzian²,

Schmittel³

et al. 2005

Biological Chemistry

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“…[20] On top of this, our knowledge on the mechanistic details of the SÀS bond fission has been limited by the fact that most of these attempts were based on symmetric model systems, in which the two substituents attached to the SÀS bridge were identical. Actually, to the best of our knowledge, only Antonello et al [21] have addressed the ECD in RSSR' unsymmetrical disulfides, where the R and R' substituents were alkyl or phenyl groups.…”

Section: Introductionmentioning

confidence: 99%

Asymmetry and Non‐Adiabaticity in Fragmentation of Disulfide Bonds upon Electron Capture

Gámez¹,

Serrano‐Andrés²,

Yáñez³

2010

ChemPhysChem

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Although it has been generally assumed that electron attachment to disulfide derivatives leads to a systematic and significant activation of the S-S bond, we show, by using [CH(3)SSX] (X = CH(3), NH(2), OH, F) derivatives as model compounds, that this is the case only when the X substituents have low electronegativity. Through the use of MP2, QCI and CASPT2 molecular orbital (MO) methods, we elucidate, for the first time, the mechanisms that lead to unimolecular fragmentation of disulfide derivatives after electron attachment. Our theoretical scrutiny indicates that these mechanisms are more intricate than assumed in previous studies. The most stable products, from a thermodynamic viewpoint, correspond to the release of neutral molecules; CH(4), NH(3), H(2)O, and HF. However, the barriers to reach these products depend strongly on the electronegativity of the X substituents. Only for very electronegative substituents, such as OH or F, the loss of H(2)O or HF is the most favorable process, and likely the only one observed. This is possible because of two concomitant factors, 1) the extra electron for [CH(3)SSX](-) (X = OH, F) occupies a sigma*(S-X) MO, which favors the cleavage of the S-X bond, and 2) the activation barriers associated with the hydrogen transfer process to produce H(2)O and HF are rather low. Only when the substituents are less electronegative (X = H, CH(3), NH(2)) the extra electron is located in a sigma*(S-S) orbital and the cleavage of the disulfide bridge becomes the most favorable process. The intimate mechanism associated with the S-S bond dissociation process also depends strongly on the nature of the substituent. For X = H or CH(3) the process is strictly adiabatic, while for X = NH(2) it proceeds through a conical intersection (CI) associated with the charge reorganization necessary to obtain, from a molecular anion with the extra electron delocalized in a sigma*(S-S) antibonding orbital, two fragments with the proper charge localization.

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“…The study of the electrochemical behavior of DDS and C 6 H 5 SH on GC electrode allows to clarify the nature of the ET process in aprotic solvent (ACN), and the overall electrochemical reduction mechanism. The S À S bond free energy was calculated using E8 values obtained by a convolution method [21,22,23].…”

Section: Introductionmentioning

confidence: 99%

Electrochemical Behavior of Diphenyl Disulfide and Thiophenol on Glassy Carbon and Gold Electrodes in Aprotic Media

2003

Self Cite

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The investigation of the electrochemical reduction processes of C 6 H 5 SSC 6 H 5 and C 6 H 5 SH in CH 3 CN using cyclic voltammetry indicates a different behavior on GC and Au electrodes. On GC surface adsorption phenomena are absent, the electrochemical reduction process is irreversible and diffusion controlled. For both the starting molecules the same species, C 6 H 5 S À , is formed upon reduction. The E8 values of the reduction processes were determined by convolution method and the standard free energy of the SÀS bond of C 6 H 5 SSC 6 H 5 estimated. On Au surface instead, a self-assembled monolayer of C 6 H 5 SAu ads originated after the SÀS or SÀH bond breaking can be observed by simply dipping the electrode in solution of C 6 H 5 SSC 6 H 5 and C 6 H 5 SH, respectively. The properties of the SAM were investigated by electrochemical reduction of the adsorbed thiolates. On Au electrode the reduction processes involve C 6 H 5 SAu ads and give rise to desorbed C 6 H 5 S À . A neutral radical is obtained by electrochemical oxidation of thiolate anion. It reacts rapidly with the electrode surface to give the S-Au bond again.

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Theoretical and Electrochemical Analysis of Dissociative Electron Transfers Proceeding through Formation of Loose Radical Anion Species: Reduction of Symmetrical and Unsymmetrical Disulfides

Cited by 127 publications

References 88 publications

Spectroscopic and theoretical approaches for studying radical reactions in class I ribonucleotide reductase

Spectroscopic and theoretical approaches for studying radical reactions in class I ribonucleotide reductase

Asymmetry and Non‐Adiabaticity in Fragmentation of Disulfide Bonds upon Electron Capture

Electrochemical Behavior of Diphenyl Disulfide and Thiophenol on Glassy Carbon and Gold Electrodes in Aprotic Media

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