Incorporation of Selenocysteine into Proteins Using Peptide Ligation

Hondal, Robert J.

doi:10.2174/0929866054864319

Cited by 29 publications

(16 citation statements)

References 62 publications

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“…Koppenol and coworkers found that at pH 7, a selenolate catalyzed the reduction of a disulfide *390-fold faster than a thiol. This data is not dissimilar from the data reported in (33) at neutral pH [also see (32)]. The authors noted that the difference in nucleophilicity is significantly decreased, to 10-100-fold, to account for differences in the ionization state of the two chalcogens.…”

supporting

confidence: 67%

Selenocysteine in Thiol/Disulfide-Like Exchange Reactions

Hondal

Marino

Gladyshev

2013

Antioxidants & Redox Signaling

151

119

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Significance: Among trace elements used as cofactors in enzymes, selenium is unique in that it is incorporated into proteins co-translationally in the form of an amino acid, selenocysteine (Sec). Sec differs from cysteine (Cys) by only one atom (selenium versus sulfur), yet this switch dramatically influences important aspects of enzyme reactivity. Recent Advances: The main focus of this review is an updated and critical discussion on how Sec might be used to accelerate thiol/disulfide-like exchange reactions in natural selenoenzymes, compared with their Cys-containing homologs. Critical Issues: We discuss in detail three major aspects associated with thiol/ disulfide exchange reactions: (i) nucleophilicity of the attacking thiolate (or selenolate); (ii) electrophilicity of the center sulfur (or selenium) atom; and (iii) stability of the leaving group (sulfur or selenium). In all these cases, we analyze the benefits that selenium might provide in these types of reactions. Future Directions: It is the biological thiol oxidoreductase-like function that benefits from the use of Sec, since Sec functions to chemically accelerate the rate of these reactions. We review various hypotheses that could help explain why Sec is used in enzymes, particularly with regard to competitive chemical advantages provided by the presence of the selenium atom in enzymes. Ultimately, these chemical advantages must be connected to biological functions of Sec.

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supporting

confidence: 67%

Selenocysteine in Thiol/Disulfide-Like Exchange Reactions

Hondal

Marino

Gladyshev

2013

Antioxidants & Redox Signaling

151

119

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“…Our research efforts over the past several years have focused on synthesizing peptides containing selenocysteine (Sec, U) [1] (Abbreviations used in this paper follow the guidelines recommended by Jones JH) for use in peptide ligation reactions [2,3]. One problem with using Sec in solid-phase peptide synthesis (SPPS) is the requirement for using benzyl-type protecting groups for the selenol side-chain owing to the incompatibility of a trityl group (Trt) with this sidechain [4][5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Studies on deprotection of cysteine and selenocysteine side‐chain protecting groups

Harris¹,

Flemer²,

Hondal³

2006

Journal of Peptide Science

101

113

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Abstract:We present here a simple method for deprotecting p-methoxybenzyl groups and acetamidomethyl groups from the sidechains of cysteine and selenocysteine. This method uses the highly elecrophilic, aromatic disulfides 2,2 -dithiobis(5-nitropyridine) (DTNP) and 2,2 -dithiodipyridine (DTP) dissolved in TFA to effect removal of these heretofore difficult-to-remove protecting groups. The dissolution of these reagents in TFA, in fact, serves to 'activate' them for the deprotection reaction because protonation of the nitrogen atom of the pyridine ring makes the disulfide bond more electrophilic. Thus, these reagents can be added to any standard cleavage cocktail used in peptide synthesis.The p-methoxybenzyl group of selenocysteine is easily removed by DTNP. Only sub-stoichiometric amounts of DTNP are required to cause full removal of the p-methoxybenzyl group, with as little as 0.2 equivalents necessary to effect 70% removal of the protecting group. In order to remove the p-methoxybenzyl group from cysteine, 2 equivalents of DTNP and the addition of thioanisole was required to effect removal. Thioanisole was absolutely required for the reaction in the case of the sulfur-containing amino acids, while it was not required for selenocysteine. The results were consistent with thioanisole acting as a catalyst. The acetamidomethyl group of cysteine could also be removed using DTNP, but required the addition of >15 equivalents to be effective. DTP was less robust as a deprotection reagent. We also demonstrate that this chemistry can be used in a simultaneous cyclization/deprotection reaction between selenocysteine and cysteine residues protected by p-methoxybenzyl groups to form a selenylsulfide bond, demonstrating future high utility of the deprotection method.

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“…According to Scheme 9, the iodination -selenylation protocol was directly applied to lcystine protected with Fmoc groups, 13a, which has a free COOH group. Trapping of the iodide intermediate (18) with the selenolate that was produced by reduction of bis(4-methoxybenzyl) diselenide with NaBH 4 indeed gave the desired product 10 in 12% isolated yield. Although the reaction yield was not remarkably increased compared with the path shown in Scheme 7, the result suggested the compatibility of the S !…”

Section: Synthesis Of Selenocysteinementioning

confidence: 94%

Synthesis of Selenocysteine and Selenomethionine Derivatives from Sulfur‐Containing Amino Acids

Iwaoka

Ooka

Nakazato

et al. 2008

Chemistry & Biodiversity

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Selenium-containing amino acids have attracted increasing interest from view points of the importance as active centers of several selenoenzymes, the biological synthesis, the metabolism, and the use for structure determination of proteins. In this article, our recent progresses in the transformation from sulfur-containing amino acids to selenocysteine (SeCys) and selenomethionine (SeMet) derivatives are reviewed along with the surveys of general organic methodologies for the synthesis of SeCys and SeMet derivatives in the literature. The S-->Se modification (i.e., the chemical atomic mutation) would be a useful approach to peptide synthesis involving selenoamino acid residues.

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Incorporation of Selenocysteine into Proteins Using Peptide Ligation

Cited by 29 publications

References 62 publications

Selenocysteine in Thiol/Disulfide-Like Exchange Reactions

Selenocysteine in Thiol/Disulfide-Like Exchange Reactions

Studies on deprotection of cysteine and selenocysteine side‐chain protecting groups

Synthesis of Selenocysteine and Selenomethionine Derivatives from Sulfur‐Containing Amino Acids

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