Native Chemical Ligation at Serine Revisited

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Catalysis of Hydrazone and Oxime Peptide Ligation by Arginine

International audienceHydrazone and oxime peptide ligations are catalyzed by arginine. The catalysis is assisted intramolecularly by the side-chain guanidinium group. Hydrazone ligation in the presence of arginine proceeds efficiently in phosphate buffer at neutral pH but is particularly powerful in bicarbonate/CO2 buffer. In addition to acting as a catalyst, arginine prevents the aggregation of proteins during ligation. With its dual properties as a nucleophilic catalyst and a protein aggregation inhibitor, arginine hydrochloride is a useful addition to the hydrazone/oxime ligation toolbox

Catalysis of Hydrazone and Oxime Peptide Ligation by Arginine

Hydrazone and oxime peptide ligations are catalyzed by arginine. The catalysis is assisted intramolecularly by the side-chain guanidinium group. Hydrazone ligation in the presence of arginine proceeds efficiently in phosphate buffer at neutral pH but is particularly powerful in bicarbonate/CO2 buffer. In addition to acting as a catalyst, arginine prevents the aggregation of proteins during ligation. With its dual properties as nucleophilic catalyst and protein aggregation inhibitor, arginine hydrochloride is a useful addition to the hydrazone/oxime ligation toolbox.<br /

Fast protein modification in the nanomolar concentration range using an oxalyl amide as latent thioester

We show that latent oxalyl thioester surrogates are a powerful means to modify peptides and proteins in highly dilute conditions in purified aqueous media or in mixtures as complex as cell lysates. Designed to be shelf-stable reagents, they can be activated on-demand for enabling ligation reactions down to peptide concentrations as low as a few hundreds nM at rates approaching 30 M-1 s-1

SEA Ligation Is Accelerated at Mildly Acidic pH. Application to the Formation of Difficult Peptide Junctions

The bis(2-sulfanylethyl)amido (SEA)-mediated ligation has been introduced in 2010 as a novel chemoselective peptide bond forming reaction. SEA ligation is a useful reaction for protein total synthesis that is complementary to the native chemical ligation (NCL). In particular, SEA ligation proceeds efficiently in a wide range of pH, from neutral pH to pH 3-4. Thus, the pH can be chosen to optimize the solubility of the peptide segments or final product. It can be also chosen to facilitate the formation of difficult junctions, since the rate of SEA ligation increases significantly by decreasing the pH from 7.2 to 4.0. Here we describe a protocol for SEA ligation at pH 5.5 in the presence of 4-mercaptophenylacetic acid (MPAA) or at pH 4.0 in the presence of a newly developed diselenol catalyst. The protocols describe the formation of a valyl-cysteinyl peptide bond between two model peptides.<br /

Insights into the Mechanism and Catalysis of Peptide Thioester Synthesis by Alkylselenols Provide a New Tool for Chemical Protein Synthesis

Posté sur ChemRxiv le 2021-02-11.While thiol-based catalysts are widely employed for chemical protein synthesis relying on peptide thioester chemistry, this is less true for selenol-based catalysts whose development is in its infancy. In this study, we compared different selenols derived from the selenocysteamine scaffold for their capacity to promote thiol-thioester exchanges in water at mildly acidic pH and the production of peptide thioesters from bis(2-sulfanylethyl)amido (SEA) peptides. The usefulness of a selected selenol compound is illustrated by the total synthesis of a biologically active human chemotactic protein, which plays an important role in innate and adaptive immunit

Insights into the Mechanism and Catalysis of Peptide Thioester Synthesis by Alkylselenols Provide a New Tool for Chemical Protein Synthesis

While thiol-based catalysts are widely employed for chemical protein synthesis relying on peptide thioester chemistry, this is less true for selenol-based catalysts whose development is in its infancy. In this study, we compared different selenols derived from the selenocysteamine scaffold for their capacity to promote thiol-thioester exchanges in water at mildly acidic pH and the production of peptide thioesters from bis(2-sulfanylethyl)amido (SEA) peptides. The usefulness of a selected selenol compound is illustrated by the total synthesis of a biologically active human chemotactic protein, which plays an important role in innate and adaptive immunity<br /

Fast protein modification in the nanomolar concentration range using an oxalyl amide as latent thioester

International audienceWe show that latent oxalyl thioester surrogates are a powerful means to modify peptides and proteins in highly dilute conditions in purified aqueous media or in mixtures as complex as cell lysates. Designed to be shelf-stable reagents, they can be activated on-demand for enabling ligation reactions down to peptide concentrations as low as a few hundreds nM at rates approaching 30 M-1 s-1

Catalysis of Thiol–Thioester Exchange by Water-Soluble Alkyldiselenols Applied to the Synthesis of Peptide Thioesters and SEA-Mediated Ligation

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