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

N-Alkyl bis(2-selanylethyl)amines catalyze the synthesis of peptide thioesters or peptide ligation from bis(2-sulfanylethyl)amido (SEA) peptides. These catalysts are generated in situ by reduction of the corresponding cyclic diselenides by tris(2-carboxyethyl)phosphine. They are particularly efficient at pH 4.0 by accelerating the thiol-thioester exchange processes, which are otherwise rate-limiting at this pH. By promoting SEA-mediated reactions at mildly acidic pH, they facilitate the synthesis of complex peptides such as cyclic O-acyl isopeptides that are otherwise hardly accessible.

One-pot chemical synthesis of small ubiquitin-like modifier protein-peptide conjugates using bis(2-sulfanylethyl)amido peptide latent thioester surrogates.

Small ubiquitin-like modifier (SUMO) post-translational modification (PTM) of proteins has a crucial role in the regulation of important cellular processes. This protocol describes the chemical synthesis of functional SUMO-peptide conjugates. The two crucial stages of this protocol are the solid-phase synthesis of peptide segments derivatized by thioester or bis(2-sulfanylethyl)amido (SEA) latent thioester functionalities and the one-pot assembly of the SUMO-peptide conjugate by a sequential native chemical ligation (NCL)/SEA native peptide ligation reaction sequence. This protocol also enables the isolation of a SUMO SEA latent thioester, which can be attached to a target peptide or protein in a subsequent step. It is compatible with 9-fluorenylmethoxycarbonyl (Fmoc) chemistry, and it gives access to homogeneous, reversible and functional SUMO conjugates that are not easily produced using living systems. The synthesis of SUMO-peptide conjugates on a milligram scale takes 20 working days.

Selenopeptide transamidation and metathesis.

Selenopeptides can be transamidated by cysteinyl peptides in water using mild conditions (pH 5.5, 37 °C) in the presence of an arylthiol catalyst. Similar conditions also catalyze the metathesis of selenopeptides. The usefulness of the selenophosphine derived from TCEP (TCEP═Se) for inhibiting the TCEP-induced deselenization of selenocysteine residue is also reported.

Tidbits for the synthesis of bis(2-sulfanylethyl)amido (SEA) polystyrene resin, SEA peptides and peptide thioesters.

Protein total chemical synthesis enables the atom-by-atom control of the protein structure and therefore has a great potential for studying protein function. Native chemical ligation of C-terminal peptide thioesters with N-terminal cysteinyl peptides and related methodologies are central to the field of protein total synthesis. Consequently, methods enabling the facile synthesis of peptide thioesters using Fmoc-SPPS are of great value. Herein, we provide a detailed protocol for the preparation of bis(2-sulfanylethyl)amino polystyrene resin as a starting point for the synthesis of C-terminal bis(2-sulfanylethyl)amido peptides and of peptide thioesters derived from 3-mercaptopropionic acid.

RYH: a minimal peptidic sequence obtained from beta-chain hemoglobin exhibiting an antimicrobial activity.

Bovine hemoglobin is an animal protein described as source of bioactive peptides. Enzymatic hydrolysis of this protein results into some peptides exhibiting antimicrobial activity against Gram-positive and Gram-negative bacteria. In this study, a family of peptides from the beta chain (beta-114-145 derived peptides) obtained by peptic hydrolysis of bovine hemoglobin, was purified by reverse-phase HPLC and characterized by different analytical techniques (mass spectrometry, circular dichroism). The minimum inhibitory concentration was determined to show the antimicrobial activity of these peptides. Four bacterial strains were used: two Gram-negative (Escherichia coli and Salmonella Enteritidis) and two Gram-positive strains (Listeria innocua and Micrococcus luteus). The effect of these peptides on artificial membrane was also measured. Our findings showed that the peptide ß114-145 and its peptic derivatives contain the RYH sequence. The most antimicrobial peptide is the RYH peptide which was the shortest one.

Bis(2-sulfanylethyl)amino native peptide ligation.

The reaction of a peptide featuring a bis(2-sulfanylethyl)amino (SEA) group on its C-terminus with a cysteinyl peptide in water at pH 7 and 37 °C leads to the chemoselective and regioselective formation of a native peptide bond. This method called SEA ligation enriches the native peptide ligation repertoire available to the peptide chemist. Preparation of an innovative solid support which allows the straightforward synthesis of peptide SEA fragments using standard Fmoc/tert-butyl solid phase peptide synthesis procedures is also described.

Assembly/disassembly of drug conjugates using imide ligation.

A strategy is described that allows the easy assembly and controlled disassembly of drug conjugates. Imide ligation, that is, the reaction of a peptide thioacid with an azidoformate, is used for conjugate assembly. The imide bond participates also with an endopeptidase-triggered cyclization-based disassembly mechanism.

Synthesis of peptide-protein conjugates using N-succinimidyl carbamate chemistry.

Peptide-protein conjugates are useful tools in different fields of research as, for instance, the development of vaccines and drugs or for studying biological mechanisms, to cite only few applications. N-Succinimidyl carbamate (NSC) chemistry has been scarcely used in this area. We show that unprotected peptides, featuring one lysine residue within their sequences, can be converted in good yield into NSC derivatives by reaction with disuccinimidylcarbonate (DSC). No hydrolysis of the NSC group was observed during RP-HPLC purification, lyophilization, or storage. NSC peptides reacted efficiently within minutes with lysozyme used as model protein. To illustrate usefulness of the method consisting of the synthesis of a peptide-protein conjugate of biological interest, a NSC peptide derived from a peptide substrate for tyrosylprotein sulfotransferase (TS) was synthesized and ligated to receptor-binding nontoxic B-subunit of Shiga toxin (STxB). Immunofluorescence studies showed the intracellular delivery of the TS-STxB conjugate and its ability to circulate to the Golgi as the native STxB protein. Moreover, we demonstrate that the TS label could be sulfated by tyrosylprotein sulfotransferases present in the Golgi. Thus, NSC chemistry permitted rapid synthesis of a peptide-protein conjugate worthwhile for studying the transport of proteins from the plasma membrane to the Golgi. The second part of this article describes a more general method for synthesizing peptide-protein conjugates without any limitation of the peptide sequence. The conjugates were assembled by combining NSC chemistry and alpha-oxo semicarbazone ligation. To this end, a glyoxylyl NSC peptide was synthesized and reacted with lysozyme. The glyoxylyl groups on the protein were then reacted with a semicarbazide peptide to produce the target peptide-protein conjugate. Both reactions, namely, urea bond formation and alpha-oxo semicarbazone ligation, were carried at pH 8.0 using a one-pot procedure.

Chemistry-based protein modification strategy for endocytic pathway analysis.

BACKGROUND INFORMATION: The integrated analysis of intracellular trafficking pathways is one of the current challenges in the field of cell biology, and functional proteomics has become a powerful technique for the large-scale identification of proteins or lipids and the elucidation of biological processes in their natural contexts. For this, new dynamic strategies must be devised to trace proteins that follow a specific pathway such that their initial and final destinations can be detected by automated means. RESULTS: Here, we report a novel vectorial strategy for trafficking pathway analysis. This strategy is based on a chemical modification of plasma membrane proteins with a bSuPeR (biotinylated sulfation site peptide reagent) and metabolic labelling in the Golgi apparatus, such that plasma membrane proteins that traffic via the retrograde route become detectable in complex mixtures. Efficient synthesis schemes are presented for tailor-made chemical tools that are then applied to the step-by-step validation of the strategy, using a known retrograde cargo protein: the STxB (Shiga toxin B-subunit). bSuPeR modification at the plasma membrane does not affect STxB transport to the Golgi apparatus, where the protein is metabolically labelled, allowing its detection in cell lysates. CONCLUSIONS: Our vectorial concept proposes a new chemical approach for traffic-based profiling of proteins that may prove to be applicable to the analysis of diverse endocytic pathways.

Silver-catalyzed azaGly ligation. Application to the synthesis of azapeptides and of lipid-peptide conjugates.

Glycine is a amino acid frequently found in peptides. Substitution of a glycine residue by an azaglycine allows the modulation of peptide conformation, bioactivity, or stability. Azapeptides are usually prepared using solid-phase synthetic procedures. We show here that azaGly peptides can be assembled chemoselectively and without racemization using unprotected peptide fragments by silver-catalyzed reaction of C-terminal peptide hydrazides with N-terminal phenylthiocarbonyl peptides. The reaction was performed in a tBuOH/water mixture and the control of apparent pH permitted the clean formation of the azaGly bond in the presence of lysine residues. We show also that this novel ligation method, called azaGly ligation, can be used for the assembly of lipopeptides. For this, lipid hydrazides were reacted with a phenylthiocarbonyl peptide in the presence of silver ions. This ligation method allows incorporation of acid-sensitive lipid moieties that are incompatible with standard solid-phase peptide synthesis procedures, and more generally should be of interest for the modification of peptides by sensitive acyl moieties.