Protocol for protein modification using oxalyl thioester-mediated chemoselective ligation.

The development of fast ligation chemistries for the site-specific modification of proteins has become a major focus in chemical biology. We describe steps for preparing an oxalyl thioester precursor in the form of an N-oxalyl perhydro-1,2,5-dithiazepine handle, i.e.

Incorporation of a Highly Reactive Oxalyl Thioester-Based Interacting Handle into Proteins.

Providing biomolecules with extended physicochemical, biochemical, or biological properties is a contemporary challenge motivated by impactful benefits in life or materials sciences. In this study, we show that a latent and highly reactive oxalyl thioester precursor can be efficiently introduced as a pending functionality into a fully synthetic protein domain following a protection/late-stage deprotection strategy and can serve as an on-demand reactive handle. The approach is illustrated with the production of a 10 kDa ubiquitin Lys48 conjugate.

Electrostatic Assistance of 4-Mercaptophenylacetic Acid-Catalyzed Native Chemical Ligation.

4-Mercaptophenylacetic acid (MPAA) is a popular catalyst of the native chemical ligation (NCL) but has to be used in large excess for achieving practically useful rates (up to 50-100 equiv). We report here that the catalytic potency of MPAA can be boosted by introducing a stretch of arginines in the departing thiol from the thioester. By doing so, the electrostatically assisted NCL reaction proceeds rapidly by using substoichiometric concentrations of MPAA, an advantage that enables useful synthetic applications.

An Iron-Catalyzed Protein Desulfurization Method Reminiscent of Aquatic Chemistry.

One pillar of protein chemical synthesis based on the application of ligation chemistries to cysteine is the group of reactions enabling the selective desulfurization of cysteine residues into alanines. Modern desulfurization reactions use a phosphine as a sink for sulfur under activation conditions involving the generation of sulfur-centered radicals. Here we show that cysteine desulfurization by a phosphine can be effected efficiently by micromolar concentrations of iron under aerobic conditions in hydrogen carbonate buffer, that is using conditions that are reminiscent of iron-catalyzed oxidation phenomena occurring in natural waters.

A biomimetic electrostatic assistance for guiding and promoting N-terminal protein chemical modification.

The modification of protein electrostatics by phosphorylation is a mechanism used by cells to promote the association of proteins with other biomolecules. In this work, we show that introducing negatively charged phosphoserines in a reactant is a powerful means for directing and accelerating the chemical modification of proteins equipped with oppositely charged arginines. While the extra charged amino acid residues induce no detectable affinity between the reactants, they bring site-selectivity to a reaction that is otherwise devoid of such a property.

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/CO buffer.

Natural T Cell Epitope Containing Methyl Lysines on Mycobacterial Heparin-Binding Hemagglutinin.

T cell epitopes are mostly nonmodified peptides, although posttranslationally modified peptide epitopes have been described, but they originated from viral or self-proteins. In this study, we provide evidence of a bacterial methylated T cell peptide epitope. The mycobacterial heparin-binding hemagglutinin (HBHA) is a protein Ag with a complex C-terminal methylation pattern and is recognized by T cells from humans latently infected with By comparing native HBHA with recombinant HBHA produced in (rHBHA-), we could link antigenic differences to differences in the methylation profile.

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.

Accelerated microfluidic native chemical ligation at difficult amino acids toward cyclic peptides.

Cyclic peptide-based therapeutics have a promising growth forecast that justifies the development of microfluidic systems dedicated to their production, in phase with the actual transitioning toward continuous flow and microfluidic technologies for pharmaceutical production. The application of the most popular method for peptide cyclization in water, i.e.

A simple and traceless solid phase method simplifies the assembly of large peptides and the access to challenging proteins.

Chemical protein synthesis gives access to well-defined native or modified proteins that are useful for studying protein structure and function. The majority of proteins synthesized up to now have been produced using native chemical ligation (NCL) in solution. Although there are significant advantages to assembling large peptides or proteins by solid phase ligation, reports of such approaches are rare.

Correction: A simple and traceless solid phase method simplifies the assembly of large peptides and the access to challenging proteins.

[This corrects the article DOI: 10.1039/C7SC01912B.].

A Central Cysteine Residue Is Essential for the Thermal Stability and Function of SUMO-1 Protein and SUMO-1 Peptide-Protein Conjugates.

SUMOylation constitutes a major post-translational modification (PTM) used by the eukaryote cellular machinery to modulate protein interactions of the targeted proteins. The small ubiquitin-like modifier-1 (SUMO-1) features a central and conserved cysteine residue (Cys52) that is located in the hydrophobic core of the protein and in tight contact with Phe65, suggesting the occurrence of an S/π interaction. To investigate the importance of Cys52 on SUMO-1 thermal stability and biochemical properties, we produced by total chemical synthesis SUMO-1 or SUMO-1 Cys52Ala peptide-protein conjugates featuring a native isopeptidic bond between SUMO-1 and a peptide derived from p53 tumor suppressor protein.

Accelerating chemoselective peptide bond formation using bis(2-selenylethyl)amido peptide selenoester surrogates.

Given the potential of peptide selenoesters for protein total synthesis and the paucity of methods for the synthesis of these sensitive peptide derivatives, we sought to explore the usefulness of the bis(2-selenylethyl)amido (SeEA) group, the selenium analog of the bis(2-sulfanylethyl)amido (SEA) group, for accelerating peptide bond formation. A chemoselective exchange process operating in water was devised for converting SEA peptides into the SeEA ones. Kinetic studies show that SeEA ligation, which relies on an initial ,-acyl shift process, proceeds significantly faster than SEA ligation.

Synthesis of Unprotected Linear or Cyclic O-Acyl Isopeptides in Water Using Bis(2-sulfanylethyl)amido Peptide Ligation.

SEA ligation proceeds chemoselectively at pH 3, i.e., at a pH where the O-acyl isopeptides are protected by protonation.

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.

Thiocarbamate-linked polysulfonate-peptide conjugates as selective hepatocyte growth factor receptor binders.

The capacity of many proteins to interact with natural or synthetic polyanions has been exploited for modulating their biological action. However, the polydispersity of these macromolecular polyanions as well as their poor specificity is a severe limitation to their use as drugs. An emerging trend in this field is the synthesis of homogeneous and well-defined polyanion-peptide conjugates, which act as bivalent ligands, with the peptide part bringing the selectivity of the scaffold.

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.

Total synthesis of biotinylated N domain of human hepatocyte growth factor.

Hepatocyte growth factor/scatter factor (HGF/SF) is the high affinity ligand of MET tyrosine kinase receptor. We report here the total synthesis of a biotinylated analogue of human HGF/SF N domain. Functionally, N domain is part of the HGF/SF high affinity binding site for MET and also the main HGF/SF binding site for heparin.

Polysaccharide microarrays: application to the identification of heparan sulphate mimetics.

The interaction of polysaccharides with proteins modulates or triggers many biological effects. In particular, heparan sulphate proteoglycans (HSPGs) have multiple regulatory interactions with growth factors, enzymes, enzyme inhibitors, and some components of the extracellular matrix. The important role played by HSPGs has motivated the synthesis and selection of HSPG mimetics for modulating the biological activity of HS-binding proteins.

Chips from chips: application to the study of antibody responses to methylated proteins.

Peptide microarrays are useful tools for the characterization of humoral responses against peptide antigens. The study of post-translational modifications requires the printing of appropriately modified peptides, whose synthesis can be time-consuming and expensive. We describe here a method named "chips from chips", which allows probing the presence of antibodies directed toward modified peptide antigens starting from unmodified peptide microarrays.

In situ chemical modification of peptide microarrays: application to the study of the antibody responses to methylated antigens.

Peptide microarrays are useful tools for characterizing the humoral response against methylated antigens. They are usually prepared by printing unmodified and methylated peptides on substrates such as functionalized microscope glass slides. The preferential capture of antibodies by methylated peptides suggests the specific recognition of methylated epitopes.

PASE: a web-based platform for peptide/protein microarray experiments.

Peptide microarray technology requires bioinformatics and statistical tools to manage, store, and analyze the large amount of data produced. To address these needs, we developed a system called protein array software environment (PASE) that provides an integrated framework to manage and analyze microarray information from polypeptide chip technologies.

In situ ligation between peptides and silica nanoparticles for making peptide microarrays on polycarbonate.

Bisphenol A polycarbonate (PC) is emerging as an interesting alternative to silicon oxide substrates for making microarrays. We show that the printing of peptide/nanoparticle mixtures allows the creation of complex peptide microarrays. Semicarbazone ligation was used for linking the peptides to the nanoparticles.

Imaging of protein layers with an optical microscope for the characterization of peptide microarrays.

Solid-phase assays play a crucial role today in biological studies. These assays are based on the immobilization of probe molecules on a surface, which are able to capture specifically soluble receptors. In particular, peptide microarrays have emerged as powerful tools in a variety of applications.