Phenylthiocarbamate or N-carbothiophenyl group chemistry in peptide synthesis and bioconjugation.

The design of novel chemoselective and site-specific ligation methods provides new tools for obtaining complex scaffolds, peptidomimetics, and peptide conjugates. The chemistry of the N-phenylthiocarbonyl group has led to several developments in peptide ligation chemistry and peptide bioconjugation during the last 10 years. The aim of this review is to provide an overview of this emerging field.

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. Alternately, this strategy can be used for improving the binding of short peptides to polyanion-binding protein targets. This work describes the design and first synthesis of homogeneous polysulfonate-peptide conjugates using thiocarbamate ligation for binding to the extracellular domain of MET tyrosine kinase receptor for hepatocyte growth factor.

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.

Antioxydant activity of ß-carboline derivatives in the LDL oxidation model.

A series of ß-carboline compounds were synthesized, starting from compound GWC22, their antioxidant activity was determined by inhibition of lipid peroxidation. The oxidation of LDL was induced in the presence of CuSO4 or 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH). The protective actions of these compounds against the cytotoxicity were evaluated with lactate dehydrogenase (LDH) activity in bovine aortic endothelial cells (BAECs) and cellular vitality by measuring mitochondrial activity in the presence of MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide). Most of compounds showed an higher antioxidant activity than GWC22 derivative (R=1.6 for 5 µM CuSO4). The best antioxidant activities are phenolic and benzyloxy derivatives with ratio R=1.9 to 2.8 for 1 µM CuSO4. These substances have protective actions and increase significantly the cell viability.

Thiocarbamate-linked peptides by chemoselective peptide ligation.

Peptide chemical ligation chemistries, which allow the chemoselective coupling of unprotected peptide fragments, are useful tools for synthesizing native polypeptides or unnatural peptide-based macromolecules. We show here that the phenylthiocarbonyl group can be easily introduced into peptides on alpha or epsilon amino groups using phenylthiochloroformate and standard solid-phase method. It reacts chemoselectively with cysteinyl peptides to give an alkylthiocarbamate bond. S,N-shift of the alkylaminocarbonyl group from the Cys side chain to the alpha-amino group did not occur. The method was used for linking two peptide chains through their N-termini, for the synthesis of a cyclic peptide or for the synthesis of di- or tetravalent multiple antigenic peptides (MAPs). Thiocarbamate ligation is thus complementary to thioether, thioester or disulfide ligation methods.