Native chemical ligation at a base-labile 4-mercaptobutyrate N(α)-auxiliary.

Native chemical ligation (NCL) proceeds via a S-N acyl shift and, therefore, requires N-terminal cysteine. N(α)-auxiliaries have long been used to enable NCL beyond cysteine. However, the reversibility of the S-N acyl shift under the acidic conditions used to remove the commonly applied N-benzyl auxiliaries limits the scope of this reaction. Herein, we introduce a new class of N(α)-auxiliary which is designed for removal under mild basic conditions. The 3-N-linked 4-mercaptobutyrate auxiliary is readily synthesized in a single step and enables introduction on solid phase by means of reductive amination. The usefulness of the new auxiliary was demonstrated in the synthesis of the anti-microbial C-terminal domain of Dermicidine-1L.

A Type of Auxiliary for Native Chemical Peptide Ligation beyond Cysteine and Glycine Junctions.

Native chemical ligation enables the chemical synthesis of proteins. Previously, thiol-containing auxiliary groups have been used to extend the reaction scope beyond N-terminal cysteine residues. However, the N-benzyl-type auxiliaries used so far result in rather low reaction rates. Herein, a new N(α) -auxiliary is presented. Consideration of a radical fragmentation for cleavage led to the design of a new auxiliary group which is selectively removed under mildly basic conditions (pH 8.5) in the presence of TCEP and morpholine. Most importantly and in contrast to previously described auxiliaries, the 2-mercapto-2-phenethyl auxiliary is not limited to Gly-containing sites and ligations succeed at sterically demanding junctions. The auxiliary is introduced in high yield by on-resin reductive amination with commercially available amino acid building blocks. The synthetic utility of the method is demonstrated by the synthesis of two antimicrobial proteins, DCD-1L and opistoporin-2.

Side-chain assisted ligation in protein synthesis.

Chemical ligation methods for the assembly of functional proteins continue to advance our basic understanding of protein structure and function. In this work, we report on our progress towards the full synthesis of HIV-1 Tat utilizing our newly developed ligation method; side-chain assisted ligation. The HIV-1 Tat was assembled from three fragments wherein the two thioester peptides were synthesized efficiently using the side-chain anchoring strategy following Fmoc-SPPS. The side-chain assisted ligation step was efficient and provided the ligation product in good yield. Following this step, native chemical ligation was used to fully assemble the HIV-1 Tat protein. Although the removal of the auxiliary in small peptides was straightforward, in the case of HIV-1 Tat this step was inefficient thus hampering the completion of the synthesis.