Synthesis of Chlorinated Oligopeptides via γ- and δ-Selective Hydrogen Atom Transfer Enabled by the N-Chloropeptide Strategy.

The introduction of a chlorine atom could potentially endow peptide derivatives with notable bioactivity and applicability. However, despite considerable recent progress in C(sp3)-H functionalization chemistry, a general method for the site-selective chlorination of inert aliphatic C-H bonds in peptides still remains elusive. Herein, we report a site-selective C(sp3)-H chlorination of oligopeptides based on an N-chloropeptide strategy. N-chloropeptides, which are easily prepared from the corresponding native oligopeptides, are smoothly degraded in the presence of an appropriate copper catalyst, and a subsequent 1,5-hydrogen atom transfer affords γ- or δ-chlorinated peptides in excellent yield. A wide variety of amino acid residues can thus be site-selectively chlorinated in a predictable manner. This method hence enables the efficient synthesis of otherwise less accessible, chlorine-containing peptide fragments of natural peptides. We moreover demonstrate here the successful estimation of the stereochemistry of the chlorinated carbon atom in aquimarin A. Furthermore, we reveal that side-chain-chlorinated peptides can serve as highly useful substructures with a fine balance between stability and reactivity, which renders them promising targets for synthetic and medicinal applications.

Late-Stage Installation of Dehydroamino Acid Motifs into Peptides Enabled by an N-Chloropeptide Strategy.

Conventional methods for the construction of dehydroamino acids (ΔAAs), which are a unique class of non-proteinogenic amino acids, require the pre-installation of special amino acids. Herein, we report and demonstrate the practical utility of an N-chloropeptide strategy for the rapid construction of ΔAA-containing peptides. The electrophilic N-chlorination of peptide bonds is drastically accelerated by a catalytic amount of quinuclidine (ABCO), and the subsequent ß-elimination of N-chloroamide efficiently provides ΔAA-containing peptides in high yield. The strategy enables, for the first time, the construction of a wide variety of ΔAA residues in peptides without any pre-functionalized side chains and facilitates the late-stage installation of ΔAA motifs into already-constructed oligopeptides, including a medicinally important macrocyclic peptide.