Incorporation of unprotected heterocyclic side chains into peptoid oligomers via solid-phase submonomer synthesis.

Peptoids (N-substituted glycines) are an important class of biomimetic oligomers that have made a significant impact in the areas of combinatorial drug discovery, gene therapy, drug delivery, and biopolymer folding in recent years. Sequence-specific peptoid oligomers are easily assembled from primary amines by the solid-phase submonomer method. However, most amines that contain heterocyclic nitrogens in the side chain do not incorporate efficiently. We present here a straightforward revision of the submonomer method that allows efficient incorporation of unprotected imidazoles, pyridines, pyrazines, indoles, and quinolines into oligomers as long as 15 monomers in length. This improved method uses chloroacetic acid instead of bromoacetic acid in the acylation step of the monomer addition cycle, and allows for the incorporation of new side chains that should enable the synthesis of peptoids with entirely new properties.

Toward the synthesis of artificial proteins: the discovery of an amphiphilic helical peptoid assembly.

While nature exploits folded biopolymers to achieve molecular recognition and catalysis, comparable abiological heteropolymer systems have been difficult to create. We synthesized and identified abiological peptoid heteroploymers capable of binding a dye. Using combinatorial synthesis, we constructed a library of 3400 amphiphilic 15-mer peptoids on an ultra-high-capacity beaded support. Individual macrobeads, each containing a single peptoid sequence, were arrayed into plates, cleaved, and screened in aqueous solution to locate dye binding heteropolymer assemblies. Resynthesis and characterization demonstrated the formation of defined helical assemblies as judged by size-exclusion chromatography, circular dichroism, and analytical ultracentrifugation. Inspired by nature's process of sequence variation and natural selection, we identified rare abiological sequence-specific heteropolymers that begin to mimic the structure and functional properties of their biological counterparts.