Peptide Formation and Applications

A peptide is a sequence of amino acids, typically ranging between 2 to 70 in length, linked by amide bonds. Unlike proteins, peptides do not need to fold to function biologically. Peptides naturally appear in the form of hormones like angiotensin and enkephalin, and can also be found as toxins in plants and animals. Their significance extends to drug development, vaccine creation, biomaterials, histological studies, and antibody generation.

Peptides can be chemically synthesized in liquid form or on a solid surface. The synthesis entails forming an amide bond between an N-protected amino acid and another amino acid that has a free amino group and a shielded carboxylic acid. In solid-phase synthesis, the amino acid's carboxyl-protective group is tethered to a polymer. After the bond is created, the dipeptide's amino-protective group is detached, making way for the coupling of the next N-protected amino acid.

Solid-phase peptide synthesis (SPPS) is popular for its straightforwardness and effectiveness. It involves adding protected amino acid units to an amino acid or peptide on a non-soluble polymeric base sequentially. There are two main N-α-protection methods: the acid-sensitive Boc group (Boc SPPS) or the base-sensitive Fmoc group (Fmoc SPPS). After removing the protecting group, the subsequent protected amino acid is integrated. The peptide's C-terminal amino acid is anchored to the resin using a linker, dictating the conditions for releasing the peptide. Notably, side-chain protective groups in SPPS are selected to be removed along with the peptide's detachment from the resin.

The Fmoc method is the preferred synthesis technique since it concludes with trifluoroacetic acid treatment, while the Boc method requires the more hazardous anhydrous HF.

Peptides comprising up to 50 amino acids are regularly produced. However, creating proteins with over 100 amino acids isn't uncommon. For longer proteins, deprotected peptides are combined in solution through native chemical ligation. This approach enables the synthesis of unique peptides, the inclusion of unnatural amino acids, and the creation of cyclic, labeled, and post-translationally modified peptides.

Though liquid-phase synthesis was once standard, solid-phase synthesis has largely taken its place, leaving liquid-phase mainly for large-scale industrial peptide production.