Orthogonal side chain protecting groups, particularly for Fmoc-based solid phase peptide synthesis, are growing not only in diversity, but also in popularity. These protecting groups enable post-synthesis chemistry while the peptide is still on resin, often times increasing efficiency, decreasing side reactions, and generally simplifying the overall process.
I’ve already done some work with many of the commercially available orthogonally protected amino acids including allyl and alloc, Acm, and ivDde for a variety of downstream applications. In today’s post, I’ll discuss some work optimizing the removal of a 4-methoxytrityl (Mmt) group from cysteine side chains.
Continue reading How to: Measure and optimize the removal of Mmt protecting groups
Disulfide rich peptides are being identified in species of both plants and animals at increasing rates. As new molecules are discovered and disulfide bonding patterns characterized, the need for simplified chemical synthesis strategies is also increasing.
I have previously written about optimizing removal of several orthogonal side chain protecting groups including allyl, alloc, ivDde and acetamidomethyl (Acm) groups. The question that I’ll address today, though, is does the order in which the disulfide bonds are formed matter for cleaning up reactions to produce chemically synthesized disulfide rich peptides?
Continue reading Disulfide rich peptides – in which order should the disulfide bonds be formed during on-resin oxidation?