Summary
Researchers in UCLA's Department of Medicine have developed a novel peptide bridging technology that is a more efficient and cost-effective alternative to stapling technology for the manufacturing of peptide therapeutics.
Background
Stapled peptide technology utilizes chemical bonds to constrain peptides into a-helical conformations and results in an extension of potency due to increased resistance to proteases as well as greater cell permeability and bioactivity by the protein. Thus, stapled peptides have emerged as promising therapeutic candidates for treating a variety of human diseases. Numerous studies have been carried out to develop bioactive-stapled peptides. Among them, there are ring closing metathesis (RCM), azide-alkyne Huisgen cycloaddition (CuAAC), alkylation of cysteine, and lactam bridge formation. However, the RCM and CuAAC methods are very expensive and the latter two methods are generally low efficiency reactions. To address these problems, UCLA researchers have developed an alternative approach to producing stapled peptides that of very low cost and high efficiency.
Innovation
The novel approach developed from UCLA utilizes compounds for simultaneous S-alkylation of two strategically placed cysteine residues within the peptide, resulting in the formation of bis(thioether)-Aryl-Bridge (tABTM). The compounds necessary for this approach are both commercially available and inexpensive. The tABTM reaction can be performed both on resin and in solution. Two potential anticancer agents engineered by the tABTM approach possessed biological activity in vitro and in vivo.
Applications
Production of peptide-based therapeutics
Advantages
State Of Development
Some of the tAB-developed peptides showed in vitro and in vivo bioactivity.