Peptide native chemical ligation

Jung JP, Jones JL, Cronier SA et al (2008) Modulating the mechanical properties of self-assembled peptide hydrogels via native chemical ligation. Biomaterials 29 2143-2151... 

Peptides typically are prepared for this ligation process using a-alkyl thioesters, because they are simple to make at the time of peptide synthesis. However, due to the relatively slow reaction kinetics of alkyl thioesters, most native chemical ligation processes have been catalyzed through the use of thiol compound additives, such as benzyl mercaptan or thiophenol (Dawson et al., 1997). These compounds react with the initial a-alkyl thioester to form another intermediate, an aryl thioester, which is more reactive toward the N-terminal cysteine on the other peptide to be coupled. A study... 

Native chemical ligation has been used successfully to couple two unprotected peptides together during solid phase synthesis, wherein one of the peptides is attached to the resin using a thioester linkage and the other peptide is introduced containing a cysteine at its N-terminal... 

Figure 17.25 The native chemical ligation reaction can be used to form larger peptides from smaller peptides, if one contains a cysteine residue at its N-terminal and the other one contains a thioester on its C-terminal. Reaction of the peptide derivatives gives a native peptide (amide) bond.

Native chemical ligation also can be extended to the conjugation of peptides or proteins to other molecules or surfaces. For instance, Reulen et al. (2007) prepared liposomes that contained cysteine-PEG-phospholipid derivatives and then coupled thioester-modified peptides or proteins to form a protein-liposome conjugate. Using this procedure, approximately 100 molecules of a collagen binding protein could be coupled to the cysteine-containing liposomes. 

In addition, Dose and Seitz (2005) employed native chemical ligation to synthesize peptide nucleic acids (PNAs) by linking shorter segments of PNAs to make long contiguous strands, which could not be made through typical oligo synthesis procedures. 

Muir et al. (1998) realized that the intein reaction could be used to facilitate a native chemical ligation with a synthetic N-terminal cysteine-containing peptide or cysteine-containing molecule. With the discovery of a mutant intein that could form an intermediate thioester but not go on to complete the splice and ligation reaction (Xu and Perler, 1996 Chong et al.,... 

Figure 17.27 The EPL process involves a fusion protein containing an intein tag plus a CBD. The fusion protein is captured on an immobilized chitin resin and after removal of contaminating proteins, it is eluted using thiophenol, which cleaves at the thioester bond between the intein and the desired expressed protein. This releases a phenylth-ioester-activated protein that can be used in the native chemical ligation reaction with another peptide containing an N-terminal cysteine residue. Conjugation results in a native amide (peptide) bond formed between them.

However, if the expressed protein is treated on the affinity support using thiophenol, this also will release the protein and result in a phenylthioester at its C-terminal, which is the reactive intermediate imminendy suitable for native chemical ligation. Treatment of this activated thioester protein with a N-terminal cysteine peptide induces the native chemical ligation reaction and couples the peptide to the expressed protein through an amide bond (Severinov and Muir, 1998) (Figure 17.27). 

The following protocol for EPL, including purification using a CBD fusion tag followed by native chemical ligation, is based on the methods of Muir et al. (1998), Chong et al. (1997, 1998), Evans et al. (1998), Severinov and Muir (1998), and the NEB instruction manual for the IMPACT-TWIN system. The recombinant protein is recovered from the affinity column as the thioester derivative ready for reaction with a N-terminal Cys peptide or another tag containing a Cys residue. 

Dose, C., and Seitz, O. (2005) Convergent synthesis of peptide nucleic acids by native chemical ligation. Org. Lett. 7(20), 4365-4368. 

Paramonov SE, Gauba V, Hartgerink JD. Synthesis of coUagen-Uke peptide polymers by native chemical ligation. Macromolecules 2005 38 7555-7561. 

Two approaches for solid-phase chemical ligation have been described. Canne et al. have developed an elegant system that utilizes an oxime forming ligation to attach the first peptide to the resin, a selectively cleavable ester link to remove the peptide from the resin as a C-terminal carboxylic acid, and the Acm group to protect the N-terminal cysteine residue)311 A complementary approach has been developed by Brik et al. that utilizes native chemical ligation to attach the first peptide to the solid support, a safety-catch acid labile linker to remove the final polypeptide from the support as a C-terminal amide and either Acm or Msc group for N-terminal cysteine protection)32 ... 

When synthesizing proteins it is natural to think first in terms of the creation of a backbone consisting only of peptide bonds. Two approaches are used in semisynthesis native chemical ligation and reverse proteolysis. 

Native chemical ligation of unprotected peptide segments involves reaction between a peptide-o -thioester and an N-terminal cysteine-peptide to yield a product with a... 

At present, it appears that the most powerful method for the coupling of two unprotected peptide segments is the Native Chemical Ligation (NCL) developed by Dawson and Kent [21], As indicated by its name, NCL gives rise to the formation of a natural peptide bond. This reaction was described in principle as early as 1953, by Wieland, who reported that the reaction between the (S)-valine thiophenyl ester 22 and cysteine 23 proceeded by transfer of... 

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