BACKGROUND: Molecular diversity in nature is developed through a combination of genetic and chemical elements. We have developed a method that permits selective manipulation of both these elements in one protein engineering tool. It combines the ability to introduce non-natural amino acids into a protein using native chemical ligation with exhaustive targeted mutagenesis of the protein via phage-display mutagenesis. RESULTS: A fully functional biosynthetic version of the protease inhibitor eglin c was constructed. The amino-terminal fragment (residues 8-40) was chemically synthesized with a non-natural amino acid at position 25. The remaining carboxy-terminal fragment was expressed as a 30-residue peptide extension of gIIIp or gVIIIp on filamentous phage in a phage-display mutagenesis format. Native chemical ligation was used to couple the two fragments and produced a protein that refolded to its active form. To facilitate the packing of the introduced non-natural amino acid, residues 52 and 54 in the carboxy-terminal fragment were fully randomized by phage-display mutagenesis. Although the majority of the observed solutions for residues 52 and 54 were hydrophobic - complementing the stereochemistry of the introduced non-natural amino acid - a significant number of residues (unexpected because of stereochemical and charge criteria) were observed in these positions. CONCLUSIONS: Peptide synthesis and phage-display mutagenesis can be combined to produce a very powerful protein engineering tool. The physical properties of the environment surrounding the introduced non-natural residue can be selected for by evaluating all possible combinations of amino acid types at a targeted set of sites using phage-display mutagenesis.
BACKGROUND: Molecular diversity in nature is developed through a combination of genetic and chemical elements. We have developed a method that permits selective manipulation of both these elements in one protein engineering tool. It combines the ability to introduce non-natural amino acids into a protein using native chemical ligation with exhaustive targeted mutagenesis of the protein via phage-display mutagenesis. RESULTS: A fully functional biosynthetic version of the protease inhibitor eglin c was constructed. The amino-terminal fragment (residues 8-40) was chemically synthesized with a non-natural amino acid at position 25. The remaining carboxy-terminal fragment was expressed as a 30-residue peptide extension of gIIIp or gVIIIp on filamentous phage in a phage-display mutagenesis format. Native chemical ligation was used to couple the two fragments and produced a protein that refolded to its active form. To facilitate the packing of the introduced non-natural amino acid, residues 52 and 54 in the carboxy-terminal fragment were fully randomized by phage-display mutagenesis. Although the majority of the observed solutions for residues 52 and 54 were hydrophobic - complementing the stereochemistry of the introduced non-natural amino acid - a significant number of residues (unexpected because of stereochemical and charge criteria) were observed in these positions. CONCLUSIONS: Peptide synthesis and phage-display mutagenesis can be combined to produce a very powerful protein engineering tool. The physical properties of the environment surrounding the introduced non-natural residue can be selected for by evaluating all possible combinations of amino acid types at a targeted set of sites using phage-display mutagenesis.
Authors: Xiaojuan Khoo; George A O'Toole; Shrikumar A Nair; Brian D Snyder; Daniel J Kenan; Mark W Grinstaff Journal: Biomaterials Date: 2010-09-22 Impact factor: 12.479
Authors: Tjibbe Bosma; Anneke Kuipers; Erna Bulten; Louwe de Vries; Rick Rink; Gert N Moll Journal: Appl Environ Microbiol Date: 2011-08-05 Impact factor: 4.792
Authors: Steven R Meyers; Xiaojuan Khoo; Xin Huang; Elisabeth B Walsh; Mark W Grinstaff; Daniel J Kenan Journal: Biomaterials Date: 2008-10-17 Impact factor: 12.479