P Kristensen1, G Winter. 1. MRC, Centre for Protein Engineering, Hills Road, Cambridge, CB2 2QH, UK. pk2@mrc-lmb.cam.ac.uk
Abstract
BACKGROUND: Filamentous bacteriophages have been used for the selection of folded peptide and protein 'ligands' by binding the phage to 'receptor'-coated solid phase. Here, using proteolysis, we have developed a technique for the selection of folded and stable proteins that is independent of their binding activities. RESULTS: When a 21-residue peptide comprising a protease cleavage site was introduced into the flexible linker between the second and third domains of the minor coat protein p3 of filamentous bacteriophage, the phages could be cleaved by trypsin and were rendered non-infective. By contrast, phages displaying mutant barnases at this site were resistant to proteolysis, but were cleaved and their infectivity was destroyed as the temperature was raised. By mixing phages bearing two barnase mutants of differing stability, and adding protease at a temperature at which one mutant was resistant and the other was sensitive, we were able to enrich by 1.6 x 10(4)-fold for phages bearing the more stable barnase. CONCLUSIONS: The approach provides a means for the selection of folded and stable proteins, and may be applicable to the selection of de novo proteins.
BACKGROUND: Filamentous bacteriophages have been used for the selection of folded peptide and protein 'ligands' by binding the phage to 'receptor'-coated solid phase. Here, using proteolysis, we have developed a technique for the selection of folded and stable proteins that is independent of their binding activities. RESULTS: When a 21-residue peptide comprising a protease cleavage site was introduced into the flexible linker between the second and third domains of the minor coat protein p3 of filamentous bacteriophage, the phages could be cleaved by trypsin and were rendered non-infective. By contrast, phages displaying mutant barnases at this site were resistant to proteolysis, but were cleaved and their infectivity was destroyed as the temperature was raised. By mixing phages bearing two barnase mutants of differing stability, and adding protease at a temperature at which one mutant was resistant and the other was sensitive, we were able to enrich by 1.6 x 10(4)-fold for phages bearing the more stable barnase. CONCLUSIONS: The approach provides a means for the selection of folded and stable proteins, and may be applicable to the selection of de novo proteins.
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