Helix stability in barstar peptides.

The complex between the ribonuclease barnase and barstar, its intracellular inhibitor, is a very good model for studying protein folding and molecular recognition. We have studied the stability of different peptides that cover the barstar alpha-helix2 involved in the binding to barnase. A linear correlation between the helical amphipathy of these peptides and their inhibitory ability was obtained: the more helically amphipathic, the more the affinity for barnase. We estimated the amount of helix of these peptides in water and in trifluoroethanol by circular dichroism. There is a moderate correlation between the helical amphipathy and the helical content in water, in agreement with previous results that have shown the importance of the hydrophobicity periodicity in the design of peptides. The helical content in trifluoroethanol is related to helical propensity and helical amphipathy, suggesting that the local sequence determines these maximum helicities. The predicted helicity of these peptides, obtained using the algorithm AGADIR [Muñoz, V. & Serrano, L. (1994) Nat. Struct. Biol. 1, 399-409], appears to correlate with their ability to inhibit the activity of barnase in water. The correlation of inhibition constants, helical content in water, and maximum content of helix in trifluoroethanol with helical amphipathy supports the very important role of hydrophobicity pattern in peptide stability.

Circular dichroism of denatured barstar suggests residual structure,.

The circular dichroism (CD) spectrum of the denatured state of barstar has been analyzed as a function of urea and temperature. The near- and far-UV CD spectra change very rapidly in magnitude and shape with increasing temperature, unlike those of native protein, suggesting the presence of residual structure that changes with denaturing conditions. The effect of mutations indicates that there is residual structure in helix1 of the protein, consistent with NMR data. The changes in CD with conditions are consistent with the denatured state being a mixture of conformations of similar energy.

The folding pathway of a protein at high resolution from microseconds to seconds.

We have documented the folding pathway of the 10-kDa protein barstar from the first few microseconds at the resolution of individual residues from its well characterized denatured state. The denatured state had been shown from NMR to have flickering native-like structure in the first two of its four alpha-helices. phi-value analysis shows that the first helix becomes substantially consolidated as the intermediate is formed in a few hundred microseconds, as does the second to a lesser extent. A native-like structure then is formed in a few hundred milliseconds as the whole structure consolidates. Peptide fragments corresponding to sequences containing the first two helices separately and together as a helix-loop-helix motif have little helical structure under conditions that favor folding. The early stages of folding fit the nucleation-condensation model that was proposed for the smaller chymotrypsin inhibitor 2, which is a single module of structure and folds by two-state kinetics. The early stages of the multistate folding of the larger, multimodular, barnase have proved experimentally inaccessible. The folding pathway of barstar links those of CI2 and barnase to give a unified scheme for folding.

A strategy of exon shuffling for making large peptide repertoires displayed on filamentous bacteriophage.

It has been suggested that recombination and shuffling between exons has been a key feature in the evolution of proteins. We propose that this strategy could also be used for the artificial evolution of proteins in bacteria. As a first step, we illustrate the use of a self-splicing group I intron with inserted lox-Cre recombination site to assemble a very large combinatorial repertoire (> 10(11) members) of peptides from two different exons. Each exon comprised a repertoire of 10 random amino acids residues; after splicing, the repertoires were joined together through a central five-residue spacer to give a combinatorial repertoire of 25-residue peptides. The repertoire was displayed on filamentous bacteriophage by fusion to the pIII phage coat protein and selected by binding to several proteins, including beta-glucuronidase. One of the peptides selected against beta-glucuronidase was chemically synthesized and shown to inhibit the enzymatic activity (inhibition constant: 17 nM); by further exon shuffling, an improved inhibitor was isolated (inhibition constant: 7 nM). Not only does this approach provide the means for making very large peptide repertoires, but we anticipate that by introducing constraints in the sequences of the peptides and of the linker, it may be possible to evolve small folded peptides and proteins.