Origins of helix-coil switching in a light-sensitive peptide.

Intramolecular cross-linking of peptides by the light-sensitive compound diiodoacetamideazobenzene has been shown to permit reversible photocontrol of the helix-coil transition. Cross-linking between Cys residues spaced at i and i + 7 positions with the trans form of the linker was found to produce a decreased helix content compared to that of the non-cross-linked peptide. Photoisomerization to the cis form of the linker led to substantially higher helix content than in the non-cross-linked peptide. Detailed conformational analysis of the system leads to the conclusion that photocontrol of helix content does not involve specific interactions between the linker and the peptide. Instead, the change in peptide helix content caused by photoisomerization can be predicted by comparing the length ranges of the cis and trans forms of the linker with the expected distance distribution of the Cys attachment points in the intrinsic conformational ensemble of the peptide. The analysis presented here should help to guide the use of these and related linkers for the conformational control of a variety of peptide and protein systems.

Achieving photo-control of protein conformation and activity: producing a photo-controlled leucine zipper.

We have recently developed a technique that has great potential in producing proteins with photo-control of conformation and consequently activity (J. R. Kumita, O. S. Smart and G. A. Woolley, Proc. Natl. Acad. Sci. U. S. A., 2000, 97, 3803-3808). The method is based on incorporating two cysteine residues into the sequence of a polypeptide. An azobenzene derivative is subsequently used to produce an intramolecular cross-link between the cysteine sulfhydryl groups. In previous work photo-isomerisation of the azobenzene moiety has been used to control the helicity of a monomeric peptide. In the experiments described here this method has been applied to the coiled coil leucine zipper peptide GCN4-p1. The aim was to produce a variant of GCN4-p1 whose helicity and consequently dimerisation is under direct photo-control. We have produced a modified GCN4-p1 incorporating two cysteine residues. The mutations introduced are shown to interfere with the ability of the uncross-linked peptide to form a coiled coil. After the peptide was cross-linked with the azobenzene derivative more normal coiled-coil behaviour was restored. Irradiation of the peptide producing a conformational change in the azobenzene cross-linker was accompanied by an increase in the helicity of the peptide. The work presented here highlights the potential of the use of photo-isomerisable cross-linkers to control protein activity through induced conformational change. In addition, the methodology has the potential to provide a fast trigger for the initiation of protein conformational changes.

Photo-control of peptide helix content by an azobenzene cross-linker: steric interactions with underlying residues are not critical.

Photo-control of protein conformation could prove useful for probing function in diverse biological systems. Recently, we reported photo-switching of helix content in a short peptide containing an azobenzene cross-linker between cysteine residues at positions i and i + 7 in the sequence. In the original sequence, underlying residues at positions i + 3 and i + 4 were made bulky as preliminary modelling suggested that this would enhance photo-control of helix content. To test this hypothesis, peptides with Val, Aib; Ile, Aib; and Ala, Ala at positions i + 3 and i + 4 were synthesized, cross-linked and characterized. Before cross-linking, the peptides show distinct conformational behaviours: two with differing helix/coil mixtures whereas the other has a circular dichroism (CD) spectrum characteristic of beta-sheet and a tendency to aggregate. However, upon cross-linking the peptides have very similar CD spectra: predominantly random coil in the dark but predominantly helical upon irradiation. These results refute the original hypothesis. Steric interactions between the linker and underlying residues do not appear to be critical for photo-switching behaviour. When the cross-linking bridge is lengthened by replacing the i, i + 7 cysteine residues with homocysteine, a lower degree of photo-control of helicity is observed. Furthermore, a non-cross-linking version of the azobenzene reagent is shown not to produce any photo-control of helicity. We conclude that the intramolecular cross-link is essential for photo-switching and that it should be applicable to a wide range of peptides and proteins.

Using an azobenzene cross-linker to either increase or decrease peptide helix content upon trans-to-cis photoisomerization.

Reversible photocontrol of peptide and protein conformation could prove to be a powerful tool for probing function in diverse biological systems. Here, we report reversible photoswitching of the helix content in short peptides containing an azobenzene cross-linker between cysteine residues at positions i, i + 4, or i, i + 11 in the sequence. Trans-to-cis photoisomerization significantly increases the helix content in the i, i + 4 case and significantly decreases the helix content in the i, i + 11 case. These cross-linker designs significantly expand the possibilities for photocontrol of peptide and protein structure.