Characterization of the 4D5Flu single‐chain antibody with a stimulus‐responsive elastin‐like peptide linker: A potential reporter of peptide linker conformation

Single‐chain antibodies (scFvs) are comprised of IgG variable light and variable heavy domains tethered together by a peptide linker whose length and sequence can affect antigen binding properties. The ability to modulate antigen binding affinity through the use of environmental triggers would be of great interest for many biotechnological applications. We have characterized the antigen binding properties of an anti‐fluorescein scFv, 4D5Flu, containing stimulus‐responsive short elastin‐like peptide linkers and nonresponsive flexible linkers. Comparison of length‐matched flexible and short elastin‐like peptide linkers indicates that a stimulus‐responsive linker can confer stimulus‐responsive control of fluorescein binding. A linker length of either six or 10 amino acids proved to have the largest thermally induced response. Similar differences in binding free energy changes indicate a common underlying mechanism of thermal responsiveness. Contrary to the thermal behavior, the effect of salt, another elastin β‐turn‐inducing stimulus, stabilized antigen binding in the six‐ and 10‐amino‐acid linkers such that elastin‐like linkers became less stimulus‐responsive as compared with flexible linkers. Again, the thermodynamic analysis indicates a common mechanism of salt responsiveness. Characterization of the room‐temperature binding affinities and evidence indicating a dimeric state of the scFvs concomitantly suggest the major contribution to the stimulus‐responsive behavior derives from the perturbation of interdomain associations, rather than the linker‐constrained disruption of the intramolecular association. The ability to use stimulus‐responsive peptide modules to exert a novel control over protein function will likely find application in the creation of allosteric antibodies and scFv‐based biosensors, and as a platform to enable the evolution of new stimulus‐responsive peptides.