Role of the mobility of antigen binding site in high affinity antibody elucidated by surface plasmon resonance

Antibody is known to exhibit conformational change in the antigen recognition site after forming the initial complex. This structural change, which is widely known as "induced fit", is believed to be critical for high affinity (Kd of nM range) of antigen-antibody interaction. Elucidation of this 'induced fit' process is essential for rational design of high affinity antibody, while it is prevented by limitation of the available biophysical and biochemical data of the initial complex. Here, we performed kinetic and thermodynamic analysis of the interaction between single-chain variable fragment (denoted as scFv) of 64M5 antibody and a (6-4) photoproduct by using surface plasmon resonance (denoted as SPR). It revealed that the 64M5scFv associates the (6-4) photoproduct at initial step by hydrophobic interactions, and enthalpy-driving interactions, hydrogen bonds and van der Waals interactions, were formed by second step structural rearrangement. Furthermore, mutational analysis revealed that the mobility of the antigen-binding site is critical for the second step. It could be assumed that optimization of the mobility of the antigen recognition site is a clue for rational design of high affinity antibody.