Transition-state theory and secondary forces in antigen--antibody complexes.

Secondary forces, defined as those interactions between the antigen (epitope including the surrounding environment) and areas immediately adjacent to the antibody active site, were investigated using monofluorescein-derivatized synthetic peptides of varying electrostatic properties. Secondary forces were quantitated by measuring the unimolecular rate constants at two different temperatures using the high-affinity anti-fluorescein monoclonal antibody 4-4-20 complexed with fluorescein-derivatized synthetic peptides. Unimolecular rate constants were correlated with transition-state theory to explain secondary effects. An acidic peptide produced a large temperature-dependent effect upon binding including a significant enthalpic factor (+33.28 kcal/mol) relative to the binding of fluorescein ligand (+23.96 kcal/mol). Binding of a basic peptide produced both a relatively smaller temperature effect and enthalpy factor than fluorescein ligand. The antibody-ligand binding results were interpreted invoking the concepts of thermally averaged metatypic (liganded) states of the antibody as well as potential biochemical interactions between the antigen and accessible surface regions of the antibody's complementarity determining regions.