Isothermal titration calorimetry determination of thermodynamics of binding of cocaine and its metabolites to humanized h2E2 anti-cocaine mAb

Abstract

We analyzed the thermodynamics of binding of cocaine and several cocaine metabolites to a humanized anti-cocaine mAb (h2E2), which is under development for the treatment of cocaine use disorders, using isothermal titration calorimetry. The calculated equilibrium dissociation (binding) constants were consistent with previous findings using other methods. All three ligands that display high affinity (nM) binding to the mAb (cocaine, cocaethylene, and benzoylecgonine) displayed similar enthalpically driven binding with substantial enthalpy-entropy compensation. The increased affinity of the cocaethylene metabolite compared to cocaine and benzoylecgonine is mostly attributable to a substantially less negative entropic binding component for cocaethylene, resulting in a more favorable binding energy, and thus, a higher affinity. The much lower affinity cocaine metabolites, norcocaine and ecgonine methyl ester, have much lower binding enthalpies than the high affinity ligands, and in contrast to the three high affinity ligands, have favorable (positive) entropic thermodynamic components of binding. Surprisingly, approximately 3.7 molecules of norcocaine are bound per mAb Fab site, as determined by isothermal titration calorimetry. This is in contrast to the three high affinity ligands, which bound with the expected stoichiometry of one drug molecule bound per one mAb Fab site. The results are discussed in relation to the previously published Fab:benzoylecgonine crystal structure for this h2E2 mAb, and compared to the isothermal titration calorimetry results published previously using an unrelated anti-cocaine mAb, mAb08.