Abstract
Fifteen murine monoclonal antibodies (mAb) were produced that reacted with conformational epitopes present on the Fc portion of all human IgG subclasses (PAN-Fc). Inhibition and sandwich ELISA were used to elucidate overlapping and distinct epitopes. The epitopes were aligned to form a continuous "chain" of overlapping determinants from the CH2-CH3 interface to the direction of hinge.
The five more hinge-proximal epitopes demonstrated high lability both in competitive and sandwich assays, being completely or partially destroyed when any of these 15 other mAb bound the IgG first. Heat-inactivation of IgG caused full disruption of these epitopes. In contrast, epitopes situated at the opposite distal of the "chain" were more stable and mAb binding could only be affected by occupying an overlapping epitope. Under heat-inactivation these epitopes were affected, but not completely destroyed.
Human IgG class anti-DNA autoantibodies were bound to insolubilized dsDNA and their reaction with PAN-Fc mAb was studied. mAb titration plots on IgG and dsDNA-IgG were compared. Five epitopes proved to be altered by antigen (dsDNA) binding. Two of these were the labile hinge-proximal epitopes and the other three were situated near the CH2-CH3 interface. Cross-reactivity of mAb with xenogeneic IgG was also studied. An "epitope map" of the crystallographic model of human IgG Fc portion drawn was based on these experimental data and printed matter, concerning the location of subclass-specific amino acids and homology regions of human and animal IgG.
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