High-affinity uranyl-specific antibodies suitable for cellular imaging.

Monoclonal antibodies (mAbs) have proved to be valuable models for the study of protein-metal interactions, and previous reports have described very specific antibodies to chelated metal ions, including uranyl. We raised specific mAbs against UO2(2+)-DCP-BSA (DCP, 1,10-phenanthroline-2,9-dicarboxylic acid) to generate new sets of antibodies that might cross-react with various complexed forms of uranyl in different environments for further application in the field of toxicology. Using counter-screening with UO2(2+)-DCP-casein, we selected two highly specific mAbs against uranyl-DCP ( K D 10-100 pM): U04S and U08S. Competitive assays in the presence of different metal ions (UO2(2+), Fe (3+), Zn2+, Cu2+, and Ca2+) showed that uranyl in solution can act as a good competitor, suggesting some antibody ability to cross-react with chelating groups other than DCP in the UO2(2+) equatorial coordination plane. Interestingly, one of the antibodies could be used for revealing uranyl cations in cell samples. Fluorescence activated cell sorting analyses after immunolabeling revealed the interaction of uranyl with human kidney cells HK2. The intracellular accumulation of uranyl could be directly visualized by metal-immunostaining using fluorescent-labeled mAb. Our results suggest that U04S mAb epitopes mostly include the uranyl fraction and its paratopes can accommodate a wide variety of chelating groups.

Covalent and noncovalent modifications induce allosteric binding behavior in a monoclonal antibody.

Detailed equilibrium binding studies were conducted on a monoclonal antibody (8A11) directed against UO22+ complexed with 2,9-dicarboxy-1,10-phenanthroline (DCP-UO22+). Covalent modification of 8A11 with amine-reactive derivatives of Cy5 or Alexa 488 altered the binding curves obtained with DCP-UO22+ from hyperbolic to sigmoidal, the latter characterized by Hill coefficients of 1.5-1.6. Binding curves obtained with DCP-UO22+ and the bivalent (Fab)2 or the monovalent Fab fragments derived from limited proteolysis of the covalently modified 8A11 were characterized by Hill coefficients of 1.2 and 1.0, respectively. Incubation of 8A11 with saturating concentrations of the Fab fragments of goat antibodies directed against the Fc portion of mouse IgG increased the affinity of the native 8A11 for DCP-UO22+ by 3-fold. Conversely, incubation of the 8A11-Cy5 covalent conjugate with saturating concentrations of protein G (which likewise binds to the constant regions of mouse IgG) decreased the affinity of the primary antibody for DCP-UO22+ by 4-fold. In addition, the binding curves obtained with 8A11-Cy5 and DCP-UO22+ species changed from sigmoidal to hyperbolic at high concentrations of protein G. The presence of the antigen had a reciprocal effect on the binding of protein G to the 8A11-Cy5 conjugate; incubation of the 8A11-Cy5 conjugate with saturating concentrations of DCP-UO22+ decreased the affinity of the conjugate for protein G by 20-fold. These complex binding data were interpreted in terms of a free energy binding model in which (i) 2 mol of DCP-UO22+ and 1 mol of protein G bind to each mole of the 8A11-Cy5 conjugate, (ii) binding of the first equivalent of DCP-UO22+ to the antibody promotes the binding of the second equivalent of antigen in the absence of protein G, and (iii) DCP-UO22+ and protein G oppose each other's binding to the antibody. This is the first detailed description of the energetic balance of reciprocal binding events among the antigen binding sites and distant points on the constant portion of an immunoglobulin.