Targeted theranostics heavily rely on metal isotopes conjugated to antibodies. Single-domain antibodies, known as nanobodies, are much smaller in size without compromising specificity and affinity. The conventional way of conjugating metals to nanobodies involves non-specific modification of amino acid residues with bifunctional chelating agents. We demonstrate that mutagenesis of a single residue in a nanobody creates a triple cysteine motif that selectively binds bismuth which is, for example, used in targeted alpha therapy. Two mutations create a quadruple cysteine mutant specific for gallium and indium used in positron emission tomography and single-photon emission computed tomography, respectively. Labelling is quantitative within a few minutes. The metal nanobodies maintain structural integrity and stability over weeks, resist competition from endogenous metal binders like glutathione, and retain functionality.
Keywords: bismuth; gallium; indium; nanobody; theranostics.
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