Characterization of Americium and Curium Complexes with the Protein Lanmodulin: A Potential Macromolecular Mechanism for Actinide Mobility in the Environment Article Swipe
YOU?
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· 2021
· Open Access
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· DOI: https://doi.org/10.1021/jacs.1c07103
· OA: W3199101324
Anthropogenic radionuclides, including long-lived heavy actinides such as americium and curium, represent the primary long-term challenge for management of nuclear waste. The potential release of these wastes into the environment necessitates understanding their interactions with biogeochemical compounds present in nature. Here, we characterize the interactions between the heavy actinides, Am<sup>3+</sup> and Cm<sup>3+</sup>, and the natural lanthanide-binding protein, lanmodulin (LanM). LanM is produced abundantly by methylotrophic bacteria, including <i>Methylorubrum extorquens</i>, that are widespread in the environment. We determine the first stability constant for an Am<sup>3+</sup>-protein complex (Am<sub>3</sub>LanM) and confirm the results with Cm<sub>3</sub>LanM, indicating a ∼5-fold higher affinity than that for lanthanides with most similar ionic radius, Nd<sup>3+</sup> and Sm<sup>3+</sup>, and making LanM the strongest known heavy actinide-binding protein. The protein's high selectivity over <sup>243</sup>Am's daughter nuclide <sup>239</sup>Np enables lab-scale actinide-actinide separations as well as provides insight into potential protein-driven mobilization for these actinides in the environment. The luminescence properties of the Cm<sup>3+</sup>-LanM complex, and NMR studies of Gd<sup>3+</sup>-LanM, reveal that lanmodulin-bound f-elements possess two coordinated solvent molecules across a range of metal ionic radii. Finally, we show under a wide range of environmentally relevant conditions that lanmodulin effectively outcompetes desferrioxamine B, a hydroxamate siderophore previously proposed to be important in trivalent actinide mobility. These results suggest that natural lanthanide-binding proteins such as lanmodulin may play important roles in speciation and mobility of actinides in the environment; it also suggests that protein-based biotechnologies may provide a new frontier in actinide remediation, detection, and separations.
