Cuproxidases form a subgroup of the blue multicopper oxidase family. They display disordered methionine-rich loops, not observable in most available crystal structures, which have been suggested to bind toxic Cu(I) ions before oxidation into less harmful Cu(II) by the core enzyme. We found that the location of the Met-rich regions is highly variable in bacterial cuproxidases, but always inserted in solvent exposed surface loops, at close proximity of the conserved T1 copper binding site. We took advantage of the large differences in loop length between cold-adapted, mesophilic and thermophilic oxidase homologs to unravel the function of the methionine-rich regions involved in copper detoxification. Using a newly developed anaerobic assay for cuprous ions, it is shown that the number of Cu(I) bound is nearly proportional to the loop lengths in these cuproxidases and to the number of potential Cu(I) ligands in these loops. In order to substantiate this relation, the longest loop in the cold-adapted oxidase was deleted, lowering bound extra Cu(I) from 9 in the wild-type enzyme to 2-3 Cu(I) in deletion mutants. These results demonstrate that methionine-rich loops behave as molecular octopus scavenging toxic cuprous ions in the periplasm and that these regions are essential components of bacterial copper resistance.
Keywords: Copper resistance; CueO; Cuproxidases; Extremophiles; Laccase; Multicopper oxidase.
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