Bacteria overexpress, under condition of starvation or oxidative stress, Dps (DNA-binding proteins from starved cells), hollow sphere formed by 12 identical subunits endowed with ferritin-like activity. The iron oxidation and incorporation in Dps take place using H2O2 produced under starvation as preferred iron oxidant, thereby protecting bacteria from oxidative damage. Even if the role of Dps is well known, the mechanism of iron oxidation and incorporation remain to be elucidated. Here, we have used the EPR technique to shed light on the Fe(II) binding and oxidation mechanism at the ferroxidase center using both the wild-type (wt) protein and mutants of the iron ligands (H31G, H43G and H31G-H43G-D58A). The EPR titration of wt Dps and the H31G mutant with Fe(II) upon H2O2 addition shows that Fe(II) is oxidized with the increase of the signal at g = 4.3, reaching a maximum for 12 Fe(II)/subunit. The EPR signal becomes negligible when the titration is carried out on the triple mutant. These experiments indicate that the iron firstly occupied the A site at the ferroxidase center and confirm that the residues H31, H43 and D58 have a key role in the iron oxidation and incorporation process. Moreover, the data indicate that the ferroxidase center, upon mutation of H31 or H43 to Gly, changes the mode of iron binding. Finally, we demonstrate here that, when the iron micelle forms, the EPR signal at g = 4.3 disappears indicating that iron leaves the ferroxidase center to reach the inner cavity.