The DNA binding proteins from starved cells from Deinococcus radiodurans, Dps1-DR2263 and Dps2-DRB0092, have a common overall structure of hollow spherical dodecamers. Their involvement in the homeostasis of intracellular metal and DNA protection was addressed. Our results show that DrDps proteins are able to oxidize ferrous to ferric iron by oxygen or hydrogen peroxide. The iron stored inside the hollow sphere cavity is fully released. Furthermore, these proteins are able to store and release manganese, suggesting they can play a role in manganese homeostasis as well. The interaction of DrDps with DNA was also addressed. Even though DrDps1 binds both linear and coiled DNA, DrDps2 preferentially binds to coiled DNA, forming different protein-DNA complexes, as clearly shown by atomic force microscopy. DrDps1 (dimer and dodecamer) and DrDps2 can protect DNA against reactive oxygen species, although the protection occurs at different Fe to protein ratios. The difference between DrDps could be the result of the DrDps1 higher iron oxidation rate in the presence of hydrogen peroxide and its higher affinity to bind DNA than in DrDps2. Using cellular extracts obtained from D. radiodurans cultures, we showed that DrDps1 oligomers observed in in vitro conditions are also present in vivo. This indicates that DrDps1 has a structural dynamic plasticity that allows its oligomeric state to change between dimer, trimer and dodecamer. This in turn suggests the existence of a regulation mechanism that modulates the oligomer equilibrium and is dependent on growth stages and environmental conditions.
The bacterium Deinococcus radiodurans is highly resistant to several stress conditions, such as radiation. According to several reports, manganese plays a crucial role in stress protection, and a high Mn/Fe ratio is essential in this process. However, mobilization of manganese and iron, and the role of DNA-binding-proteins-under-starved-conditions during oxidative-stress remained open questions. We used synchrotron-based X-ray fluorescence imaging at nano-resolution to follow element-relocalization upon stress, and its dependency on the presence of Dps proteins, using dps knockout mutants. We show that manganese, calcium, and phosphorus are mobilized from rich-element regions that resemble electron-dense granules towards the cytosol and the cellular membrane, in a Dps-dependent way. Moreover, iron delocalizes from the septum region to the cytoplasm affecting cell division, specifically in the septum formation. These mechanisms are orchestrated by Dps1 and Dps2, which play a crucial role in metal homeostasis, and are associated with the D. radiodurans tolerance against reactive oxygen species.
The protective mechanisms of Deinococcus radiodurans against primary reactive oxygen species involve nonenzymatic scavengers and a powerful enzymatic antioxidant system including catalases, peroxidases and superoxide dismutases that prevents oxidative damage. Catalase is an enzyme that is responsible for the conversion of H 2 O 2 to O 2 and H 2 O, protecting the organism from the oxidative effect of H 2 O 2 . This study reports the purification and crystallization of the DR1998 catalase from D. radiodurans. The crystals diffracted to 2.6 Å resolution and belonged to space group C222 1 , with unit-cell parameters a = 97.33, b = 311.88, c = 145.63 Å , suggesting that they contain four molecules per asymmetric unit. The initial phases were determined by molecular replacement and the obtained solution shows the typical catalase quaternary structure. A preliminary model of the protein structure has been built and refinement is currently in progress.
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