This article appeared in a journal published by Elsevier. The attached copy is furnished to the author for internal non-commercial research and education use, including for instruction at the authors institution and sharing with colleagues.Other uses, including reproduction and distribution, or selling or licensing copies, or posting to personal, institutional or third party websites are prohibited. Background: In Gram-negative bacteria the ZnuABC transporter ensures adequate zinc import in Zn(II)-poor environments, like those encountered by pathogens within the infected host. Recently, the metal-binding protein ZinT was suggested to operate as an accessory component of ZnuABC in periplasmic zinc recruitment. Since ZinT is known to form a ZinT-ZnuA complex in the presence of Zn(II) it was proposed to transfer Zn(II) to ZnuA. The present work was undertaken to test this claim. Methods: ZinT and its structural relationship with ZnuA have been characterized by multiple biophysical techniques (X-ray crystallography, SAXS, analytical ultracentrifugation, fluorescence spectroscopy). Results: The metal-free and metal-bound crystal structures of Salmonella enterica ZinT show one Zn(II) binding site and limited structural changes upon metal removal. Spectroscopic titrations with Zn(II) yield a K D value of 22 ± 2 nM for ZinT, while those with ZnuA point to one high affinity (K D b 20 nM) and one low affinity Zn(II) binding site (K D in the micromolar range). Sedimentation velocity experiments established that Zn(II)-bound ZinT interacts with ZnuA, whereas apo-ZinT does not. The model of the ZinT-ZnuA complex derived from small angle X-ray scattering experiments points to a disposition that favors metal transfer as the metal binding cavities of the two proteins face each other. Conclusions: ZinT acts as a Zn(II)-buffering protein that delivers Zn(II) to ZnuA. General significance: Knowledge of the ZinT-ZnuA relationship is crucial for understanding bacterial Zn(II) uptake.
The cyanobacterium Thermosynechococcus elongatus is one the few bacteria to possess two Dps proteins, DpsA‐Te and Dps‐Te. The present characterization of DpsA‐Te reveals unusual structural and functional features that differentiate it from Dps‐Te and the other known Dps proteins. Notably, two Zn(II) are bound at the ferroxidase center, owing to the unique substitution of a metal ligand at the A‐site (His78 in place of the canonical aspartate) and to the presence of a histidine (His164) in place of a hydrophobic residue at a metal‐coordinating distance in the B‐site. Only the latter Zn(II) is displaced by incoming iron, such that Zn(II)–Fe(III) complexes are formed upon oxidation, as indicated by absorbance and atomic emission spectroscopy data. In contrast to the typical behavior of Dps proteins, where Fe(II) oxidation by H2O2 is about 100‐fold faster than by O2, in DpsA‐Te the ferroxidation efficiency of O2 is very high and resembles that of H2O2. Oxygraphic experiments show that two Fe(II) are required to reduce O2, and that H2O2 is not released into solution at the end of the reaction. On this basis, a reaction mechanism is proposed that also takes into account the formation of Zn(II)–Fe(III) complexes. The physiological significance of the DpsA‐Te behavior is discussed in the framework of a possible localization of the protein at the thylakoid membranes, where photosynthesis takes place, with the consequent increased formation of reactive oxygen species.
Structured digital abstract
http://mint.bio.uniroma2.it/mint/search/interaction.do?interactionAc=MINT-7312099: DpsA (uniprotkb:http://www.uniprot.org/uniprot/Q8DL82?format=text&ascii) and DpsA (uniprotkb:http://www.uniprot.org/uniprot/Q8DL82?format=text&ascii) bind (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0407) by x‐ray crystallography (http://www.ebi.ac.uk/ontology-lookup/?termId=MI:0114)
DNA‐binding proteins from starved cells (Dps proteins) protect bacteria primarily from oxidative damage. They are composed of 12 identical subunits assembled with 23‐symmetry to form a compact cage‐like structure known to be stable at temperatures > 70 °C and over a wide pH range. Thermosynechococcus elongatus Dps thermostability is increased dramatically relative to mesophilic Dps proteins. Hydrophobic interactions at the dimeric and trimeric interfaces called Dps‐like are replaced by salt bridges and hydrogen bonds, a common strategy in thermophiles. Moreover, the buried surface area at the least‐extended Dps‐like interface is significantly increased. A peculiarity of T. elongatus Dps is the presence of a chloride ion coordinated with threefold symmetry‐related arginine residues lining the opening of the Dps‐like pore toward the internal cavity. T. elongatus Dps conserves the unusual intersubunit ferroxidase centre that allows the Dps protein family to oxidize Fe(II) with hydrogen peroxide, thereby inhibiting free radical production via Fenton chemistry. This catalytic property is of special importance in T. elongatus (which lacks the catalase gene) in the protection of DNA and photosystems I and II from hydrogen peroxide‐mediated oxidative damage.
Site-directed mutagenesis was performed on a set of six aspartate residues of Fet3, the multicopper ferroxidase involved in high-affinity iron transport in Saccharomyces cerevisiae, in order to comprehend the molecular determinants of the protein function. Asp312, Asp315, Asp319 and Asp320 were predicted by homology modelling to be located in a negatively charged surface-exposed loop of the protein. Other two aspartate residues (Asp278 and Asp279) are placed close to the type 1 copperand iron-binding sites, possibly linking these sites to the negatively charged region. In vivo results showed that mutation of Asp319 and Asp320 to yield D319N and D320N derivatives strongly impairs the ability of the yeast to grow under ironlimiting conditions. In particular, substitution of Asp320 with asparagine essentially abolished the Fet3-dependent iron transport activity. All other mutants (D278Q, D279N, D312N and D315I) behaved essentially as the wild-type protein. The electron paramagnetic resonance spectrum of the soluble forms of D319N and D320N showed significant changes of the copper sites' geometry in D319N but not in D320N. At variance with the membrane-bound forms, soluble D319N and D320N derivatives were highly susceptible to proteolytic degradation, suggesting that replacement of Asp319 or Asp320 locally modifies the structure of Fet3, making the protein sensitive to proteolysis when it is not protected by the membrane environment. In turn, this might be evidence of a shielding role of the permease Ftr1, which could interact with Fet3 at the level of the aspartate-rich negatively charged region.
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