Urease activation is critical to the virulence of many human and animal pathogens. Urease possesses multiple, nickel-containing active sites, and UreE, the only nickel-binding protein among the urease accessory proteins, activates urease by transporting nickel ions. We performed NMR experiments to investigate the solution structure and the nickel-binding properties of Bacillus pasteurii (Bp) UreE. The secondary structures and global folds of BpUreE were determined for its metal-free and nickel-bound forms. The results indicated that no major structural change of BpUreE arises from the nickel binding. In addition to the previously identified nickel-binding site (Gly 97 -Cys 103 ), the C-terminal tail region (Lys 141 -His 147 ) was confirmed for the first time to be involved in the nickel binding. The C-terminally conserved sequence ( 144 GHQH 147 ) was confirmed to have an inherent nickel-binding ability. Nickel addition to 1.6 mM subunit, a concentration where BpUreE predominantly forms a tetramer upon the nickel binding, induced a biphasic spectral change consistent with binding of up to at least three nickel ions per tetrameric unit. In contrast, nickel addition to 0.1 mM subunit, a concentration at which the protein is primarily a dimer, caused a monophasic spectral change consistent with more than 1 equivalent per dimeric unit. Combined with the equilibrium dialysis results, which indicated 2.5 nickel equivalents binding per dimer at a micromolar protein concentration, the nickel-binding stoichiometry of BpUreE at a physiological concentration could be three nickel ions per dimer. Altogether, the present results provide the first detailed structural data concerning the nickel-binding properties of intact, wild-type BpUreE in solution.
SAV0506 is an 87 residue hypothetical protein from Staphylococcus aureus strain Mu50 and also predicted to have similar function to ribosome associated heat shock protein, Hsp 15. Hsp15 is thought to be involved in the repair mechanism of erroneously produced 50S ribosome subunit. In this report, we present the sequence specific backbone resonance assignment of SAV0506. About 82.5% of all resonances could be assigned unambiguously. By analyzing deviations of the Cα and Cβ chemical shift values, we could predict the secondary structure of SAV0506. This study is an essential step towards the structural characterization of SAV0506.
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