The biosynthesis of the active metal-bound form of the nickel-dependent enzyme urease involves the formation of a lysine-carbamate functional group concomitantly with the delivery of two Ni(2+) ions into the precast active site of the apoenzyme and with GTP hydrolysis. In the urease system, this role is performed by UreG, an accessory protein belonging to the group of homologous P-loop GTPases, often required to complete the biosynthesis of nickel-enzymes. This study is focused on UreG from Helicobacter pylori (HpUreG), a bacterium responsible for gastric ulcers and cancer, infecting large part of the human population, and for which urease is a fundamental virulence factor. The soluble HpUreG was expressed in E. coli and purified to homogeneity. On-line size exclusion chromatography and light scattering indicated that apo-HpUreG exists as a monomer in solution. Circular dichroism, which demonstrated the presence of a well-defined secondary structure, and NMR spectroscopy, which revealed a large number of residues that appear structured on the basis of their backbone amide proton chemical shift dispersion, indicated that, at variance with other UreG proteins so far characterized, this protein is significantly folded in solution. The amino acid sequence of HpUreG is 29% identical to that of HypB from Methanocaldococcus jannaschii, a dimeric zinc-binding GTPase involved in the in vivo assembly of [Ni,Fe]-hydrogenase. A homology-based molecular model of HpUreG was calculated, which allowed us to identify structural and functional features of the protein. Isothermal titration microcalorimetry demonstrated that HpUreG specifically binds 0.5 equivalents of Zn(2+) per monomer (K(d) = 0.33 +/- 0.03 microM), whereas it has 20-fold lower affinity for Ni(2+) (K(d) = 10 +/- 1 microM). Zinc ion binding (but not Ni(2+) binding) causes protein dimerization, as confirmed using light scattering measurements. The structural rearrangement occurring upon Zn(2+)-binding and consequent dimerization was evaluated using circular dichroism and fluorescence spectroscopy. Fully conserved histidine and cysteine residues were identified and their role in zinc binding was verified by site-directed mutagenesis and microcalorimetry. The results are analyzed and discussed with respect to analogous examples of GTPases in nickel metabolism.
Dual fluorescence is an anomalous photophysical phenomenon observed in very few chromophores in which a two-color radiative process occurs that involves two distinct excited electronic states. To date its observation was linked either to electronic rearrangement of an excited fluorophore leading to two conformers with distinct emissive properties, or to a photochemical modification leading to different fluorescent species. In both cases, emission originates from the lowest excited state of the resulting molecular configurations, in line with the so-called Kasha's rule. We report here a combined theoretical and spectroscopic study showing, for the first time, an anti-Kasha dual-emission mechanism, in which simultaneous two-color emission takes place from the first and second excited state of a coumarin derivative. We argue that the observed environmental sensitivity of this peculiar optical response makes the present compound ideally suited for biosensing applications in living cells.
UreG is an essential protein for the in vivo activation of urease. In a previous study, UreG from Bacillus pasteurii was shown to behave as an intrinsically unstructured dimeric protein. Here, intrinsic and extrinsic fluorescence experiments were performed, in the absence and presence of denaturant, to provide information about the form (fully folded, molten globule, premolten globule, or random coil) that the native state of BpUreG assumes in solution. The features of the emission band of the unique tryptophan residue (W192) located on the C-terminal helix, as well as the rate of bimolecular quenching by potassium iodide, indicated that, in the native state, W192 is protected from the aqueous polar solvent, while upon addition of denaturant, a conformational change occurs that causes solvent exposure of the indole side chain. This structural change, mainly affecting the C-terminal helix, is associated with the release of static quenching, as shown by resolution of the decay-associated spectra. The exposure of protein hydrophobic sites, monitored using the fluorescent probe bis-ANS, indicated that the native dimeric state of BpUreG is disordered even though it maintains a significant amount of tertiary structure. ANS fluorescence also indicated that, upon addition of a small amount of GuHCl, a transition to a molten globule state occurs, followed by formation of a pre-molten globule state at a higher denaturant concentration. The latter form is resistant to full unfolding, as also revealed by far-UV circular dichroism spectroscopy. The hydrodynamic parameters obtained by time-resolved fluorescence anisotropy at maximal denaturant concentrations (3 M GuHCl) confirmed the existence of a disordered but stable dimeric protein core. The nature of the forces holding together the two monomers of BpUreG was investigated. Determination of free thiols in native or denaturant conditions, as well as light scattering experiments in the absence and presence of dithiothreitol as a reducing agent, under native or denaturing conditions, indicates that a disulfide bond, involving the unique conserved cysteine C68, is present under native conditions and maintained upon addition of denaturant. This covalent bond is therefore important for the stabilization of the dimer under native conditions. The intrinsically disordered structure of UreG is discussed with respect to the role of this protein as a chaperone in the urease assembly system.
In the past, enzymatic activity has always been expected to be dependent on overall protein rigidity, necessary for substrate recognition and optimal orientation. However, increasing evidence is now accumulating, revealing that some proteins characterized by intrinsic disorder are actually able to perform catalysis. Among them, the only known natural intrinsically disordered enzyme is UreG, a GTPase that, in plants and bacteria, is involved in the protein interaction network leading to Ni(2+) ions delivery into the active site of urease. In this paper, we report a detailed analysis of the unfolding behaviour of UreG from Bacillus pasteurii (BpUreG), following its thermal and chemical denaturation with a combination of fluorescence spectroscopy, calorimetry, CD and NMR. The results demonstrate that BpUreG exists as an ensemble of inter-converting conformations, whose degrees of secondary structure depend on temperature and denaturant concentration. In particular, three major types of conformational ensembles with different degrees of residual structure were identified, with major structural characteristics resembling those of a molten globule (low temperature, absence of denaturant), pre-molten globule (high temperature, absence or presence of denaturant) and random coil (low temperature, presence of denaturant). Transitions among these ensembles of conformational states occur non-cooperatively although reversibly, with a gradual loss or acquisition of residual structure depending on the conditions. A possible role of disorder in the biological function of UreG is envisaged and discussed.
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