Publications (14) View all
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Article: Characterization of ancient and modern papers by CW-EPR spectroscopy
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ABSTRACT: Several old (15th to 18th century), new (1900–1950) and recently produced (after 1990) papers have been investigated by X-band continuous-wave electron paramagnetic resonance (EPR) spectroscopy. Signals from Cu(II), Fe(III), Mn(II) and radicals are apparent. A clear-cut distinction is observed between recently produced papers and the other samples: recent papers show just EPR signals from Mn(II) and sometimes small signals from Fe(III) in rhombic site, while the older samples show usually strong signals from Fe(III), Mn(II), Cu(II) and radicals. Furthermore, Mn(II) EPR signals from recent papers are characterized by small zero-field splitting (ZFS) parameters, indicating Mn(II) in high-symmetry sites, while older samples show broader Mn(II) EPR signals, typical for Mn(II) in low-symmetry sites (increased ZFS parameters).Applied Magnetic Resonance 04/2012; 35(2):213-220. · 0.75 Impact Factor -
Article: Structural characterization of a high affinity mononuclear site in the copper(II)-α-synuclein complex.
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ABSTRACT: Human α-Synuclein (aS), a 140 amino acid protein, is the main constituent of Lewy bodies, the cytoplasmatic deposits found in the brains of Parkinson's disease patients, where it is present in an aggregated, fibrillar form. Recent studies have shown that aS is a metal binding protein. Moreover, heavy metal ions, in particular divalent copper, accelerate the aggregation process of the protein. In this work, we investigated the high affinity binding mode of truncated aS (1-99) (aS99) with Cu(II), in a stoichiometric ratio, to elucidate the residues involved in the binding site and the role of copper ions in the protein oligomerization. We used Electron Paramagnetic Resonance spectroscopy on the Cu(II)-aS99 complex at pH 6.5, performing both multifrequency continuous wave experiments and pulsed experiments at X-band. The comparison of 9.5 and 95 GHz data showed that at this pH only one binding mode is present. To identify the nature of the ligands, we performed Electron Spin Echo Envelope Modulation, Hyperfine Sublevel Correlation Spectroscopy, and pulsed Davies Electron-Nuclear Double Resonance (Davies-ENDOR) experiments. We determined that the EPR parameters are typical of a type-II copper complex, in a slightly distorted square planar geometry. Combining the results from the different pulsed techniques, we obtained that the equatorial coordination is {N(Im), N(-), H(2)O, O}, where N(im) is the imino nitrogen of His50, N(-) a deprotonated amido backbone nitrogen that we attribute to His50, H(2)O an exchangeable water molecule, and O an unidentified oxygen ligand. Moreover, we propose that the free amino terminus (Met1) participates in the complex as an axial ligand. The MXAN analysis of the XAS k-edge absorption data allowed us to independently validate the structural features proposed on the basis of the magnetic parameters of the Cu(II)-aS99 complex and then to further refine the quality of the proposed structural model.Journal of the American Chemical Society 12/2010; 132(51):18057-66. · 9.91 Impact Factor -
Article: Cross-linked polyvinyl polymers versus polyureas as designed supports for catalytically active M(0) nanoclusters. Part III. Nanometer scale structure of the cross-linked polyurea support EnCat 30 and of the Pd(II)/EnCat 30 and Pd(0)/EnCat 30NP catalysts.
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ABSTRACT: The cross-linked polyurea support EnCat 30, its related macromolecular complex Pd(II)/EnCat 30 and its related Pd(0)/EnCat 30NP nanocomposite are thoroughly investigated with SEM, TEM, ISEC and ESR in the solid state (SEM and TEM) and swollen state in THF (ISEC and ESR). Pd(II)/EnCat 30 and its related Pd(0)/EnCat 30NP are obtained by microencapsulation of palladium acetate in a polyurea framework, which is formed upon hydrolysis/condensation of mixtures of multi-functional oligo-arylisocyanates in dichloroethane. Most remarkably, both Pd(II)/EnCat and Pd(0)/EnCat 30NP turn out to be far more (nano)porous and swellable materials than the blank polyurea matrix (EnCat 30). It is proposed that there is a strong nanostructural effect exerted by Pd(II) species due to its interaction with functional groups (amines stemming from the hydrolysis of the isocyanato groups or ureido groups belonging to the polymer chains) during the growth of the cross-linked polymer framework. As a consequence, the catalytic species in both Pd(II)/EnCat 30 and Pd(0)/EnCat 30NP are much more accessible to molecules diffusing from liquid phases in contact with the materials and, hence, are better catalysts than expected from the morphology of blank polyurea EnCat 30.Physical Chemistry Chemical Physics 06/2009; 11(20):4068-76. · 3.57 Impact Factor -
Article: Three different tyrosyl radicals identified in L-tyrosine HCl crystals upon gamma-irradiation: magnetic characterization and temporal evolution.
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ABSTRACT: High-frequency electron paramagnetic resonance (EPR) and X-band electron-nuclear double resonance (ENDOR) spectroscopies were used to investigate the effect of gamma-irradiation on single crystals of L-tyrosine hydrochloride at room temperature. The oxidation product is the tyrosyl radical formed by hydrogen abstraction from the phenolic group; interestingly, on freshly irradiated crystals, two tyrosyl radicals were identified, characterized by slightly different magnetic parameters. In particular, one of the two radicals, with a gxx value of 2.00621, has its phenoxyl oxygen strongly hydrogen-bonded to one or more donors; to our knowledge, this is the lower gxx value reported for tyrosyl radicals. These two oxidation radicals are found to evolve very slowly to a third, single more stable radical conformation. To interpret the experimental data, a possible molecular scenario is presented, where the process of radical formation can be seen as a hydrogen atom transfer or a proton-coupled electron transfer. These processes seem to be controlled by the specific network of hydrogen-bond interactions present in the crystal. The results are discussed in relation to their relevance for the interpretation of EPR spectra of tyrosyl radicals in biological systems.The Journal of Physical Chemistry B 04/2008; 112(12):3812-20. · 3.70 Impact Factor -
Article: Conformational role of the divalent metal in bovine heart mitochondrial F1-ATPase: an electron spin echo envelope modulation study.
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ABSTRACT: The catalytic sites of beef heart mitochondrial F1-ATPase were studied by electron spin echo envelope modulation (ESEEM) spectroscopy, using Mn(II) as a paramagnetic probe, which replaces the naturally occurring Mg(II), maintaining the enzyme catalytic activity. F1-ATPase was purified from beef heart mitochondria. A protein still containing three endogenous nucleotides, named MF1(1,2), is obtained under milder conditions, whereas a harsher treatment gives a fully depleted F1, named MF1(0,0). Several samples were prepared, loading MF1(0,0) or MF1(1,2) with Mn(II) or MnIIADP in both substoichiometric and excess amounts. When MF1(1,2) is loaded with Mn(II) in a 1:0.8 ratio, the FT-ESEEM spectrum shows evidence of a nitrogen interacting with the metal, while this interaction is not present in MF1(0,0) + Mn(II) in a 1:0.8 ratio. However, when MF1(0,0) is loaded with 2.4 Mn(II), the FT-ESEEM spectrum shows a metal-nitrogen interaction resembling that present in MF1(1,2) + Mn(II) in a 1:0.8 ratio. These results strongly support the role of the metal alone in shaping and structuring the catalytic sites of the enzyme. When substoichiometric ADP is added to MF1(1,2) preloaded with 0.8 equiv of Mn(II), the ESEEM spectra show evidence of a phosphorus nucleus coupled to the metal, indicating that the nucleotide phosphate binding to Mn(II) occurs in a catalytic site. Generally, 14N coordination to the metal is clearly identified in the ESEEM spectra of all the samples containing more than one metal equivalent. One point of note is that the relevant nitrogen-containing ligand(s), responsible for the signals in the ESEEM spectra, has not yet been identified in the available X-ray structures.Biochemistry 12/2007; 46(46):13443-50. · 3.42 Impact Factor
