Your search keyword '"Andrea Ilari"' showing total 6 results

1. The Truncated Oxygen-avid Hemoglobin from Bacillus subtilis

Author

Alberto Boffi, Veronica Morea, Andrea Ilari, Laura Giangiacomo, and Emilia Chiancone

Subjects

Steric effects, biology, Stereochemistry, Chemistry, Hydrogen bond, Cell Biology, Bacillus subtilis, Ligand (biochemistry), biology.organism_classification, Biochemistry, Binding constant, chemistry.chemical_compound, Ferricyanide, Hemoglobin, Molecular Biology, Heme

Abstract

The group II truncated hemoglobin from Bacillus subtilis has been cloned, expressed, purified, and characterized. B. subtilis truncated hemoglobin is a monomeric protein endowed with an unusually high oxygen affinity (in the nanomolar range) such that the apparent thermodynamic binding constant for O2 exceeds that for CO by 1 order of magnitude. The kinetic 2basis of the high oxygen affinity resides mainly in the very slow rate of ligand release. The extremely stable ferrous oxygenated adduct is resistant to oxidation, which can be achieved only with oxidant in large excess, e.g. ferricyanide in 50-fold molar excess. The three-dimensional crystal structure of the cyano-Met derivative was determined at 2.15 A resolution. Although the overall fold resembles that of other truncated hemoglobins, the distal heme pocket displays a unique array of hydrophilic side chains in the topological positions that dominate the steric interaction with iron-bound ligands. In fact, the Tyr-B10, Thr-E7, and Gln-E11 oxygens on one side of the heme pocket and the Trp-G8 indole NE1 nitrogen on the other form a novel pattern of the “ligand-inclusive hydrogen bond network” described for mycobacterial HbO. On the proximal side, the histidine residue is in an unstrained conformation, and the iron-His bond is unusually short (1.91 A).

Published

2005

2. Information Transfer in the Penta-EF-hand Protein Sorcin Does Not Operate via the Canonical Structural/Functional Pairing

Author

Emilia Chiancone, Andrea Ilari, Daniela Verzili, Gianni Colotti, Manuela Mella, and Carlotta Zamparelli

Subjects

Circular dichroism, Conformational change, Chemistry, Ryanodine receptor, EF hand, Cell Biology, Biochemistry, Cytosol, Protein structure, Helix, Biophysics, Molecular Biology, Peptide sequence

Abstract

Sorcin is a typical penta-EF-hand protein that participates in Ca2+-regulated processes by translocating reversibly from cytosol to membranes, where it interacts with different target proteins in different tissues. Binding of two Ca2+/monomer triggers translocation, although EF1, EF2, and EF3 are potentially able to bind calcium at micromolar concentrations. To identify the functional pair, the conserved bidentate -Z glutamate in these EF-hands was mutated to yield E53Q-, E94A-, and E124A-sorcin, respectively. Limited structural perturbations occur only in E124A-sorcin due to involvement of Glu-124 in a network of interactions that comprise the long D helix connecting EF3 to EF2. The overall affinity for Ca2+ and for two sorcin targets, annexin VII and the ryanodine receptor, follows the order wild-type > E53Q- > E94A- > E124A-sorcin, indicating that disruption of EF3 has the largest functional impact and that disruption of EF2 and EF1 has progressively smaller effects. Based on this experimental evidence, EF3 and EF2, which are not paired in the canonical manner, are the functional EF-hands. Sorcin is proposed to be activated upon Ca2+ binding to EF3 and transmission of the conformational change at Glu-124 via the D helix to EF2 and from there to EF1 via the canonical structural/functional pairing. This mechanism may be applicable to all penta-EF-hand proteins.

Published

2003

3. Escherichia coli Flavohemoglobin Is an Efficient Alkylhydroperoxide Reductase

Author

Alessandra Bonamore, M. Eugenia Schininà, Patrizia Gentili, Andrea Ilari, and Alberto Boffi

Subjects

Hemeproteins, Protein Conformation, Stereochemistry, Oxidative phosphorylation, Photochemistry, Biochemistry, Peroxide, Catalysis, Phospholipases A, Adduct, Ferrous, chemistry.chemical_compound, Bacterial Proteins, Escherichia coli, Hydrogen peroxide, Molecular Biology, Alkylhydroperoxide reductase activity, biology, Escherichia coli Proteins, Peroxiredoxins, Cell Biology, Kinetics, Peroxidases, chemistry, Spectrophotometry, biology.protein, Peroxidase

Abstract

Escherichia coli flavohemoglobin (HMP) is shown to be capable of catalyzing the reduction of several alkylhydroperoxide substrates into their corresponding alcohols using NADH as an electron donor. In particular, HMP possesses a high catalytic activity and a low Km toward cumyl, linoleic acid, and tert-butyl hydroperoxides, whereas it is a less efficient hydrogen peroxide scavenger. An analysis of UV-visible spectra during the stationary state reveals that at variance with classical peroxidases, HMP turns over in the ferrous state. In particular, an iron oxygen adduct intermediate whose spectrum is similar to that reported for the oxo-ferryl derivative in peroxidases (Compound II), has been identified during the catalysis of hydrogen peroxide reduction. This finding suggests that hydroperoxide cleavage occurs upon direct binding of a peroxide oxygen atom to the ferrous heme iron. Competitive inhibition of the alkylhydroperoxide reductase activity by carbon monoxide has also been observed, thus confirming that heme iron is directly involved in the catalytic mechanism of hydroperoxide reduction. The alkylhydroperoxide reductase activity taken together with the unique lipid binding properties of HMP suggests that this protein is most likely involved in the repair of the lipid membrane oxidative damage generated during oxidative/nitrosative stress.

Published

2003

4. The Dps Protein of Agrobacterium tumefaciens Does Not Bind to DNA but Protects It toward Oxidative Cleavage

Author

Elisabetta Falvo, Pierpaolo Ceci, Andrea Ilari, and Emilia Chiancone

Subjects

chemistry.chemical_classification, Radical, Iron-binding proteins, Cell Biology, Agrobacterium tumefaciens, Biology, medicine.disease_cause, biology.organism_classification, Biochemistry, Amino acid, chemistry.chemical_compound, chemistry, medicine, biology.protein, Hydroxyl radical, Protein A, Molecular Biology, Escherichia coli, DNA

Abstract

Agrobacterium tumefaciens Dps (DNA-binding proteins from starved cells), encoded by the dps gene located on the circular chromosome of this plant pathogen, was cloned, and its structural and functional properties were determined in vitro. In Escherichia coli Dps, the family prototype, the DNA binding properties are thought to be associated with the presence of the lysine-containing N-terminal tail that extends from the protein surface into the solvent. The x-ray crystal structure of A. tumefaciens Dps shows that the positively charged N-terminal tail, which is 11 amino acids shorter than in the E. coli protein, is blocked onto the protein surface. This feature accounts for the lack of interaction with DNA. The intersubunit ferroxidase center characteristic of Dps proteins is conserved and confers to the A. tumefaciens protein a ferritin-like activity that manifests itself in the capacity to oxidize and incorporate iron in the internal cavity and to release it after reduction. In turn, sequestration of Fe(II) correlates with the capacity of A. tumefaciens Dps to reduce the production of hydroxyl radicals from H2O2 through Fenton chemistry. These data demonstrate conclusively that DNA protection from oxidative damage in vitro does not require formation of a Dps-DNA complex. In vivo, the hydroxyl radical scavenging activity of A. tumefaciens Dps may be envisaged to act in concert with catalase A to counteract the toxic effect of H2O2, the major component of the plant defense system when challenged by the bacterium.

Published

2003

5. Iron and Hydrogen Peroxide Detoxification Properties of DNA-binding Protein from Starved Cells

Author

N. Dennis Chasteen, Laura Giangiacomo, Emilia Chiancone, Thomas M. Laue, Guanghua Zhao, Andrea Ilari, and Pierpaolo Ceci

Subjects

biology, Spin trapping, DNA-binding protein from starved cells, Inorganic chemistry, Cell Biology, engineering.material, Biochemistry, Medicinal chemistry, Ferrous, Hydrous ferric oxides, Ferritin, chemistry.chemical_compound, chemistry, medicine, engineering, biology.protein, Ferric, Hydroxyl radical, Hydrogen peroxide, Molecular Biology, medicine.drug

Abstract

The DNA-binding proteins from starved cells (Dps) are a family of proteins induced in microorganisms by oxidative or nutritional stress. Escherichia coli Dps, a structural analog of the 12-subunit Listeria innocua ferritin, binds and protects DNA against oxidative damage mediated by H(2)O(2). Dps is shown to be a Fe-binding and storage protein where Fe(II) oxidation is most effectively accomplished by H(2)O(2) rather than by O(2) as in ferritins. Two Fe(2+) ions bind at each of the 12 putative dinuclear ferroxidase sites (P(Z)) in the protein according to the equation, 2Fe(2+) + P(Z) --> [(Fe(II)(2)-P](FS)(Z+2) + 2H(+). The ferroxidase site (FS) bound iron is then oxidized according to the equation, [(Fe(II)(2)-P](FS)(Z+2) + H(2)O(2) + H(2)O --> [Fe(III)(2)O(2)(OH)-P](FS)(Z-1) + 3H(+), where two Fe(II) are oxidized per H(2)O(2) reduced, thus avoiding hydroxyl radical production through Fenton chemistry. Dps acquires a ferric core of approximately 500 Fe(III) according to the mineralization equation, 2Fe(2+) + H(2)O(2) + 2H(2)O --> 2Fe(III)OOH((core)) + 4H(+), again with a 2 Fe(II)/H(2)O(2) stoichiometry. The protein forms a similar ferric core with O(2) as the oxidant, albeit at a slower rate. In the absence of H(2)O(2) and O(2), Dps forms a ferrous core of approximately 400 Fe(II) by the reaction Fe(2+) + H(2)O + Cl(-) --> Fe(II)OHCl((core)) + H(+). The ferrous core also undergoes oxidation with a stoichiometry of 2 Fe(II)/H(2)O(2). Spin trapping experiments demonstrate that Dps greatly attenuates hydroxyl radical production during Fe(II) oxidation by H(2)O(2). These results and in vitro DNA damage assays indicate that the protective effect of Dps on DNA most likely is exerted through a dual action, the physical association with DNA and the ability to nullify the toxic combination of Fe(II) and H(2)O(2). In the latter process a hydrous ferric oxide mineral core is produced within the protein, thus avoiding oxidative damage mediated by Fenton chemistry.

Published

2002

6. Reassessment of Protein Stability, DNA Binding, and Protection of Mycobacterium smegmatis Dps.

Author

Ceci, Pierpaolo, Andrea Ilari, Falvo, Elisabetta, Giangiacomo, Laura, and Chiancone, Emilia

Subjects

*DNA-binding proteins, *MYCOBACTERIUM, *PROTEINS, *MYCOBACTERIA, *BACTERIAL genetics, *BACTERIOLOGY, *BIOCHEMISTRY

Abstract

The structure and function of Mycobacterium smegmatis Dps (DNA-binding proteins from starved cells) and of the protein studied by Gupta and Chatterji (Gupta, S., and Chatterji, D. (2003) J Biol. Chem. 278, 5235–5241 ), in which the C terminus that is used for binding DNA contains a histidine tag, have been characterized in parallel. The native dodecamer dissociated reversibly into dimers above pH 7.5 and below pH 6.0, with apparent pKa values of ∼7.65 and 4.75; at pH ∼4.0, dimers formed monomers. Based on structural analysis, the two dissociation steps have been attributed to breakage of the salt bridges between Glu157 and Arg99 located at the 3-fold symmetry axes and to protonation of Asp66 hydrogen- bonded to Lys36 across the dimer interface, respectively. The C-terminal tag did not affect subunit dissociation, but altered DNA binding dramatically. At neutral pH, protonation of the histidine tag promoted DNA condensation, whereas in the native C terminus, compensation of negative and positive charges led to DNA binding without condensation. This different mode of interaction with DNA has important functional consequences as indicated by the failure of the native protein to protect DNA from DNase-mediated cleavage and by the efficiency of the tagged protein in doing so as a result of DNA sequestration in the condensates. Chemical protection of DNA from oxidative damage is realized by Dps proteins in a multi-step iron oxidation/uptake/mineralization process. Dimers have a decreased protection efficiency due to disruption of the dodeeamer internal cavity, where iron is deposited and mineralized after oxidation at the ferroxidase center. [ABSTRACT FROM AUTHOR]

Published

2005