Maria Giulia Bigotti scite author profile

A model-free analysis of Pseudomonas aeruginosa ferricytochrome c(551) dynamics based on (15)N R(1), (15)N R(2), and [(1)H]-(15)N heteronuclear nuclear Overhauser effect data is reported. The protein backbone is highly rigid (< S(2)>=0.924+/-0.005) and displays little variation in picosecond-nanosecond time scale dynamics over the structure. The loop structure containing the axial methionine ligand (loop 3) displays anomalous rigidity, which is attributed to its high proline content. Also reported are protection factors calculated from hydrogen-exchange rates. These data reveal that loop 3 residues, including the axial methionine, are protected from exchange as a result of long-range hydrogen-bonding interactions. These results are contrasted with data reported for Saccharomyces cerevisiae iso-1-ferricytochrome c, which displays higher overall flexibility (< S(2)>=0.80+/-0.07), greater variation of dynamics as a function of structure, and low protection factors for loop 3. This analysis reveals that heme proteins with similar functions and topologies may display diverse dynamical properties.

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Chaperonins: The hunt for the Group II mechanism

Bigotti

Clarke

2008

Archives of Biochemistry and Biophysics

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Tyrosine as a redox-active center in electron transfer to ferryl heme in globins

Reeder

Cutruzzolà

Bigotti

et al. 2008

Free Radical Biology and Medicine

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Comparative Study of Tyrosine Radicals in Hemoglobin and Myoglobins Treated with Hydrogen Peroxide

Svistunenko

Dunne

Fryer

et al. 2002

Biophysical Journal

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The reactions of hydrogen peroxide with human methemoglobin, sperm whale metmyoglobin, and horse heart metmyoglobin were studied by electron paramagnetic resonance (EPR) spectroscopy at 10 K and room temperature. The singlet EPR signal, one of the three signals seen in these systems at 10 K, is characterized by a poorly resolved, but still detectable, hyperfine structure that can be used to assign it to a tyrosyl radical. The singlet is detectable as a quintet at room temperature in methemoglobin with identical spectral features to those of the well characterized tyrosyl radical in photosystem II. Hyperfine splitting constants found for Tyr radicals were used to find the rotation angle of the phenoxyl group. Analysis of these angles in the crystal structures suggests that the radical resides on Tyr151 in sperm whale myoglobin, Tyr133 in soybean leghemoglobin, and either alphaTyr42, betaTyr35, or betaTyr130 in hemoglobin. In the sperm whale metmyoglobin Tyr103Phe mutant, there is no detectable tyrosyl radical present. Yet the rotation angle of Tyr103 (134 degrees) is too large to account for the observed EPR spectrum in the wild type. Tyr103 is the closest to the heme. We suggest that Tyr103 is the initial site of the radical, which then rapidly migrates to Tyr151.

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Functional diversity of dystroglycan

et al. 2009

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