Monika Sommerhalter scite author profile

The R2 subunit of Escherichia coli ribonucleotide reductase contains a dinuclear iron center that generates a catalytically essential stable tyrosyl radical by one electron oxidation of a nearby tyrosine residue. After acquisition of Fe(II) ions by the apo protein, the resulting diiron(II) center reacts with O(2) to initiate formation of the radical. Knowledge of the structure of the reactant diiron(II) form of R2 is a prerequisite for a detailed understanding of the O(2) activation mechanism. Whereas kinetic and spectroscopic studies of the reaction have generally been conducted at pH 7.6 with reactant produced by the addition of Fe(II) ions to the apo protein, the available crystal structures of diferrous R2 have been obtained by chemical or photoreduction of the oxidized diiron(III) protein at pH 5-6. To address this discrepancy, we have generated the diiron(II) states of wildtype R2 (R2-wt), R2-D84E, and R2-D84E/W48F by infusion of Fe(II) ions into crystals of the apo proteins at neutral pH. The structures of diferrous R2-wt and R2-D48E determined from these crystals reveal diiron(II) centers with active site geometries that differ significantly from those observed in either chemically or photoreduced crystals. Structures of R2-wt and R2-D48E/W48F determined at both neutral and low pH are very similar, suggesting that the differences are not due solely to pH effects. The structures of these "ferrous soaked" forms are more consistent with circular dichroism (CD) and magnetic circular dichroism (MCD) spectroscopic data and provide alternate starting points for consideration of possible O(2) activation mechanisms.

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X-ray Crystallography and Biological Metal Centers: Is Seeing Believing?

Sommerhalter

Lieberman

Rosenzweig

2005

Inorg. Chem.

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Metalloenzyme crystal structures have a major impact on our understanding of biological metal centers. They are often the starting point for mechanistic and computational studies and inspire synthetic modeling chemistry. The strengths and limitations of X-ray crystallography in determining properties of biological metal centers and their corresponding ligand spheres are explored through examples, including ribonucleotide reductase R2 and particulate methane monooxygenase. Protein crystal structures locate metal ions within a protein fold and reveal the identities and coordination geometries of amino acid ligands. Data collection strategies that exploit the anomalous scattering effect of metal ions can establish metal ion identity. The quality of crystallographic data, particularly the resolution, determines the level of detail that can be extracted from a protein crystal structure. Complementary spectroscopic techniques can provide crucial information regarding the redox state of the metal center as well as the presence, type, and protonation state of exogenous ligands. The final result of the crystallographic characterization of a metalloenzyme is a model based on crystallographic data, supported by information from biophysical and modeling studies, influenced by sample handling, and interpreted carefully by the crystallographer.

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Characterization of polyphenol oxidase activity in Ataulfo mango

Cheema

Sommerhalter

2015

Food Chemistry

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The Unusal Redox Centers of SoxXA, a Novel c-Type Heme-Enzyme Essential for Chemotrophic Sulfur-Oxidation of Paracoccus pantotrophus

Reijerse¹,

Sommerhalter²,

Hellwig³

et al. 2007

Biochemistry

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The heterodimeric hemoprotein SoxXA, essential for lithotrophic sulfur oxidation of the aerobic bacterium Paracoccus pantotrophus, was examined by a combination of spectroelectrochemistry and EPR spectroscopy. The EPR spectra for SoxXA showed contributions from three paramagnetic heme iron centers. One highly anisotropic low-spin (HALS) species (gmax = 3.45) and two "standard" cytochrome-like low-spin heme species with closely spaced g-tensor values were identified, LS1 (gz = 2.54, gy = 2.30, and gx = 1.87) and LS2 (gz = 2.43, gy = 2.26, and gx = 1.90). The crystal structure of SoxXA from P. pantotrophus confirmed the presence of three heme groups, one of which (heme 3) has a His/Met axial coordination and is located on the SoxX subunit [Dambe et al. (2005) J. Struct. Biol. 152, 229-234]. This heme was assigned to the HALS species in the EPR spectra of the isolated SoxX subunit. The LS1 and LS2 species were associated with heme 1 and heme 2 located on the SoxA subunit, both of which have EPR parameters characteristic for an axial His/thiolate coordination. Using thin-layer spectroelectrochemistry the midpoint potentials of heme 3 and heme 2 were determined: Em3 = +189 +/- 15 mV and Em2 = -432 +/- 15 mV (vs NHE, pH 7.0). Heme 1 was not reducible even with 20 mM titanium(III) citrate. The Em2 midpoint potential turned out to be pH dependent. It is proposed that heme 2 participates in the catalysis and that the cysteine persulfide ligation leads to the unusually low redox potential (-436 mV). The pH dependence of its redox potential may be due to (de)protonation of the Arg247 residue located in the active site.

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Structures of the Yeast Ribonucleotide Reductase Rnr2 and Rnr4 Homodimers^,

et al. 2004

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Class I ribonucleotide reductases (RNRs) catalyze the reduction of ribonucleotides to deoxyribonucleotides. Eukaryotic RNRs comprise two subunits, the R1 subunit, which contains substrate and allosteric effector binding sites, and the R2 subunit, which houses a catalytically essential diiron-tyrosyl radical cofactor. In Saccharomyces cerevisiae, there are two variants of the R2 subunit, called Rnr2 and Rnr4. Rnr4 is unique in that it lacks three iron-binding residues conserved in all other R2s. Nevertheless, Rnr4 is required to activate Rnr2, and the functional species in vivo is believed to be a heterodimeric complex between the two proteins. The crystal structures of the Rnr2 and Rnr4 homodimers have been determined and are compared to that of the heterodimer. The homodimers are very similar to the heterodimer and to mouse R2 in overall fold, but there are several key differences. In the Rnr2 homodimer, one of the iron-binding helices, helix alphaB, is not well-ordered. In the heterodimer, interactions with a loop region connecting Rnr4 helices alphaA and alpha3 stabilize this Rnr2 helix, which donates iron ligand Asp 145. Sequence differences between Rnr2 and Rnr4 prevent the same interactions from occurring in the Rnr2 homodimer. These findings provide a structural rationale for why the heterodimer is the preferred complex in vivo. The active-site region in the Rnr4 homodimer reveals interactions not apparent in the heterodimer, supporting previous conclusions that this subunit does not bind iron. When taken together, these results support a model in which Rnr4 stabilizes Rnr2 for cofactor assembly and activity.

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Detection of Heme Oxygenase Activity in a Library of Four-helix Bundle Proteins: Towards the de Novo Synthesis of Functional Heme Proteins

Monien¹,

Drepper²,

Sommerhalter³

et al. 2007

Journal of Molecular Biology

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Identification of genes induced in proteoid roots of white lupin under nitrogen and phosphorus deprivation, with functional characterization of a formamidase

et al. 2010

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White lupin (Lupinus albus L.) is considered a model system for understanding plant acclimation to nutrient deficiency. It acclimates to phosphorus (P) and iron (Fe) deficiency by the development of short, densely clustered lateral roots called proteoid (or cluster) roots; proteoid-root development is further influenced by nitrogen (N) supply. In an effort to better understand proteoid root function under various nutrient deficiencies, we used nylon filter arrays to analyze 2,102 expressed sequence tags (ESTs) from proteoid roots of P-deficient white lupin. These have been previously analyzed for up-regulation in −P proteoid roots, and were here analyzed for upregulation in proteoid roots of N-deprived plants. We identified a total of 19 genes that displayed upregulation in proteoid roots under both P and N Plant Soil (2010) 334:137-150 deprivation. One of these genes showed homology to putative formamidases. The corresponding open reading frame was cloned, overexpressed in E. coli, and the encoded protein was purified; functional characterization of the recombinant protein confirmed formamidase activity. Though many homologues of bacterial and fungal formamidases have been identified in plants, to our knowledge, this is the first report of a functional characterization of a plant formamidase.

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Solution Structure of the COMMD1 N-terminal Domain

Sommerhalter

Zhang

Rosenzweig

2007

Journal of Molecular Biology

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COMMD1 is the prototype of a new protein family that plays a role in several important cellular processes, including NF-kappaB signaling, sodium transport, and copper metabolism. The COMMD proteins interact with one another via a conserved C-terminal domain, whereas distinct functions are predicted to result from a variable N-terminal domain. The COMMD proteins have not been characterized biochemically or structurally. Here, we present the solution structure of the N-terminal domain of COMMD1 (N-COMMD1, residues 1-108). This domain adopts an alpha-helical structure that bears little resemblance to any other helical protein. The compact nature of N-COMMD1 suggests that full-length COMMD proteins are modular, consistent with specific functional properties for each domain. Interactions between N-COMMD1 and partner proteins may occur via complementary electrostatic surfaces. These data provide a new foundation for biochemical characterization of COMMD proteins and for probing COMMD1 protein-protein interactions at the molecular level.

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