Hannah S. Shafaat scite author profile

Although metallocofactors are ubiquitous in enzyme catalysis, how metal binding specificity arises remains poorly understood, especially in the case of metals with similar primary ligand preferences such as manganese and iron. The biochemical selection of manganese over iron presents a particularly intricate problem because manganese is generally present in cells at a lower concentration than iron, while also having a lower predicted complex stability according to the Irving-Williams series (Mn II < Fe II < Ni II < Co II < Cu II > Zn II ). Here we show that a heterodinuclear Mn/Fe cofactor with the same primary protein ligands in both metal sites self-assembles from Mn II and Fe II in vitro, thus diverging from the Irving-Williams series without requiring auxiliary factors such as metallochaperones. Crystallographic, spectroscopic, and computational data demonstrate that one of the two metal sites preferentially binds Fe II over Mn II as expected, whereas the other site is nonspecific, binding equal amounts of both metals in the absence of oxygen. Oxygen exposure results in further accumulation of the Mn/Fe cofactor, indicating that cofactor assembly is at least a twostep process governed by both the intrinsic metal specificity of the protein scaffold and additional effects exerted during oxygen binding or activation. We further show that the mixed-metal cofactor catalyzes a two-electron oxidation of the protein scaffold, yielding a tyrosine-valine ether cross-link. Theoretical modeling of the reaction by density functional theory suggests a multistep mechanism including a valyl radical intermediate.H alf of all enzymes are estimated to contain metallocofactors (1). An important subset uses transition metal ions to perform key redox reactions such as oxygen activation. The diiron cofactor of the ferritin-like superfamily of proteins is particularly versatile (2). While ferritin itself simply oxidizes and sequesters iron (3), in other family members the diiron center acts as a transient one-or two-electron oxidant. In the R2 subunits of class I ribonucleotide reductases (RNRs) it generates a redoxactive tyrosyl radical (4, 5), whereas in the bacterial multicomponent monooxygenases (BMMs) it catalyzes the hydroxylation of a variety of hydrocarbons (6). For four decades it was assumed that all ferritin superfamily proteins contained diiron cofactors. However, in recent years new subfamilies harboring either a dimanganese or heterodinuclear Mn/Fe cofactor have been documented (7)(8)(9)(10)(11)(12)(13)(14). The Mn/Fe cofactor was discovered in class Ic RNR R2 subunits, where its Mn IV /Fe III state functionally replaces the diiron-tyrosyl radical cofactor of class Ia R2s (9, 10). After a long controversy, class Ib R2 proteins were shown to use a dimanganese cofactor in the same scaffold (7,8). These recent developments highlight the complexity of correctly identifying the metals that make up native metallocofactors. While the metal preferences of some primary coordination motifs are well known and distinct, others ar...

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[NiFe] hydrogenases: A common active site for hydrogen metabolism under diverse conditions

Shafaat

Rüdiger

Ogata

et al. 2013

Biochimica et Biophysica Acta (BBA) - Bioenergetics

239

231

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Hydrogenase proteins catalyze the reversible conversion of molecular hydrogen to protons and electrons. The most abundant hydrogenases contain a [NiFe] active site; these proteins are generally biased towards hydrogen oxidation activity and are reversibly inhibited by oxygen. However, there are [NiFe] hydrogenase that exhibit unique properties, including aerobic hydrogen oxidation and preferential hydrogen production activity; these proteins are highly relevant in the context of biotechnological devices. This review describes four classes of these "nonstandard" [NiFe] hydrogenases and discusses the electrochemical, spectroscopic, and structural studies that have been used to understand the mechanisms behind this exceptional behavior. A revised classification protocol is suggested in the conclusions, particularly with respect to the term "oxygen-tolerance". This article is part of a special issue entitled: metals in bioenergetics and biomimetics systems.

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Bacterial diversity in hyperarid Atacama Desert soils

et al. 2007

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[1] Surface and subsurface soil samples analyzed for this investigation were collected from the hyperarid Yungay region in the Atacama Desert, Chile. This report details the bacterial diversity derived from DNA and PLFA extracted directly from these extremely desiccated soils. Actinobacteria, Proteobacteria, Firmicutes and TM7 division bacteria were detected. Ninety-four percent of the 16S rRNA genes cloned from these soils belong to the Actinobacteria phylum, and the majority of these were most closely related to the genus Frankia. A 24-hour water activity (a w ) time course showed a diurnal cycle that peaked at 0.52 in the early predawn hours, and ranged from 0.01-0.08 during the day. All measured water activity values were below the levels required for microbial growth or enzyme activity. Total organic carbon (TOC) concentrations were above the limit of detection and below the limit of quantification (i.e., 200 mg/g < TOC < 1000 mg/g), and phospholipid fatty acid (PLFA) concentrations ranged from 2 Â 10 5 to 7 Â 10 6 cell equivalents per gram of soil. Soil extracts analyzed for culturable biomass yielded mostly no growth on R2A media; the highest single extract yielded 47 colony forming units (CFU) per gram of soil.Citation: Connon, S.

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Spectroscopic Comparison of Photogenerated Tryptophan Radicals in Azurin: Effects of Local Environment and Structure

et al. 2010

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Tryptophan radicals play a significant role in mediating biological electron transfer. We report the photogeneration of a long-lived, neutral tryptophan radical (Az48W*) from the native residue tryptophan-48 in the hydrophobic core of azurin. The optical absorption, electron paramagnetic resonance, and resonance Raman spectra strongly support the formation of a neutral radical, and the data are consistent with direct electron transfer between tryptophan and the copper(II) center. Spectra of the long-lived Az48W* species are compared to those of a previously studied, solvent-exposed radical at position 108 to identify signatures of tryptophan radicals that are sensitive to the local environment. The absorption maxima of Az48W* display an approximately 23 nm hypsochromic shift in the nonpolar environment. The majority of the resonance Raman frequencies are downshifted by approximately 7 cm(-1) relative to the solvent-exposed radical, and large changes in intensity are observed for some modes. The resonance Raman excitation profiles for Az48W* exhibit distinct maxima within the absorption envelope. Electron paramagnetic resonance spectroscopy yields spectra with partially resolved lines caused by hyperfine couplings; the differences between the coupling constants for the buried and solvent-exposed radical are primarily caused by variations in structure. The insights gained by electronic, vibrational, and magnetic resonance spectroscopy enhance our fundamental understanding of the effects of protein environment on radical properties. Hypotheses for the proton transfer pathway within azurin and a deprotonation rate of approximately 5 x 10(6) s(-1) are proposed.

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Electronic Structural Flexibility of Heterobimetallic Mn/Fe Cofactors: R2lox and R2c Proteins

et al. 2014

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The electronic structure of the Mn/Fe cofactor identified in a new class of oxidases (R2lox) described by Andersson and Högbom [Proc. Natl. Acad. Sci. U.S.A. 2009, 106, 5633] is reported. The R2lox protein is homologous to the small subunit of class Ic ribonucleotide reductase (R2c) but has a completely different in vivo function. Using multifrequency EPR and related pulse techniques, it is shown that the cofactor of R2lox represents an antiferromagnetically coupled Mn(III)/Fe(III) dimer linked by a μ-hydroxo/bis-μ-carboxylato bridging network. The Mn(III) ion is coordinated by a single water ligand. The R2lox cofactor is photoactive, converting into a second form (R2loxPhoto) upon visible illumination at cryogenic temperatures (77 K) that completely decays upon warming. This second, unstable form of the cofactor more closely resembles the Mn(III)/Fe(III) cofactor seen in R2c. It is shown that the two forms of the R2lox cofactor differ primarily in terms of the local site geometry and electronic state of the Mn(III) ion, as best evidenced by a reorientation of its unique (55)Mn hyperfine axis. Analysis of the metal hyperfine tensors in combination with density functional theory (DFT) calculations suggests that this change is triggered by deprotonation of the μ-hydroxo bridge. These results have important consequences for the mixed-metal R2c cofactor and the divergent chemistry R2lox and R2c perform.

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Hannah S. Shafaat

Direct observation of structurally encoded metal discrimination and ether bond formation in a heterodinuclear metalloprotein

[NiFe] hydrogenases: A common active site for hydrogen metabolism under diverse conditions

Bacterial diversity in hyperarid Atacama Desert soils

Spectroscopic Comparison of Photogenerated Tryptophan Radicals in Azurin: Effects of Local Environment and Structure

Electronic Structural Flexibility of Heterobimetallic Mn/Fe Cofactors: R2lox and R2c Proteins

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