Michael P. Hendrich scite author profile

We report reversible switching of paramagnetism in a well-defined gold nanoparticle system consisting of atomically monodisperse nanoparticles containing 25 gold atoms protected by 18 thiolates [abbreviated as Au(25)(SR)(18)]. The magnetism in these nanoparticles can be switched on or off by precisely controlling the charge state of the nanoparticle, that is, the magnetic state of the Au(25)(SR)(18) nanoparticles is charge-neutral while the nonmagnetic state is an anionic form of the particle. Electron paramagnetic resonance (EPR) spectroscopy measurements establish that the magnetic state of the Au(25)(SR)(18) nanoparticles possess one unpaired spin per particle. EPR studies also imply an unusual electronic structure of the Au(25)(SR)(18) nanoparticle. Density functional theory calculations coupled with the experiments successfully explain the origin of the observed magnetism in a Au(25)(SR)(18) nanoparticle as arising from one unpaired spin having distinct P-like character and delocalized among the icosahedral Au(13) core of the particle in the highest occupied molecular orbital. The results suggest that the Au(25)(SR)(18) nanoparticles are best considered as ligand-protected superatoms.

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O ₂ Activation by Nonheme Iron Complexes: A Monomeric Fe(III)-Oxo Complex Derived From O ₂

MacBeth¹,

Golombek

Young

et al. 2000

Science

430

313

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Iron species with terminal oxo ligands are implicated as key intermediates in several synthetic and biochemical catalytic cycles. However, there is a dearth of structural information regarding these types of complexes because their instability has precluded isolation under ambient conditions. The isolation and structural characterization of an iron(III) complex with a terminal oxo ligand, derived directly from dioxygen (O2), is reported. A stable structure resulted from placing the oxoiron unit within a synthetic cavity lined with hydrogen-bonding groups. The cavity creates a microenvironment around the iron center that aids in regulating O2 activation and stabilizing the oxoiron unit. These cavities share properties with the active sites of metalloproteins, where function is correlated strongly with site structure.

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Trapping and spectroscopic characterization of an Fe^III-superoxo intermediate from a nonheme mononuclear iron-containing enzyme

Mbughuni

Chakrabarti

Hayden

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

136

297

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Fe III -O 2 •− intermediates are well known in heme enzymes, but none have been characterized in the nonheme mononuclear Fe II enzyme family. Many steps in the O 2 activation and reaction cycle of Fe II -containing homoprotocatechuate 2,3-dioxygenase are made detectable by using the alternative substrate 4-nitrocatechol (4NC) and mutation of the active site His200 to Asn (H200N). Here, the first intermediate (Int-1) observed after adding O 2 to the H200N-4NC complex is trapped and characterized using EPR and Möss-bauer (MB) spectroscopies. Int-1 is a high-spin ( (1)(2)(3)(4)(5)(6)(7)(8). Internal electron transfer to form an Fe III -superoxo species converts the kinetically inert triplet ground state of O 2 to a doublet that can participate in the many types of chemistry characteristic of this mechanistically diverse group of enzymes. The same strategy is usually employed by heme-containing oxygenases and oxidases, leading in some cases to comparatively stable Fe III -superoxo intermediates that have been structurally and spectroscopically characterized (9-12). Instability of the putative superoxo intermediate in all mononuclear nonheme iron-containing enzymes has prevented similar characterization, although a superoxide level species has been reported for the dinuclear iron site of myo-inositol oxygenase (13).In recent studies of the nonheme Fe II -containing homoprotocatechuate 2,3-dioxygenase (2,3-HPCD), we have shown that three intermediates of the catalytic cycle can be trapped in one crystal for structural analysis (14). One of these intermediates has been proposed to be an Fe II -superoxo species based on the long Fe-O bond distances and an unexpected lack of planarity of the aromatic ring of the alternative substrate 4-nitrocatechol (4NC), which chelates the iron in ligand sites adjacent to that of the O 2 . In accord with the mechanism postulated for this enzyme class as illustrated in Scheme 1 (1, 8, 15-21), we have proposed that net electron transfer from 4NC through the Fe II to O 2 forms adjacent substrate and oxygen radicals (Scheme 1B). Recombination of the radicals would begin the ring cleavage and oxygen insertion reactions of this enzyme that eventually yield a muconic semialdehyde adduct as the product. A localized radical on the 4NC semiquinone at the incipient position of oxygen attack would account for the lack of ring planarity. Although this is the only structurally characterized nonheme Fe-superoxo species, the iron oxidation state differs from all of the other postulated Fe-superoxo intermediates.The mechanism that emerges from the structural and kinetic studies does not require a change in metal oxidation state to form a reactive intermediate (22). However, our studies of 2,3-HPCD in which Fe II is replaced with Mn II suggest that transient formaScheme 1. Proposed mechanism for extradiol dioxygenases. In the case of 2,3-HPCD, R is −CH 2 COO − and B is His200. When R is −NO 2 and His200 is changed to Asn, the reaction stalls before reaching intermediate C. Peroxide is slowly released a...

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Moessbauer, EPR, and ENDOR studies of the hydroxylase and reductase components of methane monooxygenase from Methylosinus trichosporium OB3b

et al. 1993

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Soluble methane monooxygenase (MMO) isolated from Methylosinus trichosporium OB3b consists of three components: hydroxylase, reductase, and component B. The active-site diiron cluster of the hydroxylase has been studied with Mossbauer, ENDOR, and EPR spectroscopies. Móssbauer spectra of the oxidized cluster show that the two high-spin irons are antiferromagnetically coupled in accord with our preliminary study (Fox et al. J. Biol. Chem. 1988, 263, 10553-10556). Mossbauer studies also reveal the presence of two cluster conformations at pH 9. The excited-state S = 2 multiple! of the exchange-coupled cluster (Fe3+-Fe3+) gives rise to an integer-spin EPR signal near g = 8; this is the first quantitative study of such a signal from any system. Analysis of the temperature dependence of the g = 8 signal yields J -15 ± 5 cm™1 for the exchange-coupling constant (Htx = /Si-S2). This value is more than 1 order of magnitude smaller than those reported for the oxo-bridged clusters of hemerythrin and Escherichia coli ribonucleotide reductase (Hex = /Si-S2, J = 270 and 220 cm™1, respectively), suggesting that the bridging ligand of the hydroxylase cluster is not an unsubstituted oxygen atom. Móssbauer spectra of the hydroxylase in applied fields of up to 8 T reveal a paramagnetic admixture of a low-lying excited state into the ground singlet. Both the spectral shape and intensity are well represented by assuming that the spin expectation values for the cluster sites increase

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A High-Valent Nonheme Iron Intermediate. Structure and Properties of [Fe2(.mu.-O)2(5-Me-TPA)2](ClO4)3

et al. 1995

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Formation, Structure, and EPR Detection of a High Spin Fe^IV—Oxo Species Derived from Either an Fe^III—Oxo or Fe^III—OH Complex

et al. 2010

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High spin oxoiron(IV) complexes have been proposed to be a key intermediate in numerous non-heme metalloenzymes. The successful detection of similar complexes has been reported for only two synthetic systems. A new synthetic high spin oxoiron(IV) complex is now reported that can be prepared from a well-characterized oxoiron(III) species. This new oxoiron(IV) complexes can also be prepared from a hydroxoiron(III) species via a proton-coupled electron transfer process—a first in synthetic chemistry. The oxoiron(IV) complexes has been characterized with a variety of spectroscopic methods: FTIR studies showed a feature associated with the Fe–O bond at ν(Fe16O) = 799 cm−1 that shifted to 772 cm−1 in the 18O complex; Mössbauer experiments show a signal with an δ = 0.02 mm/s and |ΔEQ | = 0.43 mm/s, electronic parameters consistent with a Fe(IV) center; and optical spectra had visible bands at λmax = 440 (εM = 3100), 550 (εM = 1900) and 808 (εM = 280) nm. In addition, the oxoiron(IV) complex gave the first observable EPR features in the parallel-mode EPR spectrum with g-values at 8.19 and 4.06. A simulation for an S = 2 species with D = 4.0(5) cm−1, E/D = 0.03, σE/D = 0.014, and gz = 2.04 generates a fit that accurately predicted the intensity, lineshape, and position of the observed signals. These results showed the EPR spectroscopy can be a useful method for determining the properties of high spin oxoiron(IV) complexes. The oxoiron(VI) complex was crystallized at −35°C and its structure was determined by X-ray diffraction methods. The complex has a trigonal bipyramidal coordination geometry with the Fe–O unit positioned within a hydrogen bonding cavity. The FeIV–O unit bond length is 1.680(1) Å, which is the longest distance yet reported for monomeric oxoiron(IV) complex.

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Chloroperoxidase compound I: electron paramagnetic resonance and Moessbauer studies

Rutter¹,

Hager²,

Dhonau³

et al. 1984

Biochemistry

234

221

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The green primary compound of chloroperoxidase was prepared by freeze-quenching the enzyme after rapid mixing with a 5-fold excess of peracetic acid. The electron paramagnetic resonance (EPR) spectra of these preparations consisted of at least three distinct signals that could be assigned to native enzyme, a free radical, and the green compound I as reported earlier. The absorption spectrum of compound I was obtained through subtraction of EPR signals measured under passage conditions. The signal is well approximated by an effective spin Seff = 1/2 model with g = 1.64, 1.73, 2.00 and a highly anisotropic line width. Mössbauer difference spectra of compound I samples minus native enzyme showed well-resolved magnetic splitting at 4.2 K, an isomer shift delta Fe = 0.15 mm/s, and quadrupole splitting delta EQ = 1.02 mm/s. All data are consistent with the model of an exchange-coupled spin S = 1 ferryl iron and a spin S' = 1/2 porphyrin radical. As a result of the large zero field splitting, D, of the ferryl iron and of intermediate antiferromagnetic exchange, S.J.S'.J approximately 1.02 D, the system consists of three Kramers doublets that are widely separated in energy. The model relates the EPR and Mössbauer spectra of the ground doublet to the intrinsic parameters of the ferryl iron, D/k = 52 K, E/D congruent to 0.035, and A perpendicular (gn beta n) = 20 T, and the porphyrin radical.(ABSTRACT TRUNCATED AT 250 WORDS)

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The Nitric Oxide Reductase Mechanism of a Flavo-Diiron Protein: Identification of Active-Site Intermediates and Products

et al. 2014

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The unique active site of flavo-diiron proteins (FDPs) consists of a nonheme diiron-carboxylate site proximal to a flavin mononucleotide (FMN) cofactor. FDPs serve as the terminal components for reductive scavenging of dioxygen or nitric oxide to combat oxidative or nitrosative stress in bacteria, archaea, and some protozoan parasites. Nitric oxide is reduced to nitrous oxide by the four-electron reduced (FMNH2–FeIIFeII) active site. In order to clarify the nitric oxide reductase mechanism, we undertook a multispectroscopic presteady-state investigation, including the first Mössbauer spectroscopic characterization of diiron redox intermediates in FDPs. A new transient intermediate was detected and determined to be an antiferromagnetically coupled diferrous-dinitrosyl (S = 0, [{FeNO}7]2) species. This species has an exchange energy, J ≥ 40 cm–1 (JS1 ° S2), which is consistent with a hydroxo or oxo bridge between the two irons. The results show that the nitric oxide reductase reaction proceeds through successive formation of diferrous-mononitrosyl (S = 1/2, FeII{FeNO}7) and the S = 0 diferrous-dinitrosyl species. In the rate-determining process, the diferrous-dinitrosyl converts to diferric (FeIIIFeIII) and by inference N2O. The proximal FMNH2 then rapidly rereduces the diferric site to diferrous (FeIIFeII), which can undergo a second 2NO → N2O turnover. This pathway is consistent with previous results on the same deflavinated and flavinated FDP, which detected N2O as a product (HayashiHayashi20669924Biochemistry2010497040). Our results do not support other proposed mechanisms, which proceed either via “super-reduction” of [{FeNO}7]2 by FMNH2 or through FeII{FeNO}7 directly to a diferric-hyponitrite intermediate. The results indicate that an S = 0 [{FeNO}7}]2 complex is a proximal precursor to N–N bond formation and N–O bond cleavage to give N2O and that this conversion can occur without redox participation of the FMN cofactor.

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