Multiple States of Nitrile Hydratase from <i>Rhodococcus equi</i> TG328-2: Structural and Mechanistic Insights from Electron Paramagnetic Resonance and Density Functional Theory Studies

Stein, Natalia; Gumataotao, Natalie; Hajnas, Natalia; Wu, Rui; Lankathilaka, K.P. Wasantha; Bornscheuer, Uwe T.; Liu, Dali; Fiedler, Adam T.; Holz, Richard C.; Bennett, Brian

doi:10.1021/acs.biochem.6b00876

Cited by 11 publications

(37 citation statements)

References 50 publications

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“…Because the g ϭ 1.92 region contains only the contributions from overlapping individual g 2 or g 2,3 (g Ќ ) lines of distinct multiline rhombic or axial signals, the raw integral was multiplied by a factor of 7.41. This factor was derived from comparison of the integrated intensities of the g ʈ line and the entire spectrum of a rhombic S ϭ 1 ⁄ 2 Fe(III) signal from nitrile hydratase, with a spectral envelope of 450 G, that showed that 6% of the total spin density was reflected in the double integral of the single g ʈ line (114). The conversion factor was then scaled for the ratios of the squares of the spectral envelopes of the nitrile hydratase signal (450 G) and an averaged envelope for the FeS clusters (300 G) that contribute to the g ϭ 1.92 region (7).…”

Section: Mitochondrial Oxidants Targeted Probes and Techniquesmentioning

confidence: 99%

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

Cheng¹,

Zielonka²,

Dranka³

et al. 2018

Journal of Biological Chemistry

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Reactive oxygen and nitrogen species (ROS/RNS) such as superoxide (O), hydrogen peroxide, lipid hydroperoxides, peroxynitrite, and hypochlorous and hypobromous acids play a key role in many pathophysiological processes. Recent studies have focused on mitochondrial ROS as redox signaling species responsible for promoting cell division, modulating and regulating kinases and phosphatases, and activating transcription factors. Many ROS also stimulate cell death and senescence. The extent to which these processes occur is attributed to ROS levels (low or high) in cells. However, the exact nature of ROS remains unknown. Investigators have used redox-active probes that, upon oxidation by ROS, yield products exhibiting fluorescence, chemiluminescence, or bioluminescence. Mitochondria-targeted probes can be used to detect ROS generated in mitochondria. However, because most of these redox-active probes (untargeted and mitochondria-targeted) are oxidized by several ROS species, attributing redox probe oxidation to specific ROS species is difficult. It is conceivable that redox-active probes are oxidized in common one-electron oxidation pathways, resulting in a radical intermediate that either reacts with another oxidant (including oxygen to produce O) and forms a stable fluorescent product or reacts with O to form a fluorescent marker product. Here, we propose the use of multiple probes and complementary techniques (HPLC, LC-MS, redox blotting, and EPR) and the measurement of intracellular probe uptake and specific marker products to identify specific ROS generated in cells. The low-temperature EPR technique developed to investigate cellular/mitochondrial oxidants can easily be extended to animal and human tissues.

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Section: Mitochondrial Oxidants Targeted Probes and Techniquesmentioning

confidence: 99%

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

Cheng¹,

Zielonka²,

Dranka³

et al. 2018

Journal of Biological Chemistry

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“…It is known that Fe 3+ −NHases shows higher affinity to aliphatic nitriles as substrates, while the Co 3+ −NHases to aromatic compounds. Experimental EPR measures are available [124] only for Fe 3+ -type NHase, because the d 6 low spin electronic configuration of Co 3+ −NHase enzymes does not allow their inspection by EPR spectroscopy. However, other spectroscopic data are available for Co 3+ −NHases [124].…”

Section: Low Spin Fe 3+ and Co 3+ Nitrile Hydratasementioning

confidence: 99%

“…Experimental EPR measures are available [124] only for Fe 3+ -type NHase, because the d 6 low spin electronic configuration of Co 3+ −NHase enzymes does not allow their inspection by EPR spectroscopy. However, other spectroscopic data are available for Co 3+ −NHases [124].…”

Section: Low Spin Fe 3+ and Co 3+ Nitrile Hydratasementioning

confidence: 99%

“…Despite the catalytic reaction of the nitrile hydrolysis by both Fe 3+ − and Co 3+ −NHases was extensively studied at the experimental level, [111,122,124,[128][129][130] its working mechanism remains poorly understood. At theoretical level, exhaustive studies exist only for the Fe 3+ −NHase enzyme [105,[114][115][116][117][118].…”

Section: Low Spin Fe 3+ and Co 3+ Nitrile Hydratasementioning

confidence: 99%

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The Effects of the Metal Ion Substitution into the Active Site of Metalloenzymes: A Theoretical Insight on Some Selected Cases

et al. 2020

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A large number of enzymes need a metal ion to express their catalytic activity. Among the different roles that metal ions can play in the catalytic event, the most common are their ability to orient the substrate correctly for the reaction, to exchange electrons in redox reactions, to stabilize negative charges. In many reactions catalyzed by metal ions, they behave like the proton, essentially as Lewis acids but are often more effective than the proton because they can be present at high concentrations at neutral pH. In an attempt to adapt to drastic environmental conditions, enzymes can take advantage of the presence of many metal species in addition to those defined as native and still be active. In fact, today we know enzymes that contain essential bulk, trace, and ultra-trace elements. In this work, we report theoretical results obtained for three different enzymes each of which contains different metal ions, trying to highlight any differences in their working mechanism as a function of the replacement of the metal center at the active site.

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“…Additional "fields" due to nuclear Zeeman and quadrupolar interactions can generally be neglected in the present context. EPR can, in principle, provide a wealth of information on the identity, chemical nature, chemical environment, electronic structure, and physical structure of the analyte from analysis of each of these interactions, typically employing computer analysis and simulations, and increasingly with quantum chemistry calculations (density functional theory, Taylor theory) [65][66][67][68][69][70][71][72][73][74][75][76] . However, in the case of biological tissues, the origins and spectroscopic parameters of many of the EPR signals have been well-characterized, as described in detail below.…”

Section: Electron Paramagnetic Resonancementioning

confidence: 99%

Cryogenic electron paramagnetic resonance spectroscopy of flash-frozen tissue for characterization of mitochondrial disease

Bennett¹

2020

JTGG

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Multiple States of Nitrile Hydratase from Rhodococcus equi TG328-2: Structural and Mechanistic Insights from Electron Paramagnetic Resonance and Density Functional Theory Studies

Cited by 11 publications

References 50 publications

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

The Effects of the Metal Ion Substitution into the Active Site of Metalloenzymes: A Theoretical Insight on Some Selected Cases

Cryogenic electron paramagnetic resonance spectroscopy of flash-frozen tissue for characterization of mitochondrial disease

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