X-ray absorption spectroscopic characterization of the diferric-peroxo intermediate of human deoxyhypusine hydroxylase in the presence of its substrate eIF5a

Jasniewski, Andrew J.; Engstrom, Lisa; Vu, Van V.; Park, Myung Hee; Que, Lawrence

doi:10.1007/s00775-016-1373-8

Cited by 21 publications

(35 citation statements)

References 126 publications

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“…Extra carbon scatterers at 3.56 Å also improve the fit, and are consistent with assignment to the C β atom of an N δ -bound histidine ligand (Table S3, fit 22 vs 23). 35 In addition, the EXAFS fit does not include the carbon scatterer at ~2.6 Å that is associated with the terminal bidentate carboxylate found in the crystal structure of WT R and observed in its EXAFS fit. This result would be consistent with this carboxylate no longer coordinating in a bidentate mode upon binding of untethered CmlP AT to WT R .…”

Section: Resultsmentioning

confidence: 99%

“…35 The relative invariance of the cluster structure was proposed to be a consequence of the unique HEAT-repeat protein fold in DOHH that allowed for rigid cross-domain binding of the 4-His-2-carboxylate ligand framework to the Fe centers. It could be argued that the unusual metallo-β-lactamase fold of CmlA may also innately impart rigidity to the diiron cluster, but our data does not provide us clear insight into the issue.…”

Section: Discussionmentioning

confidence: 99%

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A Carboxylate Shift Regulates Dioxygen Activation by the Diiron Nonheme β-Hydroxylase CmlA upon Binding of a Substrate-Loaded Nonribosomal Peptide Synthetase

Jasniewski

Knoot

Lipscomb³

et al. 2016

Biochemistry

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The first step in the nonribosomal peptide synthetase (NRPS)-based biosynthesis of chloramphenicol is the β-hydroxylation of the precursor L-para-aminophenylalanine (L-PAPA) catalyzed by the monooxygenase CmlA. The active site of CmlA contains a dinuclear iron cluster which is reduced to the diferrous state (WT R ) to initiate O 2 activation. However, rapid O 2 activation only occurs when WT R is bound to CmlP, the NRPS to which L-PAPA is covalently attached. Here the X-ray crystal structure of WT R is reported, which is very similar to that of the as-isolated diferric enzyme in which the irons are coordinately saturated. X-ray absorption spectroscopy is used to investigate the WT R cluster ligand structure as well as the structures of WT R in complex with a functional CmlP variant (CmlP AT ) with and without L-PAPA attached. It is found that formation of the active WT R -CmlP AT~L -PAPA complex converts at least one iron of the cluster from six-to five-coordinate by changing a bidentately bound amino acid carboxylate to monodentate on Fe1. The only bidentate carboxylate in the structure of WT R is E377. The crystal structure of the CmlA variant E377D shows only monodentate carboxylate coordination. Reduced E377D reacts rapidly with O 2 in the presence or absence of CmlP AT~L -PAPA, showing loss of regulation. However this variant fails to catalyze hydroxylation, suggesting that E377 has the dual role of coupling regulation of O 2 reactivity with juxtaposition of the substrate and the reactive oxygen species. The carboxylate shift in response to substrate binding represents a novel regulatory strategy for oxygen activation in diiron oxygenases. Graphical abstract * Corresponding Authors

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

A Carboxylate Shift Regulates Dioxygen Activation by the Diiron Nonheme β-Hydroxylase CmlA upon Binding of a Substrate-Loaded Nonribosomal Peptide Synthetase

Jasniewski

Knoot

Lipscomb³

et al. 2016

Biochemistry

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“…The Mn(III)/ Mn(IV) center can be probed by MCD and the Fe(III) center by NRVS to correlate with the binuclear non-heme Fe enzymes [93]. Finally, a number of new biferrous enzyme classes are emerging (deoxyhypusine hydroxylase (DOHH) [94, 131], urease [95], CmlI [132], etc.) that are accessible to the VTVH MCD/DFT approach presented above to extend Table 1 and develop additional structure/function correlations.…”

Section: Concluding Commentsmentioning

confidence: 99%

Structure/function correlations over binuclear non-heme iron active sites

Solomon

Park

2016

J Biol Inorg Chem

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Binuclear non-heme iron enzymes activate O2 to perform diverse chemistries. Three different structural mechanisms of O2 binding to a coupled binuclear iron site have been identified utilizing variable-temperature, variable-field magnetic circular dichroism spectroscopy (VTVH MCD). For the μ-OH-bridged Fe(II)2 site in hemerythrin, O2 binds terminally to a five-coordinate Fe(II) center as hydroperoxide with the proton deriving from the μ-OH bridge and the second electron transferring through the resulting μ-oxo superexchange pathway from the second coordinatively saturated Fe(II) center in a proton-coupled electron transfer process. For carboxylate-only-bridged Fe(II)2 sites, O2 binding as a bridged peroxide requires both Fe(II) centers to be coordinatively unsaturated and has good frontier orbital overlap with the two orthogonal O2 π* orbitals to form peroxo-bridged Fe(III)2 intermediates. Alternatively, carboxylate-only-bridged Fe(II)2 sites with only a single open coordination position on an Fe(II) enable the one-electron formation of Fe(III)–O2− or Fe(III)–NO− species. Finally, for the peroxo-bridged Fe(III)2 intermediates, further activation is necessary for their reactivities in one-electron reduction and electrophilic aromatic substitution, and a strategy consistent with existing spectral data is discussed.

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“…These spectral changes have been attributed to the presence of an additional μ -hydroxo bridge. 18,27 Recently, the crystal structure of toluene 4-monooxygenase (T4MO) has been obtained with O 2 and substrate bound, and based on Fe–O distances, an Fe(II)Fe(III)-superoxide species rather than a peroxo biferric species has been suggested as the active intermediate. 28 …”

Section: Introductionmentioning

confidence: 99%

Peroxide Activation for Electrophilic Reactivity by the Binuclear Non-heme Iron Enzyme AurF

Park

Kwak

et al. 2017

J. Am. Chem. Soc.

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Binuclear non-heme iron enzymes activate O2 for diverse chemistries that include oxygenation of organic substrates and hydrogen atom abstraction. This process often involves the formation of peroxo-bridged biferric intermediates, only some of which can perform electrophilic reactions. To elucidate the geometric and electronic structural requirements to activate peroxo reactivity, the active peroxo intermediate in 4-aminobenzoate N-oxygenase (AurF) has been characterized spectroscopically and computationally. A magnetic circular dichroism study of reduced AurF shows that its electronic and geometric structures are poised to react rapidly with O2. Nuclear resonance vibrational spectroscopic definition of the peroxo intermediate formed in this reaction shows that the active intermediate has a protonated peroxo bridge. Density functional theory computations on the structure established here show that the protonation activates peroxide for electrophilic/single-electron-transfer reactivity. This activation of peroxide by protonation is likely also relevant to the reactive peroxo intermediates in other binuclear non-heme iron enzymes.

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X-ray absorption spectroscopic characterization of the diferric-peroxo intermediate of human deoxyhypusine hydroxylase in the presence of its substrate eIF5a

Cited by 21 publications

References 126 publications

A Carboxylate Shift Regulates Dioxygen Activation by the Diiron Nonheme β-Hydroxylase CmlA upon Binding of a Substrate-Loaded Nonribosomal Peptide Synthetase

A Carboxylate Shift Regulates Dioxygen Activation by the Diiron Nonheme β-Hydroxylase CmlA upon Binding of a Substrate-Loaded Nonribosomal Peptide Synthetase

Structure/function correlations over binuclear non-heme iron active sites

Peroxide Activation for Electrophilic Reactivity by the Binuclear Non-heme Iron Enzyme AurF

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