Diradical intermediate within the context of tryptophan tryptophylquinone biosynthesis

Yukl, Erik T.; Liu, Fange; Krzystek, J.; Shin, Sooim; Jensen, L.M.R.; Davidson, Victor L.; Wilmot, Carrie M.; Liu, Aimin

doi:10.1073/pnas.1215011110

Cited by 47 publications

(71 citation statements)

References 44 publications

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“…Completion of TTQ biosynthesis on preMADH could be catalysed by MauG in vitro [10,11] (Figure 1). The order of reactions in this biosynthetic process is cross-link formation between the hydroxylated βTrp 57 and βTrp 108 , a second hydroxylation of βTrp 57 , and oxidation of the quinol MADH (methylamine dehydrogenase) to the quinone state [12]. The process requires three two-electron oxidation reactions.…”

Section: Introductionmentioning

confidence: 99%

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Shin¹,

Feng

Davidson³

2013

Biochemical Journal

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The dihaem enzyme MauG catalyses a six-electron oxidation required for post-translational modification of preMADH (precursor of methylamine dehydrogenase) to complete the biosynthesis of its TTQ (tryptophan tryptophylquinone) cofactor. Trp93 of MauG is positioned midway between its two haems, and in close proximity to a Ca2+ that is critical for MauG function. Mutation of Trp93 to tyrosine caused loss of bound Ca2+ and changes in spectral features similar to those observed after removal of Ca2+ from WT (wild-type) MauG. However, whereas Ca2+-depleted WT MauG is inactive, W93Y MauG exhibited TTQ biosynthesis activity. The rate of TTQ biosynthesis from preMADH was much lower than that of WT MauG and exhibited highly unusual kinetic behaviour. The steady-state reaction exhibited a long lag phase, the duration of which was dependent on the concentration of preMADH. The accumulation of reaction intermediates, including a diradical species of preMADH and quinol MADH (methylamine dehydrogenase), was detected during this pre-steady-state phase. In contrast, steady-state oxidation of quinol MADH to TTQ, the final step of TTQ biosynthesis, exhibited no lag phase. A kinetic model is presented to explain the long pre-steady-state phase of the reaction of W93Y MauG, and the role of this conserved tryptophan residue in MauG and related dihaem enzymes is discussed.

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Section: Introductionmentioning

confidence: 99%

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Shin¹,

Feng

Davidson³

2013

Biochemical Journal

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“…Mutations of this residue disrupted the position and orientation of Glu113, which in turn altered the water network (29). Mutations of Pro107 as well as a Q103A mutation also increased the susceptibility of the three Met residues to autooxidation (15,29).…”

Section: Tsmentioning

confidence: 99%

“…1). Concomitant with this ET is the formation of free-radical intermediates on preMADH that go on to form the TTQ product (15). In the absence of preMADH, the autoreduction of the bis-Fe IV redox state to the diferric state leads to inactivation of MauG (16).…”

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confidence: 99%

Roles of multiple-proton transfer pathways and proton-coupled electron transfer in the reactivity of the bis -Fe ^IV state of MauG

Williamson

Davidson

2015

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

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The high-valent state of the diheme enzyme MauG exhibits charge–resonance (CR) stabilization in which the major species is a bis-FeIV state with one heme present as FeIV=O and the other as FeIV with axial heme ligands provided by His and Tyr side chains. In the absence of its substrate, the high-valent state is relatively stable and returns to the diferric state over several minutes. It is shown that this process occurs in two phases. The first phase is redistribution of the resonance species that support the CR. The second phase is the loss of CR and reduction to the diferric state. Thermodynamic analysis revealed that the rates of the two phases exhibited different temperature dependencies and activation energies of 8.9 and 19.6 kcal/mol. The two phases exhibited kinetic solvent isotope effects of 2.5 and 2.3. Proton inventory plots of each reaction phase exhibited extreme curvature that could not be fit to models for one- or multiple-proton transfers in the transition state. Each did fit well to a model for two alternative pathways for proton transfer, each involving multiple protons. In each case the experimentally determined fractionation factors were consistent with one of the pathways involving tunneling. The percent of the reaction that involved the tunneling pathway differed for the two reaction phases. Using the crystal structure of MauG it was possible to propose proton–transfer pathways consistent with the experimental data using water molecules and amino acid side chains in the distal pocket of the high-spin heme.

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“…It is well established that multi-step tunnelling, called hopping, is required for functional charge transport in many redox enzymes (examples include ribonucleotide reductase [1][2][3][4][5][6][7][8][9], photosystem II [10][11][12], DNA photolyase [13][14][15][16][17][18][19][20][21], MauG [22][23][24][25] and cytochrome c peroxidase [26,27]). Here, we advance the hypothesis that many such enzymes, most especially those that generate high-potential intermediates during turnover, could be irreversibly damaged if the intermediates are not inactivated in some way.…”

Section: Introductionmentioning

confidence: 99%

Could tyrosine and tryptophan serve multiple roles in biological redox processes?

Winkler

2015

Phil. Trans. R. Soc. A.

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Single-step electron tunnelling reactions can transport charges over distances of 15–20 Åin proteins. Longer-range transfer requires multi-step tunnelling processes along redox chains, often referred to as hopping. Long-range hopping via oxidized radicals of tryptophan and tyrosine, which has been identified in several natural enzymes, has been demonstrated in artificial constructs of the blue copper protein azurin. Tryptophan and tyrosine serve as hopping way stations in high-potential charge transport processes. It may be no coincidence that these two residues occur with greater-than-average frequency in O 2 - and H 2 O 2 -reactive enzymes. We suggest that appropriately placed tyrosine and/or tryptophan residues prevent damage from high-potential reactive intermediates by reduction followed by transfer of the oxidizing equivalent to less harmful sites or out of the protein altogether.

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Diradical intermediate within the context of tryptophan tryptophylquinone biosynthesis

Cited by 47 publications

References 44 publications

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Roles of multiple-proton transfer pathways and proton-coupled electron transfer in the reactivity of the bis -Fe ^IV state of MauG

Could tyrosine and tryptophan serve multiple roles in biological redox processes?

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Diradical intermediate within the context of tryptophan tryptophylquinone biosynthesis

Cited by 47 publications

References 44 publications

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Mutation of Trp93 of MauG to tyrosine causes loss of bound Ca2+ and alters the kinetic mechanism of tryptophan tryptophylquinone cofactor biosynthesis

Roles of multiple-proton transfer pathways and proton-coupled electron transfer in the reactivity of the bis -Fe IV state of MauG

Could tyrosine and tryptophan serve multiple roles in biological redox processes?

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Roles of multiple-proton transfer pathways and proton-coupled electron transfer in the reactivity of the bis -Fe ^IV state of MauG