Biochemical and crystallographic investigations into isonitrile formation by a nonheme iron-dependent oxidase/decarboxylase

Jonnalagadda, R.; Flores, Antonio Del Rio; Cai, Wenlong; Mehmood, Rimsha; Narayanamoorthy, Maanasa; Ren, Chaoxiang; Zaragoza, Jan Paulo T.; Kulik, Heather J.; Zhang, Wenjun; Drennan, Catherine L.

doi:10.1074/jbc.ra120.015932

Cited by 18 publications

(33 citation statements)

References 41 publications

(71 reference statements)

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“…1 was proposed to be the first intermediate in the pathway based on the previously reported structure of ScoE with 1 and detection of 1 from a 13 C NMR experiment analyzing an enzymatic assay from SfaA . Our recent structures of ScoE with bound CABA further demonstrated one of the C5 hydrogen points toward the iron cofactor, suggesting that C5 was the most likely site of initial C–H activation and hydroxylation . Consistently, we observed a transient production of 1 where it was detected from a 3 h assay at 4 °C, but not from an overnight assay based on the NMR analysis, thus supporting the intermediacy of this compound (Figures S4 and S9).…”

Section: Resultsmentioning

confidence: 86%

“…We obtained several crystal structures of ScoE with and without substrates and noted an ordered water network extending from the CABA site. , Through site-directed mutagenesis, we confirmed the importance of Tyr96, Tyr97, Tyr101, and Arg195 at maintaining the hydrogen-bonding network between three ordered water molecules because alterations of these residues completely abrogated or severely compromised isonitrile formation. Several pathways to isonitrile formation were previously proposed; however, a definitive pathway with evidence for reaction intermediates remains elusive. ,, …”

Section: Introductionmentioning

confidence: 99%

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Probing the Mechanism of Isonitrile Formation by a Non-Heme Iron(II)-Dependent Oxidase/Decarboxylase

Flores

Kastner

et al. 2022

J. Am. Chem. Soc.

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The isonitrile moiety is an electron-rich functionality that decorates various bioactive natural products isolated from diverse kingdoms of life. Isonitrile biosynthesis was restricted for over a decade to isonitrile synthases, a family of enzymes catalyzing a condensation reaction between L-Trp/L-Tyr and ribulose-5phosphate. The discovery of ScoE, a non-heme iron(II) and αketoglutarate-dependent dioxygenase, demonstrated an alternative pathway employed by nature for isonitrile installation. Biochemical, crystallographic, and computational investigations of ScoE have previously been reported, yet the isonitrile formation mechanism remains obscure. In the present work, we employed in vitro biochemistry, chemical synthesis, spectroscopy techniques, and computational simulations that enabled us to propose a plausible molecular mechanism for isonitrile formation. Our findings demonstrate that the ScoE reaction initiates with C5 hydroxylation of (R)-3-((carboxymethyl)amino)butanoic acid to generate 1, which undergoes dehydration, presumably mediated by Tyr96 to synthesize 2 in a trans configuration. (R)-3-isocyanobutanoic acid is finally generated through radical-based decarboxylation of 2, instead of the common hydroxylation pathway employed by this enzyme superfamily.

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Section: Resultsmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Probing the Mechanism of Isonitrile Formation by a Non-Heme Iron(II)-Dependent Oxidase/Decarboxylase

Flores

Kastner

et al. 2022

J. Am. Chem. Soc.

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“…Crystallographic studies showed that the position of the Lys 193 residue in the ScoE appears to be dependent on whether substrate is bound or not. Thus, in the crystal structure coordinates of the resting state protein without substrate bound (6DCH pdb file) the Lys 193 side chain points away from the active site, whereas in the most recent substrate-bound structure (6XN6 pdb file [103]) it points into the active site. In particular, the Lys 193 side chain in the substrate-bound structure is seen to form a hydrogen bonding interaction with the carboxylate group of (R)-3-((carboxymethyl)amino)butanoic acid (CABA) substrate.…”

Section: Reaction Mechanism With Lys 193 Removed From the Modelmentioning

confidence: 99%

Density Functional Theory Study into the Reaction Mechanism of Isonitrile Biosynthesis by the Nonheme Iron Enzyme ScoE

2021

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The nonheme iron enzyme ScoE catalyzes the biosynthesis of an isonitrile substituent in a peptide chain. To understand details of the reaction mechanism we created a large active site cluster model of 212 atoms that contains substrate, the active oxidant and the first- and second-coordination sphere of the protein and solvent. Several possible reaction mechanisms were tested and it is shown that isonitrile can only be formed through two consecutive catalytic cycles that both use one molecule of dioxygen and α-ketoglutarate. In both cycles the active species is an iron(IV)-oxo species that in the first reaction cycle reacts through two consecutive hydrogen atom abstraction steps: first from the N–H group and thereafter from the C–H group to desaturate the NH-CH2 bond. The alternative ordering of hydrogen atom abstraction steps was also tested but found to be higher in energy. Moreover, the electronic configurations along that pathway implicate an initial hydride transfer followed by proton transfer. We highlight an active site Lys residue that is shown to donate charge in the transition states and influences the relative barrier heights and bifurcation pathways. A second catalytic cycle of the reaction of iron(IV)-oxo with desaturated substrate starts with hydrogen atom abstraction followed by decarboxylation to give isonitrile directly. The catalytic cycle is completed with a proton transfer to iron(II)-hydroxo to generate the iron(II)-water resting state. The work is compared with experimental observation and previous computational studies on this system and put in a larger perspective of nonheme iron chemistry.

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“…timescales, as we have shown in non-heme Fe(II) enzymes. [36,63] In such cases, MM dynamics for extensive sampling must be balanced with large-QM-region QM/MM geometry optimizations to quantify critical interactions [36] (e.g., covalent contributions to HBs [64]). We also recently showed [55] that while properties approach asymptotic limits slowly with increasing QM region size, the fluctuations of a property of a representative metal binding site of Zndependent DNA methyltransferase were as large as the differences between configurationally averaged values for different size QM regions.…”

Section: Configurational Sampling Challengesmentioning

confidence: 99%

Harder, better, faster, stronger: Large-scale QM and QM/MM for predictive modeling in enzymes and proteins

Vennelakanti

Nazemi

Mehmood

et al. 2022

Current Opinion in Structural Biology

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Biochemical and crystallographic investigations into isonitrile formation by a nonheme iron-dependent oxidase/decarboxylase

Cited by 18 publications

References 41 publications

Probing the Mechanism of Isonitrile Formation by a Non-Heme Iron(II)-Dependent Oxidase/Decarboxylase

Probing the Mechanism of Isonitrile Formation by a Non-Heme Iron(II)-Dependent Oxidase/Decarboxylase

Density Functional Theory Study into the Reaction Mechanism of Isonitrile Biosynthesis by the Nonheme Iron Enzyme ScoE

Harder, better, faster, stronger: Large-scale QM and QM/MM for predictive modeling in enzymes and proteins

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