Structure and assembly of the diiron cofactor in the heme-oxygenase-like domain of the<i>N</i>-nitrosourea-producing enzyme SznF

McBride, Molly J.; Pope, Sarah R.; Kai, Hu; Slater, Jeffrey W.; Okafor, C. Denise; Balskus, Emily P.; Bollinger, J. Martin; Boal, Amie K.

doi:10.1101/2020.07.29.227702

Cited by 9 publications

(13 citation statements)

References 59 publications

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“…As-purified, CADD contained ~0.05-0.1 Fe ions per monomer, indicating that the majority of the enzyme population lacks the expected diiron cofactor. This result is consistent with other HDO family members (6,7,9,12,13,17), where the metallocofactor is apparently highly unstable. LC-MS analysis of reactions containing as-purified CADD (154 µM) under aerobic conditions showed the production of ~3 µM pAB when the enzyme was incubated with dithiothreitol (DTT) versus ~1 µM pAB detected when incubated without a reducing agent (Figure 2A).…”

Section: Resultssupporting

confidence: 91%

“…Thus, CADD is a member of the emerging heme-oxygenase-like diiron oxidase (HDO) superfamily, of which ~10,000 members are bioinformatically proposed, but only a handful have defined enzymatic activities (6). Characterized HDOs catalyze diverse reactions including N-oxygenation (SznF (6)(7)(8)(9), RohS (10), and FlcE (11)), oxidative C-C bond cleavage (UndA (12)(13)(14), BesC (15)(16)(17), and FlcE (11)), and methylene excision (FlcD) (11).…”

Section: Introductionmentioning

confidence: 99%

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CADD from Chlamydia trachomatis is a manganese-dependent oxygenase that employs a self-sacrificing reaction for the synthesis of p-aminobenzoate

Wooldridge

Stone

Pedraza

et al. 2022

Preprint

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CADD (chlamydia protein associating with death domains) is a p-aminobenzoate synthase involved in a non-canonical route for tetrahydrofolate biosynthesis in the intracellular bacterial pathogen, Chlamydia trachomatis. The previously solved crystal structure revealed a seven-helix bundle architecture similar to heme oxygenase with a diiron active site, making CADD a founding member of the emerging HDO (heme-oxygenase-like diiron oxidase) superfamily. The CADD-dependent route for pAB biosynthesis was shown to use L-tyrosine as a precursor, however, in vitro reactions were not stimulated by the addition of free L-tyrosine or other tyrosine-derived metabolites, leading to the proposal that the enzyme uses an internal active site tyrosine residue as a precursor to pAB. Here, we perform further biochemical characterization of CADD to clarify the details of the unique self-sacrificing reaction. Surprisingly, the pAB synthase reaction was shown to be dependent on manganese as opposed to iron and the data are most consistent with an active dimanganese cofactor analogous to class Ib and class Id ribonucleotide reductases. Experiments with 18O2 demonstrated the incorporation of two oxygen atoms from molecular oxygen into the pAB product, supporting the proposed mechanism requiring two monooxygenase reactions. Mass spectrometry-based proteomic analyses of CADD-derived peptides demonstrated a glycine substitution at Tyr27, a modification that was increased in reactions that produced pAB in vitro. Additionally, Lys152 was found to be deaminated and oxidized to aminoadipic acid. Taken together, our results support the conclusion that CADD is a manganese-dependent oxygenase that uses Tyr27 and possibly Lys152 as sacrificial substrates for pAB biosynthesis.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

CADD from Chlamydia trachomatis is a manganese-dependent oxygenase that employs a self-sacrificing reaction for the synthesis of p-aminobenzoate

Wooldridge

Stone

Pedraza

et al. 2022

Preprint

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“…It has been proposed that the NO generated in situ could bind to the active site iron of the StzF cupin domain to form a nitrosyl-metal intermediate and then be incorporated into L-HMC to provide an N -nitroso group . The fact that no N -nitroso product was observed in the StzF in vitro reactions might due to the very little iron bound (<0.02 equiv) by StzF and the instability of di-iron cofactor as described elsewhere. , NO is an active species for nitrogen–nitrogen bond formation involved in both the inorganic nitrogen cycle and natural product biosynthesis. , The nitrosyl-metal intermediate has already been identified in the reaction catalyzed by NO reductase CYP450nor, which converts NO to N 2 O (Figure C) . Taken together, we cannot rule out the possibility that NO is the distal nitrogen atom donor of the N -nitroso group in streptozotocin ( 5 ) biosynthesis.…”

Section: Rearrangement Reactions In Nitrogen–nitrogen Bond Formationmentioning

confidence: 90%

“…62 The fact that no N-nitroso product was observed in the StzF in vitro reactions might due to the very little iron bound (<0.02 equiv) by StzF and the instability of di-iron cofactor as described elsewhere. 63,64 NO is an active species for nitrogen−nitrogen bond formation involved in both the inorganic nitrogen cycle and natural product biosynthesis. 25,39 The nitrosyl-metal intermediate has already been identified in the reaction catalyzed by NO reductase CYP450nor, which converts NO to N 2 O (Figure 2C).…”

Section: ■ Rearrangement Reactions In Nitrogen−nitrogen Bond Formationmentioning

confidence: 99%

“…Alternatively, the other proposal confirmed that SznF di-iron domain sequentially hydroxylates two nitrogen atoms of the guanidine group of 25 to form L-DHMA (28; Figure 4 A). 61,63,64 The rearrangement of L-DHMA (28) to form nitrogen−nitrogen bond occurs in the SznF cupin domain in which the iron is coordinated to three His residues (H448, H409 and H307). The coordination of the dihydroxyl intermediate 28 with SznF indicates a significant binding pattern between the N δ -hydroxyl moiety and the iron center.…”

Section: ■ Rearrangement Reactions In Nitrogen−nitrogen Bond Formationmentioning

confidence: 99%

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Nitrogen–Nitrogen Bond Formation Reactions Involved in Natural Product Biosynthesis

2021

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Construction of nitrogen–nitrogen bonds involves sophisticated biosynthetic mechanisms to overcome the difficulties inherent to the nucleophilic nitrogen atom of amine. Over the past decade, a multitude of reactions responsible for nitrogen–nitrogen bond formation in natural product biosynthesis have been uncovered. On the basis of the intrinsic properties of these reactions, this Review classifies these reactions into three categories: comproportionation, rearrangement, and radical recombination reactions. To expound the metallobiochemistry underlying nitrogen–nitrogen bond formation reactions, we discuss the enzymatic mechanisms in comparison to well characterized canonical heme-dependent enzymes, mononuclear nonheme iron-dependent enzymes, and nonheme di-iron enzymes. We also illuminate the intermediary properties of nitrogen oxide species NO2 –, NO+, and N2O3 in nitrogen–nitrogen bond formation reactions with clues derived from inorganic nitrogen metabolism driven by anammox bacteria and nitrifying bacteria. These multidimentional discussions will provide further insights into the mechanistic proposals of nitrogen–nitrogen bond formation in natural product biosynthesis.

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The Chlamydia trachomatis p‐aminobenzoate synthase CADD is a manganese‐dependent oxygenase that uses its own amino acid residues as substrates

et al. 2023

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Edited by Peter BrzezinskiCADD (chlamydia protein associating with death domains) is a paminobenzoate (pAB) synthase involved in a noncanonical route for tetrahydrofolate biosynthesis in Chlamydia trachomatis. Although previously implicated to employ a diiron cofactor, here, we show that pAB synthesis by CADD requires manganese and the physiological cofactor is most likely a heterodinuclear Mn/Fe cluster. Isotope-labeling experiments revealed that the two oxygen atoms in the carboxylic acid portion of pAB are derived from molecular oxygen. Further, mass spectrometry-based proteomic analyses of CADD-derived peptides demonstrated a glycine substitution at Tyr27, providing strong evidence that this residue is sacrificed for pAB synthesis. Additionally, Lys152 was deaminated and oxidized to aminoadipic acid, supporting its proposed role as a sacrificial amino group donor.

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Structure and assembly of the diiron cofactor in the heme-oxygenase-like domain of theN-nitrosourea-producing enzyme SznF

Cited by 9 publications

References 59 publications

CADD from Chlamydia trachomatis is a manganese-dependent oxygenase that employs a self-sacrificing reaction for the synthesis of p-aminobenzoate

CADD from Chlamydia trachomatis is a manganese-dependent oxygenase that employs a self-sacrificing reaction for the synthesis of p-aminobenzoate

Nitrogen–Nitrogen Bond Formation Reactions Involved in Natural Product Biosynthesis

The Chlamydia trachomatis p‐aminobenzoate synthase CADD is a manganese‐dependent oxygenase that uses its own amino acid residues as substrates

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