The Structural Basis of Malodorant Skatole Formation by the Glycyl Radical Enzyme Indoleacetate Decarboxylase.
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| Abstract | Glycyl radical enzymes (GREs) catalyze challenging chemical reactions using a post-translationally installed glycyl radical cofactor. One such enzyme, indoleacetate decarboxylase (IAD), performs the radical-based decarboxylation of indole-3-acetate (I3A) to form the malodorant molecule skatole. In addition to being an odor nuisance, skatole is a human and livestock lung toxin, a suspected carcinogen, and a mosquito attractant, all of which impact human health, agriculture, food production, and wastewater treatment. Here, we use cryogenic electron microscopy to solve a 2.45-Ã… resolution structure of indoleacetate decarboxylase from the gut bacterium . We observe IAD in a homotetrameric form with the substrate I3A bound in all four protomers. The positioning of the I3A in the active site is unexpected and is more consistent with a Kolbe-type decarboxylation mechanism, i.e. a decarboxylation initiated by a 1-electron oxidation of the carboxylate moiety rather than being initiated by hydrogen atom transfer (HAT). Previously, a high deuterium content in skatole from IAD assays in DO was used to support a HAT mechanism over a Kolbe-type mechanism. However, we show here that deuterium content does not necessarily inform on mechanism as IAD can catalyze the exchange of skatole's 3'-methyl hydrogens post-turnover. Structural comparisons show that both IAD and HPAD display structural features that are not found in other characterized GREs, suggesting that they represent a distinct GRE-subclass. Collectively, these insights will inform IAD inhibitor design aimed at decreasing skatole production. |
| Year of Publication | 2026
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| Journal | bioRxiv : the preprint server for biology
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| Date Published | 05/2026
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| ISSN | 2692-8205
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| DOI | 10.64898/2026.05.24.727522
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| PubMed ID | 42244603
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