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Algal neurotoxin biosynthesis repurposes the terpene cyclase structural fold into an <i>N</i> -prenyltransferase

Jonathan R. Chekan, Shaun M. K. McKinnie, Joseph P. Noel, Bradley S. Moore

2020Proceedings of the National Academy of Sciences25 citationsDOIOpen Access PDF

Abstract

Prenylation is a common biological reaction in all domains of life wherein prenyl diphosphate donors transfer prenyl groups onto small molecules as well as large proteins. The enzymes that catalyze these reactions are structurally distinct from ubiquitous terpene cyclases that, instead, assemble terpenes via intramolecular rearrangements of a single substrate. Herein, we report the structure and molecular details of a new family of prenyltransferases from marine algae that repurposes the terpene cyclase structural fold for the N -prenylation of glutamic acid during the biosynthesis of the potent neurochemicals domoic acid and kainic acid. We solved the X-ray crystal structure of the prenyltransferase found in domoic acid biosynthesis, DabA, and show distinct active site binding modifications that remodel the canonical magnesium (Mg 2+ )-binding motif found in terpene cyclases. We then applied our structural knowledge of DabA and a homologous enzyme from the kainic acid biosynthetic pathway, KabA, to reengineer their isoprene donor specificities (geranyl diphosphate [GPP] versus dimethylallyl diphosphate [DMAPP]) with a single amino acid change. While diatom DabA and seaweed KabA enzymes share a common evolutionary lineage, they are distinct from all other terpene cyclases, suggesting a very distant ancestor to the larger terpene synthase family.

Topics & Concepts

PrenyltransferaseTerpenePrenylationBiochemistryBiosynthesisCyclaseChemistryEnzymeStereochemistryTerpenoidAmino acidBiologyPlant biochemistry and biosynthesisMicrobial Natural Products and BiosynthesisBiochemical and biochemical processes