Vinylogous Dehydration by a Polyketide Dehydratase Domain in Curacin Biosynthesis

William D. Fiers, Greg J. Dodge, David H. Sherman, Janet L. Smith, Courtney C. Aldrich

Research output: Contribution to journalArticlepeer-review

19 Scopus citations


Polyketide synthase (PKS) enzymes continue to hold great promise as synthetic biology platforms for the production of novel therapeutic agents, biofuels, and commodity chemicals. Dehydratase (DH) catalytic domains play an important role during polyketide biosynthesis through the dehydration of the nascent polyketide intermediate to provide olefins. Our understanding of the detailed mechanistic and structural underpinning of DH domains that control substrate specificity and selectivity remains limited, thus hindering our efforts to rationally re-engineer PKSs. The curacin pathway houses a rare plurality of possible double bond permutations containing conjugated olefins as well as both cis- and trans-olefins, providing an unrivaled model system for polyketide dehydration. All four DH domains implicated in curacin biosynthesis were characterized in vitro using synthetic substrates, and activity was measured by LC-MS/MS analysis. These studies resulted in complete kinetic characterization of the all-trans-trienoate-forming CurK-DH, whose kcat of 72 s-1 is more than 3 orders of magnitude greater than that of any previously reported PKS DH domain. A novel stereospecific mechanism for diene formation involving a vinylogous enolate intermediate is proposed for the CurJ and CurH DHs on the basis of incubation studies with truncated substrates. A synthetic substrate was co-crystallized with a catalytically inactive Phe substitution in the His-Asp catalytic dyad of CurJ-DH to elucidate substrate-enzyme interactions. The resulting complex suggested the structural basis for dienoate formation and provided the first glimpse into the enzyme-substrate interactions essential for the formation of olefins in polyketide natural products. This examination of both canonical and non-canonical dehydration mechanisms reveals hidden catalytic activity inherent in some DH domains that may be leveraged for future applications in synthetic biology.

Original languageEnglish (US)
Pages (from-to)16024-16036
Number of pages13
JournalJournal of the American Chemical Society
Issue number49
StatePublished - Dec 14 2016

Bibliographical note

Funding Information:
This work was supported by a grant (GM081544 to J.L.S.) from the National Institutes of Health. Mass spectrometry was carried out with the assistance of Dr. Bruce A. Witthuhn in the Analytical Biochemistry Shared Resource of the Masonic Cancer Center, University of Minnesota, funded in part by Cancer Center Support Grant CA-77598. We also gratefully acknowledge financial support from the Department of Medicinal Chemistry, University of Minnesota (to W.D.F.).

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