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      Substrate selectivity of an isolated enoyl reductase catalytic domain from an iterative highly reducing fungal polyketide synthase reveals key components of programming†

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          Abstract

          The complete stereochemical course and substrate selectivity of the enoyl reductase domain from the fungal polyketide synthase squalestatin tetraketide synthase (SQTKS) have been determined.

          Abstract

          A cis-acting enoyl reductase (ER) catalytic domain was isolated from a fungal highly reducing iterative polyketide synthase (HR-iPKS) for the first time and studied in vitro. The ER from the squalestatin tetraketide synthase forms a discrete dimeric protein in solution. The ER shows broad substrate selectivity, reducing enoyl species including both natural and unnatural substrates. Pantetheine-bound substrate thiolesters reacted much faster than the corresponding SNAC thiolesters. The unnatural substrates included Z-olefins, 2-ethyl olefins and pentaketides. Methylation of the substrate modifies the activity of the ER such that the 2,4-dimethyl oct-2-enoyl substrate fits into the active site but cannot be reduced. A new NMR-based assay was developed for the direct observation of the stereochemical preferences at the 4′ position of the NADPH cofactor and the C-2 and C-3 positions of the substrates. The assay reveals that the fungal iPKS ER-catalysed reaction is stereochemically identical to that of the vertebrate FAS (vFAS) at the cofactor 4′ position and the substrate 3-position, but the high stereoselectivity displayed by intact SQTKS is lost such that reprotonation at the 2-position is unselective by the isolated ER. A 3D model of ER was consistent with these observations and showed that the ER may sequester its final substrate to prevent further chain extension. The results support a developing model for programming by HR-iPKS in which competition for substrates between restrictive and permissive catalytic domains chaperones the growing polyketide to completion, while allowing for errors and evolution.

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          Most cited references23

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          Zaragozic acids: a family of fungal metabolites that are picomolar competitive inhibitors of squalene synthase.

          Three closely related fungal metabolites, zaragozic acids A, B, and C, that are potent inhibitors of squalene synthase have been isolated and characterized. Zaragozic acids A, B, and C were produced from an unidentified sterile fungal culture, Sporormiella intermedia, and Leptodontium elatius, respectively. The structures of the zaragozic acids and their trimethyl esters were determined by a combination of physical and chemical techniques. The zaragozic acids are characterized by a novel 2,8-dioxobicyclo[3.2.1]octane-4,6,7- trihydroxyl-3,4,5-tricarboxylic acid core and differ from each other in the structures of the 6-acyl and 1-alkyl side chains. They were found to be potent competitive inhibitors of rat liver squalene synthase with apparent Ki values of 78 pM, 29 pM, and 45 pM, respectively. They inhibited cholesterol synthesis in Hep G2 cells, and zaragozic acid A was an inhibitor of acute hepatic cholesterol synthesis in the mouse (50% inhibitory dose of 200 micrograms/kg of body weight). Inhibition of squalene synthase in cells and in vivo was accompanied by an accumulation of label from [3H]mevalonate into farnesyl diphosphate, farnesol, and organic acids. These data indicate that the zaragozic acids are a previously unreported class of therapeutic agents with potential for the treatment of hypercholesterolemia.
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            Prediction and manipulation of the stereochemistry of enoylreduction in modular polyketide synthases.

            When an enoylreductase enzyme of a modular polyketide synthase reduces a propionate extender unit that has been newly added to the growing polyketide chain, the resulting methyl branch may have either S or R configuration. We have uncovered a correlation between the presence or absence of a unique tyrosine residue in the ER active site and the chirality of the methyl branch that is introduced. When this position in the active site is occupied by a tyrosine residue, the methyl branch has S configuration, otherwise it has R configuration. In a model PKS in vivo, a mutation (Tyr to Val) in an erythromycin PKS-derived ER caused a switch in the methyl branch configuration in the product from S to R. In contrast, alteration (Val to Tyr) at this position in a rapamycin-derived PKS ER was insufficient to achieve a switch from R to S, showing that additional residues also participate in stereocontrol of enoylreduction.
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              Redox control of secondary structure in a designed peptide

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                Author and article information

                Journal
                Chem Sci
                Chem Sci
                Chemical Science
                Royal Society of Chemistry
                2041-6520
                2041-6539
                01 February 2017
                26 September 2016
                : 8
                : 2
                : 1116-1126
                Affiliations
                [a ] School of Chemistry , University of Bristol , Cantock's Close , Bristol BS8 1TS , UK
                [b ] Institute for Organic Chemistry , BMWZ , Leibniz Universität Hannover , Schneiderberg 1b , 30167 , Hannover , Germany . Email: russell.cox@ 123456oci.uni-hannover.de
                Author information
                http://orcid.org/0000-0002-1844-0157
                Article
                c6sc03496a
                10.1039/c6sc03496a
                5369529
                28451251
                96dba3d7-c383-47b5-8b7f-126c248dae3a
                This journal is © The Royal Society of Chemistry 2016

                This is an Open Access article distributed under the terms of the Creative Commons Attribution 3.0 Unported License ( http://creativecommons.org/licenses/by/3.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

                History
                : 5 August 2016
                : 21 September 2016
                Categories
                Chemistry

                Notes

                †Electronic supplementary information (ESI) available: Details of all experimental and characterisation data. See DOI: 10.1039/c6sc03496a


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