Abscisic acid (ABA) is a well-known phytohormone that regulates abiotic stresses. ABA produced by fungi is also proposed to be a virulence factor of fungal pathogens. Although its biosynthetic pathway in fungi was proposed by a series of feeding experiments, the enzyme catalyzing the reaction from farnesyl diphosphate to α-ionylideneethane remains to be identified. In this work, we identified the novel type of sesquiterpene synthase BcABA3 and its unprecedented three-step reaction mechanism involving two neutral intermediates, β-farnesene and allofarnesene. Database searches showed that BcABA3 has no homology with typical sesquiterpene synthases and that the homologous enzyme genes are found in more than 100 bacteria, suggesting that these enzymes form a new family of sesquiterpene synthases.
Highly reducing polyketide synthases (HR-PKSs) produce structurally diverse polyketides (PKs). The PK diversity is constructed by av ariety of factors,i ncluding the b-keto processing,c hain length, methylation pattern, and relative and absolute configurations of the substituents.W e examined the stereochemical course of the PK processing for the synthesis of polyhydroxyPKs such as phialotides,phomenoic acid, and ACR-toxin. Heterologous expression of aH R-PKS gene,atrans-acting enoylreductase gene,and atruncated non-ribosomal peptide synthetase gene resulted in the formation of al inear PK with multiple stereogenic centers.T he absolute configurations of the stereogenic centers were determined by chemical degradation followed by comparison of the degradation products with synthetic standards.As tereochemical rule was proposed to explain the absolute configurations of other reduced PKs and highlights an error in the absolute configurations of ar eported structure.T he present work demonstrates that focused functional analysis of functionally related HR-PKSs leads to ab etter understanding of the stereochemical course.
Abscisic acid (ABA) is one of the plant hormones that regulates physiological functions in various organisms, including plants, sponges, and humans. The biosynthetic machinery in plants is firmly established, while that in fungi is still unclear. Here, we elucidated the functions of the four biosynthetic genes, bcABA1-bcABA4, found in Botrytis cinerea by performing biotransformation experiments and in vitro enzymatic reactions with putative biosynthetic intermediates. The first-committed step is the cyclization of farnesyl diphosphate to give α-ionylideneethane catalyzed by a novel sesquiterpene synthase, BcABA3, which exhibits low amino acid sequence identities with sesquiterpene synthases. Subsequently, two cytochrome P450s, BcABA1 and BcABA2, mediate oxidative modifications of the cyclized product to afford 1ʹ,4ʹ-trans-dihydroxy-α-ionylideneacetic acid, which undergoes alcohol oxidation to furnish ABA. Our results demonstrated that production of ABA does not depend on the nucleotide sequence of bcABA genes. The present study set the stage to investigate the role of ABA in infections.
Antihypercholesterolemic
agent phomoidride (PMD) B has
a highly
elaborated bicyclo[4.3.1]deca-1,6-diene core scaffold derived from
dimeric anhydride with a nine-membered ring. This report elucidated
the late stage transformation from an anhydride monomer to PMD B through
the heterologous expression of three enzyme genes, TstC, TstK, and
TstE. Additional in vitro studies of TstK and TstE provided evidence
on the formation of PMD via dimerization, three-step oxidation, and
unusual methylation-triggered bicyclic ketal formation. Elucidation
of the function of cyclase TstC prompts us to examine the cyclization
mechanism of TstC by using a computational approach. Computational
analytical data on PMD and structurally related glaucanic acid indicated
that the initial decarboxylation of monomer results in enolate and
subsequent double Michael reactions of another monomer, followed by
an optional aldol reaction proceeding in an endo-selective
manner to give cycloadducts, supporting the fact that the starting
orientation of two monomers is directly transferred to the product
configurations.
Previously, we succeeded to produce the core structure of the host-selective ACR-toxin (1) on brown leaf spot on rough lemon when the polyketide synthase ACRTS2 gene was heterologously expressed in Aspergillus oryzae (AO). To confirm the production of 1 in AO, the detection limit and suppressing decarboxylation were improved, and these efforts led us to conclude the direct production of 1 instead of its decarboxylation product. During this examination, minor ACR-toxin-related metabolites were found. Their structure determination enabled us to propose a decarboxylation mechanism and novel branching route forming byproducts from the coupling of the dihydropyrone moiety of 1 with the acetaldehyde and kojic acid abundant in AO. The involvement of putative cyclase ACRTS3 in the chain release of linear polyketide was excluded by the co-expression analysis of ACRTS2 and ACRTS3. Taken together, we concluded the production of 1 in AO is solely responsible for ACRTS2.
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