Engineering of complex polyketide biosynthesis--insights from sequencing of the monensin biosynthetic gene cluster.

The biosynthesis of complex reduced polyketides is catalysed in actinomycetes by large multifunctional enzymes, the modular Type I polyketide synthases (PKSs). Most of our current knowledge of such systems stems from the study of a restricted number of macrolide-synthesising enzymes. The sequencing of the genes for the biosynthesis of monensin A, a typical polyether ionophore polyketide, provided the first genetic evidence for the mechanism of oxidative cyclisation through which polyethers such as monensin are formed from the uncyclised products of the PKS. Two intriguing genes associated with the monensin PKS cluster code for proteins, which show strong homology with enzymes that trigger double bond migrations in steroid biosynthesis by generation of an extended enolate of an unsaturated ketone residue. A similar mechanism operating at the stage of an enoyl ester intermediate during chain extension on a PKS could allow isomerisation of an E double bond to the Z isomer. This process, together with epoxidations and cyclisations, form the basis of a revised proposal for monensin formation. The monensin PKS has also provided fresh insight into general features of catalysis by modular PKSs, in particular into the mechanism of chain initiation.

Crystallization and preliminary X-ray diffraction studies of a monooxygenase from Streptomyces coelicolor A3(2) involved in the biosynthesis of the polyketide actinorhodin.

The aromatic monooxygenase ActVA-Orf6 from Streptomyces coelicolor A3(2) that catalyses an unusual oxidation on the actinorhodin biosynthetic pathway has been crystallized. The crystals diffract to 1.73 A and belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 46.95, b = 59.29, c = 71.67 A. Solvent-content (44%) and self-rotation function calculations predict the presence of two molecules in the asymmetric unit. Structure determination should provide further insight into the enzyme mechanism and aid in the design of biosynthetic pathways to produce new polyketide natural products with novel functionality.

Two distinct nucleosome alterations characterize chromatin remodeling at the Saccharomyces cerevisiae ADH2 promoter.

Glucose depletion derepresses the Saccharomyces cerevisiae ADH2 gene; this metabolic change is accompanied by chromatin structural modifications in the promoter region. We show that the ADR6/SWI1 gene is not necessary for derepression of the wild type chromosomal ADH2, whereas the transcription factor Adr1p, which regulates several S. cerevisiae functions, plays a major role in driving nucleosome reconfiguration and ADH2 expression. When we tested the effect of individual domains of the regulatory protein Adr1p on the chromatin structure of ADH2, a remodeling consisting of at least two steps was observed. Adr1p derivatives were analyzed in derepressing conditions, showing that the Adr1p DNA binding domain alone causes an alteration in chromatin organization in the absence of transcription. This alteration differs from the remodeling observed in the presence of the Adr1p activation domain when the promoter is transcriptionally active.

Modulation of polyketide synthase activity by accessory proteins during lovastatin biosynthesis.

Polyketides, the ubiquitous products of secondary metabolism in microorganisms, are made by a process resembling fatty acid biosynthesis that allows the suppression of reduction or dehydration reactions at specific biosynthetic steps, giving rise to a wide range of often medically useful products. The lovastatin biosynthesis cluster contains two type I polyketide synthase genes. Synthesis of the main nonaketide-derived skeleton was found to require the previously known iterative lovastatin nonaketide synthase (LNKS), plus at least one additional protein (LovC) that interacts with LNKS and is necessary for the correct processing of the growing polyketide chain and production of dihydromonacolin L. The noniterative lovastatin diketide synthase (LDKS) enzyme specifies formation of 2-methylbutyrate and interacts closely with an additional transesterase (LovD) responsible for assembling lovastatin from this polyketide and monacolin J.

DnrD cyclase involved in the biosynthesis of doxorubicin: purification and characterization of the recombinant enzyme.

Mutations in the Streptomyces peucetius dnrD gene block the ring cyclization leading from aklanonic acid methyl ester (AAME) to aklaviketone (AK), an intermediate in the biosynthetic pathway to daunorubicin (DNR) and doxorubicin. To investigate the role of DnrD in this transformation, its gene was overexpressed in Escherichia coli and the DnrD protein was purified to homogeneity and characterized. The enzyme was shown to catalyze the conversion of AAME to AK presumably via an intramolecular aldol condensation mechanism. In contrast to the analogous intramolecular aldol cyclization catalyzed by the TcmI protein from the tetracenomycin (TCM) C pathway in Streptomyces glaucescens, where a tricyclic anthraquinol carboxylic acid is converted to its fully aromatic tetracyclic form, the conversion catalyzed by DnrD occurs after anthraquinone formation and requires activation of a carboxylic acid group by esterification of aklanonic acid, the AAME precursor. Also, the cyclization is not coupled with a subsequent dehydration step that would result in an aromatic ring. As the substrates for the DnrD and TcmI enzymes are among the earliest isolable intermediates of aromatic polyketide biosynthesis, an understanding of the mechanism and active site topology of these proteins will allow one to determine the substrate and mechanistic parameters that are important for aromatic ring formation. In the future, these parameters may be able to be applied to some of the earlier polyketide cyclization processes that currently are difficult to study in vitro.

Identification of a monooxygenase from Streptomyces coelicolor A3(2) involved in biosynthesis of actinorhodin: purification and characterization of the recombinant enzyme.

The oxidation of phenols to quinones is an important reaction in the oxidative tailoring of many aromatic polyketides from bacterial and fungal systems. Sequence similarity between ActVA-Orf6 protein from the actinorhodin biosynthetic cluster and the previously characterized TcmH protein that is involved in tetracenomycin biosynthesis suggested that ActVA-Orf6 might catalyze this transformation as a step in actinorhodin biosynthesis. To investigate the role of ActVA-Orf6 in this oxidation, we have expressed the actVA-Orf6 gene in Escherichia coli and purified and characterized the recombinant protein. ActVA-Orf6 was shown to catalyze the monooxygenation of the tetracenomycin intermediate TcmF1 to TcmD3, strongly suggesting that it catalyzes oxidation of a similar intermediate in actinorhodin biosynthesis. The monooxygenase obeys simple reaction kinetics and has a Km of 4.8 +/- 0.9 microM, close to the figure reported for the homologous enzyme TcmH. The enzyme contains no prosthetic groups and requires only molecular oxygen to catalyze the oxidation. Site-directed mutagenesis was used to investigate the role of histidine residues thought to be important in the reaction; mutants lacking His-52 displayed much-reduced activity, consistent with the proposed mechanistic hypothesis that this histidine acts as a general base during catalysis.

Identification of a flavin:NADH oxidoreductase involved in the biosynthesis of actinorhodin. Purification and characterization of the recombinant enzyme.

The biosynthesis of the polyketide antibiotic actinorhodin by Streptomyces coelicolor involves the oxidative dimerization and hydroxylation of a precursor, most likely dihydrokalafungin, as the final steps in its formation. Mutations in the actVB gene block these last steps, and the mutants secrete kalafungin as a shunt product. To investigate the role of the actVB gene in these transformation, we have overexpressed the gene in Escherichia coli and purified and characterized the recombinant protein. ActVB was shown to catalyze the reduction of FMN by NADH to give NAD and FMNH2, which, unusually, is released into solution. The protein contains no chromogenic cofactors and exhibits no requirements for added metal ions. The reaction obeys simple kinetics and proceeds through the formation of a ternary complex; Km values for FMN and NADH are 1.5 and 7.3 microM, respectively, and kcat is about 5 s-1. FAD and riboflavin are also substrates for the enzyme, although they have much higher Km values. The subunit structure of the enzyme was investigated by analytical ultracentrifugation, which showed the protein to exist in rapid equilibrium between monomer and dimer forms. The possible role of this oxidoreductase in the oxidative chemistry of actinorhodin biosynthesis is discussed.