Iterative type II polyketide synthases, cyclases and ketoreductases exhibit context-dependent behavior in the biosynthesis of linear and angular decapolyketides.

BACKGROUND: Iterative type II polyketide synthases (PKSs) produce polyketide chains of variable but defined length from a specific starter unit and a number of extender units. They also specify the initial regiospecific folding and cyclization pattern of nascent polyketides either through the action of a cyclase (CYC) subunit or through the combined action of site-specific ketoreductase (KR) and CYC subunits. Additional CYCs and other modifications may be necessary to produce linear aromatic polyketides. The principles of the assembly of the linear aromatic polyketides, several of which are medically important, are well understood, but it is not clear whether the assembly of the angular aromatic (angucyclic) polyketides follows the same rules. RESULTS: We performed an in vivo evaluation of the subunits of the PKS responsible for the production of the angucyclic polyketide jadomycin (jad), in comparison with their counterparts from the daunorubicin (dps) and tetracenomycin (tcm) PKSs which produce linear aromatic polyketides. No matter which minimal PKS was used to produce the initial polyketide chain, the JadD and DpsF CYCs produced the same two polyketides, in the same ratio; neither product was angularly fused. The set of jadABCED PKS plus putative jadl CYC genes behaved similarly. Furthermore, no angular polyketides were isolated when the entire set of jad PKS enzymes and Jadl or the jad minimal PKS, Jadl and the TcmN CYC were present. The DpsE KR was able to reduce decaketides but not octaketides; in contrast, the KRs from the jad PKS (JadE) or the actinorhodin PKS (ActIII) could reduce octaketide chains, giving three distinct products. CONCLUSIONS: It appears that the biosynthesis of angucyclic polyketides cannot be simply accomplished by expressing the known PKS subunits from artificial gene cassettes under the control of a non-native promoter. The characteristic structure of the angucycline ring system may arise from a kinked precursor during later cyclization reactions involving additional, but so far unknown, components of the extended decaketide PKS. Our results also suggest that some KRs have a minimal chain length requirement and that CYC enzymes may act aberrantly as first-ring aromatases that are unable to perform all of the sequential cyclization steps. Both of these characteristics may limit the widespread application of CYC or KR enzymes in the synthesis of novel polyketides.

Novel natural products from soil DNA libraries in a streptomycete host.

As a route to accessing the potential chemical diversity of uncultivable microbes from the soil, combinatorial biosynthetic libraries were constructed by cloning large fragments of DNA isolated from soil into a Streptomyces lividans host. Four novel compounds, terragines A (1), B (2), C (3), and D (4), were isolated from recombinant 436-s4-5b1, and another novel compound, terragine E (5), was isolated from 446-s3-102g1. The structures were determined by a combination of spectroscopic techniques, primarily 2D NMR.

Functional analysis of putative beta-ketoacyl:acyl carrier protein synthase and acyltransferase active site motifs in a type II polyketide synthase of Streptomyces glaucescens.

The significance of potential active site motifs for acyltransferase and beta-ketoacyl:acyl carrier protein synthase regions within the TcmK protein was investigated by determining the effects of mutations in the proposed active sites on the production of tetracenomycins F2 and C. In a Streptomyces glaucescens tcmGHI JKLMNO null mutant, plasmids carrying the S351A mutation produced high amounts of tetracenomycin F2 but plasmids carrying the C173A or C173S mutation or the H350L-S351A double mutation produced no detectable amount of any known intermediate. In a tcmK mutant, plasmids with the S351A mutation restored high production of tetracenomycin C and plasmids carrying the other mutations were able to complement the chromosomal defect to some extent. None of the mutations affected the amount of TcmK produced.

Heterologous expression and biochemical characterization of two functionally different type I fatty acid synthases from Brevibacterium ammoniagenes.

The coryneform bacterium, Brevibacterium ammoniagenes, contains two structurally related but functionally differentiated type I fatty acid synthases, FAS-A and FAS-B. Isolation of homogeneous preparations of both enzymes was achieved by constructing specific fasA and fasB expression systems. In B. ammoniagenes, insertional mutagenesis of fasB allowed the specific production of enzymatically active FAS-A. The corresponding fasA mutant was not suited for FAS-B purification as the level of this enzyme was extremely low, in the fasA-disruptants. Instead, FAS-B could be efficiently expressed in the heterologous host, Escherichia coli. Using specific antisera against each of the two FAS variants, FAS-A was shown to be the predominant FAS protein in B. ammoniagenes. In contrast the two enzymes are expressed at comparable rates in E. coli even though the same upstream sequences were associated with fasA and fasB, as in B. ammoniagenes. Due to their differential capacities of being activated to the phosphopantetheine-containing holo-enzyme in the heterologous host, only FAS-B but not FAS-A exhibited overall FAS activity when isolated from E. coli. Irrespective of their origin, the purified FAS-A and FAS-B proteins were indistinguishable with respect to their flavin fluorescence, their subunit size and their sucrose density gradient sedimentation characteristics. Nevertheless, the in vitro products of both enzymes differ characteristically: while FAS-A synthesizes mainly the 18-carbon fatty acids oleate and stearate with only traces of palmitate, the major product of FAS-B is palmitic acid. No unsaturated fatty acids are produced by FAS-B. Thus, the two B ammoniogenes type I fatty acid synthases differ, in spite of their very similar overall protein structure, in both their ability to synthesize oleic acid and in their chain-length specificities.

Molecular structure of the multifunctional fatty acid synthetase gene of Brevibacterium ammoniagenes: its sequence of catalytic domains is formally consistent with a head-to-tail fusion of the two yeast genes FAS1 and FAS2.

The Brevibacterium ammoniagenes fatty acid synthetase (FAS) gene was isolated from a series of overlapping clones by both immunological and plaque hybridization screening of two independent gene libraries. From the isolated DNA a contiguous segment of 10,549 bp was sequenced in both directions. The sequenced DNA contained a very long (9312 nucleotides) open reading frame coding for a protein of 3104 amino acids and with a molecular mass of 327,466 daltons. Based on characteristic sequence motifs known from other FAS systems, seven different FAS active centres were identified at distinct locations within the polypeptide chain. Only one component enzyme, the 3-hydroxydecanoyl beta, gamma-dehydratase, has not yet been localized definitively within the gene. Translation is presumed to start from a GUG triplet located 25 nucleotides downstream of the transcriptional initiation site. There is a canonical Shine-Dalgarno sequence just before this start codon. Comparison of the B. ammoniagenes FAS sequence with those of other known fatty acid synthetases revealed a particularly high degree of similarity to the products of the two yeast genes, FAS1 and FAS2 (30% identical and 46% identical plus closely related amino acids). This similarity extends over the entire length of the genes and involves not only the primary sequences of individual component enzymes but also their sequential order within the multifunctional proteins. These data, together with those on the structure of other fatty acid synthetases, are interpreted in terms of a contribution of both primary structure and subunit cooperation to a conserved topology of functional domains common to all type I FAS complexes.

A study of iterative type II polyketide synthases, using bacterial genes cloned from soil DNA: a means to access and use genes from uncultured microorganisms.

To examine as randomly as possible the role of the beta-ketoacyl and acyl carrier protein (ACP) components of bacterial type II polyketide synthases (PKSs), homologs of the chain-length-factor (CLF) genes were cloned from the environmental community of microorganisms. With PCR primers derived from conserved regions of known ketosynthase (KSalpha) and ACP genes specifying the formation of 16- to 24-carbon polyketides, two CLF (KSbeta) genes were cloned from unclassified streptomycetes isolated from the soil, and two were cloned from soil DNA without the prior isolation of the parent microorganism. The sequence and deduced product of each gene were distinct from those of known KSbeta genes and, by phylogenetic analysis, belonged to antibiotic-producing PKS gene clusters. Hybrid PKS gene cassettes were constructed with each novel KSbeta gene substituted for the actI-ORF2 or tcmL KSbeta subunit genes, along with the respective actI-ORF1 or tcmK KSalpha, tcmM ACP, and tcmN cyclase genes, and were found to produce an octaketide or decaketide product characteristic of the ones known to be made by the heterologous KSalpha gene partner. Since substantially less than 1% of the microorganisms present in soil are thought to be cultivatable by standard methods, this work demonstrates a potential way to gain access to a more extensive range of microbial molecular diversity and to biosynthetic pathways whose products can be tested for biological applications.