Biosynthesis of anthraquinones by interspecies cloning of actinorhodin biosynthesis genes in streptomycetes: clarification of actinorhodin gene functions.

Streptomyces galilaeus ATCC 31133 and ATCC 31671, producers of the anthracyclines aclacinomycin A and 2-hydroxyaklavinone, respectively, formed an anthraquinone, aloesaponarin II, when they were transformed with DNA from Streptomyces coelicolor containing four genetic loci, actI, actIII, actIV, and actVII, encoding early reactions in the actinorhodin biosynthesis pathway. Subcloning experiments indicated that a 2.8-kilobase-pair XhoI fragment containing only the actI and actVII loci was necessary for aloesaponarin II biosynthesis by S. galilaeus ATCC 31133. Aloesaponarin II was synthesized via the condensation of 8 acetyl coenzyme A equivalents, followed by a decarboxylation reaction as demonstrated by [1,2-13C2]acetate feeding experiments. S. coelicolor B22 and B159, actVI blocked mutants, also formed aloesaponarin II as an apparent shunt product. Mutants of S. coelicolor blocked in several other steps in actinorhodin biosynthesis did not synthesize aloesaponarin II or other detectable anthraquinones. When S. galilaeus ATCC 31671 was transformed with the DNA carrying the actI, actIII, and actVII loci, the recombinant strain produced both aloesaponarin II and aklavinone, suggesting that the actinorhodin biosynthesis DNA encoded a function able to deoxygenate 2-hydroxyaklavinone to aklavinone. When S. galilaeus ATCC 31671 was transformed with a plasmid carrying only the intact actIII gene (pANT45), aklavinone was formed exclusively. These experiments indicate a function for the actIII gene, which is the reduction of the keto group at C-9 from the carboxy terminus of the assembled polyketide to the corresponding secondary alcohol. In the presence of the actIII gene, anthraquinones or anthracyclines formed as a result of dehydration and aromatization lack an oxygen function on the carbon on which the keto reductase operated. When S. galilaeus ATCC 31671 was transformed with the DNA carrying the actI, actVII, and actIV loci, the recombinant strain produced two novel anthraquinones, desoxyerythrolaccin, the 3-hydroxy analog of aloesaponarin II, and 1-O-methyldesoxyerythrolaccin. The results obtained in these experiments together with earlier data suggest a pathway for the biosynthesis of actinorhodin and related compounds by S. coelicolor.     

Significance of anthraquinone formation resulting from the cloning of actinorhodin genes in heterologous streptomycetes

This review explores the underlying biochemical and genetic principles leading to the formation of hybrid anthraquinones by recombinant anthracycline-producing streptomycetes transformed with genes encoding the early steps in actinorhodin biosynthesis. Experiments indicate that simple aromatic polyketides are probably synthesized using very similar mechanisms, allowing for the interspecies cloning of polyketide synthase genes for the potential production of novel aromatic polyketide structures.     

A gene cluster involved in nogalamycin biosynthesis fromStreptomyces nogalater: sequence analysis and complementation of early-block mutations in the anthracycline pathway

We have analyzed an anthracycline biosynthesis gene cluster fromStreptomyces nogalater. Based on sequence analysis, a contiguous region of 11 kb is deduced to include genes for the early steps in anthracycline biosynthesis, a regulatory gene (snoA) promoting the expression of the biosynthetic genes, and at least one gene whose product might have a role in modification of the glycoside moiety. The three ORFs encoding a minimal polyketide synthase (PKS) are separated from the regulatory gene (snoA) by a comparatively AT-rich region (GC content 60%). Subfragments of the DNA region were transferred toStreptomyces galilaeus mutants blocked in aclacinomycin biosynthesis, and to a regulatory mutant ofS. nogalater. TheS. galilaeus mutants carrying theS. nogalater minimal PKS genes produced auramycinone glycosides, demonstrating replacement of the starter unit for polyketide biosynthesis. The product ofsnoA seems to be needed for expression of at least the genes for the minimal PKS.     

Heterologous expression of the naphthocyclinone hydroxylase gene from Streptomyces arenae for production of novel hybrid polyketides

Streptomyces arenae produces at least four different isochromanequinone antibiotics, the naphthocyclinones, of which the - and -form are active against Gram-positive bacteria. The naphthocyclinone biosynthesis gene cluster was isolated from Streptomyces arenae DSM 40737 and by sequence analysis the minimal polyketide synthase genes and several genes encoding tailoring enzymes were identified. Southern blot analysis of the naphthocyclinone gene cluster indicated that a 3.5 kb BamHI fragment located approximately 9 kb downstream of the minimal PKS genes hybridizes to the schC hydroxylase DNA probe isolated from S. halstedii. Two complete and one incomplete open reading frames were identified on this fragment. Sequence analysis revealed strong homology to the genes of the actVA region of S. coelicolor, to several (suggested) hydroxylases and a putative FMN-dependent monooxygenase. The proposed hydroxylase, encoded by ncnH, could hydroxylate aloesaponarin II, a molecule that is produced by the actinorhodin minimal polyketide synthase in combination with the actinorhodin ketoreductase, aromatase and cyclase. Furthermore, this enzyme is capable of accepting additional polyketide core structures that contain a 5-hydroxy-1,4-naphthoquinone moiety as substrates which makes it an interesting tailoring enzyme for the modification of polyketide structures.     

A gene cluster involved in nogalamycin biosynthesis fromStreptomyces nogalater: sequence analysis and complementation of early-block mutations in the anthracycline pathway

We have analyzed an anthracycline biosynthesis gene cluster fromStreptomyces nogalater. Based on sequence analysis, a contiguous region of 11 kb is deduced to include genes for the early steps in anthracycline biosynthesis, a regulatory gene (snoA) promoting the expression of the biosynthetic genes, and at least one gene whose product might have a role in modification of the glycoside moiety. The three ORFs encoding a minimal polyketide synthase (PKS) are separated from the regulatory gene (snoA) by a comparatively AT-rich region (GC content 60%). Subfragments of the DNA region were transferred toStreptomyces galilaeus mutants blocked in aclacinomycin biosynthesis, and to a regulatory mutant ofS. nogalater. TheS. galilaeus mutants carrying theS. nogalater minimal PKS genes produced auramycinone glycosides, demonstrating replacement of the starter unit for polyketide biosynthesis. The product ofsnoA seems to be needed for expression of at least the genes for the minimal PKS.     

Minimal polyketide pathway expression in an actinorhodin cluster-deleted and regulation-stimulated <Emphasis Type="Italic">Streptomyces coelicolor</Emphasis>

Along with traditional random mutagenesis-driven strain improvement, cloning and heterologous expression of Streptomyces secondary metabolite gene clusters have become an attractive complementary approach to increase its production titer, of which regulation is typically under tight control via complex multiple regulatory networks present in a metabolite low-producing wild-type strain. In this study, we generated a polyketide non-producing strain by deleting the entire actinorhodin cluster from the chromosome of a previously generated S. coelicolor mutant strain, which was shown to stimulate actinorhodin biosynthesis through deletion of two antibiotic downregulators as well as a polyketide precursor flux downregulator (Kim et al. in Appl Environ Microbiol 77:1872–1877, 2011). Using this engineered S. coelicolor mutant strain as a surrogate host, a model minimal polyketide pathway for aloesaponarin II, an actinorhodin shunt product, was cloned in a high-copy conjugative plasmid, followed by functional pathway expression and quantitative metabolite analysis. Aloesaponarin II production was detected only in the presence of a pathway-specific regulatory gene, actII-ORF4, and its production level was the highest in the actinorhodin cluster-deleted and downregulator-deleted mutant strain, implying that this engineered polyketide pathway-free and regulation-optimized S. coelicolor mutant strain could be used as a general surrogate host for efficient expression of indigenous or foreign polyketide pathways derived from diverse actinomycetes in nature.     

Evidence from proteomics that some of the enzymes of actinorhodin biosynthesis have more than one form and may occupy distinctive cellular locations

An important attribute of proteome analysis carried out with the aid of two-dimensional gel electrophoresis is that post-translational modifications of proteins can often be revealed. Large-scale proteomic analysis of Streptomyces coelicolor A3(2) has been made possible with the availability of its genome sequence. Here, we bring together observations on the proteins specifically associated with biosynthesis of the isochromanequinone polyketide antibiotic actinorhodin. The predicted products of 14 of the genes annotated as belonging to the act gene cluster were detected. They were generally present only in stationary phase cultures. Plausible explanations are presented for the absence of the other nine. For six of the gene products detected, there was evidence of either specific processing or covalent modification; in the case of the pyran ring closure enzyme ActVI-ORF3, the cleavage of the N-terminal 31 or 34 amino acids was previously shown to be associated with an extracytoplasmic location for the mature gene product [Hesketh A, et al. (2002) Mol Microbiol 46:917–932]. These observations may have implications for the regulation of actinorhodin biosynthesis, and for biochemical studies of artificially expressed Act proteins.     

Functional replacement of genes for individual polyketide synthase components in Streptomyces coelicolor A3(2) by heterologous genes from a different polyketide pathway.

Streptomyces coelicolor A3(2) and Streptomyces violaceoruber Tü22 produce the antibiotics actinorhodin and granaticin, respectively. Both the aglycone of granaticin and the half-molecule of actinorhodin are derived from one acetyl coenzyme A starter unit and seven malonyl coenzyme A extender units via the polyketide pathway to produce benzoisochromane quinone moieties with identical structures (except for the stereochemistry at two chiral centers). In S. coelicolor and S. violaceoruber, the type II polyketide synthase (PKS) is encoded by clusters of five and six genes, respectively. We complemented a series of S. coelicolor mutants (act) defective in different components of the PKS (actI for carbon chain assembly, actIII for ketoreduction, and actVII for cyclization-dehydration) by the corresponding genes (gra) from S. violaceoruber introduced in trans on low-copy-number plasmids. This procedure showed that four of the act PKS components could be replaced by a heterologous gra protein to give a functional PKS. The analysis also served to identify which of three candidate open reading frames (ORFs) in the actI region had been altered in each of a set of 13 actI mutants. It also proved that actI-ORF2 (whose putative protein product shows overall similarity to the beta-ketoacyl synthase encoded by actI-ORF1 but whose function is unclear) is essential for PKS function. Mutations in each of the four complemented act genes (actI-ORF1, actI-ORF2, actIII, and actVII) were cloned and sequenced, revealing a nonsense or frameshift mutation in each mutant.     

Nucleotide sequence and deduced functions of a set of cotranscribed genes of Streptomyces coelicolor A3(2) including the polyketide synthase for the antibiotic actinorhodin.

A 5.3-kb region of the Streptomyces coelicolor actinorhodin gene cluster, including the genes for polyketide biosynthesis, was sequenced. Six identified open reading frames (ORF1-6) were related to genetically characterized mutations of classes actI, VII, IV, and VB by complementation analysis. ORF1-6 run divergently from the adjacent actIII gene, which encodes the polyketide synthase (PKS) ketoreductase, and appear to form an operon. The deduced gene products of ORF1-3 are similar to fatty acid synthases (FAS) of different organisms and PKS genes from other polyketide producers. The predicted ORF5 gene product is similar to type II beta-lactamases of Bacillus cereus and Bacteroides fragilis. The ORF6 product does not resemble other known proteins. Combining the genetical, biochemical, and similarity data, the potential activities of the products of the six genes can be postulated as: 1) condensing enzyme/acyl transferase (ORF1 + ORF2); 2) acyl carrier protein (ORF3); 3) putative cyclase/dehydrase (ORF4); 4) dehydrase (ORF5); and 5) "dimerase" (ORF6). The data show that the actinorhodin PKS consists of discrete monofunctional components, like that of the Escherichia coli (Type II) FAS, rather than the multifunctional polypeptides for the macrolide PKSs and vertebrate FASs (Type I).     

产生变活霉素的变株的分离与初步鉴别

对天然无抗菌活性的链霉菌1254菌株进行诱变．获导了二株有抗菌活性的变株。变株113产生的抗生素为一组新蒽环类化合物．有抗病毒活性,定名为变活霉素。变株2—6产生碱性永溶性物质。初步实验结果表明,原株1254及变株2-6均是胞壁类型1,为链霉菌属。变株113为胞壁类型Ⅳ,不含有枝菌酸。原株1254与变株113的阻断变株共合成的产物与变活霉素相局,以放线紫红素聚酮合成酶基因act1为探针与原株1254的总DNA进行Southern杂交为阳性。根据这二个实验的结果推断,在1254菌株中可能存在一条变活霉素的合成途径,但有的基因处于未表达状态,诱发突变使其被活化。     

Biosynthesis of Polyketide Antibiotics by Various StreptomycesSpecies that Produce Actinomycins

A collection of actinomycin-producing Streptomycesstrains, their variants with different levels of antibiotic biosynthesis, and recombinant strains were screened in order to select new strains that produce polyketide antibiotics. Screening with the use of the cloned actgene encoding a component of actinorhodin polyketide synthase (PKS) multienzyme complex from Streptomyces coelicolorrevealed that many strains tested can synthesize polyketide antibiotics along with actinomycins. A relationship between the biosynthetic pathways of actinomycins and polyketides is discussed.     

High-yield actinorhodin production in fed-batch culture by a Streptomyces lividans strain overexpressing the pathway-specific activator gene actll-ORF4

Streptomyces lividans 1326 usually does not produce the red/blue colored polyketide actinorhodin in liquid culture even though it carries the entire actinorhodin biosynthesis gene cluster. The bacterium can be forced to produce this secondary metabolite by introducing actII-ORF4, the actinorhodin pathway-specific activator gene from Streptomyces coelicolor, on a multicopy plasmid. The production of actinorhodin by such a strain has been optimized by medium and process manipulations in fed-batch cultures. With high-yield cultivation conditions, 5 g actinorhodin/l are produced during 7 days of cultivation; or approximately 0.1 g actinorhodin/g dry weight (DW)/day in the production phase. The yield in this phase is 0.15 Cmol actinorhodin/Cmol glucose, which is in the range of 25% to 40% of the maximum theoretical yield. This high-level production mineral medium is phosphate limited. In contrast, nitrogen limitation resulted in low-level production of actinorhodin and high production of α-ketoglutaric acid. Ammonium as nitrogen source was superior to nitrate supporting an almost three times higher actinorhodin yield as well as a two times higher specific production rate. The wild-type strain lacking the multicopy plasmid did not produce actinorhodin when cultivated under any of these conditions. This work examines the actinorhodin-producing potential of the strain, as well as the necessity to improve the culture conditions to fully utilize this potential. The overexpression of biosynthetic pathway-specific activator genes seems to be a rational first step in the design of secondary metabolite overproducing strains prior to alteration of primary metabolic pathways for redirection of metabolic fluxes. Journal of Industrial Microbiology & Biotechnology (2002) 28, 103–111 DOI: 10.1038/sj/jim/7000219 Received 04 April 2001/ Accepted in revised form 30 October 2001     

Increasing the efficiency of heterologous promoters in actinomycetes

An Escherichia coli-actinomycete shuttle vector, pCJW93, was constructed which places cloned genes under the control of the thiostrepton-inducible tip promoter from Streptomyces lividans. We also constructed expression vectors bearing the actII-ORF4/PactI activator-promoter system of the actinorhodin biosynthetic pathway of Streptomyces coelicolor. With both types of vector, levels of expression varied widely in different actinomycete strains, indicating different levels of the host factors needed for optimal expression. Deletion of the actII-ORF4 activator gene from one such plasmid in Saccharopolyspora erythraea drastically reduced expression from the cognate actI promoter, showing that host factors are required for optimal production of the activator protein itself. However, a low copy number expression vector pWIZ1 for the polyketide synthase DEBS1-TE, in which the promoter for the activator gene was replaced by the strong heterologous ermE* promoter of S. erythraea directed highly efficient production of polyketide synthase protein in Streptomyces cinnamonensis; and the levels of triketide lactone product found were up to 100-fold greater than were produced by the same plasmid in which actII-ORF4 was expressed from its own promoter. Ensuring appropriate expression of a specific activator protein should enable more convenient and consistent heterologous expression of genes in a broad range of actinomycete hosts.     

A two-vector system for the production of recombinant polyketides in Streptomyces

A two-vector system was developed for heterologous expression of the three genes comprising the 6-deoxyerythronolide B synthase (DEBS) polyketide gene cluster. Individual DEBS genes and pairwise combinations of two such genes were each cloned downstream of the actinorhodin (actI) promoter in two compatible Streptomyces vectors: the autonomously replicating vector, pKAO127′Kan′, and the integrating vector, pSET152. The resulting plasmids were either simultaneously or sequentially transformed into Streptomyces lividans K4-114. Efficient trans-complementation of modular polyketide synthase subunit proteins occurred when the respective genes were transcribed from the two vectors and resulted in production of the erythromycin precursor 6-deoxyerythronolide B (6-dEB). Journal of Industrial Microbiology & Biotechnology (2000) 24, 46–50. Received 17 March 1999/ Accepted in revised form 15 September 1999     

Characterisation of actI-homologous DNA encoding polyketide synthase genes from the monensin producer Streptomyces cinnamonensis

Summary Cloned DNA encoding polyketide synthase (PKS) genes from one Streptomyces species was previously shown to serve as a useful hybridisation probe for the isolation of other PKS gene clusters from the same or different species. In this work, the actI and actIII genes, encoding components of the actinorhodin PKS of Streptomyces coelicolor, were used to identify and clone a region of homologous DNA from the monensin-producing organism S. cinnamonensis. A 4799 by fragment containing the S. cinnamonensis act-homologous DNA was sequenced. Five open reading frames (ORFs 1–5) were identified on one strand of this DNA. The five ORFs show high sequence similarities to ORFs that were previously identified in the granaticin, actinorhodin, tetracenomycin and whiE PKS gene clusters. This allowed the assignment of the following putative functions to these five ORFS : a heterodimeric -ketoacyl synthase (ORF1 and ORF2), an acyl carrier protein (ORF3), a -ketoacyl reductase (ORF5), and a bifunctional cyclase/dehydrase (ORF4). The ORFs are encoded in the order ORFl-ORF2-ORF3-ORF5-ORF4, and ORFs-1 and -2 show evidence for translational coupling. This act-homologous region therefore appears to encode a PKS gene cluster. A gene disruption experiment using the vector pGM 160, and other evidence, suggests that this cluster is not essential for monensin biosynthesis but rather is involved in the biosynthesis of a cryptic aromatic polyketide in S. cinnamonensis. An efficient plasmid transformation system for S. cinnamonensis has been established, using the multicopy plasmids pWOR120 and pWOR125.     

Saccharopolyspora hirsuta 367 encodes clustered genes similar to ketoacyl synthase, ketoacyl reductase, acyl carrier protein, and biotin carboxyl carrier protein

The actI gene, encoding a component of the actinorhodin polyketide synthase of Streptomyces coelicolor, was used to identify and clone a homologous 11.7 kb BamHI DNA fragment from Saccharopolyspora hirsuta 367. The cloned fragment complemented actinorhodin production in a strain of Streptomyces coelicolor bearing a mutant actI gene. The DNA sequence of a 5.1 kb fragment revealed 6 open reading frames (ORF). ORF1 does not resemble any known DNA or deduced protein sequence, while the deduced protein sequence of ORF2 resembles that of biotin carboxyl carrier proteins. Based on the similarity to deduced protein sequences from cloned genes of polyketide producers, ORF3 would code for a ketoreductase, ORF4 and ORF5 for the putative heterodimeric -ketoacyl synthase, and ORF6 for an acyl carrier protein.     

Organisation and functions of the actV A region of the actinorhodin biosynthetic gene cluster of Streptomyces coelicolor

Summary Sequence analysis of the actVA region of the actinorhodin biosynthetic gene cluster of Streptomyces coelicolor revealed a succession of six open reading frames (ORFs), all running in the same direction and extending over 5.32 kb. The protein product of actVA-ORF1 strongly resembles that of another gene, elsewhere in the act cluster (actII-ORF2), which codes for a trans-membrane protein previously implicated in actinorhodin export from the mycelium. This suggests that the two gene products may co-operate in actinorhodin export, perhaps being sufficient for self-protection of the organism against suicide. At least four of the other five ORFs are implicated in the control of the C-6 and C-8 ring-hydroxylation reactions, lacking in actVA mutants, that occur at middle to late stages in the actinorhodin biosynthetic pathway. This conclusion was reached by genetic mapping of actVA mutants to actVA-ORF3 and-ORF5 (and perhaps -ORF4), and by the finding of strong resemblances between the protein products of actVA-ORF2 and -ORF6 and the products of genes of the oxytetracycline or tetracenomycin gene clusters that have been implicated in ring-hydroxylation reactions in the biosynthesis of these other aromatic polyketide antibiotics.     

Isolation and sequence analysis of polyketide synthase genes from the daunomycin-producing Streptomyces sp. strain C5.

A contiguous region of about 30 kbp of DNA putatively encoding reactions in daunomycin biosynthesis was isolated from Streptomyces sp. strain C5 DNA. The DNA sequence of an 8.1-kbp EcoRI fragment, which hybridized with actI polyketide synthase (PKS) and actIII polyketide reductase (PKR) gene probes, was determined, revealing seven complete open reading frames (ORFs), two in one cluster and five in a divergently transcribed cluster. The former two genes are likely to encode PKR and a bifunctional cyclase/dehydrase. The five latter genes encode: (i) a homolog of TcmH, an oxygenase of the tetracenomycin biosynthesis pathway; (ii) a PKS Orf1 homolog; (iii) a PKS Orf2 homolog (chain length factor); (iv) a product having moderate sequence identity with Escherichia coli beta-ketoacyl acyl carrier protein synthase III but lacking the conserved active site; and (v) a protein highly similar to several acyltransferases. The DNA within the 8.1-kbp EcoRI fragment restored daunomycin production to two dauA non-daunomycin-producing mutants of Streptomyces sp. strain C5 and restored wild-type antibiotic production to Streptomyces coelicolor B40 (act VII; nonfunctional cyclase/dehydrase), and to S. coelicolor B41 (actIII) and Streptomyces galilaeus ATCC 31671, strains defective in PKR activity.     

Clusters of genes for the biosynthesis of antibiotics: Regulatory genes and overproduction of pharmaceuticals

Summary In the last decade numerous genes involved in the biosynthesis of antibiotics, pigments, herbicides and other secondary metabolites have been cloned. The genes involved in the biosynthesis of penicillin, cephalosporin and cephamycins are organized in clusters as occurs also with the biosynthetic genes of other antibiotics and secondary metabolites (see review by Martín and Liras [65]). We have cloned genes involved in the biosynthesis of -lactam antibiotics from five different -lactam producing organisms both eucaryotic (Penicillium chrysogenum, Cephalosporium acremonium (syn.Acremonium chrysogenum) Aspergillus nidulans) and procaryotic (Nocardia lactamdurans, Streptomyces clavuligerus). InP. chrysogenum andA. nidulans the organization of thepcbAB,pcbC andpenDE genes for ACV synthetase, IPN synthase and IPN acyltransferase showed a similar arrangement. InA. chrysogenum two different clusters of genes have been cloned. The cluster of early genes encodes ACV synthetase and IPN synthase, whereas the cluster of late genes encodes deacetoxycephalosporin C synthetase/hydroxylase and deacetylcephalosporin C acetyltransferase. InN. lactamdurans andS. clavuligerus a cluster of early cephamycin genes has been fully characterized. It includes thelat (for lysine-6-aminotransferase),pcbAB (for ACV synthase) andpcbC (for IPN synthase) genes. Pathway-specific regulatory genes which act in a positive (or negative) form are associated with clusters of genes involved in antibiotic biosynthesis. In addition, widely acting positive regulatory elements exert a pleiotropic control on secondary metabolism and differentiation of antibiotic producing microorganisms.The application of recombinant DNA techniques will contribute significantly to the improvement of fermentation organisms.