Genetic analysis of polyketide synthase and peptide synthetase genes in cyanobacteria as a mining tool for secondary metabolites

Molecular screening using degenerate PCR to determine the presence of secondary metabolite genes in cyanobacteria was performed. This revealed 18 NRPS and 19 PKS genes in the 21 new cyanobacterial strains examined, representing three families of cyanobacteria (Nostocales, Chroococales and Oscillatoriales). A BLAST analysis shows that these genes have similarities to known cyanobacterial natural products. Analysis of the NRPS adenylation domain indicates the presence of novel features previously ascribed to both proteobacteria and cyanobacteria. Furthermore, binding-pocket predictions reveal diversity in the amino acids used during the biosynthesis of compounds. A similar analysis of the PKS ketosynthase domain shows significant structural diversity and their presence in both mixed modules with NRPS domains and individually as part of a PKS module. We have been able to classify the NRPS genes on the basis of their binding-pockets. Further, we show how this data can be used to begin to link structure to function by an analysis of the compounds Scyptolin A and Hofmannolin from Scytonema sp. PCC 7110.     

The expansion of mechanistic and organismic diversity associated with non-ribosomal peptides

Non-ribosomal peptides are a group of secondary metabolites with a wide range of bioactivities, produced by prokaryotes and lower eukaryotes. Recently, non-ribosomal synthesis has been detected in diverse microorganisms, including the myxobacteria and cyanobacteria. Peptides biosynthesized non-ribosomally may often play a primary or secondary role in the producing organism. Non-ribosomal peptides are often small in size and contain unusual or modified amino acids. Biosynthesis occurs via large modular enzyme complexes, with each module responsible for the activation and thiolation of each amino acid, followed by peptide bond formation between activated amino acids. Modules may also be responsible for the enzymatic modification of the substrate amino acid. Recent analysis of biosynthetic gene clusters has identified novel integrated, mixed and hybrid enzyme systems. These diverse mechanisms of biosynthesis result in the wide variety of non-ribosomal peptide structures and bioactivities seen today. Knowledge of these biosynthetic systems is rapidly increasing and methods of genetically engineering these systems are being developed. In the future, this may lead to rational drug design through combinatorial biosynthesis of these enzyme systems.     

Architecture of a PKS-NRPS hybrid megaenzyme involved in the biosynthesis of the genotoxin colibactin

1. Download : Download high-res image (146KB)
2. Download : Download full-size image

     

Iteratively improving natamycin production in Streptomyces gilvosporeus by a large operon-reporter based strategy

Many high-value secondary metabolites are assembled by very large multifunctional polyketide synthases or non-ribosomal peptide synthetases encoded by giant genes, for instance, natamycin production in an industrial strain of Streptomyces gilvosporeus. In this study, a large operon reporter-based selection system has been developed using the selectable marker gene neo to report the expression both of the large polyketide synthase genes and of the entire gene cluster, thereby facilitating the selection of natamycin-overproducing mutants by iterative random mutagenesis breeding. In three successive rounds of mutagenesis and selection, the natamycin titer was increased by 110%, 230%, and 340%, respectively, and the expression of the whole biosynthetic gene cluster was correspondingly increased. An additional copy of the natamycin gene cluster was found in one overproducer. These findings support the large operon reporter-based selection system as a useful tool for the improvement of industrial strains utilized in the production of polyketides and non-ribosomal peptides.     

Phylogenetic analysis of type I polyketide synthase and nonribosomal peptide synthetase genes in Antarctic sediment

The modular polyketide synthase (PKS) and nonribosomal peptide synthetase (NRPS) have been found to be involved in natural product synthesis in many microorganisms. Study on their diversities in natural environment may provide important ecological insights, in addition to opportunities for antibacterial drugs development. In this study, the PKS and NRPS gene diversities in two coast sediments near China Zhongshan Station were studied. The phylogenetic analysis of amino acid (AA) sequences indicated that the identified ketosynthase (KS) domains were clustered with those from diverse bacterial groups, including Proteobacteria, Firmicutes, Planctomycetes, Cyanobacteria, Actinobacteria, and some uncultured symbiotic bacteria. One new branch belonging to hybrid PKS/NRPS enzyme complexes and five independent clades were found on the phylogenetic tree. The obtained adenylation (A) domains were mainly clustered within the Cyanobacteria and Proteobacteria group. Most of the identified KS and A domains showed below 80 and 60% identities at the AA level to their closest matches in GenBank, respectively. The diversities of both KS and A domains in natural environmental sample were different from those in sewage-contaminated sample. These results revealed the great diversity and novelty of both PKS and NRPS genes in Antarctic sediment.     

Functional characterization of 4'-phosphopantetheinyl transferase genes of bacterial and fungal origin by complementation of Saccharomyces cerevisiae lys5

Lysine biosynthesis in yeast requires the posttranslational conversion of the alpha-aminoadipate semialdehyde reductase Lys2 by the 4'-phosphopantetheinyl transferase (PPTase) Lys5 from the inactive apo-form into the catalytically active holo-form. In this reaction, the peptidyl carrier domain of Lys2 is modified at a conserved serine residue side chain with the 4'-phosphopantetheine moiety derived from coenzyme A. We have deleted the lys5 gene in Saccharomyces cerevisiae to investigate the substrate specificity of various heterologous PPTase genes of bacterial and fungal origin by testing their ability to complement lys5 in trans. Genes encoding PPTases Sfp and Gsp from Bacillus spp., which are involved in non-ribosomal peptide antibiotic synthesis, complemented the lys5 deletion, whereas ydcB of Bacillus subtilis, which encodes the acyl carrier protein synthase involved in fatty acid synthesis, could not. Two yet uncharacterized fungal genes, q10474 of Schizosaccharomyces pombe, meanwhile annotated as the putative lys7 gene, and npgA of Aspergillus nidulans, also complemented the lys5 deletion and have thus been functionally characterized as PPTases. The complementation system described also provides the basis for a simple method of functional characterization of PPTase candidate genes and their cloning from chromosomal DNA or cDNA libraries of diverse origin.     

Effect of aposymbiotic conditions on colony growth and secondary metabolite production in the lichen-forming fungus Ramalina dilacerata

The production of secondary metabolites by aposymbiotic lichen-forming fungi in culture is thought to be influenced by environmental conditions. The effects of the environment may be studied by culturing fungi under defined growing parameters to provide a better understanding of the role of the large number of polyketide synthase (PKS) gene paralogs detected in the genomes of many fungi. The objectives of this study were to examine the effects of culture conditions (media composition and pH level) on the colony growth, the numbers of secondary products, and the expression of two PKS genes by the lichen-forming fungus Ramalina dilacerata. Four types of growth media at four different pH levels were prepared to culture spore isolates of R. dilacerata. Colony diameter and texture were recorded. The number of secondary compounds were determined by thin layer chromatography (TLC) and high performance liquid chromatography (HPLC). Expression of two PKS genes (non-reducing (NR) and 6-MSAS-type PKS) were compared with expression of an internal control mitochondrial small subunit gene (mtSSU). The results showed that media containing yeast extracts produced the largest colony diameters and the fewest number of secondary metabolites. Colony growth rates also varied with different media conditions, and a significant negative relationship occurred between colony diameter and number of secondary metabolites. Expression of the NR PKS gene was significantly higher at pH 6.5 on the glucose malt agar than any other media, and expression of the 6-MSAS-type (partially-reducing) PKS gene was significantly higher at pH 8.5 on (malt agar) malt agar than on the other types of agar. Gene expression was correlated with the pH level and media conditions that induced the production of the larger number of secondary substances. This is the first study to examine secondary metabolite production in R. dilacerata by comparing the number of polyketides detected with quantitative polymerase chain reaction (qPCR) of two PKS genes under different culture conditions.     

Evidence for an ergot alkaloid gene cluster in Claviceps purpurea

A gene (cpd1) coding for the dimethylallyltryptophan synthase (DMATS) that catalyzes the first specific step in the biosynthesis of ergot alkaloids, was cloned from a strain of Claviceps purpurea that produces alkaloids in axenic culture. The derived gene product (CPD1) shows only 70% similarity to the corresponding gene previously isolated from Claviceps strain ATCC 26245, which is likely to be an isolate of C. fusiformis. Therefore, the related cpd1 most probably represents the first C. purpurea gene coding for an enzymatic step of the alkaloid biosynthetic pathway to be cloned. Analysis of the 3′-flanking region of cpd1 revealed a second, closely linked ergot alkaloid biosynthetic gene named cpps1, which codes for a 356-kDa polypeptide showing significant similiarity to fungal modular peptide synthetases. The protein contains three amino acid-activating modules, and in the second module a sequence is found which matches that of an internal peptide (17 amino acids in length) obtained from a tryptic digest of lysergyl peptide synthetase 1 (LPS1) of C. purpurea, thus confirming that cpps1 encodes LPS1. LPS1 activates the three amino acids of the peptide portion of ergot peptide alkaloids during D-lysergyl peptide assembly. Chromosome walking revealed the presence of additional genes upstream of cpd1 which are probably also involved in ergot alkaloid biosynthesis: cpox1 probably codes for an FAD-dependent oxidoreductase (which could represent the chanoclavine cyclase), and a second putative oxido-reductase gene, cpox2, is closely linked to it in inverse orientation. RT-PCR experiments confirm that all four genes are expressed under conditions of peptide alkaloid biosynthesis. These results strongly suggest that at least some genes of ergot alkaloid biosynthesis in C. purpurea are clustered, opening the way for a detailed molecular genetic analysis of the pathway. Received: 26 August 1998 / Accepted: 19 October 1998     

链霉菌磷酸泛酰巯基乙胺基转移酶对载体蛋白的底物选择性的研究进展

磷酸泛酰巯基乙胺基转移酶(PPTase)催化脂肪酸合酶(FAS)、聚酮合酶(PKS)和非核糖体肽合成酶(NRPS)中载体蛋白从脱辅基形态转化为全辅基形态,对脂肪酸、PKS产物和NRPS产物的生物合成起着不可或缺的作用。本文介绍并总结了链霉菌PPTase对载体蛋白底物选择性的最新研究进展:Ⅲ型PPTase特异性催化同一个多肽链中ACP的辅基化;Ⅱ型PPTase倾向于催化Ⅰ型PKS中ACP和NRPS中PCP的辅基化;Ⅰ型PPTase倾向于催化Ⅱ型PKS中ACP和Ⅱ型FAS中ACP的辅基化;编码基因位于基因簇内的Ⅰ型/Ⅱ型PPTase倾向于催化编码基因位于同基因簇内的PKS/NRPS中ACP/PCP的辅基化;这些研究结果为阐明并改造链霉菌辅基化网络以提高特定次级代谢产物的产量提供了参考和借鉴。     

Genetic manipulation of secondary metabolite biosynthesis for improved production in Streptomyces and other actinomycetes

Journal of Industrial Microbiology & Biotechnology - Actinomycetes continue to be important sources for the discovery of secondary metabolites for applications in human medicine, animal health,...     

Specific enrichment of nonribosomal peptide synthetase module by an affinity probe for adenylation domains

We targeted the development of an affinity probe for adenylation (A) domains that can facilitate enrichment, identification, and quantification of A domain-containing modules in nonribosomal peptide synthetase (NRPS)-polyketide synthase (PKS) hybrids and NRPSs. A 5′-O-sulfamoyladenosine (AMS) non-hydrolyzable analogue of adenosine monophosphate (AMP) has been reported as a scaffold for the design of inhibitors exhibiting tight binding of adenylation enzymes. Here we describe the application of an affinity probe for A domains. Our synthetic probe, a biotinylated l-Phe-AMS (l-Phe-AMS-biotin) specifically targets the A domains in NRPS modules that activates l-Phe to an aminoacyladenylate intermediate in both recombinant NRPS enzyme systems and whole proteomes.     

Characterization of two polyketide synthase genes in Exophiala lecanii-corni, a melanized fungus with bioremediation potential

Exophiala lecanii-corni has significant bioremediation potential because it can degrade a wide range of volatile organic compounds. In order to identify sites for the insertion of genes that might enhance this potential, a genetic analysis of E. lecanii-corni was undertaken. Two polyketide synthase genes, ElPKS1 and ElPKS2, have now been discovered by a PCR-based strategy. ElPKS1 was isolated by a marker rescue technique. The nucleotide sequence of ElPKS1 consists of a 6576-bp open reading frame encoding a protein with 2192 amino acids, which was interrupted by a 60-bp intron near the 5' end and a 54-bp intron near the 3' end. Sequence analysis, results from disruption experiments, and physiological tests showed that ElPKS1 encoded a polyketide synthase required for melanin biosynthesis. Since ElPKS1 is non-essential, it is a desirable bioengineering target site for the insertion of native and foreign genes. The successful expression of these genes could enhance the bioremediation capability of the organism. ElPKS2 was cloned by colony hybridization screening of a partial genomic library with an ElPKS2 PCR product. ElPKS2 had a 6465-bp open reading frame that encoded 2155 amino acids and had introns of 56, 67, 54, and 71 bp. Although sequence analysis of the derived protein of ElPKS2 confirmed the polyketide synthase nature of its protein product, the function of that product remains unclear.     

Cloning and characterization of a gene cluster for geldanamycin production in Streptomyces hygroscopicus NRRL 3602

We illustrate the use of a PCR-based method by which the genomic DNA of a microorganism can be rapidly queried for the presence of type I modular polyketide synthase genes to clone and characterize, by sequence analysis and gene disruption, a major portion of the geldanamycin production gene cluster from Streptomyces hygroscopicus var. geldanus NRRL 3602.     

Engineering the plant cell factory for secondary metabolite production

Plant secondary metabolism is very important for traits such as flower color, flavor of food, and resistance against pests and diseases. Moreover, it is the source of many fine chemicals such as drugs, dyes, flavors, and fragrances. It is thus of interest to be able to engineer the secondary metabolite production of the plant cell factory, e.g. to produce more of a fine chemical, to produce less of a toxic compound, or even to make new compounds, Engineering of plant secondary metabolism is feasible nowadays, but it requires knowledge of the biosynthetic pathways involved. To increase secondary metabolite production different strategies can be followed, such as overcoming rate limiting steps, reducing flux through competitive pathways, reducing catabolism and overexpression of regulatory genes. For this purpose genes of plant origin can be overexpressed, but also microbial genes have been used successfully. Overexpression of plant genes in microorganisms is another approach, which might be of interest for bioconversion of readily available precursors into valuable fine chemicals. Several examples will be given to illustrate these various approaches. The constraints of metabolic engineering of the plant cell factory will also be discussed. Our limited knowledge of secondary metabolite pathways and the genes involved is one of the main bottlenecks. This revised version was published online in August 2006 with corrections to the Cover Date.     

Genetic methods and strategies for secondary metabolite yield improvement in actinomycetes

The foundation for any strain improvement program is efficient random chemically-induced mutagenesis coupled with highly reproducible fermentation and product assays. The broad spectrum of spontaneous mutations can be leveraged in some cases by direct selection of mutants with desired traits. Transposons containing outward-reading promoter activity might be used to enhance yields by inducing promoter fusions, disrupting negative regulatory elements, or disrupting genes involved in competing pathways. Transposons might also be used to identify and clone positive regulatory genes. As knowledge of the key elements in the fermentation process and secondary metabolite biosynthesis grows, gene cloning and targeted gene duplication becomes an important tool. Duplication of genes involved in rate limiting steps can be achieved to improve product yields by inserting the desired gene(s) into neutral sites in the chromosome by homologous recombination or by site-specific integration. The probabilities and frequencies of success of the molecular genetic approaches should increase with an increasing knowledge of key factors influencing product yields. This knowledge can be broadened dramatically by a combination of structural and functional genomics, gene disruption analysis and metabolic modeling. Protoplast fusion can be used to recombine beneficial traits from any of the other approaches.     

Regulation of secondary metabolite production in filamentous ascomycetes

Fungi are renowned for their ability to produce bioactive small molecules otherwise known as secondary metabolites. These molecules have attracted much attention due to both detrimental (e.g. toxins) and beneficial (e.g. pharmaceuticals) effects on human endeavors. Once the topic only of chemical and biochemical studies, secondary metabolism research has reached a sophisticated level in the realm of genetic regulation. This review covers the latest insights into the processes regulating secondary metabolite production in filamentous fungi.     

Metabolic engineering of<Emphasis Type="Italic"> Escherichia coli</Emphasis> for improved 6-deoxyerythronolide B production

Escherichia coli is an attractive candidate as a host for polyketide production and has been engineered to produce the erythromycin precursor polyketide 6-deoxyerythronolide B (6dEB). In order to identify and optimize parameters that affect polyketide production in engineered E. coli, we first investigated the supply of the extender unit (2S)-methylmalonyl-CoA via three independent pathways. Expression of the Streptomyces coelicolor malonyl/methylmalonyl-CoA ligase (matB) pathway in E. coli together with methylmalonate feeding resulted in the accumulation of intracellular methylmalonyl-CoA to as much as 90% of the acyl-CoA pool. Surprisingly, the methylmalonyl-CoA generated from the matB pathway was not converted into 6dEB. In strains expressing either the S. coelicolor propionyl-CoA carboxylase (PCC) pathway or the Propionibacteria shermanii methylmalonyl-CoA mutase/epimerase pathway, methylmalonyl-CoA accumulated up to 30% of the total acyl-CoA pools, and 6dEB was produced; titers were fivefold higher when strains contained the PCC pathway rather than the mutase pathway. When the PCC and mutase pathways were expressed simultaneously, the PCC pathway predominated, as indicated by greater flux of ¹³C-propionate into 6dEB through the PCC pathway. To further optimize the E. coli production strain, we improved 6dEB titers by integrating the PCC and mutase pathways into the E. coli chromosome and by expressing the 6-deoxyerythronolide B synthase (DEBS) genes from a stable plasmid system.S. Murli and J. Kennedy contributed equally to this work     

Nitric oxide elicitation for secondary metabolite production in cultured plant cells

Nitric oxide (NO) is an important signal molecule in stress responses. Accumulation of secondary metabolites often occurs in plants subjected to stresses including various elicitors or signal molecules. NO has been reported to play important roles in elicitor-induced secondary metabolite production in tissue and cell cultures of medicinal plants. Better understanding of NO role in the biosynthesis of such metabolites is very important for optimizing the commercial production of those pharmaceutically significant secondary metabolites. This paper summarizes progress made on several aspects of NO signal leading to the production of plant secondary metabolites, including various abiotic and biotic elicitors that induce NO production, elicitor-triggered NO generation cascades, the impact of NO on growth development and programmed cell death in medicinal plants, and NO-mediated regulation of the biosynthetic pathways of such metabolites. Cross-talks among NO signaling and reactive oxygen species, salicylic acid, and jasmonic acid are discussed. Some perspectives on the application of NO donors for induction of the secondary metabolite accumulation in plant cultures are also presented.