Heterologous expression of natural product biosynthetic gene clusters in Streptomyces coelicolor: from genome mining to manipulation of biosynthetic pathways

Heterologous gene expression is one of the main strategies used to access the full biosynthetic potential of actinomycetes, as well as to study the metabolic pathways of natural product biosynthesis and to create unnatural pathways. Streptomyces coelicolor A3(2) is the most studied member of the actinomycetes, bacteria renowned for their prolific capacity to synthesize a wide range of biologically active specialized metabolites. We review here the use of strains of this species for the heterologous production of structurally diverse actinomycete natural products.     

Nature’s combinatorial biosynthesis and recently engineered production of nucleoside antibiotics in <Emphasis Type="Italic">Streptomyces</Emphasis>

Modified nucleosides produced by Streptomyces and related actinomycetes are widely used in agriculture and medicine as antibacterial, antifungal, anticancer and antiviral agents. These specialized small-molecule metabolites are biosynthesized by complex enzymatic machineries encoded within gene clusters in the genome. The past decade has witnessed a burst of reports defining the key metabolic processes involved in the biosynthesis of several distinct families of nucleoside antibiotics. Furthermore, genome sequencing of various Streptomyces species has dramatically increased over recent years. Potential biosynthetic gene clusters for novel nucleoside antibiotics are now apparent by analysis of these genomes. Here we revisit strategies for production improvement of nucleoside antibiotics that have defined mechanisms of action, and are in clinical or agricultural use. We summarize the progress for genetically manipulating biosynthetic pathways for structural diversification of nucleoside antibiotics. Microorganism-based biosynthetic examples are provided and organized under genetic principles and metabolic engineering guidelines. We show perspectives on the future of combinatorial biosynthesis, and present a working model for discovery of novel nucleoside natural products in Streptomyces.     

海洋放线菌的研究现状及未来展望

【背景】放线菌具有丰富的遗传和功能多样性,其次级代谢产物活性广泛,在临床医疗、农业生产和污染防治等领域都发挥着重要的作用。海洋放线菌由于其特殊的代谢途径,能产生独特的活性天然产物而受到广泛关注。【目的】探究国内外海洋放线菌领域研究的热点和趋势,为后续研究提供参考。【方法】以“marine actinomycetes or marine actinobacteria”为关键词,在Web of Science中检索海洋放线菌领域的文章进行计量分析,使用VOSviewer软件对其关键词、国家、机构、作者、发表时间进行可视化分析。【结果】海洋放线菌领域的文章发表数量总体呈逐年上升趋势,主要集中在微生物学及药学领域,中美两国在论文数量和引用频次上远超其他国家,海洋放线菌领域的研究集中在菌株的分离鉴定、活性天然产物挖掘以及生物信息学等方面。【结论】海洋放线菌在全球范围内愈发受到重视,国内外机构应当加强合作,运用生物信息学技术进一步挖掘活性次级代谢产物,推动海洋放线菌领域进一步发展。     

Analysis of myxobacterial secondary metabolism goes molecular

During the last 20 years myxobacteria have made their way from highly exotic organisms to one of the major sources of microbial secondary metabolites besides actinomycetes and fungi. The pharmaceutical interest in these peculiar prokaryotes lies in their ability to produce a variety of structurally unique compounds and/or metabolites with rare biological activities. This review deals with the recent progress toward a better understanding of the biology, the genetics, the biochemistry and the regulation of secondary metabolite biosynthesis in myxobacteria. These research efforts paved the way to sophisticated in vitro studies and to the heterologous expression of complete biosynthetic pathways in conjunction with their targeted manipulation. The progress made is a prerequisite for using the vast resource of myxobacterial diversity regarding secondary metabolism more efficiently in the future.     

Mining and engineering natural-product biosynthetic pathways

Natural products continue to fulfill an important role in the development of therapeutic agents. In addition, with the advent of chemical genetics and high-throughput screening platforms, these molecules have become increasingly valuable as tools for interrogating fundamental aspects of biological systems. To access the vast portion of natural-product structural diversity that remains unexploited for these and other applications, genome mining and microbial metagenomic approaches are proving particularly powerful. When these are coupled with recombineering and related genetic tools, large biosynthetic gene clusters that remain intractable or cryptic in the native host can be more efficiently cloned and expressed in a suitable heterologous system. For lead optimization and the further structural diversification of natural-product libraries, combinatorial biosynthetic engineering has also become indispensable. However, our ability to rationally redesign biosynthetic pathways is often limited by our lack of understanding of the structure, dynamics and interplay between the many enzymes involved in complex biosynthetic pathways. Despite this, recent structures of fatty acid synthases should allow a more accurate prediction of the likely architecture of related polyketide synthase and nonribosomal peptide synthetase multienzymes.     

Biosynthesis of mycobacterial lipids by polyketide synthases and beyond

Abstract

Over a decade ago, the analysis of the complete sequence of the genome of the human pathogen Mycobacterium tuberculosis revealed an unexpectedly high number of open reading frames encoding proteins with homology to polyketide synthases (PKSs). PKSs form a large family of fascinating multifunctional enzymes best known for their involvement in the biosynthesis of hundreds of polyketide natural products with diverse biological activities. The surprising polyketide biosynthesis capacity of M. tuberculosis has been investigated since its initial inference from genome analysis. This investigation has been based on the genes found in M. tuberculosis or their orthologs found in other Mycobacterium species. Today, the majority of the PKS-encoding genes of M. tuberculosis have been linked to specific biosynthetic pathways required for the production of unique lipids or glycolipid conjugates that are critical for virulence and/or components of the extraordinarily complex mycobacterial cell envelope. This review provides a synopsis of the most relevant studies in the field and an overview of our current understanding of the involvement of PKSs and several other polyketide production pathway-associated proteins in critical biosynthetic pathways of M. tuberculosis and other mycobacteria. In addition, the most relevant studies on PKS-containing biosynthetic pathways leading to production of metabolites from mycobacteria other than M. tuberculosis are reviewed.     

The detection of diverse aminoglycoside phosphotransferases within natural populations of actinomycetes

The conserved nature of the genes that code for actinomycete secondary metabolite biosynthetic pathways suggests a common evolutionary ancestor and incidences of lateral gene transfer. Resistance genes associated with these biosynthetic pathways also display a high degree of similarity. Actinomycete aminoglycoside phosphotransferase antibiotic resistance enzymes (APH) are coded for by such genes and are therefore good targets for evaluating the bioactive potential of actinomycetes. A set of universal PCR primers for APH encoding genes was used to probe genomic DNA from three collections of actinomycetes to determine the utility of molecular screening. An additional monitoring of populations for the predominance of specific classes of enzymes to predict the potential of environmental sites for providing isolates with interesting metabolic profiles. Approximately one-fifth of all isolates screened gave a positive result by PCR. The PCR products obtained were sequenced and compared to existing APH family members. Sequence analysis resolved the family into nine groups of which six had recognizable phenotypes: 6′-phosphotransferase (APH(6)), 3′-phosphotransferase (APH(3)), hydroxyurea phosphotransferase (HUR), peptide phosphotransferase, hygromycin B phosphotransferase (APH(7″)) and oxidoreductase. The actinomycetes screened fell into seven groups, including three novel groups with unknown phenotypes. The strains clustered according to the environmental site from where they were obtained, providing evidence for the movement of these genes within populations. The value of this as a method for obtaining novel compounds and the significance to the ecology of antibiotic biosynthesis are discussed. Journal of Industrial Microbiology & Biotechnology (2002) 29, 60–69 doi:10.1038/sj.jim.7000260 Received 25 June 2001/ Accepted in revised form 26 March 2002     

Biosynthesis of protein products by animal cells. Are growth and non-growth associated concepts valid or useful?

The application of simple growth and non-growth associated concepts from microbial systems describing substrate uptake and production formation is considered unlikely to assist in the understanding of antibody formation and, hence, in maximising antibody yield. Such concepts have many significant limitations — notably, their strict application only to products of catabolic pathways and their inability to include metabolisms which either have multiple catabolic pathways (eg, fermentation and respiration in yeast and animal cells) or in which the major product of interest is predominantly anabolic in nature (eg. amino acid production in bacteria and antibody formation in animal cells). In addition, products which undergo an assembly and secretion process or a secretion process which allows intracellular pools of product to exist are also not well described by such simple relationships. In this work, inadequacies in the current approach to the study of the kinetics of growth of hybridoma cells and antibody production are described and the examples of growth ofSaccharomyces cerevisiae andCandida utilis, amino acid production by bacteria and antibody production by animal cells are used to illustrate these limitations. Having identified these limitations, suggestions are made as to how studies might be undertaken to assist our future understanding of the process of antibody manufacture and, subsequently, maximizing antibody yield. The process of characterising the metabolism of anabolic products is subject to detailed computer simulation of the pathways involved. It is argued that such approaches will assist us in understanding more fully the nature of biosynthetic products and how they integrate with the major energy producing pathways of the cell and the cell cycle. This will assist in maximising the yield of such products.     

西沙海藻共附生放线菌的分离鉴定及其抗菌活性评价

【目的】为了探究南海海藻共附生放线菌资源的多样性及潜在的应用价值,对中国西沙群岛来源的海藻进行共附生放线菌的分离鉴定与抗菌活性筛选。【方法】利用稀释涂布平板法,采用2种不同分离培养基对不同采样位点的6种海藻进行放线菌分离;通过16S rRNA基因序列分析、构建系统发育树对分离的放线菌进行鉴定;用打孔法对无乳链球菌(Streptococcus agalactiae)等10种敏感细菌进行抗菌活性筛选;对筛选得到的目标活性菌株HZ014进行全基因组测序,通过AntiSMASH在线工具分析其次级代谢产物生物合成基因簇,预测其产生新型活性物质的潜力。【结果】从6种海藻中分离得到36株共附生放线菌,基于16S rRNA基因序列比对和系统发育分析,鉴定结果为链霉菌属(Streptomyces) 2株、红球菌属(Rhodococcus) 2株、诺卡氏菌属(Nocardia)3株、小单孢菌属(Micromonospora) 5株和盐孢菌属(Salinispora) 24株;抗菌活性筛选结果表明,36株共附生放线菌发酵粗提物对至少1种敏感细菌表现出一定的抑制作用,不同菌株发酵粗提物的抗菌活性存在明显差异,...     

Genetic approaches for controlling ratios of related polyketide products in fermentation processes

Simple acyl thioesters are used as precursors for both the initiation and elongation steps in polyketide biosynthetic processes. Several structurally related polyketide products are sometimes made in these processes. These analogs are typically generated by a combination of two factors: availability of structurally similar biosynthetic precursors, and biosynthetic enzymes unable to effectively discriminate between them. Often, only one polyketide product is desired from a fermentation process, requiring a method to control the ratio of these different analogs. Preferential production of one desired analog is accomplished using random mutagenesis and manipulation of fermentation conditions. A genetic enzymatic understanding of polyketide biosynthesis, as well as the pathways that provide the relevant precursors, allows for a rational and more contemporary approach for control of analogs produced in fermentation processes. This approach involves genetic manipulation of either the pathways that provide pools of the acyl CoA thioester precursors, or the function/specificity of the appropriate biosynthetic enzymes. Reviewed herein are three such examples where these approaches have been carried out successfully with polyketide biosynthetic processes. Journal of Industrial Microbiology & Biotechnology (2001) 27, 368–377. Received 01 March 2001/ Accepted in revised form 08 August 2001     

放线菌次级代谢途径的设计

近来有关放线菌次级产物生物合成的分子遗传学和生物化学方面的进展为我们改造其代谢途径提供了一个明确的方向。近年来,对微生物的初级代谢途径进行基因改造取得了成功,但放线菌的次级代谢工程产物却都没有达到中试或生产规模。进展如此缓慢的主要原因是放线菌自身复杂的代谢途径以及细胞循环中复杂的调节方式及其特异性。目前人们着力于通过基因操作改造酶,从而重新设计以其催化产物为基本骨架的代谢途径,最终产生修饰的或新的天然终产物。本文将讨论达到此目的的几种设计策略。     

放线菌中铁载体生物合成机制研究进展

铁载体是由微生物产生,对铁元素具有高亲和性的小分子化合物。这类天然产物所展现的结构多样性引起人们对其生物合成机制的极大兴趣。目前已有研究报道的铁载体生物合成途径主要有2种,一是直接由非核糖体肽合成酶(Nonribosomal peptide synthetases,NRPSs)家族的多酶复合体负责合成,另一种是以不依赖于NRPS(NRPS-independent,NIS)的方式,由一类特殊合成酶家族参与合成。在过去的十多年中,铁载体生物合成成为天然产物生物合成研究领域的热点之一,其中几种依赖于NRPS途径合成的铁载体生物合成机制已得到充分阐明,而对NIS方式合成的铁载体研究也获得了诸多进展。作为放线菌的一类重要次级代谢产物,通过遗传学、化学等手段对放线菌所产生铁载体生物合成途径的遗传学和生物化学研究,能够为发展新的抗菌药物提供契机,同时也能加深我们对这一类生物活性物质形成机制的认识。综述近期该研究方向的进展。     

Unique Actinomycetes from Marine Caves and Coral Reef Sediments Provide Novel PKS and NRPS Biosynthetic Gene Clusters

In the ever-expanding search for novel bioactive molecules and enzymes, marine actinomycetes have proven to be a productive source. While open reef sediment and sponge-associated actinomycetes have been extensively examined, their marine cave counterparts remain unevaluated. Anchialine cave systems in the Bahamas offered an ideal setting to evaluate the occurrence and variation within sediment-associated actinomycete communities. While in close geographical proximity to open reef environments, these systems provide a specialized environmental niche devoid of light and direct exposure to nutrient input. In the present study, selective isolation techniques and molecular methods were used to test the hypothesis that variable distribution of actinomycetes and secondary metabolite gene clusters occur between open reef and marine cave systems. The results indicated that differences exist within the culturable sediment-associated actinomycete communities between marine caves and open reef systems, with members of the genus Streptomyces dominating cultures from open reef sediments and a more diverse suite of actinomycetes isolated from marine cave sediment samples. Within the cave isolates, members of the proposed genus Solwaraspora were the most represented. Based on PKS- and NRPS-gene-targeted PCR amplification and sequencing, geographic variation in the occurrence of these biosynthetic pathways was also observed. These findings indicate that marine cave systems are a lucrative source in the search for novel secondary metabolite producers with biotechnological applications and that environmental and geographic factors likely affect the occurrence of these biosynthetic pathways.     

Convergent and divergent biosynthetic strategies towards phosphonic acid natural products

The phosphonate class of natural products have received significant interests in the post-genomic era due to the relative ease with which their biosynthetic genes may be identified and the resultant final products be characterized. Recent large-scale studies of the elucidation and distributions of phosphonate pathways have provided a robust landscape for deciphering the underlying biosynthetic logic. A recurrent theme in phosphonate biosynthetic pathways is the interweaving of enzymatic reactions across different routes, which enables diversification to elaborate chemically novel scaffolds. Here, we provide a few vignettes of how Nature has utilized both convergent and divergent biosynthetic strategies to compile pathways for production of novel phosphonates. These examples illustrate how common intermediates may either be generated or intercepted to diversify chemical scaffolds and provides a starting point for both biotechnological and synthetic biological applications towards new phosphonates by similar combinatorial approaches.     

Chemical variation and the species concept in lichenized ascomycetes

Differences in secondary metabolites produced by lichens are not always genetically based, and even if genetically based may represent only a one gene difference. Taxonomic decision involving secondary metabolism should be based on the degree of difference demonstrated between biosynthetic pathways, not on the individual products. No taxonomic status should be accorded to entities which differ only in products from a single biosynthetic pathway, but varietal status should be given to those which have different biosynthetic pathways. Species status is justified if chemistry is correlated with morphological or proven physiological difference, or if more than one major biosynthetic system is involved. While ecological and biogeographic differences point to the likelihood of differences being found, if no differences can be demonstrated which in themselves justify taxonomic separation, then features ought not be allowed to influence the taxonomic decision.     

Complexity of cyanobacterial exopolysaccharides: composition, structures, inducing factors and putative genes involved in their biosynthesis and assembly

Cyanobacterial extracellular polymeric substances (EPS) are mainly composed of high-molecular-mass heteropolysaccharides, with variable composition and roles according to the microorganism and the environmental conditions. The number of constituents – both saccharidic and nonsaccharidic – and the complexity of structures give rise to speculations on how intricate their biosynthetic pathways could be, and how many genes may be involved in their production. However, little is known regarding the cyanobacterial EPS biosynthetic pathways and regulating factors. This review organizes available information on cyanobacterial EPS, including their composition, function and factors affecting their synthesis, and from the in silico analysis of available cyanobacterial genome sequences, proposes a putative mechanism for their biosynthesis.     

A genomics-guided approach for discovering and expressing cryptic metabolic pathways

Genome analysis of actinomycetes has revealed the presence of numerous cryptic gene clusters encoding putative natural products. These loci remain dormant until appropriate chemical or physical signals induce their expression. Here we demonstrate the use of a high-throughput genome scanning method to detect and analyze gene clusters involved in natural-product biosynthesis. This method was applied to uncover biosynthetic pathways encoding enediyne antitumor antibiotics in a variety of actinomycetes. Comparative analysis of five biosynthetic loci representative of the major structural classes of enediynes reveals the presence of a conserved cassette of five genes that includes a novel family of polyketide synthase (PKS). The enediyne PKS (PKSE) is proposed to be involved in the formation of the highly reactive chromophore ring structure (or "warhead") found in all enediynes. Genome scanning analysis indicates that the enediyne warhead cassette is widely dispersed among actinomycetes. We show that selective growth conditions can induce the expression of these loci, suggesting that the range of enediyne natural products may be much greater than previously thought. This technology can be used to increase the scope and diversity of natural-product discovery.     

Phylum-wide comparative genomics unravel the diversity of secondary metabolism in Cyanobacteria

Background

Cyanobacteria are an ancient lineage of photosynthetic bacteria from which hundreds of natural products have been described, including many notorious toxins but also potent natural products of interest to the pharmaceutical and biotechnological industries. Many of these compounds are the products of non-ribosomal peptide synthetase (NRPS) or polyketide synthase (PKS) pathways. However, current understanding of the diversification of these pathways is largely based on the chemical structure of the bioactive compounds, while the evolutionary forces driving their remarkable chemical diversity are poorly understood.

Results

We carried out a phylum-wide investigation of genetic diversification of the cyanobacterial NRPS and PKS pathways for the production of bioactive compounds. 452 NRPS and PKS gene clusters were identified from 89 cyanobacterial genomes, revealing a clear burst in late-branching lineages. Our genomic analysis further grouped the clusters into 286 highly diversified cluster families (CF) of pathways. Some CFs appeared vertically inherited, while others presented a more complex evolutionary history. Only a few horizontal gene transfers were evidenced amongst strongly conserved CFs in the phylum, while several others have undergone drastic gene shuffling events, which could result in the observed diversification of the pathways.

Conclusions

Therefore, in addition to toxin production, several NRPS and PKS gene clusters are devoted to important cellular processes of these bacteria such as nitrogen fixation and iron uptake. The majority of the biosynthetic clusters identified here have unknown end products, highlighting the power of genome mining for the discovery of new natural products.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-977) contains supplementary material, which is available to authorized users.     

Synthetic biology and metabolic engineering of actinomycetes for natural product discovery

Actinomycetes are one of the most valuable sources of natural products with industrial and medicinal importance. After more than half a century of exploitation, it has become increasingly challenging to find novel natural products with useful properties as the same known compounds are often repeatedly re-discovered when using traditional approaches. Modern genome mining approaches have led to the discovery of new biosynthetic gene clusters, thus indicating that actinomycetes still harbor a huge unexploited potential to produce novel natural products. In recent years, innovative synthetic biology and metabolic engineering tools have greatly accelerated the discovery of new natural products and the engineering of actinomycetes. In the first part of this review, we outline the successful application of metabolic engineering to optimize natural product production, focusing on the use of multi-omics data, genome-scale metabolic models, rational approaches to balance precursor pools, and the engineering of regulatory genes and regulatory elements. In the second part, we summarize the recent advances of synthetic biology for actinomycetal metabolic engineering including cluster assembly, cloning and expression, CRISPR/Cas9 technologies, and chassis strain development for natural product overproduction and discovery. Finally, we describe new advances in reprogramming biosynthetic pathways through polyketide synthase and non-ribosomal peptide synthetase engineering. These new developments are expected to revitalize discovery and development of new natural products with medicinal and other industrial applications.