Red Soils Harbor Diverse Culturable Actinomycetes That Are Promising Sources of Novel Secondary Metabolites

Red soils, which are widely distributed in tropical and subtropical regions of southern China, are characterized by low organic carbon, high content of iron oxides, and acidity and, hence, are likely to be ideal habitats for acidophilic actinomycetes. However, the diversity and biosynthetic potential of actinomycetes in such habitats are underexplored. Here, a total of 600 actinomycete strains were isolated from red soils collected in Jiangxi Province in southeast China. 16S rRNA gene sequence analysis revealed a high diversity of the isolates, which were distributed into 26 genera, 10 families, and 7 orders within the class Actinobacteria; these taxa contained at least 49 phylotypes that are likely to represent new species within 15 genera. The isolates showed good physiological potentials for biosynthesis and biocontrol. Chemical screening of 107 semirandomly selected isolates spanning 20 genera revealed the presence of at least 193 secondary metabolites from 52 isolates, of which 125 compounds from 39 isolates of 12 genera were putatively novel. Macrolides, polyethers, diketopiperazines, and siderophores accounted for most of the known compounds. The structures of six novel compounds were elucidated, two of which had a unique skeleton and represented characteristic secondary metabolites of a putative novel Streptomyces phylotype. These results demonstrate that red soils are rich reservoirs for diverse culturable actinomycetes, notably members of the families Streptomycetaceae, Pseudonocardiaceae, and Streptosporangiaceae, with the capacity to synthesize novel bioactive compounds.     

Biosynthesis pathways for deoxysugars in antibiotic-producing actinomycetes: isolation, characterization and generation of novel glycosylated derivatives

Many bioactive natural products synthesized by actinomycetes are glycosylated compounds in which the appended sugars contribute to specific interactions with their biological target. Most of these sugars are 6-deoxyhexoses, of which more than 70 different forms have been identified, and an increasing number of gene clusters involved in 6-deoxyhexoses biosynthesis are being characterized from antibiotic-producing actinomycetes. Novel glycosylated compounds have been generated by modifying natural deoxysugar biosynthesis pathways in the producer organisms, and/or the simultaneous expression in these strains of selected deoxysugar biosynthesis genes from other strains. Non-producing strains endowed with the capacity to synthesize novel deoxysugars through the expression of engineered deoxysugar biosynthesis clusters can also be used as alternative hosts. Transfer of these deoxysugars to a multiplicity of aglycones relies upon the existence of glycosyltransferases with an inherent degree of 'relaxed substrate specificity'. In this review, we analyze how the knowledge coming out from isolation and characterization of deoxysugar biosynthesis pathways from actinomycetes is being used to produce novel glycosylated derivatives of natural products.     

PCR screening reveals considerable unexploited biosynthetic potential of ansamycins and a mysterious family of AHBA‐containing natural products in actinomycetes

Aims

Ansamycins are a family of macrolactams that are synthesized by type I polyketide synthase (PKS) using 3‐amino‐5‐hydroxybenzoic acid (AHBA) as the starter unit. Most members of the family have strong antimicrobial, antifungal, anticancer and/or antiviral activities. We aimed to discover new ansamycins and/or other AHBA‐containing natural products from actinobacteria.

Methods and Results

Through PCR screening of AHBA synthase gene, we identified 26 AHBA synthase gene–positive strains from 206 plant‐associated actinomycetes (five positives) and 688 marine‐derived actinomycetes (21 positives), representing a positive ratio of 2·4–3·1%. Twenty‐five ansamycins, including eight new compounds, were isolated from six AHBA synthase gene–positive strains through TLC‐guided fractionations followed by repeated column chromatography. To gain information about those potential ansamycin gene clusters whose products were unknown, seven strains with phylogenetically divergent AHBA synthase genes were subjected to fosmid library construction. Of the seven gene clusters we obtained, three show characteristics for typical ansamycin gene clusters, and other four, from Micromonospora spp., appear to lack the amide synthase gene, which is unusual for ansamycin biosynthesis. The gene composition of these four gene clusters suggests that they are involved in the biosynthesis of a new family of hybrid PK‐NRP compounds containing AHBA substructure.

Conclusions

PCR screening of AHBA synthase is an efficient approach to discover novel ansamycins and other AHBA‐containing natural products.

Significance and Impact of the Study

This work demonstrates that the AHBA‐based screening method is a useful approach for discovering novel ansamycins and other AHBA‐containing natural products from new microbial resources.     

西藏仲巴五彩沙漠放线菌资源勘探及生物活性筛选

【背景】细菌耐药性问题日益严峻,新抗生素的研发速度远远落后于临床需要,从特殊生境中挖掘微生物药物资源有望解决以上问题。【目的】勘探西藏仲巴五彩沙漠土壤放线菌多样性并进行生物活性筛选,为发现药用放线菌资源、开发新型抗生素奠定基础。【方法】采用8种分离培养基,通过平板稀释涂布法分离放线菌;根据分离菌株的16S r RNA基因序列同源性分析放线菌多样性;采用PCR技术对分离的放线菌菌株进行II型聚酮合酶(PKS-II)酮缩酶结构域KS、非核糖体多肽合成酶(NRPS)腺苷酸化结构域A、安莎类抗生素生物合成前体3-氨基-5-羟基-苯甲酸合酶(AHBA)保守区、黄素腺嘌呤二核苷酸卤化酶(Halo)保守区抗生素生物合成基因检测;对生物合成基因检测阳性的菌株进行液体发酵,发酵液经乙酸乙酯萃取、菌体经丙酮浸提,获得提取浓缩物样品进行抑菌活性和抗氧化活性筛选。【结果】从4份土样中分离纯化到231株放线菌,分布于7个属,其中链霉菌为优势菌属。68株放线菌的生物合成基因分析显示至少具有1种生物合成基因簇,其中6株同时具有4种生物合成基因簇;进一步的抑菌活性检测显示所有检测的菌株至少表现为对1株检定菌具有抑菌活性,其中8株具有广谱抗菌活性;抗氧化活性筛选结果为13株显示总抗氧化能力阳性,10株具有较好的羟自由基清除能力,3株显示较强的氧自由基清除能力。【结论】西藏仲巴五彩沙漠土壤中含有较丰富的放线菌药用资源,具有从中发现放线菌新菌种和开发新抗生素的潜力。     

A new method for rapid identification of ansamycin compounds by inactivating KLM gene clusters in potential ansamycin-producing actinomyces

Aims: In this study, we explored the possibility of construction of a ‘universal targeting vector’ by Red/ET recombination to inactivate L gene encoding 3‐amino‐5‐hydroxybenzoic acid (AHBA)‐oxidoreductase in AHBA biosynthetic gene cluster to facilitate the detection of ansamycins production in actinomycetes. Methods and Results: Based on the conserved regions of linked AHBA synthase (K), oxidoreductase (L) and phosphatase (M) gene clusters, degenerate primers were designed and PCR was performed to detect KLM gene clusters within 33 AHBA synthase gene‐positive actinomycetes strains. Among them, 22 KLM gene cluster‐positive strains were identified. A ‘universal targeting vector’ was further constructed using the 50‐nt homologous sequences chosen from four strains internal L gene in KLM gene clusters through Red/ET recombination. The L gene from nine of the KLM gene cluster‐positive actinomycetes strains was inactivated by insertion of a kanamycin (Km) resistance marker into its internal region from the ‘universal targeting vector’. By comparison of the metabolites produced in parent strains with those in L gene‐inactivated mutants, we demonstrated the possible ansamycins production produced by these strains. One strain (4089) was proved to be a geldanamycin producer. Three strains (3‐20, 7‐32 and 8‐32) were identified as potential triene‐ansamycins producers. Another strain (3‐27) was possible to be a streptovaricin C producer. Strains 24‐100 and 4‐124 might be served as ansamitocin‐like producers. Conclusions: The results confirmed the feasibility that a ‘universal targeting vector’ could be constructed through Red/ET recombination using the conserved regions of KLM gene clusters to detect ansamycins production in actinomycetes. Significance and Impact of the Study: The ‘universal targeting vector’ provides a rapid approach in certain degree to detect the potential ansamycin producers from the 22 KLM gene cluster‐positive actinomycetes strains.     

Distribution and Genetic Diversity of Bacteriocin Gene Clusters in Rumen Microbial Genomes

Some species of ruminal bacteria are known to produce antimicrobial peptides, but the screening procedures have mostly been based on in vitro assays using standardized methods. Recent sequencing efforts have made available the genome sequences of hundreds of ruminal microorganisms. In this work, we performed genome mining of the complete and partial genome sequences of 224 ruminal bacteria and 5 ruminal archaea to determine the distribution and diversity of bacteriocin gene clusters. A total of 46 bacteriocin gene clusters were identified in 33 strains of ruminal bacteria. Twenty gene clusters were related to lanthipeptide biosynthesis, while 11 gene clusters were associated with sactipeptide production, 7 gene clusters were associated with class II bacteriocin production, and 8 gene clusters were associated with class III bacteriocin production. The frequency of strains whose genomes encode putative antimicrobial peptide precursors was 14.4%. Clusters related to the production of sactipeptides were identified for the first time among ruminal bacteria. BLAST analysis indicated that the majority of the gene clusters (88%) encoding putative lanthipeptides contained all the essential genes required for lanthipeptide biosynthesis. Most strains of Streptococcus (66.6%) harbored complete lanthipeptide gene clusters, in addition to an open reading frame encoding a putative class II bacteriocin. Albusin B-like proteins were found in 100% of the Ruminococcus albus strains screened in this study. The in silico analysis provided evidence of novel biosynthetic gene clusters in bacterial species not previously related to bacteriocin production, suggesting that the rumen microbiota represents an underexplored source of antimicrobial peptides.     

Cloning and characterization of the polyether salinomycin biosynthesis gene cluster of Streptomyces albus XM211

Salinomycin is widely used in animal husbandry as a food additive due to its antibacterial and anticoccidial activities. However, its biosynthesis had only been studied by feeding experiments with isotope-labeled precursors. A strategy with degenerate primers based on the polyether-specific epoxidase sequences was successfully developed to clone the salinomycin gene cluster. Using this strategy, a putative epoxidase gene, slnC, was cloned from the salinomycin producer Streptomyces albus XM211. The targeted replacement of slnC and subsequent trans-complementation proved its involvement in salinomycin biosynthesis. A 127-kb DNA region containing slnC was sequenced, including genes for polyketide assembly and release, oxidative cyclization, modification, export, and regulation. In order to gain insight into the salinomycin biosynthesis mechanism, 13 gene replacements and deletions were conducted. Including slnC, 7 genes were identified as essential for salinomycin biosynthesis and putatively responsible for polyketide chain release, oxidative cyclization, modification, and regulation. Moreover, 6 genes were found to be relevant to salinomycin biosynthesis and possibly involved in precursor supply, removal of aberrant extender units, and regulation. Sequence analysis and a series of gene replacements suggest a proposed pathway for the biosynthesis of salinomycin. The information presented here expands the understanding of polyether biosynthesis mechanisms and paves the way for targeted engineering of salinomycin activity and productivity.     

Drug-induced relaxation of supercoiled plasmid DNA in Bacillus subtilis and induction of the SOS response.

Whereas treatment with many different drugs led to induction of the SOS response in Bacillus subtilis, only inhibitors of DNA gyrase subunit B and, unexpectedly, polyether antibiotics (membrane ionophores) led to relaxation of supercoiled plasmid DNA. However, treatment with DNA gyrase subunit B inhibitors but not with polyethers led to SOS induction. Thus, the presence of underwound supercoiled DNA was not sufficient to induce the SOS response. Possible mechanisms by which polyethers induce relaxation of supercoiled DNA in vivo are discussed.     

A proteomic survey of nonribosomal peptide and polyketide biosynthesis in actinobacteria

Actinobacteria such as streptomycetes are renowned for their ability to produce bioactive natural products including nonribosomal peptides (NRPs) and polyketides (PKs). The advent of genome sequencing has revealed an even larger genetic repertoire for secondary metabolism with most of the small molecule products of these gene clusters still unknown. Here, we employed a "protein-first" method called PrISM (Proteomic Investigation of Secondary Metabolism) to screen 26 unsequenced actinomycetes using mass spectrometry-based proteomics for the targeted detection of expressed nonribosomal peptide synthetases or polyketide synthases. Improvements to the original PrISM screening approach (Nat. Biotechnol. 2009, 27, 951-956), for example, improved de novo peptide sequencing, have enabled the discovery of 10 NRPS/PKS gene clusters from 6 strains. Taking advantage of the concurrence of biosynthetic enzymes and the secondary metabolites they generate, two natural products were associated with their previously "orphan" gene clusters. This work has demonstrated the feasibility of a proteomics-based strategy for use in screening for NRP/PK production in actinomycetes (often >8 Mbp, high GC genomes) versus the bacilli (2-4 Mbp genomes) used previously.     

连翘和水茄内生放线菌的多样性、活性及生物合成基因的PCR筛查

从采自成都地区的中药植物连翘Forsythia suspense和水茄Solanum torvum的根部分离到14株内生放线菌。活性筛选表明,10株菌的发酵粗提物具有不同程度的抗肿瘤活性,占全部菌株的71%;3株菌具有抗细菌活性,其中菌株A263具有较强的细胞毒活性和广谱抗细菌活性。基于16S rRNA基因部分序列的相似性分析表明,菌株A275属于克里贝拉菌属Kribbella,其余13株属于链霉菌属Streptomyces。多种生物合成基因的筛查实验表明,5株菌同时具有PKS-I、PKS-II、NRPS型基因,其中A255和A263还具有3,5-AHBA合酶基因,但仅A275具有oxyB基因。结果可以推测,链霉菌是这2种中药植物根部的优势内生放线菌,生物合成基因的PCR筛查能极大地弥补传统活性筛选模型的不足,内生放线菌具有产生丰富生物活性化合物的巨大潜力。     

Diversities Within Genotypes,Bioactivity and Biosynthetic Genes of Endophytic Actinomycetes Isolated from Three Pharmaceutical Plants

One hundred and fifty endophytic actinomycetes were isolated from three pharmaceutical plants, Annonaceae squamosal, Camptotheca acuminate and Taxus chinensis. Bioactivity test showed that 72.4% of the endophytic actinomycetes displayed inhibition against more than one indicator microorganism. In total, 9.3 and 10.7% showed the cytotoxicity and antioxidant activity, respectively. 3-Amino-5-hydroxybenzoic acid synthase (AHBA), ketosynthase (KS), cytochrome P450 hydroxylases (CYPs) and epoxidase (ES) encoding genes were found in 8.8, 23.8, 2.8 and 11.7% isolates, respectively, by genes screening. The identification based on traditional and molecular methods indicated that diverse genotypes of Streptomyces were distributed in the three pharmaceutical plants, and a few strains of Amycolatopsis were also found in the root of T. chinensis. These results indicated that endophytic actinomycetes associated with pharmaceutical plants could be a promising source of drug leads.     

Isolation of putative polyene-producing actinomycetes strains via PCR-based genome screening for polyene-specific hydroxylase genes

Polyene antibiotics, which include nystatin, pimaricin, amphotericin and candicidin, include a family of very promising antifungal polyketide compounds that are typically produced by soil actinomycetes. The presence of similar cytochrome P450 hydroxylase (CYP) genes in the biosynthetic gene clusters for these polyenes have been previously reported. Using this polyene, more than 200 independently isolated actinomycetes strains were screened by CYP-specific PCR. Four strains were isolated based on the presence of the expected size of the PCR-amplified DNA fragment in the chromosome. The nucleotide sequencing of the PCR-amplified DNA fragments showed that each of the four actinomycetes strains contained a highly homologous polyene-specific CYP gene. Each of the culture extracts from these four strains showed a typical polyene-like high-pressure liquid chromatography (HPLC) chromatogram profile, and strong antifungal activity against Candida albicans. This suggests that the polyene-specific PCR-guided genome screening approach is an efficient method for isolating potentially valuable polyene-producing actinomycetes.     

Analysis of the biosynthetic gene cluster for the polyether antibiotic monensin in Streptomyces cinnamonensis and evidence for the role of monB and monC genes in oxidative cyclization

The analysis of a candidate biosynthetic gene cluster (97 kbp) for the polyether ionophore monensin from Streptomyces cinnamonensis has revealed a modular polyketide synthase composed of eight separate multienzyme subunits housing a total of 12 extension modules, and flanked by numerous other genes for which a plausible function in monensin biosynthesis can be ascribed. Deletion of essentially all these clustered genes specifically abolished monensin production, while overexpression in S. cinnamonensis of the putative pathway-specific regulatory gene monR led to a fivefold increase in monensin production. Experimental support is presented for a recently-proposed mechanism, for oxidative cyclization of a linear polyketide intermediate, involving four enzymes, the products of monBI, monBII, monCI and monCII. In frame deletion of either of the individual genes monCII (encoding a putative cyclase) or monBII (encoding a putative novel isomerase) specifically abolished monensin production. Also, heterologous expression of monCI, encoding a flavin-linked epoxidase, in S. coelicolor was shown to significantly increase the ability of S. coelicolor to epoxidize linalool, a model substrate for the presumed linear polyketide intermediate in monensin biosynthesis.     

Multiple peptide synthetase gene clusters in Actinomycetes

Two oligonucleotide probes derived from conserved motifs in peptide synthetases were hybridized with a cosmid library of Planobispora rosea genomic DNA. Detailed characterization of the physical organization of the positive cosmids indicated the existence of at least eight unlinked contigs containing multiple fragments that hybridized to both probes. Partial sequences of PCR products from the positive cosmids confirmed the existence of peptide synthetase genes. The combined results of hybridizations and physical mapping indicate that, in all likelihood, the isolated P. rosea contigs encode over 40 putative peptide synthetase modules. Similar results were obtained on screening a cosmid library of Actinoplanes teichomyceticus DNA. Furthermore, Southern hybridizations with several actinomycete strains, belonging to different genera, indicate that most strains contain multiple hybridizing bands well in excess of the number expected from the structure of the oligopeptides produced by these strains. Even strains not reported to produce oligopeptides gave clear positive signals when examined with the probes. These results strongly suggest that actinomycetes devote a notable fraction of their genomes to the non-ribosomal synthesis of peptides, and that most strains have the genetic potential to produce more oligopeptides than are currently described.     

放线菌模块型聚酮合酶的系统发育组学分析及其在聚酮类化合物筛选中的应用

【目的】通过分析模块型聚酮合酶(polyketide synthase,PKS)的系统进化关系,阐明酮基合成酶(ketosynthase,KS)和酰基转移酶(acyltransferase,AT)序列与聚酮产物之间的关系,为放线菌天然产物的筛选提供指导。【方法】从PKSDB数据库的20个模块型PKS基因簇中调取所有KS(190个)和AT(195个)氨基酸序列,利用MEGA 4.0软件分别构建KS、AT、KS+AT 3种序列模式的系统发育树,并计算KS序列的簇内和簇间平均进化距离。设计了一对KS结构域的引物,通过PCR方法对20株活性放线菌分离菌株进行了筛选,测定了阳性菌株的KS序列,和已知的相关KS序列构建系统发育树,并对阳性菌株进行了发酵培养和代谢产物分析。【结果】放线菌来源的同一PKS的KS序列倾向于聚成一个进化枝,且按照其产物结构聚类;同一PKS的KS簇内平均进化距离小于0.300,不同PKS的KS簇间平均进化距离一般大于0.300。AT系统发育树按照其底物特异性聚成两个大的分枝;同一PKS的部分AT分别处于两个分枝,其余AT散在分布。KS+AT系统发育树则综合了KS树和AT树的拓扑结构特点。获得13株KS阳性分离菌株,它们的多数KS序列按照菌株分别聚类,其中4株菌的大部分KS各自聚成独特的簇,5株菌的大部分KS分别处在已知PKS进化枝内。从3株阳性菌中分离到预期的聚酮类产物。【结论】放线菌中KS的进化方式以垂直进化为主,而AT则以水平进化为主;KS序列与产物结构相关,且KS簇间平均进化距离可作为不同PKS的判定标准;相对于AT和KS+AT,KS系统发育组学分析更适用于指导放线菌聚酮类产物的筛选。     

不同生境放线菌的卤化酶基因分析及其对卤代产物筛选的意义

摘要：【目的】在基因水平上分析并比较陆地来源与海洋来源的放线菌产生卤化代谢产物的潜力。【方法】基于依赖黄素腺嘌呤二核苷酸的卤化酶基因筛选,从经过表型去重复的70株陆地来源和71株海洋来源的放线菌中,通过PCR筛选获得卤化酶基因片段,并进行测序鉴定;通过卤化酶氨基酸序列的系统发育分析,比较不同来源放线菌的卤化酶序列,以及海洋链霉菌和小单孢菌的卤化酶序列。另外,对卤化酶阳性菌株进行了聚酮合酶和非核糖体多肽合成酶基因的检测。【结果】本研究中36.6%的海洋放线菌具有卤化酶基因,其阳性率远高于本研究所涉及的陆地放     

Isolation and partial characterization of a cryptic polyene gene cluster in Pseudonocardia autotrophica

The polyene antibiotics, a category that includes nystatin, pimaricin, amphotericin, and candicidin, comprise a family of very promising antifungal polyketide compounds and are typically produced by soil actinomycetes. The biosynthetic gene clusters for these polyenes have been previously investigated, revealing the presence of highly similar cytochrome P450 hydroxylase (CYP) genes. Using polyene CYP-specific PCR screening with several actinomycete genomic DNAs, Pseudonocardia autotrophica was determined to contain a unique polyene-specific CYP gene. Genomic DNA library screening using the polyene-specific CYP gene probe identified a positive cosmid clone, which contained a DNA fragment of approximately 34.5 kb. The complete sequencing of this DNA fragment revealed a total of seven complete and two incomplete open reading frames, which were found to be highly similar, but still unique, when compared to previously known polyene biosynthetic genes. These results suggest that the polyene-specific screening approach may constitute an efficient method for the isolation of potentially valuable cryptic polyene biosynthetic gene clusters from various rare actinomycetes.     

Gene clusters for beta-lactam antibiotics and control of their expression: why have clusters evolved, and from where did they originate?

While beta-lactam compounds were discovered in filamentous fungi, actinomycetes and gram-negative bacteria are also known to produce different types of beta-lactams. All beta-lactam compounds contain a four-membered beta-lactam ring. The structure of their second ring allows these compounds to be classified into penicillins, cephalosporins, clavams, carbapenens or monobactams. Most beta-lactams inhibits bacterial cell wall biosynthesis but others behave as beta-lactamase inhibitors (e.g., clavulanic acid) and even as antifungal agents (e.g., some clavams). Due to the nature of the second ring in beta-lactam molecules, the precursors and biosynthetic pathways of clavams, carbapenems and monobactams differ from those of penicillins and cephalosporins. These last two groups, including cephamycins and cephabacins, are formed from three precursor amino acids that are linked into the alpha-aminoadipyl-L-cysteinyl-D-valine tripeptide. The first two steps of their biosynthetic pathways are common. The intermediates of these pathways, the characteristics of the enzymes involved, the lack of introns in the genes and bioinformatic analysis suggest that all of them should have evolved from an ancestral gene cluster of bacterial origin, which was surely transferred horizontally in the soil from producer to non-producer microorganisms. The receptor strains acquired fragments of the original bacterial cluster and occasionally inserted new genes into the clusters, which once modified, acquired new functions and gave rise to the final compounds that we know. When the order of genes in the Streptomyces genome is analyzed, the antibiotic gene clusters are highlighted as gene islands in the genome. Nonetheless, the assemblage of the ancestral beta-lactam gene cluster remains a matter of speculation.     

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.