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.     

Identification of functionally clustered nystatin-like biosynthetic genes in a rare actinomycetes, <Emphasis Type="Italic">Pseudonocardia autotrophica</Emphasis>

The polyene antibiotics, including nystatin, pimaricin, amphotericin, and candicidin, comprise a family of very valuable antifungal polyketide compounds, and they are typically produced by soil actinomycetes. Previously, using a polyene cytochrome P450 hydroxylase-specific genome screening strategy, Pseudonocardia autotrophica KCTC9441 was determined to contain genes potentially encoding polyene biosynthesis. Here, sequence information of an approximately 125.7-kb contiguous DNA region in five overlapping cosmids isolated from the P. autotrophica KCTC9441 genomic library revealed a total of 23 open reading frames, which are presumably involved in the biosynthesis of a nystatin-like compound tentatively named NPP. The deduced roles for six multi-modular polyketide synthase (PKS) catalytic domains were found to be highly homologous to those of previously identified nystatin biosynthetic genes. Low NPP productivity suggests that the functionally clustered NPP biosynthetic pathway genes are tightly regulated in P. autotrophica. Disruption of a NPP PKS gene completely abolished both NPP biosynthesis and antifungal activity against Candida albicans, suggesting that polyene-specific genome screening may constitute an efficient method for isolation of potentially valuable previously identified polyene genes and compounds from various rare actinomycetes widespread in nature.     

A bacterial artificial chromosome (BAC) genomic approach reveals partial clustering of the furanocoumarin pathway genes in parsnip

Furanocoumarins are specialized metabolites that are involved in the defense of plants against phytophagous insects. The molecular and functional characterization of the genes involved in their biosynthetic pathway is only partially complete. Many recent reports have described gene clusters responsible for the biosynthesis of specialized metabolites in plants. To investigate possible co‐localization of the genes involved in the furanocoumarin pathway, we sequenced parsnip BAC clones spanning two different gene loci. We found that two genes previously identified in this pathway, CYP71AJ3 and CYP71AJ4, were located on the same BAC, whereas a third gene, PsPT1, belonged to a different BAC clone. Chromosome mapping using fluorescence in situ hybridization (FISH) indicated that PsPT1 and the CYP71AJ3‐CYP71AJ4 clusters are located on two different chromosomes. Sequencing the BAC clone harboring PsPT1 led to the identification of a gene encoding an Fe(II) α‐ketoglutarate‐dependent dioxygenase (PsDIOX) situated in the neighborhood of PsPT1 and confirmed the occurrence of a second gene cluster involved in the furanocoumarin pathway. This enzyme metabolizes p‐coumaroyl CoA, leading exclusively to the synthesis of umbelliferone, an important intermediate compound in furanocoumarin synthesis. This work provides an insight into the genomic organization of genes from the furanocoumarin biosynthesis pathway organized in more than one gene cluster. It also confirms that the screening of a genomic library and the sequencing of BAC clones represent a valuable tool to identify genes involved in biosynthetic pathways dedicated to specialized metabolite synthesis.     

藤黄生孢链霉菌NRRL 2401遗传操作系统和基因文库的构建北大核心CSCD

【目的】建立藤黄生孢链霉菌NRRL 2401的遗传操作系统和基因文库,以便筛选次级代谢产物生物合成基因。【方法】利用大肠杆菌和链霉菌的属间接合转移的方法,以整合型载体pPM927、pSET152和复制型载体pJTU1278构建链霉菌遗传操作系统。以pCClFOS^(TM)载体,大肠杆菌EP1300^(TM)-T1~R为宿主菌构建Fosmid文库。随后,设计引物,利用"板池-行池-单克隆"的三级PCR方法对文库进行快速筛选。【结果】pPM927、pSET152和pJTU1278均成功转入藤黄生孢链霉菌NRRL 2401,其中pSET152载体的转化效率最高。构建了稳定高效的藤黄生孢链霉菌NRRL 2401的基因文库,含2880个克隆,平均插入片段大小约为35 kb,空载率小于1%,文库覆盖率为99.99%,覆盖基因组16.5倍。同时,初步筛选出可能含有吲哚霉素生物合成基因簇的9个阳性克隆。【结论】成功构建了稳定高效的藤黄生孢链霉菌NRRL 2401遗传操作系统和高质量的基因文库,为克隆该菌中次级代谢产物生物合成基因簇以及进一步遗传改造奠定了基础。     

Carboxyl-terminal domain characterization of polyene-specific P450 hydroxylase in <Emphasis Type="Italic">Pseudonocardia autotrophica</Emphasis>

A polyene compound NPP identified in Pseudonocardia autotrophica was shown to contain an aglycone identical to nystatin, but to harbor a unique disaccharide moiety that led to higher solubility and reduced hemolytic activity. Recently, it was revealed that the final step of NPP (nystatin-like polyene) biosynthesis is C10 regio-specific hydroxylation by the cytochrome P450 hydroxylase (CYP) NppL (Kim et al. [7]). Through mutation and cross-complementation, here we found that NppL preferred a polyene substrate containing a disaccharide moiety for C10 hydroxylation, while its orthologue NysL involved in nystatin biosynthesis showed no substrate preference toward mono- and disaccharide moieties, suggesting that two homologous polyene CYPs, NppL and NysL might possess a unique domain recognizing a sugar moiety. Two hybrid NppL constructs containing the C-terminal domain of NysL exhibited no substrate preference toward 10-deoxy NPP and 10-deoxy nystatin-like NysL, implying that the C-terminal domain plays a major role in differentiating the sugar moiety responsible for substrate specificity. Further C-terminal domain dissection of NppL revealed that the last fifty amino acids play a critical role in determining substrate specificity of polyene-specific hydroxylation, setting the stage for the biotechnological application of hydroxyl diversification for novel polyene biosynthesis in actinomycetes.     

Biosynthesis of a natural polyketide-isoprenoid hybrid compound, furaquinocin A: identification and heterologous expression of the gene cluster

Furaquinocin (FQ) A, produced by Streptomyces sp. strain KO-3988, is a natural polyketide-isoprenoid hybrid compound that exhibits a potent antitumor activity. As a first step toward understanding the biosynthetic machinery of this unique and pharmaceutically useful compound, we have cloned an FQ A biosynthetic gene cluster by taking advantage of the fact that an isoprenoid biosynthetic gene cluster generally exists in flanking regions of the mevalonate (MV) pathway gene cluster in actinomycetes. Interestingly, Streptomyces sp. strain KO-3988 was the first example of a microorganism equipped with two distinct mevalonate pathway gene clusters. We were able to localize a 25-kb DNA region that harbored FQ A biosynthetic genes (fur genes) in both the upstream and downstream regions of one of the MV pathway gene clusters (MV2) by using heterologous expression in Streptomyces lividans TK23. This was the first example of a gene cluster responsible for the biosynthesis of a polyketide-isoprenoid hybrid compound. We have also confirmed that four genes responsible for viguiepinol [3-hydroxypimara-9(11),15-diene] biosynthesis exist in the upstream region of the other MV pathway gene cluster (MV1), which had previously been cloned from strain KO-3988. This was the first example of prokaryotic enzymes with these biosynthetic functions. By phylogenetic analysis, these two MV pathway clusters were identified as probably being independently distributed in strain KO-3988 (orthologs), rather than one cluster being generated by the duplication of the other cluster (paralogs).     

一种适用于链霉菌异源合成基因簇同框缺失的高效方法

【背景】对抗生素生物合成途径的阐明有助于提高目标化合物的产量并开发具有更高活性的新化合物。基因的同框缺失是天然产物生物合成研究的常规手段,通过分析突变菌株积累的中间产物,可以帮助推导天然产物的合成途径及相关基因的功能。天然产物生物合成基因簇的大小一般在20 kb以上,对每个基因进行同框缺失耗时耗力,因此,优化链霉菌来源的基因同框缺失的方法有重要的意义。【目的】基于PCR-targeting重新设计了一套在链霉菌柯斯文库质粒上进行基因同框缺失的方法,实现链霉菌基因在大肠杆菌中快速、高效的基因同框缺失的技术体系。【方法】使用氨苄青霉素抗性基因bla作为PCR-targeting DNA片段的筛选标记,同时使用体外的Pac I酶切和酶连系统代替体内的Flp/FRT系统来介导同框缺失的构建。【结果】利用这种方法,在6 d内完成了米多霉素生物合成基因簇中14个基因的同框缺失。【结论】此方法与传统的PCR-targeting方法相比,构建同框缺失载体的效率明显提高;Pac I识别序列在链霉菌基因组上的稀有性使得此方法在构建抗生素生物合成基因簇必需基因的同框缺失载体上具有普适性。     

纳他霉素高产菌株Streptomyces gilvosporeus F607基因组及其生物合成基因簇分析

【背景】纳他霉素(Natamycin)是一种天然、广谱、高效的多烯大环内酯类抗真菌剂,褐黄孢链霉菌(Streptomyces gilvosporeus)是一种重要的纳他霉素产生菌。目前S. gilvosporeus基因组序列分析还未有报道,限制了该菌中纳他霉素及其他次级代谢产物合成及调控的研究。【目的】解析纳他霉素高产菌株S. gilvosporeus F607的基因组序列信息,挖掘其次级代谢产物基因资源,为深入研究该菌株的纳他霉素高产机理及生物合成调控机制奠定基础。【方法】利用相关软件对F607菌株的基因组序列进行基因预测、功能注释、进化分析和共线性分析,并预测次级代谢产物合成基因簇;对纳他霉素生物合成基因簇进行注释分析,比较分析不同菌种中纳他霉素生物合成基因簇的差异;分析预测S.gilvosporeusF607中纳他霉素生物合成途径。【结果】F607菌株基因组总长度为8482298bp,(G+C)mol%为70.95%,分别在COG、GO、KEGG数据库提取到5 062、4 428、5063个基因的注释信息。同时,antiSMASH软件预测得到29个次级代谢产物合成基因簇,其中纳他霉素基因簇与S.natalensis、S. chattanoogensis等菌株的纳他霉素基因簇相似性分别为81%和77%。除2个参与调控的sngT和sgnH基因和9个未知功能的orf基因有差异外,S. gilvosporeus F607基因簇中其他纳他霉素生物合成基因及其排列顺序与已知的纳他霉素基因簇高度一致。【结论】分析了S. gilvosporeus全基因组信息,预测了S. gilvosporeus F607中纳他霉素生物合成的途径,为从基因组层面上解析S. gilvosporeus F607菌株高产纳他霉素的内在原因提供了基础数据,为揭示纳他霉素高产的机理及工业化生产和未来新药的发现奠定了良好的基础。     

Molecular evolution of aromatic polyketides and comparative sequence analysis of polyketide ketosynthase and 16S ribosomal DNA genes from various streptomyces species

A 613-bp fragment of an essential ketosynthase gene from the biosynthetic pathway of aromatic polyketide antibiotics was sequenced from 99 actinomycetes isolated from soil. Phylogenetic analysis showed that the isolates clustered into clades that correspond to the various classes of aromatic polyketides. Additionally, sequencing of a 120-bp fragment from the gamma-variable region of 16S ribosomal DNA (rDNA) and subsequent comparative sequence analysis revealed incongruity between the ketosynthase and 16S rDNA phylogenetic trees, which strongly suggests that there has been horizontal transfer of aromatic polyketide biosynthesis genes. The results show that the ketosynthase tree could be used for DNA fingerprinting of secondary metabolites and for screening interesting aromatic polyketide biosynthesis genes. Furthermore, the movement of the ketosynthase genes suggests that traditional marker molecules like 16S rDNA give misleading information about the biosynthesis potential of aromatic polyketides, and thus only molecules that are directly involved in the biosynthesis of secondary metabolites can be used to gain information about the biodiversity of antibiotic production in different actinomycetes.     

Identification of AHBA Biosynthetic Genes Related to Geldanamycin Biosynthesis in Streptomyces hygroscopicus 17997

To clone and study the geldanamycin biosynthetic gene cluster in Streptomyces hygroscopicus 17997, we designed degenerate primers based on the conserved sequence of the ansamycin 3-amino-5-hydroxybenzoic acid (AHBA) synthase gene. A 755-bp polymerase chain reaction product was obtained from S. hygroscopicus 17997 genomic DNA, which showed high similarity to ansamycin AHBA synthase genes. Through screening the cosmid library of S. hygroscopicus 17997, two loci of separated AHBA biosynthetic gene clusters were discovered. Comparisons of sequence homology and gene organization indicated that the two AHBA biosynthetic gene clusters could be divided into a benzenic and a naphthalenic subgroup. Gene disruption demonstrated that the benzenic AHBA gene cluster is involved in the biosynthesis of geldanamycin. However, the naphthalenic AHBA genes in the genome of Streptomyces hygroscopicus 17997 could not complement the deficiency of the benzenic AHBA genes. This is the first report on the AHBA biosynthetic gene cluster in a geldanamycin-producing strain. W. He and L. Wu contributed equally to this work.     

Structural analysis and biosynthetic engineering of a solubility-improved and less-hemolytic nystatin-like polyene in Pseudonocardia autotrophica

Polyene antibiotics such as nystatin are a large family of very valuable antifungal polyketide compounds typically produced by soil actinomycetes. Previously, using a polyene cytochrome P450 hydroxylase-specific genome screening strategy, Pseudonocardia autotrophica KCTC9441 was determined to contain an approximately 125.7-kb region of contiguous DNA with a total of 23 open reading frames, which are involved in the biosynthesis and regulation of a structurally unique polyene natural product named NPP. Here, we report the complete structure of NPP, which contains an aglycone identical to nystatin and harbors a unique di-sugar moiety, mycosaminyl-(α1-4)-N-acetyl-glucosamine. A mutant generated by inactivation of a sole glycosyltransferase gene (nppDI) within the npp gene cluster can be complemented in trans either by nppDI-encoded protein or by its nystatin counterpart, NysDI, suggesting that the two sugars might be attached by two different glycosyltransferases. Compared with nystatin (which bears a single sugar moiety), the di-sugar containing NPP exhibits approximately 300-fold higher water solubility and 10-fold reduced hemolytic activity, while retaining about 50% antifungal activity against Candida albicans. These characteristics reveal NPP as a promising candidate for further development into a pharmacokinetically improved, less-cytotoxic polyene antifungal antibiotic.     

A new approach to retrieve full lengths of functional genes from soil by PCR-DGGE and metagenome walking

Metagenomes are a vast genetic resource, and various approaches have been developed to explore them. Here, we present a new approach to retrieve full lengths of functional genes from soil DNA using PCR-denaturing gradient gel electrophoresis (DGGE) followed by metagenome walking. Partial fragments of benzoate 1,2-dioxygenase alpha subunit gene (benA) were detected from a 3-chlorobenzoate (3CB)-dosed soil by PCR-DGGE, and one DGGE band induced by 3CB was used as a target fragment for metagenome walking. The walking retrieved the flanking regions of the target fragment from the soil DNA, resulting in recovery of the full length of benA and also downstream gene (benB). The same strategy retrieved another gene, tfdC, and a complete tfdC and two downstream genes were obtained from the same soil. PCR-DGGE allows screening for target genes based on their potential for degrading contaminants in the environment. This feature provides an advantage over other existing metagenomic approaches.     

Polyene antibiotic biosynthesis gene clusters

Over the past 15 years the biosynthetic gene clusters for numerous bioactive polyketides have been intensively studied and recently this work has been extended to the antifungal polyene macrolides. These compounds consist of large macrolactone rings that have a characteristic series of conjugated double bonds, as well as an exocyclic carboxyl group and an unusual mycosamine sugar. The biosynthetic gene clusters for nystatin, pimaricin, amphotericin and candicidin have been investigated in detail. These clusters contain the largest modular polyketide synthase genes reported to date. This body of work also provides insights into the enzymes catalysing the unusual post-polyketide modifications, and the genes regulating antibiotic biosynthesis. The sequences also provide clues about the evolutionary origins of polyene biosynthetic genes. Successful genetic manipulation of the producing organisms leading to production of polyene analogues indicates good prospects for generating improved antifungal compounds via genetic engineering.     

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.     

Biosynthetic Pathway of Cephabacins in Lysobacter lactamgenus: Molecular and Biochemical Characterization of the Upstream Region of the Gene Clusters for Engineering of Novel Antibiotics

The cephabacins, one of the beta-lactam antibiotics, are produced by Lysobacter lactamgenus. The previous studies the cephabacin biosynthesis were limited to a gene cluster that encodes the gene products responsible for the biosynthesis of the cephem nucleus. The long-term goal of this research is to elucidate the metabolic diversity and biosynthetic pathway of cephabacins and to design and/or discover new pharmacologically active compounds by engineering the cephabacin biosynthetic pathway in L. lactamgenus. In this study, we have cloned and sequenced a 24-kb fragment of a DNA locus upstream of the previously reported but incomplete putative ORF9 of L. lactamgenus. This contains three putative ORFs (the complete ORF9, ORF10, and ORF11) transcribed in the same direction and one putative ORF (ORF12) in the opposite direction. The isolated DNA locus extends the previously cloned part of the DNA locus containing the genes responsible for biosynthesis of the cephem nucleus up to 45 kb. The 42-kb fragment of the 45-kb gene cluster is located between a potential TATA box just upstream of the ORF11 and a termination loop just downstream of the previously reported bla gene. The complete ORF9 contains three nonribosomal peptide synthetase (NRPS) modules and one polyketide synthase (PKS) module and the ORF11 contains one NRPS module. The complete ORF9 also contains a putative thioesterase domain at the C-terminal end. We predicted the amino acid specificity of the four NRPSs by generating specificity binding pockets and expressed one of the NRPSs to confirm the amino acid specificity. The adenylation domain of the NRPS1, which is the last module of the NRPSs, showed significant amino acid specificity for L-arginine. These findings are in perfect agreement with the composition that was expected for the structure of cephabacins which contain an acetate residue, an L-arginine, and one to three L-alanines at the C-3' position of the cephem nucleus of cephabacins. The ORF10, encoding a putative ABC transporter which might be involved in conferring resistance against cephabacins, was identified between the complete ORF9 and the ORF11. Therefore, the complete ORF9, ORF10, ORF11 reported here and the other genes previously reported constitute an operon for the biosynthesis of cephabacins in L. lactamgenus. Based on our results, the biosynthetic pathways of acetate and elongated peptide moieties and a mechanism by which cephabacins are assembled by connecting the peptide moiety synthesized by the gene products of the complete ORF9 and the ORF11 to the C-3' position of the cephem nucleus synthesized by the gene products of pcbAB, pcbC, cefE, cefF, and cefD have been elucidated.     

Genetic screening strategy for rapid access to polyether ionophore producers and products in actinomycetes

Polyether ionophores are a unique class of polyketides with broad-spectrum activity and outstanding potency for the control of drug-resistant bacteria and parasites, and they are produced exclusively by actinomycetes. A special epoxidase gene encoding a critical tailoring enzyme involved in the biosynthesis of these compounds has been found in all five of the complete gene clusters of polyether ionophores published so far. To detect potential producer strains of these antibiotics, a pair of degenerate primers was designed according to the conserved regions of the five known polyether epoxidases. A total of 44 putative polyether epoxidase gene-positive strains were obtained by the PCR-based screening of 1,068 actinomycetes isolated from eight different habitats and 236 reference strains encompassing eight major families of Actinomycetales. The isolates spanned a wide taxonomic diversity based on 16S rRNA gene analysis, and actinomycetes isolated from acidic soils seemed to be a promising source of polyether ionophores. Four genera were detected to contain putative polyether epoxidases, including Micromonospora, which has not previously been reported to produce polyether ionophores. The designed primers also detected putative epoxidase genes from diverse known producer strains that produce polyether ionophores unrelated to the five published gene clusters. Moreover, phylogenetic and chemical analyses showed a strong correlation between the sequence of polyether epoxidases and the structure of encoded polyethers. Thirteen positive isolates were proven to be polyether ionophore producers as expected, and two new analogues were found. These results demonstrate the feasibility of using this epoxidase gene screening strategy to aid the rapid identification of known products and the discovery of unknown polyethers in actinomycetes.     

Butenyl-spinosyns, a natural example of genetic engineering of antibiotic biosynthetic genes

Spinosyns, a novel class of insect active macrolides produced by Saccharopolyspora spinosa, are used for insect control in a number of commercial crops. Recently, a new class of spinosyns was discovered from S. pogona NRRL 30141. The butenyl-spinosyns, also called pogonins, are very similar to spinosyns, differing in the length of the side chain at C-21 and in the variety of novel minor factors. The butenyl-spinosyn biosynthetic genes (bus) were cloned on four cosmids covering a contiguous 110-kb region of the NRRL 30141 chromosome. Their function in butenyl-spinosyn biosynthesis was confirmed by a loss-of-function deletion, and subsequent complementation by cloned genes. The coding sequences of the butenyl-spinosyn biosynthetic genes and the spinosyn biosynthetic genes from S. spinosa were highly conserved. In particular, the PKS-coding genes from S. spinosa and S. pogona have 91–94% nucleic acid identity, with one notable exception. The butenyl-spinosyn gene sequence codes for one additional PKS module, which is responsible for the additional two carbons in the C-21 tail. The DNA sequence of spinosyn genes in this region suggested that the S. spinosa spnA gene could have been the result of an in-frame deletion of the S. pogona busA gene. Therefore, the butenyl-spinosyn genes represent the putative parental gene structure that was naturally engineered by deletion to create the spinosyn genes.