Proteomic analysis of the GlnR-mediated response to nitrogen limitation in Streptomyces coelicolor M145

GlnR is the global regulator of nitrogen assimilation in Streptomyces coelicolor M145 and other actinobacteria. Two-dimensional polyacrylamide gel electrophoresis analyses were performed to identify new GlnR target genes by proteomic comparison of wild-type S. coelicolor M145 and a ΔglnR mutant. Fifty proteins were found to be differentially regulated between S. coelicolor M145 and the ΔglnR mutant. These spots were identified by nanoHPLC–ESI-MS/MS and classified according to their cellular role. Most of the identified proteins are involved in amino acid biosynthesis and in carbon metabolism, demonstrating that the role of GlnR is not restricted to nitrogen metabolism. Thus, GlnR is supposed to play an important role in the global metabolic control of S. coelicolor M145.     

珠江口沉积物来源链霉菌SCSIO 40020中bafilomycins的鉴定及其生物合成基因簇的异源表达

【目的】从珠江口沉积物来源的菌株SCSIO40020中分离bafilomycins,并对其生物合成基因簇进行克隆和异源表达研究。【方法】通过分析菌株SCSIO 40020的16S rRNA基因序列并构建系统发育树以鉴定菌种,以柱层析法和制备色谱法对次级代谢产物进行分离纯化,借助波谱学手段完成单体化合物的结构鉴定,采用生物信息学分析定位bafilomycins的生物合成基因簇,通过筛选菌株SCSIO 40020基因组的细菌人工染色体文库和接合转移将bafilomycins生物合成基因簇导入3种链霉菌进行异源表达,利用高效液相色谱检测异源表达菌株的发酵产物。【结果】菌株SCSIO 40020被鉴定为链霉菌属菌株,从其发酵产物中分离鉴定了2个单体化合物bafilomycinsA1和D。克隆了链霉菌SCSIO40020中bafilomycins的生物合成基因簇并推导了其生物合成途径,在3种链霉菌中表达产生了bafilomycins。【结论】从珠江口环境中获得了一株产生bafilomycins的链霉菌SCSIO 40020,成功建立了该菌株次级代谢产物生物合成基因簇的异源表达体系,并首次在链霉菌...     

Multiplying the heterologous production of spinosad through tandem amplification of its biosynthetic gene cluster in Streptomyces coelicolor

Heterologous expression of the biosynthetic gene cluster (BGC) is important for studying the microbial natural products (NPs), especially for those kept in silent or poorly expressed in their original strains. Here, we cloned the spinosad BGC through the Cas9-Assisted Targeting of Chromosome segments and amplified it to five copies through a ZouA-dependent DNA amplification system in Streptomyces coelicolor M1146. The resulting strain produced 1253.9 ± 78.2 μg l⁻¹ of spinosad, which was about 224-fold compared with that of the parent strain carrying only one copy of the spinosad BGC. Moreover, we further increased spinosad to 1958.9 ± 73.5 μg l⁻¹ by the dynamic regulation of intracellular triacylglycerol degradation. Our study indicates that tandem amplification of the targeted gene cluster is particularly suitable to enhance the heterologous production of valuable NPs with efficiency and simplicity.     

Carbon-Flux Distribution within Streptomyces coelicolor Metabolism: A Comparison between the Actinorhodin-Producing Strain M145 and Its Non-Producing Derivative M1146

Metabolic Flux Analysis is now viewed as essential to elucidate the metabolic pattern of cells and to design appropriate genetic engineering strategies to improve strain performance and production processes. Here, we investigated carbon flux distribution in two Streptomyces coelicolor A3 (2) strains: the wild type M145 and its derivative mutant M1146, in which gene clusters encoding the four main antibiotic biosynthetic pathways were deleted. Metabolic Flux Analysis and ¹³C-labeling allowed us to reconstruct a flux map under steady-state conditions for both strains. The mutant strain M1146 showed a higher growth rate, a higher flux through the pentose phosphate pathway and a higher flux through the anaplerotic phosphoenolpyruvate carboxylase. In that strain, glucose uptake and the flux through the Krebs cycle were lower than in M145. The enhanced flux through the pentose phosphate pathway in M1146 is thought to generate NADPH enough to face higher needs for biomass biosynthesis and other processes. In both strains, the production of NADPH was higher than NADPH needs, suggesting a key role for nicotinamide nucleotide transhydrogenase for redox homeostasis. ATP production is also likely to exceed metabolic ATP needs, indicating that ATP consumption for maintenance is substantial.Our results further suggest a possible competition between actinorhodin and triacylglycerol biosynthetic pathways for their common precursor, acetyl-CoA. These findings may be instrumental in developing new strategies exploiting S. coelicolor as a platform for the production of bio-based products of industrial interest.     

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

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

窖泥优势拟杆菌纲微生物Petrimonas sulfuriphila的分离及其功能解析

[目的]筛选窖泥中尚未被纯培养的高丰度拟杆菌纲微生物,并在纯培养菌株层面和共培养层面探究其生理代谢特征及生态学功能。[方法]采用传代培养提高窖泥拟杆菌纲微生物的相对丰度,在此基础上进行筛菌实验,并通过发酵实验解析主体拟杆菌的代谢特征及其与主体己酸菌的相互作用关系。[结果]成功筛选到Petrimonas sulfuriphila LBM11005,该菌的主要代谢产物为乙酸和丙酸,且葡萄糖能促进该菌的生长。无论是否存在底物竞争效应,P. sulfuriphila LBM11005均能与窖泥主体己酸菌Caproicibacterium sp. LBM19010在代谢物水平上发生相互作用,表现为后者可以利用前者的代谢产物丙酸进行碳链延伸,产生新的奇数碳脂肪酸——戊酸和庚酸。[结论]探明了窖泥主体拟杆菌纲微生物P. sulfuriphila LBM11005的基本生理代谢特征,且该菌与主体己酸菌相互作用,贡献于更长碳链奇数碳脂肪酸的合成。     

基于基因组挖掘的农抗120活性成分制霉菌素和丰加霉素的发现和鉴定

【目的】分析刺孢吸水链霉菌北京变种(农抗120产生菌)基因组和次级代谢产物组分,研究并鉴定农抗120产生菌中未被发现的活性组分。【方法】利用antiSMASH在线分析农抗120产生菌Streptomyces hygrospinosusvar.beijingensis基因组信息,锁定可能的制霉菌素和丰加霉素生物合成基因簇。利用HPLC和LC-MS等分析方法对农抗120产生菌发酵产物进行分析,同时利用制霉菌素和丰加霉素标准品作为对照,以鉴定该菌株代谢组分中的次级代谢产物。此外,通过构建目标基因簇大片段缺失突变株,并对所得突变株发酵产物进行检测,以确定生物合成基因簇与目的代谢产物的对应关系。【结果】本研究综合利用基因组序列分析、基因缺失突变株构建以及代谢产物检测方法,鉴定了农抗120产生菌中制霉菌素和丰加霉素两种活性成分,并确定了负责这些化合物合成的基因簇。【结论】本研究所构建的多重基因簇失活突变株为挖掘刺孢吸水链霉菌北京变种更多的天然次级代谢产物奠定了基础。     

放线菌中亮氨酸应答调控蛋白的生物学功能及其调控机理

放线菌是一类革兰氏阳性细菌,可产生氨基酸等初级代谢产物和抗生素等次级代谢产物,其广泛用于食品、医药、添加剂及化妆品行业。此外,还有少数放线菌,如分枝杆菌等,是可以引起人和动植物病害的病原菌。亮氨酸应答调控蛋白(Leucine-responsive regulatory protein,Lrp)是一类在氨基酸代谢及其相关代谢过程中的重要转录调控子,能够应答各种氨基酸,参与调控微生物细胞的多个生理过程,例如氨基酸代谢和转运、中心代谢、细菌的持久性和毒力等。本文总结了放线菌Lrp的生物学功能,并综述了放线菌中不同种属Lrp以及天蓝色链霉菌和红色糖多孢菌Lrp调控机理的研究进展。     

染色体DNA琼脂糖包埋法辅助的ExoCET技术克隆放线菌天然产物生物合成基因簇

【目的】本研究旨在通过将琼脂糖包埋染色体DNA的方法与ExoCET重组技术相结合,建立放线菌天然产物生物合成基因簇的捕获方法。然后将克隆基因簇导入通用底盘宿主中,实现目标生物合成基因簇的异源表达。【方法】首先,利用低熔点琼脂糖包埋技术制备菌株的染色体基因组总DNA,再用限制性内切酶消化含有染色体DNA的琼脂块,获得线性化的DNA样品;然后利用ExoCET重组技术,以p15A线性载体片段将目标基因簇线性片段进行捕获;再通过PCR-targeting的方法向目标质粒中引入所需的接合转移DNA元件。接着,将改造质粒通过接合转移导入到Streptomyces coelicolor M1252宿主中,获得不同的重组菌株。最后,对不同的菌株进行发酵并提取化合物,最后进行活性检测以及质谱检测。【结果】通过该方法,从菌株S.lincolnensisNRR2936中成功获得了林可霉素生物合成基因簇(lmb-BGC),从菌株Nonomuraea nitratireducens WYY166^T中克隆得到了2个核糖体肽类化合物的生物合成基因簇(nioblantin,niob-BGC和nitblantin,nitb-BGC),并实现了lmb-BGC在天蓝色链霉菌M1252中的成功表达。【结论】本研究通过将低熔点琼脂糖包埋技术与ExoCET重组技术进行合理整合,定向克隆得到了林可霉素以及2个新颖的羊毛硫肽类化合物的生物合成基因簇。然后,分别对重组质粒改造后,在天蓝色链霉菌M1252宿主中进行表达,分别获得重组菌株MJX01、MJX02和MJX04。最后,利用质谱以及活性测试的手段对发酵提取物进行了检测,确定了林可霉素生物合成基因簇在天蓝色链霉菌M1252中成功表达。本研究为通过基因簇克隆和异源表达发掘新化合物奠定了基础。     

Generation and study of the strains of streptomycetes-heterologous hosts for the production of moenomycin

Heterologous expression of the moenomycin biosynthesis gene cluster (moe) would be one of the ways to reach this goal. Here, we report the generation of a number of novel heterologous streptomycete hosts producing nosokomycin A₂ (one of the members of Mm family) and determine their potential for the antibiotic production. The rpoB point mutation in the model strain of Streptomyces coelicolor (strain M1152) significantly improved nosokomycin A₂ production compared to parental strains (M145 and M512), while double rpoBrpsL mutation in the same species (strain M1154) decreased it. Our results point to the previously unanticipated epistatic interactions between mutations that individually are known to be highly beneficial for antibiotic production. We also showed here for the first time that facultative chemolitotrophic streptomycete S. thermospinosisporus and chloramphenicol producer S. venezuelae can be used as the hosts for moe genes.     

Analysis of intracellular metabolites of Corynebacterium glutamicum at high cell density with automated sampling and filtration and assessment of engineered enzymes for effective l‐lysine production

Engineering of enzymes and pathways is generally required for the development of efficient strains for bioproduction processes. To this end, quantitative and reliable data of intracellular metabolites are highly desired, but often not available, especially for conditions more close to industrial applications, i.e. at high cell density and product concentration. Here, we investigated the intracellular metabolite profiles of an engineered l ‐lysine‐producing Corynebacterium glutamicum strain and the corresponding wild‐type strain to assess the impacts of deregulation of product inhibition of the key enzymes aspartate kinase and phosphoenolpyruvate carboxylase and to identify potentials for their further improvement. A bioreactor system with automated fast‐sampling, filtration and on‐filter quenching of the metabolism was used for a more reliable determination of intracellular metabolites in batch cultures with optical cell density (OD₆₆₀) up to 40. The l ‐lysine‐producing strain showed substantially different metabolite profiles in the amino acid metabolism, including increased intracellular pool sizes in the l ‐lysine‐, l ‐homoserine‐ and l ‐threonine pathways and decreased intracellular pool sizes for all other determined amino acids. By comparing data of in vitro inhibition of the engineered enzymes and determined intracellular concentrations of the inhibitors it was found that the inferred in vivo activities of these enzymes are still significantly below their in vitro maximums. This work demonstrates the usefulness of metabolic analysis for assessing the impact of engineered enzymes and identifying targets for further strain development.     

HIGH AFFINITY UPTAKE OF TRANSMITTERS: STUDIES ON THE UPTAKE OF l-ASPARTATE, GABA, l-GLUTAMATE AND GLYCINE IN CAT SPINAL CORD

Abstract— The uptake of l -aspartate, l -glutamate and glycine each appeared to be mediated by two kinetically distinct systems with apparent K_m's of the order of 10 ('high affinity') and 100 μM ('low affinity') in slices of cat spinal cord, whereas the uptake of GABA appeared to be mediated by a single system of high affinity. The high affinity uptake of these amino acids in slices of spinal grey matter was approximately 5 times faster than that in slices of spinal white matter. The high affinity uptake systems in the cord slices survived homogenisation of the tissue under conditions known to preserve nerve terminals. Subcellular fractionation studies indicated that osmotically-sensitive particles of equilibrium density equivalent to that of 1.0 m -sucrose were at least in part responsible for the uptake of these amino acids. Inhibition studies indicated that three structurally specific systems of high affinity transported these amino acids:

• 1 specific for glycine—not inhibited by GABA or any of the other depressant amino acids found in cat spinal cord;
• 2 specific for GABA—not inhibited by glycine, taurine, l -aspartate or l -glutamate and (3) specific for l -aspartate and l -glutamate—not inhibited by glycine or GABA but strongly inhibited by various acidic amino acids such as l -cysteate and l -cysteine sulphinate.

The high affinity uptake of these amino acids was not inhibited by any of the known antagonists of the postsynaptic actions of these amino acids—strychnine (glycine), bicuculline and benzyl penicillin (GABA), methioninesulphoximine and l -glutamate diethyl ester (l -aspartate and l -glutamate). p-Chloromercuriphenylsulphonate strongly inhibited the high affinity uptake of glycine and GABA but was much less effective as an inhibitor of l -aspartate/l -glutamate high affinity uptake. This is in good agreement with microelectrophoretic studies in which this mercurial was found to potentiate depression of neuronal firing induced by glycine and GABA much more readily than excitation induced by l -aspartate or l -glutamate. These findings suggest the importance of high affinity transport processes in the removal of amino acids from the synaptic environment.     

Sequence analysis and heterologous expression of the lincomycin biosynthetic cluster of the type strain <Emphasis Type="Italic">Streptomyces lincolnensis</Emphasis> ATCC 25466

A cosmid bearing an insert of 38 217 bp covering the gene cluster and its flanking regions of type strain Streptomyces lincolnensis ATCC 25466 was sequenced. Two relatively extensive sequence changes and several hundred point mutations were identified if compared with the previously published sequence of the lincomycin (Lin) industrial strain S. lincolnensis 78-11. Analysis of the cluster-flanking regions revealed its localization within the genome of the ATCC 25466 strain. The cluster-bearing cosmid was integrated into the chromosome of Lin non-producing strains S. coelicolor CH 999 and S. coelicolor M 145. The modified strains heterologously produced Lin but the level dropped to ≈1–3 % of the production in the ATCC 25466 strain.     

Metabolic profiles of sunflower genotypes with contrasting response to Sclerotinia sclerotiorum infection

We report a comprehensive primary metabolite profiling of sunflower (Helianthus annuus) genotypes displaying contrasting behavior to Sclerotinia sclerotiorum infection. Applying a GC-MS-based metabolite profiling approach, we were able to identify differential patterns involving a total of 63 metabolites including major and minor sugars and sugar alcohols, organic acids, amino acids, fatty acids and few soluble secondary metabolites in the sunflower capitulum, the main target organ of pathogen attack. Metabolic changes and disease incidence of the two contrasting genotypes were determined throughout the main infection period (R5.2-R6). Both point-by-point and non-parametric statistical analyses showed metabolic differences between genotypes as well as interaction effects between genotype and time after inoculation. Network correlation analyses suggested that these metabolic changes were synchronized in a time-dependent manner in response to the pathogen. Concerted differential metabolic changes were detected to a higher extent in the susceptible, rather than the resistant genotype, thereby allowing differentiation of modules composed by intermediates of the same pathway which are highly interconnected in the susceptible line but not in the resistant one. Evaluation of these data also demonstrated a genotype specific regulation of distinct metabolic pathways, suggesting the importance of detection of metabolic patterns rather than specific metabolite changes when looking for metabolic markers differentially responding to pathogen infection. In summary, the GC-MS strategy developed in this study was suitable for detection of differences in carbon primary metabolism in sunflower capitulum, a tissue which is the main entry point for this and other pathogens which cause great detrimental impact on crop yield.     

A cryptic type I polyketide synthase (cpk) gene cluster in Streptomyces coelicolor A3(2)

The chromosome of Streptomyces coelicolor A3(2), a model organism for the genus Streptomyces, contains a cryptic type I polyketide synthase (PKS) gene cluster which was revealed when the genome was sequenced. The ca. 54-kb cluster contains three large genes, cpkA, cpkB and cpkC, encoding the PKS subunits. In silico analysis showed that the synthase consists of a loading module, five extension modules and a unique reductase as a terminal domain instead of a typical thioesterase. All acyltransferase domains are specific for a malonyl extender, and have a B-type ketoreductase. Tailoring and regulatory genes were also identified within the gene cluster. Surprisingly, some genes show high similarity to primary metabolite genes not commonly identified in any antibiotic biosynthesis cluster. Using western blot analysis with a PKS subunit (CpkC) antibody, CpkC was shown to be expressed in S. coelicolor at transition phase. Disruption of cpkC gave no obvious phenotype.     

Quorum sensing-based metabolic engineering of the precursor supply in Streptomyces coelicolor to improve heterologous production of neoaureothin

Streptomyces are important industrial bacteria that produce pharmaceutically valuable polyketides. However, mass production on an industrial scale is limited by low productivity, which can be overcome through metabolic engineering and the synthetic biology of the host strain. Recently, the introduction of an auto-inducible expression system depending on microbial physiological state has been suggested as an important tool for the industrial-scale production of polyketides. In this study, titer improvement by enhancing the pool of CoA-derived precursors required for polyketide production was driven in a quorum sensing (QS)-dependent manner. A self-sustaining and inducer-independent regulatory system, named the QS-based metabolic engineering of precursor pool (QMP) system, was constructed, wherein the expression of genes involved in precursor biosynthesis was regulated by the QS-responsive promoter, scbAp. The QMP system was applied for neoaureothin production in a heterologous host, Streptomyces coelicolor M1152, and productivity increased by up to 4-fold. In particular, the engineered hyperproducers produced high levels of neoaureothin without adversely affecting cell growth. Overall, this study showed that self-regulated metabolic engineering mediated by QS has the potential to engineer strains for polyketide titer improvement.     

Glucose kinase of Streptomyces coelicolor A3(2): large-scale purification and biochemical analysis

Glucose kinase of Streptomyces coelicolor A3(2) is essential for glucose utilisation and is required for carbon catabolite repression (CCR) exerted through glucose and other carbon sources. The protein belongs to the ROK-family, which comprises bacterial sugar kinases and regulators. To better understand glucose kinase function, we have monitored the cellular activity and demonstrated that the choice of carbon sources did not significantly change the synthesis and activity of the enzyme. The DNA sequence of the Streptomyces lividans glucose kinase gene glkA was determined. The predicted gene product of 317 amino acids was found to be identical to S. coelicolor glucose kinase, suggesting a similar role for this protein in both organisms. A procedure was developed to produce pure histidine-tagged glucose kinase with a yield of approximately 10 mg/l culture. The protein was stable for several weeks and was used to raise polyclonal antibodies. Purified glucose kinase was used to explore protein-protein interaction by surface plasmon resonance. The experiments revealed the existence of a binding activity present in S. coelicolor cell extracts. This indicated that glucose kinase may interact with (an)other factor(s), most likely of protein nature. A possible cross-talk with proteins of the phosphotransferase system, which are involved in carbon catabolite repression in other bacteria, was investigated.     

Genetic analysis of the φC31 -specific phage growth limitation (Pgl) system of Streptomyces coelicolor A3(2)

The phage growth limitation (Pgl) system of Streptomyces coelicolor A3(2) was shown to be specific to φC31 homo-immune phages, and to be absent from the closely related strain Streptomyces Iividans. A 16 kb fragment of S. coelicolor A3(2) DNA was isolated which complemented the Pgl^? phenotype of J1501, a pgl mutant derivative of the Pgl^tsS. coelicolor strain M130. The cloned DNA complemented only half of the available pgl mutants, which therefore represented at least two groups, designated Pgl class A and class B strains. It follows that more than one kind of high-frequency genetic event can lead to the Pgl^? phenotype. Crosses between class A and class B strains yielded high frequencies of Pgl⁺ recombinants. Crosses between strains of the same class gave no Pgl⁺ recombinants. The cloned DNA was altered by deletion or apparent point mutation upon passage through the two class B strains tested, such that it was no longer capable of complementing class A strains. This accumulation of mutations might suggest that the expression of the cloned DNA is toxic to at least some class B strains. The nature of the genetic instability associated with the Pgl system was not detectable by Southern blot analysis.     

Biotransformation of albendazole by Cunninghamella blakesleeana: effect of carbon and nitrogen source

A filamentous fungus Cunninghamella blakesleeana was screened for its ability to biotransform the anthelmintic drug albendazole. The fungus produced three metabolites in the presence of the carbon and nitrogen sources studied. The transformation was identified by HPLC and the structures of the transformation products were assigned by LC-MS-MS analysis and on the basis of previous reports. The results indicated that the fungus metabolized albendazole into albendazole sulfoxide (M1), albendazole sulfone (M2) and an N-methyl metabolite of albendazole sulfoxide (M3). The effect of carbon and nitrogen source on the biotransformation of albendazole was significant. Among the carbon and nitrogen sources studied, fructose and urea respectively produced maximum extent of biotransformation in terms of substrate depletion. Among the carbon sources studied, maltose produced a higher percentage of M1 whereas M2 and M3 were produced to their maximum extent in presence of d-fructose in terms of metabolite per unit quantity of biomass. In the case of nitrogen sources, ammonium acetate, calcium nitrate and barium nitrate produced maximum percentage of M1, M2 and M3 respectively. The results reveal that the carbon and nitrogen source significantly influence the microbial transformation both qualitatively and quantitatively.     

Identification and Heterologous Expression of the Chaxamycin Biosynthesis Gene Cluster from Streptomyces leeuwenhoekii

Streptomyces leeuwenhoekii, isolated from the hyperarid Atacama Desert, produces the new ansamycin-like compounds chaxamycins A to D, which possess potent antibacterial activity and moderate antiproliferative activity. We report the development of genetic tools to manipulate S. leeuwenhoekii and the identification and partial characterization of the 80.2-kb chaxamycin biosynthesis gene cluster, which was achieved by both mutational analysis in the natural producer and heterologous expression in Streptomyces coelicolor A3(2) strain M1152. Restoration of chaxamycin production in a nonproducing ΔcxmK mutant (cxmK encodes 3-amino-5-hydroxybenzoic acid [AHBA] synthase) was achieved by supplementing the growth medium with AHBA, suggesting that mutasynthesis may be a viable approach for the generation of novel chaxamycin derivatives.