Differential Regulation of rsmA Gene on Biosynthesis of Pyoluteorin and Phenazine-1-carboxylic Acid in Pseudomonas sp. M18

Summary Plant growth promoting rhizobacteria (PGPR) strain Pseudomonas sp. M18 can produce two different types of antibiotics, pyoluteorin (Plt) and phenazine-1-carboxylic acid (PCA). The global regulator RsmA is a translational repressor of secondary metabolism in many prokaryotes. A chromosomally rsmA inactivated mutant strain M18R was constructed to study the regulatory mechanism of Plt and PCA biosynthesis and enhancement of Plt or PCA production in Pseudomonas sp. M18. The accumulation of Plt increased six-fold over that of the wild-type strain whereas PCA production was not significantly affected in cultures of M18R. Plt production was inhibited completely but PCA biosynthesis was not altered after complementation with rsmA gene in trans in the strain of M18R. The differential activity of rsmA gene on these two operons was further confirmed by the analysis of β-galactosidase activities from translational phzA′-′lacZ and pltA′-′lacZ fusion, in which phzA is the first enzyme gene of the phenazine biosynthesis pathway and pltA is the first gene of the pyoluteorin biosynthesis pathway. The results indicate that RsmA can control Plt production negatively but not PCA production in M18, and show that the global regulator RsmA does not repress the biosynthesis of all secondary metabolites.     

RNA聚合酶σ^38亚基缺失对假单胞菌抗生物质合成代谢的影响

设计引物从假单胞菌M18基因组DNA中扩增并获得rpoS基因的378bp保守区段。以此为探针,从假单胞菌基因组文库中克隆了包括rpoS基因全序列及其相邻序列的3·1kbEcoRⅠ-XhoⅠ片段。通过抗性基因(抗庆大霉素基因)的定点插入构建了σ38亚基缺失突变株M18S。HPLC检测结果显示,σ38亚基缺失引起该菌株的抗生物质合成代谢的显著变化。与野生株相比,缺失突变株的吩嗪-1-羧酸在PPM和KMB中2种培养基中合成量由58μg/mL和10·2μg/mL分别减少到20·4μg/mL和0μg/mL;而缺失突变株的藤黄绿脓菌素则相反,在PPM和KMB两种培养基中合成量由0·5μg/mL和20·5μg/mL分别提高到75·4μg/mL和185·6μg/mL。表明σ38亚基可区别性调控假单胞菌M18的抗生物质合成代谢。rpoS基因的互补实验和两种抗生素基因与β-半乳糖苷酶基因的翻译融合表达实验进一步验证了上述的结果:σ38亚基正调控吩嗪-1-羧酸的表达,而负调控藤黄绿脓菌素的表达。     

假单胞菌gacA插入突变对藤黄绿脓菌素和吩嗪-1-羧酸合成代谢的差异性调控

假单胞菌株M18分泌藤黄绿脓菌素 (Pyoluteorin ,Plt )和吩嗪 1 羧酸 (Phenazine 1 carboxylicacid ,PCA)并抑制多种植物病菌的生长。从M18中克隆双基因调控系统gacS gacA的组成基因gacA ,并构建了该基因抗性插入突变株M18G。在KMB培养基中 ,M18G合成Plt的能力受到完全抑制 ,而PCA的积累约比野生型提高 31倍左右。Plt合成基因簇突变株M18T和在M18G基础上构建的PCA合成基因簇突变株M18GA的Plt和PCA合成的动力学变化表明 ,在M18G菌株中 ,Plt合成的抑制并不引起PCA的过量积累 ,PCA的过量积累也不引起Plt合成的抑制。由此推测 ,gacA在基因表达的水平上全局性地执行着调控功能     

假单胞菌M18调控因子GacA与RsmA的相关性及对抗生物质合成代谢调控机制的分析

假单胞菌M18是一株可同时合成并分泌吩嗪-1-羧酸(Phenazine-1-carboxylic acid,PCA)和藤黄绿脓菌素(Pyoluteorin,Plt)两种抗生物质的生防菌株。为了进一步研究假单胞菌M18抗生物质合成代谢的调控方式与机制,在分别构建gacAr、smA等单基因突变株基础上,又构建了gacArsmA双基因突变株M18GR以及gacA′-l′acZ和rsmA′-′lacZ等翻译融合表达载体(pMEGA和pMERA)。通过在PPM和KMB两种培养基中发酵培养和两种抗生物质PCA和Plt的HPLC定量测定显示,双突变株M18GR的PCA和Plt的合成量不论在PPM还是在KMB培养基中都介于单突变株M18G和M18R之间。由实验结果分析推测,两种调控因子对抗生物质合成的调控作用不是发生在转录水平,很可能发生在转录后水平。由β-半乳糖苷酶的定量分析表明,在假单胞菌M18中,两种调控因子不存在自诱导机制;虽然GacA未调控RsmA的合成,但RsmA可能部分正向调控GacA的表达。     

假单胞菌株M18 psrA突变株的构建及其对吩嗪-1-羧酸和藤黄绿菌素合成的调控

【目的】假单胞菌M18是一株能同时合成吩嗪-1-羧酸(PCA)和藤黄绿菌素(Plt)两种抗生素的植物根际促生细菌。PsrA为细菌TetR家族转录调控因子。为了研究PsrA对PCA与Plt生物合成的影响,从M18菌株基因组中扩增psrA基因。【方法】通过同源重组技术,构建庆大霉素抗性片段置换psrA的突变菌株M18psrA。利用基因互补、lacZ报告基因融合分析实验,验证PsrA对抗生素合成基因的调控作用。【结果】在PPM和KMB培养基中,分别比较野生型菌株M18和突变菌株M18psrA的PCA与Plt产量,突变菌株M18psrA的PCA产量显著下降;Plt产量显著升高,为野生型菌株的10-15倍。基因互补、lacZ报告基因融合分析,进一步证明了psrA正调控PCA的phz2合成基因簇,负调控Plt的合成基因簇。【结论】PsrA区别性调控抗生素PCA与Plt的生物合成。     

假单胞菌M18株pltZ基因转录阻抑藤黄绿菌素ABC转运系统

假单胞菌(Pseudomonassp .)M18株的藤黄绿菌素(Pyoluteorin ,Plt )生物合成基因簇下游存在一个Plt生物合成负调控基因pltZ和一个负责Plt分泌及自身抗性的ABC(ATP_bindingcassette)转运系统基因簇。利用启动子探针载体pME6 0 15和pME6 5 2 2分别构建ABC转运基因pltH与lacZ的翻译和转录融合表达质粒pHZLF和pHZCF ,分别引入野生型假单胞菌M18株和pltZ突变菌株M18Z。半乳糖苷酶活性的测定结果表明:在pltZ突变株M18Z中,pltH’-‘lacZ翻译融合表达水平约比野生型提高3 7～8 4倍,pltH’‘lacZ转录融合表达水平显著提高了2 8～7 4倍,表明pltZ能在转录水平上阻抑PltABC转运系统的表达,pltZ很可能通过阻抑PltABC转运系统的表达,间接地负调控Plt的生物合成     

Autoinduction of RpoS Biosynthesis in the Biocontrol Strain <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. M18

The rpoS gene from Pseudomonas sp. M18, which encodes predicted protein (an alternative sigma factor s, σ^S, or σ³⁸) with 99.5% sequence identity with RpoS from Pseudomonas aeruginosa PAO1, was first cloned. In order to investigate the mechanism of rpoS expression, an rpoS null mutant, named M18S, was constructed with insertion of aacC1 cassette bearing a gentamycin resistance gene. With introduction of a plasmid containing an rpoS′–′lacZ translational fusion (pMERS) to wild-type strain M18 or M18S, it was first found that β-galactosidase activity expressed in strain M18S (pMERS) decreased to fourfold of that expressed in the strain M18 (pMERS). When strain M18S (pMERS) was introduced with another plasmid pBBS containing the wild-type rpoS gene, its β-galactosidase expression level was enhanced and almost restored to that in strain M18 (pMERS). Similarly, expression of β-galactosidase from a chromosomal fusion of the promoter of the wild-type rpoS gene with lacZ (rpoS–lacZ) was enhanced fivefold in the presence of a plasmid with the wild-type rpoS gene. With these findings, it is suggested that RpoS sigma factor may be involved in autoinducing its own gene expression in Pseudomonas sp. M18.     

假单胞菌M18 relA 突变株的构建及其对吩嗪-1-羧酸合成的调控

假单胞菌M18是一株能同时合成吩嗪-1-羧酸(PCA)和藤黄绿菌素两种抗生素的植物根际分离细菌。RelA催化合成的效应分子ppGpp能介导细菌因营养饥饿引起的应激反应。以M18菌株染色体DNA为模板,PCR扩增获得relA基因,通过庆大霉素抗性片段插入失活与同源重组技术,构建假单胞菌M18的relA突变菌株M18RAG。在PPM培养基中进行PCA发酵分析,发现突变菌株M18RAG的PCA产量显著升高,约为野生型菌株的1.5-2倍。relA基因反式互补实验以及phzA′-′lacZ翻译融合测定结果,均进一步证明了RelA对PCA生物合成及其基因表达具有抑制作用。     

Optimization of phenazine-1-carboxylic acid production by a gacA/qscR-inactivated Pseudomonas sp. M18GQ harboring pME6032Phz using response surface methodology

Phenazine-1-carboxylic acid (PCA) production was enhanced in Pseudomonas sp. M18 wild strain and its mutants carrying recombinant pME6032Phz for phz gene cluster overexpression, among which Pseudomonas sp. strain M18GQ/pME6032Phz, a gacA and qscR double gene chromosomally inactivated mutant harboring pME6032Phz, showed the highest PCA yield. The conditions for fermentation and isopropyl-β-d-1-thiogalactopyranoside (IPTG) induction were optimized for strain M18GQ/pME6032Phz in shake flask experiments. A one-factor-at-a-time approach, followed by a fractional factorial design identified soybean meal, corn steep liquor, and ethanol as statistically significant factors. Optimal concentrations and mutual interactions of the factors were then determined by the method of steepest ascent and by response surface methodology based on the center composite design. The predicted PCA production was 6,335.2 mg/l after 60 h fermentation in the optimal medium of 65.02 g soybean meal, 15.36 g corn steep liquor, 12 g glucose, 21.70 ml ethanol, and 1 g MgSO₄ per liter in the flask fermentations, with induction of 1.0 mmol/l IPTG 24 h after inoculation. In an experimental validation under these conditions, the maximum PCA production was 6,365.0 mg/l. This represents a ∼60% increase over production by strain M18GQ in optimal conditions. The negative effect of plasmid pME6032 on the expression of chromosomally located phz gene cluster was found in Pseudomonas sp. M18GQ, and the possible reason was discussed in the text.     

藤黄绿脓菌素的自诱导及假单胞菌M18抗生物质代谢相关性初步分析

假单胞菌M18的生防功能归功于其分泌吩嗪-1-羧酸和藤黄绿脓菌素。为了研究抗生物质合成代谢相关性及调控机制,分别构建了两种抗生物质合成基因簇插入突变株M18T和M18Z1。用翻译融合表达载体pMEAZ(pltA′-′lacZ)分别转化野生株和突变株M18T、发酵培养并测定β-半乳糖苷酶活性,结果显示,添加藤黄绿脓菌素使突变株M18T(pMEAZ)的β-半乳糖苷酶活性比野生株M18(pMEAZ)增加约6倍,表明藤黄绿脓菌素对自身基因簇具正向自诱导作用。抗生物质的测定结果显示,突变株M18T无藤黄绿脓菌素合成,而吩嗪-1-羧酸的合成量与野生株相同;突变株M18Z1与野生株相比,吩嗪-1-羧酸明显减少,藤黄绿脓菌素却显著提高。过量的吩嗪-1-羧酸又抑制藤黄绿脓菌素的合成。表明,假单胞菌M18中独有的代谢相关方式为:藤黄绿脓菌素不影响吩嗪-1-羧酸,但吩嗪-1-羧酸负调控藤黄绿脓菌素。     

Las-like quorum-sensing system negatively regulates both pyoluteorin and phenazine-1-carboxylic acid production in Pseudomonas sp. M18

A las-like quorum-sensing system in Pseudomonas sp. M18 was identified, which consisted of lasI and lasR genes encoding LuxI-LuxR type regulator. Several functions of the las system from strain M18 were investigated in this study. The chromosomal inactivation of either lasI or lasR by recombination increased the production of both pyoluteorin (Plt) and phenazine-1-carboxylic acid (PCA) by 4－5 fold and 2－3 fold over that of the wild type strain of M18, respectively. Production of both antibiotics was restored to wild-type levels after in trans complementation with the wild-type lasI or lasR gene. Ex-pression of the translational fusions pltA&#1523;-&#1523;lacZ and phzA&#1523;-&#1523;lacZ further confirmed the negative effect of lasI or lasR on both biosynthetic operons, and it was also demonstrated that the las system was related to the ability of swarming motility and the inhibition of cell growth.     

假单胞菌M-18qscR突变株的构建及其对抗生素合成的调控

在革兰氏阴性菌中,全局性调控因子QscR参与菌群传感调节系统,调节多种毒素因子、次生代谢产物、稳定期基因以及参与生物膜形成的基因的表达,它通过与靶基因DNA启动子的调节元件结合,调节基因转录。假单胞菌株(Pseudomonas sp.)M-18是促进植物生长的根际细菌,能同时分泌藤黄绿菌素(pyoluterion,Plt)和吩嗪-1-羧酸(phenazine-1-carboxylicacid,PCA)。运用同源重组技术,构建了假单胞菌(Pseudomonas sp.)M-18株的qscR突变菌株M-18Q。比较野生株M-18和突变株M-18Q生物合成PCA和Plt的产量,在28℃恒温条件下,在PPM和KMB培养基中M-18Q菌株合成PCA的量分别约为野生型M-18菌株的4～6倍和3～5倍,分别达到480μg/mL和140μg/mL。在PPM培养基中,野生株M-18和突变株M-18Q几乎都没有Plt的合成,而在KMB培养基中,突变菌株和野生型M-18合成Plt的量基本一致。反式互补实验表明,在qscR突变株M-18Q中,PCA生物合成受到抑制而Plt的生物合成却不受影响。phzA基因是吩嗪合成基因簇中第一个基因,phzA‘-’lacZ翻译融合实验表明,qscR基因产物通过抑制PCA合成基因簇的表达,实施负调控作用。结果表明qscR基因是作为一个全局调控基因区别性地调控PCA和Plt的生物合成。     

假单胞菌M18rsmA-突变株的构建及其对Plt和PCA合成的区别性调控作用

假单胞菌(Pseudomonas sp．)M18是促进植物生长的根际细菌,能产生吩嗪-1-羧酸(PCA)和藤黄绿菌素(Plt)两种不同的抗生素抑制植物病原菌,保护植物免受病害。运用PCR方法,从M18基因组中,扩增出rsmA基因部分片段,并以该片段为探针,从M18的基因组柯斯文库中筛出阳性克隆,切取带有rsmA基因及两侧序列的1．5kb片段,中间插入编码Km‘的DNA片段,获得rsmA^-体外突变体。运用同源重组剔除技术,构建了M18菌株的rsmA突变株M18R^-。突变株M18R^-生物合成Plt的能力比野生型M18提高4倍,但是,PCA产量仅为野生型的20％。研究结果表明,全局性调控基因rsmA可能通过不同的机制区别性地影响Plt和PCA的生物合成。     

温度对假单胞rsmA突变株M-18R合成Plt和PCA的区别性影响

次生代谢物阻遏蛋白(Repressor of secondary metabolite,Rsm)A是一种全局性调控因子,与mRNA的RBS结合,转录后水平上抑制基因翻译。运用同源重组技术,构建了假单胞茵(Pseudomonas sp．)M-18的rsmA突变菌株M-18R。在37℃、28℃恒温和短期升温(37℃、4h培养,转28℃继续培养)条件下,比较野生株M-18和突变株M-18R生物合成藤黄绿菌素(Plt)和吩嗪-1-羧酸(PCA)的量。在37℃条件下,M-18和M-18R合成这两种抗生物质的能力几乎受到完全抑制。在28℃条件下,M-18R合成P11的量约为野生型M-18的10倍,达到270μg／mL,但是合成PCA的量仅为野生型的50％。经短期升温培养,M-18的Plt合成量明显下降,PCA产量降低不显;相反,M-18R合成Plt的量达到400μg／mL,但PCA产量的变化仍不明显。推测,M-18菌株细胞内存在着某种与RsmA相关联的温度敏感因子,在RsmA缺失条件下,作为专一性激活剂促进Plt的生物合成,但是,并不参与对PCA合成的调控。     

Suppression of maize root diseases caused by Macrophomina phaseolina, Fusarium moniliforme and Fusarium graminearum by plant growth promoting rhizobacteria

A plant growth-promoting isolate of a fluorescent Pseudomonas sp. EM85 and two bacilli isolates MR-11(2) and MRF, isolated from maize rhizosphere, were found strongly antagonistic to Fusarium moniliforme, Fusarium graminearum and Macrophomina phaseolina, causal agents of foot rots and wilting, collar rots/stalk rots and root rots and wilting, and charcoal rots of maize, respectively. Pseudomonas sp. EM85 produced antifungal antibiotics (Afa⁺), siderophore (Sid⁺), HCN (HCN⁺) and fluorescent pigments (Flu⁺) besides exhibiting plant growth promoting traits like nitrogen fixation, phosphate solubilization, and production of organic acids and IAA. While MR-11(2) produced siderophore (Sid⁺), antibiotics (Afa⁺) and antifungal volatiles (Afv⁺), MRF exhibited the production of antifungal antibiotics (Afa⁺) and siderophores (Sid⁺). Bacillus spp. MRF was also found to produce organic acids and IAA, solubilized tri-calcium phosphate and fixed nitrogen from the atmosphere. All three isolates suppressed the diseases caused by Fusarium moniliforme, Fusarium graminearum and Macrophomina phaseolina in vitro. A Tn5:: lac Z induced isogenic mutant of the fluorescent Pseudomonas EM85, M23, along with the two bacilli were evaluated for in situ disease suppression of maize. Results indicated that combined application of the two bacilli significantly (P = 0.05) reduced the Macrophomina-induced charcoal rots of maize by 56.04%. Treatments with the MRF isolate of Bacillus spp. and Tn5:: lac Z mutant (M23) of fluorescent Pseudomonas sp. EM85 significantly reduced collar rots, root and foot rots, and wilting of maize caused by Fusarium moniliforme and F. graminearum (P = 0.05) compared to all other treatments. All these isolates were found very efficient in colonizing the rhizotic zones of maize after inoculation. Evaluation of the population dynamics of the fluorescent Pseudomonas sp. EM85 using the Tn5:: lac Z marker and of the Bacillus spp. MRF and MR-11(2) using an antibiotic resistance marker revealed that all the three isolates could proliferate successfully in the rhizosphere, rhizoplane and endorhizosphere of maize, both at 30 and 60 days after seeding. Four antifungal compounds from fluorescent Pseudomonas sp. EM85, one from Bacillus sp. MR-11(2) and three from Bacillus sp. MRF were isolated, purified and tested in vitro and in thin layer chromatography bioassays. All these compounds inhibited R. solani, M. phaseolina, F. moniliforme, F. graminearum and F. solani strongly. Results indicated that antifungal antibiotics and/or fluorescent pigment of fluorescent Pseudomonas sp. EM85, and antifungal antibiotics of the bacilli along with the successful colonization of all the isolates might be involved in the biological suppression of the maize root diseases.     

Optimization of nutrient components for enhanced phenazine-1-carboxylic acid production by <Emphasis Type="Italic">gacA</Emphasis>-inactivated <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. M18G using response surface method

The nutritional requirements for phenazine-1-carboxylic acid (PCA) production using Pseudomonas sp. M18G, a gacA chromosomal-inactivated mutant of the strain M18, with a high PCA yield, were optimized statistically in shake flask experiments. Based on a single-factor experiment design, we implemented the two-level Plackett–Burman (PB) design with 11 variables to screen medium components that significantly influence PCA production. Soybean meal, glucose, soy peptone, and ethanol were identified as the most important significant factors (P < 0.05). Response surface methodology based on the Center Composite Design (CCD) was applied to determine these factors’ optimal levels and their mutual interactions between components for PCA production. The predicted results showed that 1.89 g l⁻¹ of PCA production was obtained after a 60-h fermentation period, with optimal concentrations of soybean meal powder (33.4 g l⁻¹), glucose (12.7 g l⁻¹), soy peptone (10.9 g l⁻¹), and ethanol (13.8 ml l⁻¹) in the flask fermentations. The validity of the model developed was verified, and the optimum medium led to a maximum PCA concentration of 2.0 g l⁻¹, a nearly threefold increase compared to that in the basal medium. Furthermore, the experiment was scaled up in the 10 l fermentor and 2 g l⁻¹ PCA productions were achieved in 48 h based on optimization mediums which further verified the practicability of this optimum strategy.