Pip介导铜绿假单胞菌吩嗪基因簇phz2的表达

[目的]为了确定铜绿假单胞菌调控因子Pip对两个不同吩嗪合成基因簇(phz1和phz2)的具体调控方式与可能的调控机制.[方法]根据基因比对结果,采用同源重组技术构建Pip调控因子缺失突变株PA-PG以及克隆ip基因作互补分析;再以已构建的吩嗪基因簇缺失突变株PA-Z1G和PA-Z2K为受体菌,构建突变株PA-PD-Z1G和PA-PG-Z2K,测定并比较野生株及相关突变株的吩嗪-1-羧酸和绿脓菌素的合成量,推定Pip对两个不同吩嗪合成基因簇的调控方式.[结果]在GA培养基中,突变株PA-PG的吩嗪-1-羧酸和绿脓菌素都比野生型明显减少;互补分析显示,突变株PA-PG的吩嗪-1-羧酸和绿脓菌素都显著提高并恢复到野生株PAO1水平;突变株PA-Z1G的吩嗪-1-羧酸和绿脓菌素合成量因Pip缺失而显著减少;而突变株PA-Z2K的吩嗪-1-羧酸和绿脓菌素合成量在Pip缺失后仍保持不变.[结论]初步推定,转录调控因子Pip对铜绿假单胞菌吩嗪合成代谢的确具有促进作用;Pip通过正向调控吩嗪基因簇phz2的合成功能实现对吩嗪合成代谢的调控.     

MvaT调控铜绿假单胞菌吩嗪的合成机制

【背景】属于H-NS家族的MvaT转录因子参与了铜绿假单胞菌的许多重要代谢过程,如吩嗪合成代谢,但其调控方式仍不十分明确。【目的】确定转录调控因子MvaT是否直接调控铜绿假单胞菌的吩嗪合成过程,即该蛋白是否可以直接结合2个吩嗪-1-羧酸合成基因簇(phzA1G1和phzA2G2)与3个分支转化基因(phzH、phzS和phzM)的上游启动子区域。【方法】以铜绿假单胞菌SJTD-1和其mvaT基因敲除突变株SJTD-1(ΔmvaT)为研究对象,检测其在不同培养基条件下吩嗪化合物的合成量差异。通过体外异源表达与亲和纯化,获得重组蛋白MvaT。利用凝胶阻滞实验,确定MvaT重组蛋白对5个吩嗪代谢基因簇/基因上游启动子的结合情况。【结果】mvaT基因敲除突变株SJTD-1(ΔmvaT)的吩嗪产量较野生型显著提升。MvaT重组蛋白被有效表达与纯化,体外凝胶阻滞实验结果显示,该重组蛋白可与phzA1G1、phzA2G2、phzM、phzS和phzH的上游启动子区域均发生特异性结合。其中,重组蛋白MvaT与phzA1G1和phzA2G2的结合区域位于其上游启动子的200 bp以内,而该蛋白与phzM、phzS和phzH的结合区域则位于其上游启动子的100 bp以内。【结论】MvaT蛋白通过直接结合吩嗪合成代谢基因的上游启动子区域来直接调控假单胞菌的吩嗪类化合物合成。     

铜绿假单胞菌全局调控因子RsmA的缺失影响2个吩嗪基因簇的表达

[目的]为了研究铜绿假单胞菌全局调控因子RsmA对两个吩嗪(Phenazine)合成基因簇phz1和phz2的调控方式与机制.[方法]采用基因缺失和抗性基因(gentamycin resistance cassette,aacC1)插入相结合的策略构建了rsmA基因缺失突变株PA-RG ;通过构建互补表达载体和过表达载体,进一步确认RsmA对绿脓菌素的调控作用 ;采用电转化方法将构建的翻译融合表达载体pMEZ1(phz1'-'lacZ)和pMEZ2(phz2'-'lacZ)分别导入铜绿假单胞菌突变株PA-RG和野生株PAO1,采用Miller法测定融合β-半乳糖苷酶活性.[结果]在GA培养基中,互补分析和过表达分析表明,RsmA抑制绿脓菌素的合成.此外,pMEZ1在突变株PA-RG中的表达增强,为野生株的2-3倍 ;而pMEZ2在突变株PA-RG中的表达降低,野生株是突变株的2倍.[结论]由此初步判定,铜绿假单胞菌全局调控因子RsmA对两个不同吩嗪合成基因簇的调控作用具有特异性,在一定程度上RsmA负调控phz1,正调控phz2.     

suhB基因对绿针假单胞菌HT66生防能力的影响

[背景]绿针假单胞菌(Pseudomonaschlororaphis)HT66是一株兼具生防安全性和吩嗪-1-甲酰胺(Phenazine-1-Carboxamide,PCN)高产的植物根际促生菌,在生物防治、生态农业及可持续发展农业领域具有广阔的应用前景.非编码RNA(ncRNA)SuhB参与了细胞中多个过程的代谢调控...     

荧光假单胞菌抗生性代谢产物合成相关基因的研究现状

荧光假单胞菌(Pseudomonas fluorescens)是一种重要的植物根际促生菌,它能够产生藤黄绿脓菌素、2,4-二乙酰基藤黄酚、硝吡咯菌素、吩嗪-1-羧酸等抗生性次级代谢产物,可抑制多种病原物,在农作物土传病害的生物防治研究中具有重要意义.总结了荧光假单胞菌中已确立的抗生性次级代谢产物的合成机制,重点阐述了相关基因的结构、功能,以及利用生物工程技术对荧光假单胞菌进行遗传操作的最新进展,同时对荧光假单胞菌在生物防治中的应用和其作为生防菌剂的前景进行了展望.     

rpoS基因插入突变对铜绿假单胞菌两个吩嗪合成基因簇的调控

【目的】为了研究铜绿假单胞菌rpoS基因对吩嗪(Phenazine)合成基因簇phz1和phz2的调控方式与机制。【方法】采用抗庆大霉素基因(gentamycin resistance cassette,aacC1)插入失活的策略构建了rpoS基因突变株PA-SG;同时利用lacZ的翻译融合表达载体pME6015,构建了phz1′-′lacZ和phz2′-′lacZ翻译融合表达载体pMEZ1和pMEZ2。采用电转化法分别将pMEZ1、pMEZ2和pME6015导入铜绿假单胞菌突变株PA-SG和野生株PAO1,用Miller法检测融合β-半乳糖苷酶活性。【结果】在KMB或PPM培养基中,pMEZ1在突变株PA-SG中的表达均增强,为野生株的4-5倍;而pMEZ2在突变株PA-SG中的表达均降低,野生株是突变株的2-3倍。【结论】由此推测,铜绿假单胞菌rpoS基因对两个不同吩嗪合成基因簇的调控作用具有特异性,在一定程度上,rpoS负调控phz1,正调控phz2。     

假单胞菌合成环脂肽转录调控的研究进展

假单胞菌所合成的环脂肽是一类由环状的寡肽连接一个脂肪酸链组成的两亲性分子,利用巯基化模块由非核糖体肽合成酶合成。环脂肽的生物合成受到严格、复杂的调控,GacS/GacA双组分系统和群体感应系统是其中两类重要的调控系统。本文总结假单胞菌合成环脂肽的调控机制及相关调控因子;对基于PCR的高通量分子筛选方法获取特定环脂肽进行分析,同时对基于调控机制的遗传改造提高假单胞菌产环脂肽的能力和获取更多新型环脂肽等方面的应用进行 展望。     

转录调节因子σ~(38)介导铜绿假单胞菌绿脓菌素合成代谢调控

【目的】为了进一步鉴定铜绿假单胞菌转录调控因子σ~(38)对2个拷贝吩嗪合成基因簇(phz A1-G1和phz A2-G2)的具体调控方式并推定介导绿脓菌素合成代谢的可能调控机制。【方法】根据铜绿假单胞菌基因组信息,利用同源重组原理构建rpo S基因缺失突变株Δrpo S以及克隆全长rpo S基因作互补分析;再以单一吩嗪基因簇缺失突变株Δphz1和Δphz2为出发菌株,分别构建rpo S缺失突变株Δrpo Sphz1和rpo S插入突变株Δrpo Sphz2,测定并比较野生株及相关突变株的绿脓菌素合成量,初步推定σ~(38)因子对2个不同吩嗪基因簇表达的调控方式。【结果】在GA培养基中,突变株Δrpo S的绿脓菌素合成量比野生株显著增加;互补分析证实,σ~(38)可使突变株Δrpo S的绿脓菌素降低并接近野生株PAO1水平;与对照株Δphz1相比,突变株Δrpo Sphz1的绿脓菌素合成量因σ~(38)因子缺失而显著减少;而与对照株Δphz2相比,突变株Δrpo Sphz2的绿脓菌素合成量因σ~(38)因子缺失显著增加。【结论】转录调控因子σ~(38)对铜绿假单胞菌绿脓菌素的合成代谢的确具一定的负调控作用;结合已报道的研究结果,初步推定:σ~(38)因子通过负调控吩嗪基因簇phz1,正调控吩嗪基因簇phz2的表达实现对绿脓菌素合成代谢的调控。     

铜绿假单胞菌铁摄取与生物被膜形成研究进展

生物被膜是单细胞微生物通过其分泌的胞外多聚基质粘附于介质表面并将其自身包绕其中而成的膜样微生物细胞聚集物。生物被膜的形成使细菌具有更强的适应外界环境的能力,也是导致微生物产生耐药性及慢性感染性疾病难以治疗的重要原因之一。铜绿假单胞菌在肺部的定殖是肺囊性纤维化病患者发病和死亡主要原因,其造成的感染通常与形成抗生素抗性极强的生物被膜有关。铜绿假单胞菌生物被膜的形成受控于多种复杂的细菌调控体系之下,包括群体感应系统及参与调节胞外多聚基质合成的双组分调控系统等。此外,为了利用低浓度的环境铁来维持生存并完成各种生理功能,铜绿假单胞菌进化出了一系列铁摄取系统,这些系统对其毒力因子的释放和生物被膜的形成又起着重要的调控作用。本文主要对铜绿假单胞菌生物被膜的形成与调控机制及其铁摄取系统进行了综述,为进一步了解及清除铜绿假单胞菌引发的问题提供途径与思路。     

铜绿假单胞菌的双组分系统

双组分系统是存在于原核和少部分真核生物细胞中的信号转导系统,主要由组氨酸蛋白激酶和反应调节蛋白组成,通过感应外界环境信号、信号输入、磷酸基团传递、信号输出等环节调节基因表达,使细胞能更加适应环境变化。铜绿假单胞菌为条件致病菌,其双组分系统构成多样、功能复杂且参与介导耐药性产生,因此铜绿假单胞菌的双组分系统日益引起人们关注。本文对铜绿假单胞菌双组分系统的组成、信号转导机制、种类、研究方法及其临床意义进行了综述。     

细菌Cpx双组分信号转导系统应对外界环境变化的响应调节机制研究进展

细菌能够在其他微生物无法生存的环境中生长,必然具有更加强大的适应外界环境的能力。细胞信号转导的效率决定了细菌对外界刺激做出应答反应的速率和能力。双组分调控系统是维持细菌在压力环境中存活的重要结构。Cpx双组分信号转导系统是革兰氏阴性菌中普遍存在的双组分调控系统之一,在响应外界环境变化并做出适应性反应的过程中起着主要作用。本文主要针对细菌中双组分信号转导系统的种类、Cpx双组分信号转导系统参与的调控、Cpx双组分信号转导系统所调控的靶基因及其生理行为的研究进展进行综述,以期为科研人员更深入的研究提供思路和理论基础。     

The Pho Regulons of Bacteria

Bacterial Pho regulons contain genes whose products are involved in the transport and assimilation of inorganic phosphate. The expression of these genes is regulated by a specific two-component signal transduction system. The paper summarizes data on the organization and function of Pho regulons in gram-negative and gram-positive bacteria, with particular emphasis on the Pho regulons of the best studied bacteria Escherichia coli and Bacillus subtilis.     

Signal transduction pathways in Synechocystis sp. PCC 6803 and biotechnological implications under abiotic stress

Cyanobacteria have developed various response mechanisms in long evolution to sense and adapt to external or internal changes under abiotic stresses. The signal transduction system of a model cyanobacterium Synechocystis sp. PCC 6803 includes mainly two-component signal transduction systems of eukaryotic-type serine/threonine kinases (STKs), on which most have been investigated at present. These two-component systems play a major role in regulating cell activities in cyanobacteria. More and more co-regulation and crosstalk regulations among signal transduction systems had been discovered due to increasing experimental data, and they are of great importance in corresponding to abiotic stresses. However, mechanisms of their functions remain unknown. Nevertheless, the two signal transduction systems function as an integral network for adaption in different abiotic stresses. This review summarizes available knowledge on the signal transduction network in Synechocystis sp. PCC 6803 and biotechnological implications under various stresses, with focuses on the co-regulation and crosstalk regulations among various stress-responding signal transduction systems.     

A Second Quorum-Sensing System Regulates Cell Surface Properties but Not Phenazine Antibiotic Production in Pseudomonas aureofaciens

The root-associated biological control bacterium Pseudomonas aureofaciens 30-84 produces a range of exoproducts, including protease and phenazines. Phenazine antibiotic biosynthesis by phzXYFABCD is regulated in part by the PhzR-PhzI quorum-sensing system. Mutants defective in phzR or phzI produce very low levels of phenazines but wild-type levels of exoprotease. In the present study, a second genomic region of strain 30-84 was identified that, when present in trans, increased β-galactosidase activity in a genomic phzB::lacZ reporter and partially restored phenazine production to a phzR mutant. Sequence analysis identified two adjacent genes, csaR and csaI, that encode members of the LuxR-LuxI family of regulatory proteins. No putative promoter region is present upstream of the csaI start codon and no lux box-like element was found in either the csaR promoter or the 30-bp intergenic region between csaR and csaI. Both the PhzR-PhzI and CsaR-CsaI systems are regulated by the GacS-GacA two-component regulatory system. In contrast to the multicopy effects of csaR and csaI in trans, a genomic csaR mutant (30-84R2) and a csaI mutant (30-84I2) did not exhibit altered phenazine production in vitro or in situ, indicating that the CsaR-CsaI system is not involved in phenazine regulation in strain 30-84. Both mutants also produced wild-type levels of protease. However, disruption of both csaI and phzI or both csaR and phzR eliminated both phenazine and protease production completely. Thus, the two quorum-sensing systems do not interact for phenazine regulation but do interact for protease regulation. Additionally, the CsaI N-acylhomoserine lactone (AHL) signal was not recognized by the phenazine AHL reporter 30-84I/Z but was recognized by the AHL reporters Chromobacterium violaceum CV026 and Agrobacterium tumefaciens A136(pCF240). Inactivation of csaR resulted in a smooth mucoid colony phenotype and formation of cell aggregates in broth, suggesting that CsaR is involved in regulating biosynthesis of cell surface components. Strain 30-84I/I2 exhibited mucoid colony and clumping phenotypes similar to those of 30-84R2. Both phenotypes were reversed by complementation with csaR-csaI or by the addition of the CsaI AHL signal. Both quorum-sensing systems play a role in colonization by strain 30-84. Whereas loss of PhzR resulted in a 6.6-fold decrease in colonization by strain 30-84 on wheat roots in natural soil, a phzR csaR double mutant resulted in a 47-fold decrease. These data suggest that gene(s) regulated by the CsaR-CsaI system also plays a role in the rhizosphere competence of P. aureofaciens 30-84.     

A second quorum-sensing system regulates cell surface properties but not phenazine antibiotic production in Pseudomonas aureofaciens

The root-associated biological control bacterium Pseudomonas aureofaciens 30-84 produces a range of exoproducts, including protease and phenazines. Phenazine antibiotic biosynthesis by phzXYFABCD is regulated in part by the PhzR-PhzI quorum-sensing system. Mutants defective in phzR or phzI produce very low levels of phenazines but wild-type levels of exoprotease. In the present study, a second genomic region of strain 30-84 was identified that, when present in trans, increased beta-galactosidase activity in a genomic phzB::lacZ reporter and partially restored phenazine production to a phzR mutant. Sequence analysis identified two adjacent genes, csaR and csaI, that encode members of the LuxR-LuxI family of regulatory proteins. No putative promoter region is present upstream of the csaI start codon and no lux box-like element was found in either the csaR promoter or the 30-bp intergenic region between csaR and csaI. Both the PhzR-PhzI and CsaR-CsaI systems are regulated by the GacS-GacA two-component regulatory system. In contrast to the multicopy effects of csaR and csaI in trans, a genomic csaR mutant (30-84R2) and a csaI mutant (30-84I2) did not exhibit altered phenazine production in vitro or in situ, indicating that the CsaR-CsaI system is not involved in phenazine regulation in strain 30-84. Both mutants also produced wild-type levels of protease. However, disruption of both csaI and phzI or both csaR and phzR eliminated both phenazine and protease production completely. Thus, the two quorum-sensing systems do not interact for phenazine regulation but do interact for protease regulation. Additionally, the CsaI N-acylhomoserine lactone (AHL) signal was not recognized by the phenazine AHL reporter 30-84I/Z but was recognized by the AHL reporters Chromobacterium violaceum CV026 and Agrobacterium tumefaciens A136(pCF240). Inactivation of csaR resulted in a smooth mucoid colony phenotype and formation of cell aggregates in broth, suggesting that CsaR is involved in regulating biosynthesis of cell surface components. Strain 30-84I/I2 exhibited mucoid colony and clumping phenotypes similar to those of 30-84R2. Both phenotypes were reversed by complementation with csaR-csaI or by the addition of the CsaI AHL signal. Both quorum-sensing systems play a role in colonization by strain 30-84. Whereas loss of PhzR resulted in a 6.6-fold decrease in colonization by strain 30-84 on wheat roots in natural soil, a phzR csaR double mutant resulted in a 47-fold decrease. These data suggest that gene(s) regulated by the CsaR-CsaI system also plays a role in the rhizosphere competence of P. aureofaciens 30-84.     

Identification of ColR binding consensus and prediction of regulon of ColRS two-component system

Background  

Conserved two-component system ColRS of Pseudomonas genus has been implicated in several unrelated phenotypes. For instance, deficiency of P. putida ColRS system results in lowered phenol tolerance, hindrance of transposition of Tn4652 and lysis of a subpopulation of glucose-grown bacteria. In order to discover molecular mechanisms behind these phenotypes, we focused here on identification of downstream components of ColRS signal transduction pathway.     

Ammonia oxidation by the methane oxidising bacterium Methylococcus capsulatus strain bath

Soluble extracts of Methylococcus capsulatus (Bath) that readily oxidise methane to methanol will also oxidise ammonia to nitrite via hydroxylamine. The ammonia oxidising activity requires O₂, NADH and is readily inhibited by methane and specific inhibitors of methane mono-oxygenase activity. Hydroxylamine is oxidised to nitrite via an enzyme system that uses phenazine methosulphate (PMS) as an electron acceptor. The estimated K _mvalue for the ammonia hydroxylase activity was 87 mM but the kinetics of the oxidation were complex and may involve negative cooperativity.Abbreviations PMS Phenazine methosulphate - NADH nicotinamide adenine dinucleotide, reduced form - K _m Michaelis constant - NO ₂ ^- nitrite - NH₂OH hydroxylamine     

Sensor Domain of Histidine Kinase KinB of Pseudomonas: A HELIX-SWAPPED DIMER*

The overproduction of polysaccharide alginate is responsible for the formation of mucus in the lungs of cystic fibrosis patients. Histidine kinase KinB of the KinB-AlgB two-component system in Pseudomonas aeruginosa acts as a negative regulator of alginate biosynthesis. The modular architecture of KinB is similar to other histidine kinases. However, its periplasmic signal sensor domain is unique and is found only in the Pseudomonas genus. Here, we present the first crystal structures of the KinB sensor domain. The domain is a dimer in solution, and in the crystal it shows an atypical dimer of a helix-swapped four-helix bundle. A positively charged cavity is formed on the dimer interface and involves several strictly conserved residues, including Arg-60. A phosphate anion is bound asymmetrically in one of the structures. In silico docking identified several monophosphorylated sugars, including β-d-fructose 6-phosphate and β-d-mannose 6-phosphate, a precursor and an intermediate of alginate synthesis, respectively, as potential KinB ligands. Ligand binding was confirmed experimentally. Conformational transition from a symmetric to an asymmetric structure and decreasing dimer stability caused by ligand binding may be a part of the signal transduction mechanism of the KinB-AlgB two-component system.