Identification of Novel Genes Associated with Alginate Production in Pseudomonas aeruginosa Using Mini-himar1 Mariner Transposon-mediated Mutagenesis

Pseudomonas aeruginosa is a Gram-negative, environmental bacterium with versatile metabolic capabilities. P. aeruginosa is an opportunistic bacterial pathogen which establishes chronic pulmonary infections in patients with cystic fibrosis (CF). The overproduction of a capsular polysaccharide called alginate, also known as mucoidy, promotes the formation of mucoid biofilms which are more resistant than planktonic cells to antibiotic chemotherapy and host defenses. Additionally, the conversion from the nonmucoid to mucoid phenotype is a clinical marker for the onset of chronic infection in CF. Alginate overproduction by P. aeruginosa is an endergonic process which heavily taxes cellular energy. Therefore, alginate production is highly regulated in P. aeruginosa. To better understand alginate regulation, we describe a protocol using the mini-himar1 transposon mutagenesis for the identification of novel alginate regulators in a prototypic strain PAO1. The procedure consists of two basic steps. First, we transferred the mini-himar1 transposon (pFAC) from host E. coli SM10/λpir into recipient P. aeruginosa PAO1 via biparental conjugation to create a high-density insertion mutant library, which were selected on Pseudomonas isolation agar plates supplemented with gentamycin. Secondly, we screened and isolated the mucoid colonies to map the insertion site through inverse PCR using DNA primers pointing outward from the gentamycin cassette and DNA sequencing. Using this protocol, we have identified two novel alginate regulators, mucE (PA4033) and kinB (PA5484), in strain PAO1 with a wild-type mucA encoding the anti-sigma factor MucA for the master alginate regulator AlgU (AlgT, σ²²). This high-throughput mutagenesis protocol can be modified for the identification of other virulence-related genes causing change in colony morphology.     

A mutation in algN permits trans activation of alginate production by algT in Pseudomonas species.

Conversion of the mucoid phenotype, which results from the production of the exopolysaccharide alginate, is a feature typical of Pseudomonas aeruginosa strains causing chronic pulmonary infections in patients with cystic fibrosis. In this study, we further characterized a recombinant plasmid, called pJF15, that contains DNA from the 65- to 70-min region of the chromosome of mucoid P. aeruginosa FRD1 and has loci involved in alginate conversion. Plasmid pJF15 complements algT mutations in trans and confers the mucoid phenotype in cis following gene replacement. However, the phenotype of nonmucoid P. aeruginosa carrying pJF15 is unchanged. Here we report the identification of a locus immediately downstream of algT, called algN, that may be a negative regulator that blocks algT from activating alginate production. Inactivation of algN by transposon Tn501 insertion allowed algT to stimulate alginate production in trans. The DNA sequence of this region identified an open reading frame that predicts an algN gene product of 33 kDa, but no homology was found to other proteins in a sequence data base. Clones of algT in which algN was deleted caused the activation of alginate biosynthesis in transconjugants of several P. aeruginosa strains. DNA containing algT was shown to hybridize to the genomes of several Pseudomonas species, including P. putida, P. stutzeri, and P. fluorescens. Transconjugants of these species carrying algT DNA (with a deletion of algN) from pJF15 showed a mucoid phenotype and increased production of uronic acid-containing polymers that resembled alginate.     

Cloning of genes from mucoid Pseudomonas aeruginosa which control spontaneous conversion to the alginate production phenotype.

Strains of Pseudomonas aeruginosa causing chronic pulmonary infections in patients with cystic fibrosis are known to convert to a mucoid form in vivo characterized by the production of the exopolysaccharide alginate. The alginate production trait is not stable, and mucoid strains frequently convert back to the nonmucoid form in vitro. The DNA involved in these spontaneous alginate conversions, referred to as algS, was shown here to map near hisI and pru markers on the chromosome of strain FRD, an isolate from a cystic fibrosis patient. Although cloning algS+ by trans-complementation was not possible, a clone (pJF5) was isolated that caused algS mutants to convert to the Alg+ phenotype at detectable frequencies (approximately 0.1%) in vitro. Gene replacement with transposon-marked pJF5 followed by mapping studies showed that pJF5 contained DNA transducibly close to algS in the chromosome. Another clone was identified called pJF15 which did contain algS+ from mucoid P. aeruginosa. The plasmid-borne algS+ locus could not complement spontaneous algS mutations in trans, but its cis-acting activity was readily observed after gene replacement with the algS mutant chromosome by using an adjacent transposon as the selectable marker. pJF15 also contained a trans-active gene called algT+ in addition to the cis-active gene algS+. The algT gene was localized on pJF15 by using deletion mapping and transposon mutagenesis. By using gene replacement, algT::Tn501 mutants of P. aeruginosa were constructed which were shown to be complemented in trans by pJF15. Both algS and algT were located on a DNA fragment approximately 3 kilobases in size. The algS gene may be a genetic switch which regulates the process of alginate conversion.     

Analysis of the Pseudomonas aeruginosa regulon controlled by the sensor kinase KinB and sigma factor RpoN

Alginate overproduction by Pseudomonas aeruginosa, also known as mucoidy, is associated with chronic endobronchial infections in cystic fibrosis. Alginate biosynthesis is initiated by the extracytoplasmic function sigma factor (σ(22); AlgU/AlgT). In the wild-type (wt) nonmucoid strains, such as PAO1, AlgU is sequestered to the cytoplasmic membrane by the anti-sigma factor MucA that inhibits alginate production. One mechanism underlying the conversion to mucoidy is mutation of mucA. However, the mucoid conversion can occur in wt mucA strains via the degradation of MucA by activated intramembrane proteases AlgW and/or MucP. Previously, we reported that the deletion of the sensor kinase KinB in PAO1 induces an AlgW-dependent proteolysis of MucA, resulting in alginate overproduction. This type of mucoid induction requires the alternate sigma factor RpoN (σ(54)). To determine the RpoN-dependent KinB regulon, microarray and proteomic analyses were performed on a mucoid kinB mutant and an isogenic nonmucoid kinB rpoN double mutant. In the kinB mutant of PAO1, RpoN controlled the expression of approximately 20% of the genome. In addition to alginate biosynthetic and regulatory genes, KinB and RpoN also control a large number of genes including those involved in carbohydrate metabolism, quorum sensing, iron regulation, rhamnolipid production, and motility. In an acute pneumonia murine infection model, BALB/c mice exhibited increased survival when challenged with the kinB mutant relative to survival with PAO1 challenge. Together, these data strongly suggest that KinB regulates virulence factors important for the development of acute pneumonia and conversion to mucoidy.     

MucR, a Novel Membrane-Associated Regulator of Alginate Biosynthesis in Pseudomonas aeruginosa

Alginate biosynthesis by Pseudomonas aeruginosa was shown to be regulated by the intracellular second messenger bis-(3′-5′)-cyclic-dimeric-GMP (c-di-GMP), and binding of c-di-GMP to the membrane protein Alg44 was required for alginate production. In this study, PA1727, a c-di-GMP-synthesizing enzyme was functionally analyzed and identified to be involved in regulation of alginate production. Deletion of the PA1727 gene in the mucoid alginate-overproducing P. aeruginosa strain PDO300 resulted in a nonmucoid phenotype and an about 38-fold decrease in alginate production; thus, this gene is designated mucR. The mucoid alginate-overproducing phenotype was restored by introducing the mucR gene into the isogenic ΔmucR mutant. Moreover, transfer of the MucR-encoding plasmid into strain PDO300 led to an about sevenfold increase in alginate production, wrinkly colony morphology, increased pellicle formation, auto-aggregation, and the formation of highly structured biofilms as well as the inhibition of swarming motility. Outer membrane protein profile analysis showed that overproduction of MucR mediates a strong reduction in the copy number of FliC (flagellin), required for flagellum-mediated motility. Translational reporter enzyme fusions with LacZ and PhoA suggested that MucR is located in the cytoplasmic membrane with a cytosolic C terminus. Deletion of the proposed C-terminal GGDEF domain abolished MucR function. MucR was purified and identified using tryptic peptide fingerprinting and matrix-assisted laser desorption ionization-time of flight mass spectrometry. Overall, experimental evidence was provided suggesting that MucR specifically regulates alginate biosynthesis by activation of alginate production through generation of a localized c-di-GMP pool in the vicinity of Alg44.     

Cloning of genes controlling alginate biosynthesis from a mucoid cystic fibrosis isolate of Pseudomonas aeruginosa.

Mucoid strains of Pseudomonas aeruginosa isolated from the sputum of cystic fibrosis patients produce copious quantities of an exopolysaccharide known as alginic acid. Since clinical isolates of the mucoid variants are unstable with respect to alginate synthesis and revert spontaneously to the more typical nonmucoid phenotype, it has been difficult to isolate individual structural gene mutants defective in alginate synthesis. The cloning of the genes controlling alginate synthesis has been facilitated by the isolation of a stable alginate-producing strain, 8830. The stable mucoid strain was mutagenized with ethyl methanesulfonate to obtain various mutants defective in alginate biosynthesis. Several nonmucoid (Alg-) mutants were isolated. A mucoid P. aeruginosa gene library was then constructed, using a cosmid cloning vector. DNA isolated from the stable mucoid strain 8830 was partially digested with the restriction endonuclease HindIII and ligated to the HindIII site of the broad host range cosmid vector, pCP13. After packaging in lambda particles, the recombinant DNA was introduced via transfection into Escherichia coli AC80. The clone bank was mated (en masse) from E. coli into various P. aeruginosa 8830 nonmucoid mutants with the help of pRK2013, which provided donor functions in trans, and tetracycline-resistant exconjugants were screened for the ability to form mucoid colonies. Three recombinant plasmids, pAD1, pAD2, and pAD3, containing DNA inserts of 20, 9.5, and 6.2 kilobases, respectively, were isolated based on their ability to restore alginate synthesis in various strain 8830 nonmucoid (Alg-) mutants. Mutants have been assigned to at least four complementation groups, based on complementation by pAD1, pAD2, or pAD3 or by none of them. Introduction of pAD1 into the spontaneous nonmucoid strain 8822, as well as into other nonmucoid laboratory strains of P. aeruginosa such as PAO and SB1, was found to slowly induce alginate synthesis. This alginate-inducing ability was found to reside on a 7.5-kilobase EcoRI fragment that complemented the alg-22 mutation of strain 8852. The pAD1 chromosomal insert which complements the alg-22 mutation was subsequently mapped at ca. 19 min of the P. aeruginosa PAO chromosome.     

Vanadate and triclosan synergistically induce alginate production by Pseudomonas aeruginosa strain PAO1

Alginate overproduction by P. aeruginosa strains, also known as mucoidy, is associated with chronic lung infections in cystic fibrosis (CF). It is not clear how alginate induction occurs in the wild-type (wt) mucA strains. When grown on Pseudomonas isolation agar (PIA), P. aeruginosa strains PAO1 and PA14 are non-mucoid, producing minimal amounts of alginate. Here we report the addition of ammonium metavanadate (AMV), a phosphatase inhibitor, to PIA (PIA-AMV) induced mucoidy in both these laboratory strains and early lung colonizing non-mucoid isolates with a wt mucA. This phenotypic switch was reversible depending on the availability of vanadate salts and triclosan, a component of PIA. Alginate induction in PAO1 on PIA-AMV was correlated with increased proteolytic degradation of MucA, and required envelope proteases AlgW or MucP, and a two-component phosphate regulator, PhoP. Other changes included the addition of palmitate to lipid A, a phenotype also observed in chronic CF isolates. Proteomic analysis revealed the upregulation of stress chaperones, which was confirmed by increased expression of the chaperone/protease MucD. Altogether, these findings suggest a model of alginate induction and the PIA-AMV medium may be suitable for examining early lung colonization phenotypes in CF before the selection of the mucA mutants.     

mucA基因突变的黏液型铜绿假单胞菌PA17与PD0300生物被膜形态观察和耐药性比较

目的研究新的mucA基因缺失突变的黏液型铜绿假单胞菌PA17和经典mucA基因点突变的黏液型铜绿假单胞菌PD0300在生物被膜状态下对临床常用抗菌药物的耐药性变化,探讨mucA基因突变对铜绿假单胞菌生物被膜形态及细菌耐药性的影响。方法改良的平板法建立生物被膜,将含绿色荧光蛋白的pUCP／UV质粒转化两株铜绿假单胞菌,激光共聚焦显微镜下观察生物被膜形态;采用琼脂二倍稀释法测定常用β-内酰胺类,氨基甙类,喹诺酮类抗菌药物对铜绿假单胞菌菌株PA17、PD0300的最低抑菌浓度（MIC）;利用96孔板建立生物被膜测定抗菌药物对第五天成熟生物被膜内细菌的最低杀菌浓度（MBC）。结果新的mucA基因缺失突变的黏液型PA17成熟生物被膜呈薄膜状、经典mucA基因点突变的黏液型PD0300成熟生物被膜呈蘑菇状;在浮游状态下PA17、PD0300对头孢他啶（CAZ）、妥布霉素（TOB）、庆大霉素（GEN）、亚胺培南（IPM）敏感,而对左氧氟沙星（LVX）、环丙沙星（CIP）不敏感,两者具有一致的耐药性;生物被膜状态下两者对抗菌药物敏感性降低20—8000倍;黏液型PD0300成熟生物被膜对抗菌药物敏感性低于黏液型PA17。结论黏液型铜绿假单胞菌在相同条件下能形成不同形态的生物被膜;生物被膜状态下较浮游状态下对常用抗菌药物敏感性明显下降,同时生物被膜形态也影响抗菌药物敏感性。     

Alg44, a unique protein required for alginate biosynthesis in Pseudomonas aeruginosa

Here the putative alginate biosynthesis gene alg44 of Pseudomonas aeruginosa was functionally assigned. Non-polar isogenic alg44 deletion mutants of P. aeruginosa were generated and did neither produce alginate nor released free uronic acids. No evidence for alginate enrichment in the periplasm was obtained. Alginate production was restored by introducing only the gene alg44. PhoA fusion protein analyses suggested that Alg44 is a soluble protein localized in the periplasm. Hexahistidine-tagged Alg44 was detected by immunoblotting. The corresponding 42.6 kDa protein was purified and identified by MALDI/TOF-MS analysis. Alg44 might be directly involved in alginate polymerization presumably by exerting a regulatory function.     

Relation of exaggerated cytokine responses of CF airway epithelial cells to PAO1 adherence

In many model systems, cystic fibrosis (CF) phenotype airway epithelial cells in culture respond to P. aeruginosa with greater interleukin (IL)-8 and IL-6 secretion than matched controls. In order to test whether this excess inflammatory response results from the reported increased adherence of P. aeruginosa to the CF cells, we compared the inflammatory response of matched pairs of CF and non CF airway epithelial cell lines to the binding of GFP-PAO1, a strain of pseudomonas labeled with green fluorescent protein. There was no clear relation between GFP-PAO1 binding and cytokine production in response to PAO1. Treatment with exogenous aGM1 resulted in greater GFP-PAO1 binding to the normal phenotype compared to CF phenotype cells, but cytokine production remained greater from the CF cell lines. When cells were treated with neuraminidase, PAO1 adherence was equalized between CF and nonCF phenotype cell lines, but IL-8 production in response to inflammatory stimuli was still greater in CF phenotype cells. The polarized cell lines 16HBEo-Sense (normal phenotype) and Antisense (CF phenotype) cells were used to test the effect of disrupting tight junctions, which allows access of PAO1 to basolateral binding sites in both cell lines. IL-8 production increased from CF, but not normal, cells. These data indicate that increased bacterial binding to CF phenotype cells cannot by itself account for excess cytokine production in CF airway epithelial cells, encourage investigation of alternative hypotheses, and signal caution for therapeutic strategies proposed for CF that include disruption of tight junctions in the face of pseudomonas infection.     

Co-evolution with lytic phage selects for the mucoid phenotype of Pseudomonas fluorescens SBW25

The effects of co-evolution with lytic phage on bacterial virulence-related traits are largely unknown. In this study we investigate the incidence of the mucoid phenotype of the bacterium Pseudomonas fluorescens SBW25 in response to co-evolution with the lytic phage phi2 (φ2). The mucoid phenotype of Pseudomonas spp. is due to overproduction of alginate and is a considerable virulence factor contributing to the intractability of infections most notably in cystic fibrosis (CF) lung, but also in pathogenic infections of plants. Our data show that this phenotype can evolve as an adaptive response to phage predation and is favoured under specific abiotic conditions, in particular a homogenous spatial structure and a high rate of nutrient replacement. The mucoid phenotype remains partially sensitive to phage infection, which facilitates ‘apparent competition'' with phage-sensitive competitors, partially offsetting the costs of alginate production. Although P. fluorescens SBW25 is not a pathogen, several key characteristics typical of Pseudomonas aeruginosa clinical isolates from CF lung were noted, including loss of motility on mucoid conversion and a high rate of spontaneous reversion to the wild-type phenotype. Although the genetic mechanisms of this phenotype remain unknown, they do not include mutations at many of the commonly reported loci implicated in mucoid conversion, including mucA and algU. These data not only further our understanding of the potential role phage have in the ecology and evolution of bacteria virulence in both natural and clinical settings, but also highlight the need to consider both biotic and abiotic variables if bacteriophages are to be used therapeutically.     

Controlling persister cells of Pseudomonas aeruginosa PDO300 by (Z)-4-bromo-5-(bromomethylene)-3-methylfuran-2(5H)-one

Pseudomonas aeruginosa is a major pathogen causing chronic pulmonary infections; for example, 80% of cystic fibrosis patients get infected by this bacterium as the disease progresses. Such chronic infections are challenging because P. aeruginosa exhibits high-level tolerance to antibiotics by forming biofilms (multicellular structures attached to surfaces), by entering dormancy and forming antibiotic tolerant persister cells, and by conversion to the mucoid phenotype. Recently, we reported that a synthetic quorum sensing inhibitor, (Z)-4-bromo-5-(bromomethylene)-3-methylfuran-2(5H)-one (BF8), can sensitize both planktonic and biofilm-associated persister cells of P. aeruginosa PAO1 to antibiotics at the concentrations non-inhibitory to its growth. In this study, we further characterized the effects of this compound on the mucoid strain P. aeruginosa PDO300. BF8 was found to reduce persistence during the growth of PDO300 and effectively kill the persister cells isolated from PDO300 cultures. In addition to planktonic cells, BF8 was also found to inhibit biofilm formation of PDO300 and reduce associated persistence. These findings broaden the activities of this class of compounds and indicate that BF8 also has other targets in P. aeruginosa in addition to quorum sensing.     

Use of cell wall stress to characterize σ22 (AlgT/U) activation by regulated proteolysis and its regulon in Pseudomonas aeruginosa

MucA sequesters extracytoplasmic function (ECF) σ²² ( algT/U encoded) from target promoters including P algD for alginate biosynthesis. We have shown that cell wall stress (e.g. d -cycloserine) is a potent inducer of the algD operon. Here we showed that MucB, encoded by the algT-mucABCD operon, interacts with MucA in the sigma–sequestration complex. We hypothesized that AlgW protease (a DegS homologue) is activated by cell wall stress to cleave MucA and release σ²². When strain PAO1 was exposed to d -cycloserine, MucA was degraded within just 10 min, and σ²² was activated. However, in an algW mutant, MucA was stable with no increased σ²² activity. Studies on a yaeL mutant, defective in an RseP/YaeL homologue, suggest that YaeL protease cleaves MucA only after cleavage by AlgW. A defect in mucD , encoding a periplasmic HtrA/DegP homologue, caused MucA instability, suggesting MucD degrades cell wall stress signals. Overall, these data indicate that cell wall stress signals release σ²² by regulated intramembrane proteolysis (RIP). Microarray analyses identified genes of the early and late cell wall stress stimulon, which included genes for alginate production. The subset of genes in the σ²² regulon was then determined, which included gene products predicted to contribute to recovery from cell wall stress.     

Comparative Molecular docking analysis of DNA Gyrase subunit A in Pseudomonas aeruginosaPAO1

Pseudomonas aeruginosa is an opportunistic bacterium known for causing chronic infections in cystic fibrosis and chronic obstructive pulmonary disease (COPD) patients. Recently, several drug targets in Pseudomonas aeruginosa PAO1 have been reported using network biology approaches on the basis of essentiality and topology and further ranked on network measures viz. degree and centrality. Till date no drug/ligand molecule has been reported against this targets.In our work we have identified the ligand /drug molecules, through Orthologous gene mapping against Bacillus subtilis subsp. subtilis str. 168 and performed modelling and docking analysis. From the predicted drug targets in PA PAO1, we selected those drug targets which show statistically significant orthology with a model organism and whose orthologs are present in all the selected drug targets of PA PAO1.Modeling of their structure has been done using I-Tasser web server. Orthologous gene mapping has been performed using Cluster of Orthologs (COGs) and based on orthology; drugs available for Bacillus sp. have been docked with PA PAO1 protein drug targets using MoleGro virtual docker version 4.0.2.Orthologous gene for PA3168 gyrA is BS gyrAfound in Bacillus subtilis subsp. subtilis str. 168. The drugs cited for Bacillus sp. have been docked with PA genes and energy analyses have been made. Based on Orthologous gene mapping andin-silico studies, Nalidixic acid is reported as an effective drug against PA3168 gyrA for the treatment of CF and COPD.     

Unveiling the genes responsible for the unique Pseudomonas aeruginosa oleate-diol synthase activity

Pseudomonas aeruginosa displays the ability to perform bioconversion of oleic acid into a class of hydroxylated fatty acids known as oxylipins. A diol synthase activity is responsible for such a conversion, which proceeds through the dioxygenation of oleic acid to release hydroperoxide 10-H(P)OME ((10S)-hydroxy-(8E)-octadecenoic acid), followed by conversion of the hydroperoxide intermediate into 7,10-DiHOME ((7S,10S)-dihydroxy-(8E)-octadecenoic acid), both of which accumulate in the culture supernatant. Several mutants of P. aeruginosa PAO1 were analyzed for the production of 10-H(P)OME and 7,10-DiHOME and two of them (ORFs PA2077 and PA2078), unable to release hydroxylated fatty acids, were detected and selected for further analysis. Involvement of ORFs PA2077 and PA2078 in oleate-diol synthase activity was confirmed, and their respective role in the conversion of oleic acid was analyzed by mutation complementation. Activity restoration revealed that gene PA2077 codes for the 10S-dioxygenase activity (10S-DOX) responsible for the first step of the reaction, whereas PA2078 encodes for the (7S,10S)-hydroperoxide diol synthase enzyme (7,10-DS) which allows the conversion of 10-H(P)OME into 7,10-DiHOME. Heterologous expression of both enzymes separately showed that no hetero-complex formation is required for enzymatic activity. Bioinformatics and RT-PCR analysis revealed that both genes constitute a new fine regulated oleate-diol synthase operon, originated by a gene duplication event followed by neofunctionalization for environmental adaptation, being unprecedented in prokaryotes.