Cloning of the gene coding for the outer membrane receptor protein for ferric pseudobactin, a siderophore from a plant growth-promoting Pseudomonas strain

Plant growth-promoting Pseudomonas B10 produces its yellow-green, fluorescent siderophore (microbial iron transport agent) pseudobactin under iron-limiting conditions. A structural gene encoding the 85,000-Da putative outer membrane receptor protein for ferric pseudobactin was identified in a gene bank from Pseudomonas B10 prepared with the broad host-range conjugative cosmid cloning vector pLAFR1. Transposon Tn5 mutagenesis of recombinant plasmid pJLM300 localized the functional gene to a region of approximately 2.4 kilobases consistent with the apparent molecular weight of the receptor protein. Mobilization of pJLM300 into Pseudomonas A124 and A225, whose growth was inhibited by Pseudomonas B10 or pseudobactin, rendered these strains no longer susceptible to iron starvation by pseudobactin because they were now able to transport ferric pseudobactin. Pseudobactin biosynthetic genes flanked this receptor gene on both sides and were on separate operons. Transposon Tn5 insertion mutants of Pseudomonas B10 lacking this receptor protein were generated by a marker exchange technique and were defective in ferric pseudobactin transport. Such mutants could be complemented in trans by pJLM300. The production of pseudobactin, the receptor protein, and four other outer membrane proteins in Pseudomonas B10 was coordinately regulated by the level of intracellular iron.     

Isolation and analysis of genes involved in siderophore biosynthesis in plant-growth-stimulating Pseudomonas putida WCS358

The plant-growth-stimulating Pseudomonas putida WCS358 was mutagenized with transposon Tn5. The resulting mutant colony bank was screened for mutants defective in the biosynthesis of the fluorescent siderophore. A total of 28 mutants, divided into six different classes, were isolated that were nonfluorescent or defective in iron acquisition or both. These different types of mutants together with the probable overall structure of the siderophore, i.e., a small peptide chain attached to a fluorescing group, suggest a biosynthetic pathway in which the synthesis of the fluorescing group is preceded by the synthesis of the peptide part. A gene colony bank of P. putida WCS358 was constructed with the broad-host-range cosmid vector pLAFR1. This genomic library, established in Escherichia coli, was mobilized into the 28 individual mutants, screening for transconjugants restored in fluorescence or growth under iron-limiting conditions or both. A total of 13 cosmids were found to complement 13 distinct mutants. The complementation analysis revealed that at least five gene clusters, with a minimum of seven genes, are needed for siderophore biosynthesis. Some of these genes seem to be arranged in an operon-like structure.     

Structure of pseudobactin 7SR1, a siderophore from a plant-deleterious Pseudomonas

When grown in iron-limiting culture medium, sugar beet deleterious Pseudomonas 7SR1 produced extra-cellularly the yellow-green, fluorescent siderophore pseudobactin 7SR1. Pseudobactin 7SR1 had a molecular formula of C46H63N13O23 and a molecular mass of 1166 g/mol. Pseudobactin 7SR1 contained a cyclic octapeptide with the amino acid sequence L-Ala-Gly-Ser-Ser-threo-beta-OH-Asp-Thr-Ser-N delta-OH-Orn. Since pseudobactin 7SR1 was not affected by nonspecific enzymes, it might contain D-amino acids. A yellow-green, fluorescent quinoline derivative is postulated to be attached via an ester bond to the serine residue following the glycine. A malamide group was attached to carbon 3 of the quinoline derivative. The three bidentate iron(III)-chelating groups consisted of an alpha-hydroxy acid group derived from beta-hydroxyaspartic acid, an omicron-dihydroxy aromatic group derived from the yellow-green, fluorescent chromophore, and a hydroxamate group derived from N delta-acetyl-N delta-hydroxyornithine. The chemical structure of pseudobactin 7SR1 is remarkably similar to that of pseudobactin, the siderophore of plant growth promoting Pseudomonas B10.     

Structure of pseudobactin A214, a siderophore from a bean-deleterious Pseudomonas

Bean-deleterious Pseudomonas A214 produced the extracellular yellow-green, fluorescent siderophore [microbial iron(III) transport agent] pseudobactin A214 under iron-limiting conditions. Pseudobactin A214 has a molecular formula of C46H64N13O22 and a molecular mass of 1151 g/mol. Pseudobactin A214 contained an N-blocked linear octapeptide with the amino acid sequence Ser-Ala-Gly-Ser-Ala-threo-beta-OH-Asp-L-allo-Thr-N delta-OH-Orn with a yellow-green, fluorescent quinoline derivative attached via an amide bond to the amino terminus. A succinamide group was linked to carbon 3 of the quinoline derivative. Sequencing was accomplished by two-dimensional NMR spectroscopy and by Edman degradation of smaller peptides obtained from partial acid hydrolysis. Since pseudobactin A214 was not affected by nonspecific proteolytic enzymes, it might contain D-amino acids. The three bidentate iron-(III)-chelating groups consisted of a 1,2-dihydroxy aromatic group in the quinoline chromophore, an alpha-hydroxy acid group present as beta-hydroxyaspartic acid, and a hydroxamate group derived from N delta-acetyl-N delta-hydroxyornithine. The chemical structure of pseudobactin A214 is remarkably similar to those of pseudobactin and pseudobactin 7SR1, the siderophores of plant growth promoting and plant-deleterious Pseudomonas B10 and Pseudomonas 7SR1, respectively.     

Characterization of Fluorescent Siderophore-Mediated Iron Uptake in Pseudomonas sp. Strain M114: Evidence for the Existence of an Additional Ferric Siderophore Receptor

In Pseudomonas sp. strain M114, the outer membrane receptor for ferric pseudobactin M114 was shown to transport ferric pseudobactins B10 and A225, in addition to its own. The gene encoding this receptor, which was previously cloned on pCUP3, was localized by Tn5 mutagenesis to a region comprising >1.6 kb of M114 DNA. A mutant (strain M114R1) lacking this receptor was then created by a marker exchange technique. Characterization of this mutant by using purified pseudobactin M114 in radiolabeled ferric iron uptake studies confirmed that it was completely unable to utilize this siderophore for acquisition of iron. In addition, it lacked an outer membrane protein band of 89 kDa when subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. As a result, growth of the mutant was severely restricted under low-iron conditions. However, this phenotype was reversed in the presence of another fluorescent siderophore (pseudobactin MT3A) from Pseudomonas sp. strain MT3A, suggesting the presence of a second receptor in strain M114. Furthermore, wild-type Pseudomonas sp. strain B24 was not able to utilize ferric pseudobactin MT3A, and this phenotype was not reversed upon expression of the M114 receptor encoded on pCUP3. However, a cosmid clone (pMS1047) that enabled strain B24 to utilize ferric pseudobactin MT3A was isolated from an M114 gene bank. Radiolabel transport assays with purified pseudobactin MT3A confirmed this event. Plasmid pMS1047 was shown to encode an outer membrane protein of 81 kDa in strain B24 under iron-limiting conditions; this protein corresponds to a similar protein in strain M114.     

Identification and cloning of a regulatory gene for nitrogen assimilation in the cyanobacterium Synechococcus sp. strain PCC 7942.

Twenty-seven mutants that were unable to assimilate nitrate were isolated from Synechococcus sp. strain PCC 7942. In addition to mutants that lacked nitrate reductase or nitrite reductase, seven pleiotropic mutants impaired in both reductases, glutamine synthetase, and methylammonium transport were also isolated. One of the pleiotropic mutants was complemented by transformation with a cosmid gene bank from wild-type strain PCC 7942. Three complementing cosmids were isolated, and a 3.1-kilobase-pair DNA fragment that was still able to complement the mutant was identified. The regulatory gene that was cloned (ntcA) appeared to be required for full expression of proteins subject to ammonium repression in Synechococcus sp.     

Identification of an additional ferric-siderophore uptake gene clustered with receptor, biosynthesis, and fur-like regulatory genes in fluorescent Pseudomonas sp. strain M114.

Five cosmid clones with insert sizes averaging 22.6 kilobases (kb) were isolated after complementation of 22 Tn5-induced Sid- mutants of Pseudomonas sp. strain M114. One of these plasmids (pMS639) was also shown to encode ferric-siderophore receptor and dissociation functions. The receptor gene was located on this plasmid since introduction of the plasmid into three wild-type fluorescent pseudomonads enabled them to utilize the ferric-siderophore from strain M114. The presence of an extra iron-regulated protein in the outer membrane profile of one of these strains was detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A ferric-siderophore dissociation gene was attributed to pMS639 since it complemented the ferric-siderophore uptake mutation in strain M114FR2. This mutant was not defective in the outer membrane receptor for ferric-siderophore but apparently accumulated ferric-siderophore internally. Since ferric-citrate alleviated the iron stress of the mutant, there was no defect in iron metabolism subsequent to release of iron from the ferric-siderophore complex. Consequently, this mutant was defective in ferric-siderophore dissociation. A fur-like regulatory gene also present on pMS639 was subcloned to a 7.0-kb BglII insert of pCUP5 and was located approximately 7.3 kb from the receptor region. These results established that the 27.2-kb insert of pMS639 encoded at least two siderophore biosynthesis genes, ferric-siderophore receptor and dissociation genes, and a fur-like regulatory gene from the biocontrol fluorescent Pseudomonas sp. strain M114.     

Identification of an additional ferric-siderophore uptake gene clustered with receptor, biosynthesis, and fur-like regulatory genes in fluorescent Pseudomonas sp. strain M114

Five cosmid clones with insert sizes averaging 22.6 kilobases (kb) were isolated after complementation of 22 Tn5-induced Sid- mutants of Pseudomonas sp. strain M114. One of these plasmids (pMS639) was also shown to encode ferric-siderophore receptor and dissociation functions. The receptor gene was located on this plasmid since introduction of the plasmid into three wild-type fluorescent pseudomonads enabled them to utilize the ferric-siderophore from strain M114. The presence of an extra iron-regulated protein in the outer membrane profile of one of these strains was detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A ferric-siderophore dissociation gene was attributed to pMS639 since it complemented the ferric-siderophore uptake mutation in strain M114FR2. This mutant was not defective in the outer membrane receptor for ferric-siderophore but apparently accumulated ferric-siderophore internally. Since ferric-citrate alleviated the iron stress of the mutant, there was no defect in iron metabolism subsequent to release of iron from the ferric-siderophore complex. Consequently, this mutant was defective in ferric-siderophore dissociation. A fur-like regulatory gene also present on pMS639 was subcloned to a 7.0-kb BglII insert of pCUP5 and was located approximately 7.3 kb from the receptor region. These results established that the 27.2-kb insert of pMS639 encoded at least two siderophore biosynthesis genes, ferric-siderophore receptor and dissociation genes, and a fur-like regulatory gene from the biocontrol fluorescent Pseudomonas sp. strain M114.     

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.     

Rhizosphere competence of fluorescent Pseudomonas sp. B24 genetically modified to utilise additional ferric siderophores

Abstract: The ability to utilise additional siderophores may increase the ecological fitness of biocontrol inoculants of Pseudomonas in the rhizosphere. Plasmid pCUP2 carries a copy of the gene pbu A coding for the membrane receptor of ferric pseudobactin M114. Pseudomonas sp. B24Rif containing pCUP2 can utilise ferric pseudobactin of P. fluorescens M114 in addition to its own siderophore. A larger fraction of the culturable resident fluorescent pseudomonads in the rhizosphere of sugarbeet grown in a low-iron sandy loam soil could supply siderophore-complexed iron to B24Rif(pCUP2) rather than to B24Rif. However, B24Rif and B24Rif(pCUP2) were found at similar population levels in the rhizosphere for 21 days after their inoculation on seeds. A total of 25 of 43 isolates of resident fluorescent Pseudomonas unable to cross-feed iron to B24Rif could cross-feed B24Rif(pCUP2) and they were subdivided into seven different strains by arbitrary-primed PCR fingerprinting. The siderophores produced by 11 of them were typed by HPLC and they were similar to pseudobactin M114. However, the ability to utilise ferric pseudobactin M114 did not improve the ecological fitness of B24Rif in the rhizosphere of sugarbeet although a larger fraction of the culturable resident fluorescent pseudomonads could supply pseudobactin M114-complexed iron to B24Rif(pCUP2) than to B24Rif.     

Construction and use of a gene bank of Alcaligenes eutrophus in the analysis of ribulose bisphosphate carboxylase genes.

A gene bank of the DNA from the hydrogen bacterium Alcaligenes eutrophus ATCC 17707 was constructed in the broad host range cosmid vector pVK102 and established in Escherichia coli. A triparental replica plating procedure was developed to allow rapid screening of large numbers of isolated E. coli gene bank clones for complementation of A. eutrophus mutants. This procedure was used to identify hybrid cosmids that complemented CO2 fixation-negative (Cfx-), H2 uptake-negative (Hup-), and auxotrophic A. eutrophus mutants. The average insert DNA size in these hybrid cosmids was 22 kilobases. Nine hybrid cosmids that complemented ribulose bisphosphate carboxylase-negative (RuBPCase-) mutants were characterized. They fell into two distinct groups with respect to their restriction patterns. Complementing subclones from the two groups contained no common restriction fragments, but hybridization experiments indicated a high degree of sequence homology. Restriction fragments corresponding to one of the subclones were absent in total DNA from a cured strain that had lost plasmid pAE7, indigenous to the wild type. It is concluded that functional CO2 fixation genes in the A. eutrophus ATCC 17707 chromosome are reiterated on plasmid pAE7.     

铜绿假单胞菌泳动能力相关新基因的筛选及鉴定

从Mu转座突变子文库中经过表型筛选,得到12株泳动(Swimming motility)能力缺陷的突变子,经Mu转座子插入位点的确认、基因克隆及测序分析发现其中10个突变子中Mu转座子分别插入到10个不同的与鞭毛运动和功能相关的基因中,2个突变子中Mu转座子插入到功能未知的新基因(PA2950和PA5022)中,电镜观察结果表明这2个突变株均具有完整的鞭毛,初步推测这2个基因可能是参与鞭毛泳动的能量代谢、趋化作用或信息传递的新基因。     

Cloning of DNA fragments carrying hydrogenase genes of Rhodopseudomonas capsulata

A cosmid library of Rhodopseudomonas capsulata DNA was constructed in Escherichia coli HB101 using the broad-host-range cosmid vector pLAFR1. More than ninety per cent of the clones in the bank contained cosmids with DNA inserts averaging 20 kilobase pairs in length. Mutants deficient in uptake hydrogenase (Hup-) were obtained from R. capsulata strain B10 by ethylmethylsulfonate (EMS) mutagenesis. The content of hydrogenase protein in Hup- mutant cells was tested by rocket immunoelectrophoresis. Hup- mutants (Rifr) were complemented with the clone bank by conjugation and, from the transconjugants selected by rifampicin and tetracycline resistance, Hup+ transconjugants were screened for the ability to grow photoautotrophically and to reduce methylene blue in a colony assay. The recombinant plasmid pAC57 restored hydrogenase activity in the Hup- mutants RCC8, RCC10, RCC12 and ST410 whereas pAG202 restored that of IR4. The cloned R. capsulata DNA insert of pAC57 gave 5 restriction fragments by cleavage with EcoRI endonuclease. Fragment 1 (7 kb) restored hydrogenase activity in Hup- mutant strains RCC12 and ST410 and fragment 5 (1.3 kb) in strains RCC8 and RCC10. Since the 2 cosmids pAC57 and pAG202 are different cosmids, as indicated by restriction analyses and absence of cross hybridization, it is concluded that at least two hup genes are required for the expression of hydrogenase activity in R. capsulata.