Purification and Genetic Determination of Bacteriocin Production in<i>Enterobacter cloacae</i>

Graaf, Frits K. de; Tieze, G. A.; Bonga, S.E. Wendelaar; Stouthamer, A. H.

doi:10.1128/jb.95.2.631-640.1968

Cited by 40 publications

(15 citation statements)

References 30 publications

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“…Plasmid pABN1 DNA (4) was purified by cesium chloride-ethidium bromide ultracentrifugation, and a 6.8-kilobase-pair fragment was digested with restriction endonucleases Hindlll and EcoRI (Genofit, Geneva, Switzerland) used in accordance with the recommendations of the manufacturer. bla Susceptible to cloacin DF13 Former S15 strain (14) incubation at 37°C, the colonies were lysed, and the filters were dried, baked, and hybridized with the radioactive probe as described previously (6). Strains KH576 and BM21 were used as positive and negative controls, respectively (see Fig.…”

Section: Methodsmentioning

confidence: 99%

“…Cloacin DF13 is a bacteriocin that attaches to the same outer membrane protein that is involved in the transport of aerobactin, and cloacin sensitivity is indicative of the presence of a functional aerobactin transport system (3,23). The method used to examine susceptibility to cloacin DF13 was derived from De Graaf et al (14). Mitomycin C (Sigma) was added at 1 jig/ml to an exponentially growing culture of E. coli N5160 (Table 1) in brain heart infusion broth (Difco) incubated under aerated conditions for 10 min at 37°C.…”

Section: Methodsmentioning

confidence: 99%

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Presence and expression of aerobactin genes in virulent avian strains of Escherichia coli

Lafont¹,

Dho²,

D'Hauteville³

et al. 1987

Infect Immun

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Virulent and nonvirulent isolates of avian Escherichia coli were tested for the presence of aerobactin genes by colony hybridization with a specific gene probe constructed from plasmid pABN1 (A. Bindereif and J. B. Neilands, J. Bacteriol. 153:1111Bacteriol. 153: -1113Bacteriol. 153: , 1983. Positive hybridization with the gene probe was highly correlated with virulence, as measured by the 50% lethal dose of the strains for chicks. Evidence for the expression of aerobactin genes in the virulent strains was obtained by demonstrating their susceptibility to cloacin DF13, which binds to the same receptor that binds aerobactin, and their ability to produce aerobactin, as revealed by cross-feeding the E. coli mutant W0987 (aroBfepA iuc iut+), which is unable to synthesize but capable of taking up aerobactin. We suggest that the production of aerobactin is involved in the virulence of avian septicemic E. coli.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Presence and expression of aerobactin genes in virulent avian strains of Escherichia coli

Lafont¹,

Dho²,

D'Hauteville³

et al. 1987

Infect Immun

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“…assayed by the cloacin sensitivity test (7). Cloacin DF13 was prepared by adding mitomycin to a growing nutrient broth culture of Enterobacter cloacae S458 as described by De Graff et al (13), except that the crude bacteriocin preparation was neither concentrated nor purified. Cells were pelleted by centrifugation, and the supernatant fluid containing cloacin activity was sterilized by membrane filtration and used as a crude cloacin DF13 preparation.…”

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confidence: 99%

Role of aerobactin in systemic spread of an opportunistic strain of Escherichia coli from the intestinal tract of gnotobiotic lambs

et al. 1992

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To assess the role of the aerobactin-related system in the virulence of bovine opportunistic Escherichia coli, and to determine the stage(s) of the overall infectious process at which it is acting, germfree lambs were mixedly infected orally with two derivative strains of this bacterium differing in their ability (Iut+) or inability (lut-) to express a functional aerobactin-mediated iron transport system. The Iutstrain was compared with the Iut+ strain for colonization of the gut, translocation to the mesenteric lymph nodes (MLN), and spread to other organs and to the body fluids of diassociated lambs. The Iutmutant was found in smaller numbers in the duodenum, suggesting that aerobactin conferred a significant selective advantage for colonization of this intestinal segment. Although the two challenge strains translocated to MLN, the population level in the MLN was always higher for the Iut+ strain. Moreover, experimental infections resulted in recovery of only the Iut+ strain in the organs other than the MLN and in the body fluids. These results indicate a role for aerobactin in promoting systemic spread of the bacteria from the intestine. Direct evidence was obtained that aerobactin secretion occurred in vivo at both intestinal and extraintestinal sites of infection. In contrast to enterobactin, aerobactin was detected in the duodenum, jejunum, ileum, cecum, liver, spleen, kidney, urine, cerebrospinal fluid, and bile. The highest concentration of aerobactin was found in the urine, even when the samples were devoid of infecting bacteria. All of these findings suggest that aerobactin is released in vivo in a diffusible form and that it may be an important step in the production of disease by intestinal opportunistic E. coli.

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“…The presence of the aerobactin outer membrane receptor was assayed by the cloacin sensitivity test (7). Cloacin DF13 was prepared by adding mitomycin C to a growing nutrient broth culture of Enterobacter cloacae S458 as described by De Graaf et al (11), except that the crude bacteriocin preparation was neither concentrated nor purified. XA/CV30 and H646 were used as sensitive control strains, and DB6433 and IR20/111N were used as resistant control strains.…”

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confidence: 99%

Differences in excretion and efficiency of the aerobactin and enterochelin siderophores in a bovine pathogenic strain of Escherichia coli

Vartanian¹

1988

Infect Immun

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Secretion of aerobactin is thought to play an important part in the virulence of invasive Escherichia coli also capable of synthesizing enterochelin. Why, despite its markedly lower affinity for iron than that of enterochelin, aerobactin proves to be the' predominant active siderophore for bacterial growth in transferrin was investigated. We studied the action of two iron chelators, 2,2'-dipyridyl and transferrin, in expression of the aerobactin and enterochelin genes. Specifically, we describe the sequential localization of the two siderophores in the cell compartments during bacterial growth under different iron limitation conditions. Our results demonstrated that, whatever the exogenous iron-chelating agent used, aerobactin was rapidly excreted, whereas enterochelin accumulated early in periplasm before its very belated release into the external medium. This work also showed that the advantage of aerobactin over enterochelin in competition with transferrin was not due to (i) lack of enterochelin activity, (ii) a cell-bound aerobactin-dependent mechanism, (iii) antagonism between the two siderophores, and probably (iv) genetic preferential induction of aerobactin. We propose that the superiority of aerobactin in competing with transferrin for iron(Ill) was a consequence of its more rapid excretion with respect to enterochelin. In contrast to transferrin, 2,2'-dipyridyl induced a greater efficiency of enterochelin, possibly by a more permanent function as iron-binding compounds in the bacterial envelope. In summary, unlike aerobactin, enterochelin appears to be a weakly secreted high-affinity iron ligand.

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Purification and Genetic Determination of Bacteriocin Production inEnterobacter cloacae

Cited by 40 publications

References 30 publications

Presence and expression of aerobactin genes in virulent avian strains of Escherichia coli

Presence and expression of aerobactin genes in virulent avian strains of Escherichia coli

Role of aerobactin in systemic spread of an opportunistic strain of Escherichia coli from the intestinal tract of gnotobiotic lambs

Differences in excretion and efficiency of the aerobactin and enterochelin siderophores in a bovine pathogenic strain of Escherichia coli

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