Expression in Escherichia coli K-12 of the 76,000-dalton iron-regulated outer membrane protein of Shigella flexneri confers sensitivity to cloacin DF13 in the absence of Shigella O antigen.

One of the chromosomal segments associated with virulence in Shigella flexneri encodes the production of aerobactin and the synthesis of an iron-regulated 76-kilodalton outer membrane protein believed to be the ferric-aerobactin receptor. However, S. flexneri expressing this putative aerobactin receptor, which is slightly larger than that encoded by pColV, is insensitive to the killing action of cloacin DF13, a bacteriocin which binds to other aerobactin receptor proteins and kills the cells. In this paper we show that the conjugal transfer of DNA encoding the iron-regulated 76-kilodalton protein from S. flexneri to Escherichia coli K-12 conferred cloacin DF13 sensitivity on the recipients. However, E. coli K-12 which had also inherited genes specifying Shigella O-antigen biosynthesis remained cloacin insensitive. The data suggest that it is unwise to use cloacin DF13 sensitivity alone to screen transconjugants or clinical isolates for the expression of aerobactin receptor proteins.

Temperature inhibition of siderophore production in Azospirillum brasilense.

The effect of growth at 42 degrees C on the different components of the siderophore-mediated iron transport that are induced by iron limitation in Azospirillum brasilense was examined. Biosynthesis of the siderophore spirilobactin was strongly inhibited (20-fold) by growth at 42 degrees C, whereas the transport of iron by the ferric-spirilobactin transport system and the induction of the iron-regulated outer membrane proteins were unaffected.

Cloning and characterization of a gene encoding an outer membrane protein required for siderophore-mediated uptake of Fe3+ in Pseudomonas putida WCS358.

In iron-limited environments plant-growth-stimulating Pseudomonas putida WCS358 produces a yellow-green fluorescent siderophore called pseudobactin 358. Ferric pseudobactin 358 is efficiently taken up by cells of WCS358 but not by cells of another rhizophere-colonizing strain, Pseudomonas fluorescens WCS374. A gene bank containing partial Sau3A DNA fragments from WCS358 was constructed in a derivative of the broad-host-range cosmid pLAFR1. By mobilization of this gene bank to strain WCS374 a cosmid clone, pMR, which made WCS374 competent for the utilization of pseudobactin 358 was identified. By subcloning of the 29.4-kilobase (kb) insert of pMR the essential genetic information was localized on a BglII fragment of 5.3 kb. Tn5 mutagenesis limited the responsible gene to a region of approximately 2.5 kb within this fragment. Since the gene encodes an outer membrane protein with a predicted molecular mass of 90,000 daltons, it probably functions as the receptor for ferric pseudobactin 358. The gene is flanked by pseudobactin 358 biosynthesis genes on both sides and is on a separate transcriptional unit. WCS374 cells carrying pMR derivatives with Tn5 insertions in the putative receptor gene did not produce the 90,000-dalton protein anymore and were unable to take up Fe3+ via pseudobactin 358. In WCS358 cells as well as in WCS374 cells the gene is expressed only under iron-limited conditions.

Siderophore-mediated uptake of Fe3+ by the plant growth-stimulating Pseudomonas putida strain WCS358 and by other rhizosphere microorganisms.

Under iron-limited conditions, Pseudomonas putida WCS358 produces a siderophore, pseudobactin 358, which is essential for the plant growth-stimulating ability of this strain. Cells of strain WCS358, provided that they have been grown under Fe3+ limitation, take up 55Fe3+ from the 55Fe3+-labeled pseudobactin 358 complex with Km and Vmax values of 0.23 microM and 0.14 nmol/mg of cell dry weight per min, respectively. Uptake experiments with cells treated with various metabolic inhibitors showed that this Fe3+ uptake process was dependent on the proton motive force. Furthermore, strain WCS358 was shown to be able to take up Fe3+ complexed to the siderophore of another plant-beneficial P. fluorescens strain, WCS374. The tested pathogenic rhizobacteria and rhizofungi were neither able to grow on Fe3+-deficient medium in the presence of pseudobactin 358 nor able to take up 55Fe3+ from 55Fe3+-pseudobactin 358. The same applies for three cyanide-producing Pseudomonas strains which are supposed to be representatives of the minor pathogens. These results indicate that the extraordinary ability of strain WCS358 to compete efficiently for Fe3+ is based on the fact that the pathogenic and deleterious rhizosphere microorganisms, in contrast to strain WCS358 itself, are not able to take up Fe3+ from Fe3+-pseudobactin 358 complexes.

Iron and virulence in the family Enterobacteriaceae.

The ability of bacterial pathogens to acquire iron in the host is an essential component of the disease process. Pathogenic Enterobacteriaceae spp. may either scavenge host iron sources such as heme or induce high-affinity iron-transport systems to remove iron from host proteins. The ease with which iron is acquired from the host will be at least partially determined by the iron status of the host at the time of infection. In response to infection, mammalian hosts reduce serum iron levels and withhold iron from the invading microorganisms. Thus the competition for iron is an active process which influences the outcome of a host-bacterial interaction.

Effects of siderophores on the growth of Pseudomonas aeruginosa in human serum and transferrin.

A combination of the siderophores produced by Pseudomonas aeruginosa, pyochelin and pyoverdin, dramatically stimulates the growth of this bacterium in medium containing human transferrin. The amount of growth stimulation observed when each siderophore was added alone was only slightly less than the amount observed with the combination. Siderophore-defective mutants of strain PAO1 were isolated to test the effects of siderophore production on growth in transferrin and human serum. The pyoverdin-proficient (Pvd+), pyochelin-deficient (Pch-) strain (IA5) grows just as well as the parent (PAO1), which produces both siderophores. On the other hand, the Pvd- Pch+ strain (211-5) has severely retarded growth, similar to that demonstrated by a mutant lacking production of both siderophores (IA1), but has an accelerated log phase compared with strain IA1 at the later stages of the growth curve. However, the Pvd- Pch+ strain (211-5) had no observable advantage over the Pvd- Pch- strain, IA1, during incubation in human serum. The inability of P. aeruginosa strains to produce pyochelin in glucose-minimal medium may explain the poor growth of 211-5 in this medium and in human serum. The 211-5 strain grows much better than the IA1 strain in the medium that allows pyochelin synthesis, but it still does not grow as well as the Pvd+ Pch- strain (IA5). Therefore, pyoverdin appears to be the most important siderophore for growth in human serum.

Synthesis of aerobactin and a 76,000-dalton iron-regulated outer membrane protein by Escherichia coli K-12-Shigella flexneri hybrids and by enteroinvasive strains of Escherichia coli.

One of the chromosomal segments associated with the virulence of Shigella flexneri and transferred to Escherichia coli K-12 by conjugation has been shown to code for the production of aerobactin and for the synthesis of an iron-regulated 76,000-dalton (76K) outer membrane protein. Analysis of various E. coli K-12-S. flexneri transconjugants showed that the genes involved with the synthesis of aerobactin and with the production of the 76K protein were linked to the mtl region of the S. flexneri chromosome. S. flexneri itself synthesized a 76K protein in its outer membrane under iron restriction as well as traces of 81K and 74K proteins. An examination of four enteroinvasive strains of E. coli showed that each produced aerobactin and a 76K outer membrane protein during iron-restricted growth. The profile of the iron-regulated proteins expressed by the enteroinvasive strains of E. coli was virtually identical to that expressed by the laboratory-constructed E. coli K-12-S. flexneri hybrids under the same growth conditions.

[Iron chelation. Biological significance and medical application]. / Eisenchelierung. Biologische Bedeutung und medizinische Anwendungen.

Iron, an essential element for all aerobic organisms, exists in a very insoluble form under physiological conditions. Therefore, most microorganisms secrete iron chelating compounds called siderophores which are able to sequester ferric ions from the environment. A vast number of such compounds has been isolated from cultures of microorganisms and tested for enhancement of iron excretion in experimental animals. Only one compound, deferrioxamine B, has been shown to be clinically effective and well tolerated in humans suffering from chronic iron overload. However, this drug can only be administered successfully by injection or slow infusion. In spite of considerable research it has not been possible to overcome this drawback by developing suitable formulations or derivatives which are orally active. Deferri-ferrithiocin, a novel type of siderophore, has recently been isolated from a streptomyces culture. This substance is well absorbed orally and has been shown to enhance the excretion of ferric ion in iron loaded rats. Further investigations are now necessary to establish acute toxicity levels and longterm tolerability before efficacy tests in man can be planned. Other recent developments in the field of metal chelation include experimental studies using deferrioxamine for the treatment of conditions resulting from toxic levels of iron or aluminium in chronically dialyzed patients. In addition, attempts are being made to administer chelation therapy in the treatment of various infections and chronic inflammation, as well as other conditions linked with disorders of iron metabolism.

Expression of a high-affinity mechanism for acquisition of transferrin iron by Neisseria meningitidis.

Iron-starved meningococci grown at either pH 7.2 or 6.6 were capable of removing and incorporating iron from human transferrin by a saturable, cell surface mechanism that specifically recognized transferrin rather than iron. The maximum expression of the iron uptake system occurred after 4 h of iron starvation. The uptake of the iron was dependent upon a functioning electron transport chain and was sensitive to 60 degrees C and trypsin. Cells grown under iron-sufficient conditions were incapable of accumulating iron from transferrin. No evidence was found for a primary role for cell-free soluble siderophores in the removal of iron from transferrin. The nonpathogenic neisseriae, Neisseria flava and N. sicca, were unable to utilize iron on transferrin.

Effect of pyochelin on the virulence of Pseudomonas aeruginosa.

A virulent isolate of Pseudomonas aeruginosa PAO1, which had been obtained from eight sequential intraperitoneal infections in mice compromised with iron and methotrexate, expressed greater lethality than the avirulent parent strain when both strains were injected into mice treated with iron. The present study demonstrates that pyochelin, a siderophore produced by P. aeruginosa, also increases the lethality of the virulent bacteria but not of the avirulent bacteria. Analysis of the growth and clearance of both virulent and avirulent strains in mice revealed that pyochelin increased the growth and lethality of virulent bacteria but only increased the survival of the avirulent bacteria. A streptomycin-dependent mutant of strain PAO1 (strd1) was used to demonstrate that pyochelin did not affect the clearance activity of mice. This strongly suggests that the effects of pyochelin in stimulating the persistence of avirulent bacteria and in increasing the lethality of virulent bacteria are due solely to the promotion of bacterial growth. Since the virulent bacteria were equivalent to the avirulent bacteria in utilizing pyochelin during in vitro growth in the presence of transferrin, it appears that the stimulation of growth by pyochelin allows the expression of additional virulence properties by the virulent bacteria.

Uptake of iron by Gomphosphaeria aponina, a possible control organism for the Florida red tide Pytochodiscus brevis.

The assimilation of iron, a growth-limiting metal ion of the cytotoxic marine cyanobacterium, Gomphosphaeria aponina, has been examined in both static and steady-state cultures using 59Fe (III). Uptake of iron by cells followed first-order kinetics, and biphasic (absorption and uptake) behavior was observed as suggested by noted differences between cultures incubated in the light and in the dark. Iron removal in illuminated cultures was rapid, occurring at rates comparable to exponential growth rates. Although uptake was mediated by a chelating agent (EDTA), synthesis and iron assisted transport by hydroxamate-type siderophores was not involved in the uptake of iron by cells, as determined by standard chemical and biological assays of iron deficient cultures. The ecological implications of this research is considered with respect to the cytotoxic antagonism between the cyanobacterium and Florida's red tide organism, Pytochodiscus brevis (Gymnodinium breve).

Iron status, immune response and susceptibility to infection.

Nutritional factors can modulate immune responses. The concentration of iron, amongst other nutrients, influences host defence mechanisms. In experimentally induced iron deficiency in animals, morbidity and mortality on bacterial challenge are increased several-fold. Cell-mediated immunity and intra-cellular bacterial killing by polymorphonuclear leucocytes are impaired in iron-deficient individuals. This impairment is likely to be mediated by the effect of iron lack on cell proliferation, DNA synthesis and activity of iron-containing and iron-dependent enzymes involved in killing and elimination of microbes. Conversely, the availability of the free iron is a critical determinant for bacterial multiplication. It is not surprising then that epidemiological and clinical data on the frequency of infections--bacterial, fungal and others--in iron-deficient, iron-overloaded and healthy groups differ so widely. Vulnerability to infection based on the individual's iron status must be the net result of the effect of iron, or the lack of it, on microbial growth on the one hand and on immunocompetence of the host on the other. The key to keeping these interactions within physiological bounds is 'optimal iron nutrition'.