Iron-starved Cells Research Articles

Anthranilate-promoted iron uptake in Rhizobium leguminosarum

Anthranilate promoted the uptake of ferric iron into iron-starved cells of Rhizobium leguminosarum GF160. The uptake system was a saturable function of the concentration of ferric anthranilate. It was characterized by an apparent K m of 6 μM and a V max of 1.6 nmol/min/mg cell protein. Uptake was temperature dependent and inhibited by the metabolic poisons arsenate and iodoacetate. The proton motive force may not be involved since no effect was demonstrated by the respiratory inhibitor sodium azide and by various uncouplers. The anthranilate-promoted iron uptake was lower for cells grown in increasing levels of available iron and the addition of anthranilic acid to low-iron cultures resulted in a stimulation of bacterial growth. During growth under iron deficiency, anthranilic acid was not assimilated by the cells.

Membrane Development in the Cyanobacterium, Anacystis nidulans, during Recovery from Iron Starvation

Deprivation of iron from the growth medium results in physiological as well as structural changes in the unicellular cyanobacterium Anacystis nidulans R2. Important among these changes are alterations in the composition and function of the photosynthetic membranes. Room-temperature absorption spectra of iron-starved cyanobacterial cells show a chlorophyll absorption peak at 672 nanometers, 7 nanometers blue-shifted from its normal position at 679 nanometers. Iron-starved cells have decreased amounts of chlorophyll and phycobilins. Their fluorescence spectra (77K) have one prominent chlorophyll emission peak at 684 nanometers as compared to three peaks at 687, 696, and 717 nanometers from normal cells. Chlorophyll-protein analysis of iron-deprived cells indicated the absence of high molecular weight bands. Addition of iron to iron-starved cells induced a restoration process in which new components were initially synthesized and integrated into preexisting membranes; at later times, new membranes were assembled and cell division commenced. Synthesis of chlorophyll and phycocyanins started almost immediately after the addition of iron. The absorption peak slowly returned to its normal wavelength within 24 to 28 hours. The fluorescence emission spectrum at 77K changed over a period of 14 to 24 hours during which the 696- and 717-nanometer peaks grew to their normal levels, and the 684 nanometer peak moved to 687 nanometers and its relative intensity decreased to its normal level. Analysis of chlorophyll-protein complexes on polyacrylamide gels showed that high molecular weight chlorophyll-protein bands were formed during this time, and that low molecular weight bands (related to photosystem II) disappeared. The origin of the fluorescence emission at 687 and 696 nanometers is discussed in relation to the specific chlorophyll-protein complexes formed during iron reconstitution.

Utilization of iron complexes in an animal cell.

The ciliate protozoan Tetrahymena thermophila was grown in synthetic nutrient medium in the absence of the iron chelator citrate. Utilization and toxicity of various iron compounds or complexes in iron-starved cells were assessed from the number of cell doublings obtained within a standard time. The compounds tested included complexes formed between ortho-phosphates and two forms of ferric hydroxides, native and cationized ferritin, and tris-acetylacetonato Fe(III). The ferric hydroxo ortho-phosphate particles are toxic and can be removed from the medium by Millipore filtration. Uptake of ferritin and tris-acetylacetonato-Fe(III) is independent of food vacuole formation and seems to occur by micropinocytosis and by plasma membrane translocation, respectively.

Energy-independent uptake of iron from citrate by isolated outer membranes of Neisseria meningitidis

Cyanide-poisoned Neisseria meningitidis SD1C cells rapidly took up 55Fe from iron-citrate complexes during the first 2 min, after which no further iron was accumulated. [14C]citrate was not taken up concomitantly with 55Fe by these cells. The 55Fe taken up by the poisoned cells was found in the membrane fraction after cells were broken; 70% of the radioactivity was distributed in the outer membrane, and 30% was in the inner membrane. Isolated outer membranes from iron-starved cells were as capable of iron uptake from citrate as intact cells were. As with whole cells, [14C]citrate was not taken up by isolated outer membranes. A polyacrylamide gel electrophoresis analysis of the proteins from citrate-dialyzed outer membranes after the uptake of 55Fe revealed that the radioactivity was associated with a major band of 36,500 molecular weight.

Iron Supply ofEscherichia coliwith Polymer‐Bound Ferricrocin

Uptake of ferric iron from ferricrocin was studied in Escherichia coli using a polymer-coupled ferricrocin that was unable to penetrate into the cell. Ferricrocinyl polyethylene glycol succinate (Mr 7000 -- 8500) promoted growth of E. coli K-12 AB2847 aroB under iron-limiting conditions. In iron-starved cells, uptake of 55Fe could be demonstrated; the amount of iron accumulated amounted to 10% of that observed with free ferricrocin. The iron supply by ferricrocin bound to polyethylene glycol was strictly dependent upon the functions expressed by the tonA and the tonB genes, as was the iron uptake promoted by free ferricrocin. Polymer-bound ferricrocin protected cells against colicin M and phage T5 by competition for the common tonA-coded outer membrane receptor protein. In addition, the rate of iron transport via the negatively charged ferricrocinyl succinate was as fast as via the neutral ferricrocin molecule. No ligand was found associated with the cells. Penetration of chelator beyond receptor is not necessary for siderophore-mediated iron uptake. It is concluded that sufficient amounts of iron can be released from the polymer complex to satisfy growth requirements.

A schizokinen (siderochrome) auxotroph of [formula omitted] induced with N-methyl-N′-nitro-N-nitrosoguanidine

Siderophore produced by cowpea Rhizobium GN1 (Peanut isolate) was shown to be involved in iron uptake by this organism. Siderophore enhanced iron uptake in iron-starved cells. SDS-PAGE analysis of the outer membrane proteins showed two iron repressible outer membrane proteins with approximate molecular mass of 80 kDa and 76 kDa. A siderophore non-producing mutant, which was unable to grow on a medium containing synthetic iron chelators unless and until iron was added exogenously in the medium, could use siderophore of the wild-type for iron uptake indicating that the receptor for Fe-siderophore complex was intact in the mutant.