Translational regulation of ferritin synthesis in rat spleen: effects of iron and inflammation

Translational control of ferritin synthesis was studied in rat spleen, and compared with that for liver, heart and brain, in response to iron and inflammation. Spleen concentrations of total RNA in the ribonucleoprotein (mRNP) fraction was comparable to that for liver, while polyribosomal RNA was less. Both fractions were ten-fold lower in heart and brain. In untreated animals, the mRNP fraction of all tissues had the largest portion of the ferritin mRNA, as determined by slot blot hybridization with 32P-labeled cDNA for the L subunit. Acute treatment with ferric ammonium citrate shifted the spleen ferritin mRNA to the polyribosome fraction. This was also so in liver but not in the heart and brain which took up much less iron. The findings were confirmed by hybridization studies of mRNPs and polyribosomes separated in sucrose gradients. Turpentine-induced inflammation also caused a shift in ferritin mRNA from the mRNP to the polyribosome fraction of spleen and liver, over 12 h. We conclude that as in liver, spleen ferritin synthesis is under translational control by iron, and that both tissues also respond to inflammation by shifting of ferritin mRNA to the polyribosomes.     

Iron uptake by Chang cells from transferrin,nitriloacetate and citrate complexes: The effects of iron-loading and chelation with desferrioxamine

Iron uptake by Chang liver cells in culture is about thirty times as great when ferric nitriloacetate is used as a donor as when iron-transferrin is used. Iron uptake from ferric citrate is no greater than from iron-transferrin. Most of the intracellular iron derived from transferrin is found in the supernatant after 20 000 × g centrifugation of the cell homogenate for 40 min: about half of this is in the form of ferritin. Iron derived from ferric nitriloacetate is found largley in the membranous pellet after centrifugation and very little of this is in the form of ferritin.Iron incorporated in cytosol ferritin is easily available for chelation by desferrioxamine and this process is facilitated by ascorbic acid. Membrane-bound iron is less available for chelation. This tissue culture model forms a convenient basis for the study of iron overlead and iron chelation.     

Iron prevents ferritin turnover in hepatic cells

It has long been assumed that iron regulates the turnover of ferritin, but evidence for or against this idea has been lacking. This issue was addressed using rat hepatoma cells with characteristics of hepatocytes subjected to a continuous influx of iron. Iron-pretreated cells were pulsed with [(35)S]Met for 60 min or with (59)Fe overnight and harvested up to 30 h thereafter, during which they were/were not cultured with ferric ammonium citrate (FAC; 180 microm). Radioactivity in ferritin/ferritin subunits of cell heat supernatants was determined by autoradiography of rockets obtained by immunoelectrophoresis or after precipitation with ferritin antibody and SDS-PAGE. Both methods gave similar results. During the +FAC chase, the concentration of ferritin in the cells increased linearly with time. Without FAC, the half-life of (35)S-ferritin was 19-20 h; with FAC there was no turnover. Without FAC, the iron in ferritin had an apparent half-life of 20 h; in the presence of FAC there was no loss of (59)Fe. Without FAC, concentrations of ferritin iron and protein also decreased in parallel. We conclude that a continuous influx of excess iron can completely inhibit the degradation of ferritin protein and that the iron and protein portions of ferritin molecules may be coordinately degraded.     

Differential effects of iron and inflammation on ferritin synthesis on free and membrane-bound polyribosomes of rat liver.

We have examined the distribution of ferritin mRNA to free and endoplasmic reticulum (ER)-bound liver polyribosomes during inflammation and iron treatment of rats. Postnuclear tissue supernatants were fractionated on a discontinuous sucrose gradient developed to separate free and bound polyribosomes. Total RNA recovered averaged 3.2 mg/g tissue, 40% of which was with ER and 30% with the free polyribosomes, about 25% being with the postribosomal/RNP fraction. Slot-blot hybridization of equal portions of RNA revealed that 12 h after injection of turpentine to induce inflammation, ferritin mRNA was concentrated on the ER-bound polyribosomes, while it was concentrated on the free polyribosomes 2 h after injection of ferric ammonium citrate. Differences were highly significant, based on multiple determinations and densitometry. Profiles of ferritin mRNA distribution on linear sucrose gradients corroborated the differential findings. Concentrations of total ferritin mRNA per gram liver doubled with iron treatment but were not significantly different 12 h after turpentine treatment. At the same time point after turpentine, ferritin protein synthesis was increased twofold, as measured by the 1 h incorporation of [14C]leucine. We conclude that a significant portion of ferritin mRNA always associates with the ER-bound polyribosomes, and that inflammation and iron differentially alter the polysomal distribution of ferritin mRNA, suggesting that two different kinds of mRNA may be involved.     

A study of ferritin iron formation in the rabbit alveolar macrophage

In order to investigate the intracellular pathway of iron to ferritin, rabbit alveolar macrophages were incubated with ⁵⁹FCl₃, homogenized by sonification, and a soluble cell fraction separated from the stroma by centrifugation at 23 000 g. The soluble fraction was examined by gel filtration using Sephadex. Two peaks were identified in the eluate at 254 nm; peak I contained a group of proteins, including ferritin, and most of the eluted radioactivity. The ⁵⁹Fe in this peak was confined to ferritin; no other ⁵⁹Fe-binding protein was identified. Peak II contained a small amount of ⁵⁹Fe. Chase experiments with ‘cold’ iron showed that peak I ⁵⁹Fe was derived from ⁵⁹Fe associated with the cell stroma. A protein carrier for ⁵⁹Fe between the stroma and ferritin was not identified in the eluate of the soluble fraction. Rather it appeared that iron moved from the stroma through the cytoplasm to ferritin in a low molecular weight form.     

Mode of action of iron on arylsulphatases under acute lead acetate treated conditions in rats

Arylsulphatases A, B and C were found to be inhibited in liver and kidney tissues under lead acetate-treated conditions (both in vivo and in vitro) in rats. When lead acetate-treated animals (in vivo) were supplemented with ferric ammonium citrate (in vivo), a remarkable recovery was found in the activities of all arylsulphatases A, B and C whereas ferric ammonium citrate itself had no effect on the activities of arylsulphatases. When both the in vivo and in vitro lead acetate-treated arylsulphatases were supplemented with the purified ferritins (in vitro) it was observed that lead-induced inhibition of the activities of arylsulphatases was successfully reversed. It was also found that ferritins were able to bind a large quantity of lead. These results indicated that ferritins were directly involved for reactivation of arylsulphatases which were inhibited by lead. It was well established that a response to iron administration in rats was an immediate de novo stimulation of ferritin biosynthesis. Iron might therefore protect the enzymatic activities of arylsulphatases by enhancing the level of ferritin in liver and kidney tissues which is known to bind a large quantity of lead thereby ameliorating their toxic effects in the living system.     

Influence of iron-saturation of plasma transferrin in iron distribution in the brain

Based on the evidence that iron distribution in the peripheral tissues is changed by iron-saturation of plasma transferrin, the influence of iron-saturation of plasma transferrin in iron delivery to the brain was examined. Mouse plasma was pre-incubated with ferric chloride in citrate buffer to saturate transferrin and then incubated with (59)FeCl(3). Peak retention time of (59)Fe was transferred from the retention time of transferrin to that of mercaptalbumin, suggesting that iron may bind to albumin in the plasma in the case of iron-saturation of transferrin. When mice were intravenously injected with ferric chloride in citrate buffer 10 min before intravenous injection of (59)FeCl(3), 59Fe concentration in the plasma was remarkably low. (59)Fe concentration in the liver of iron-loaded mice was four times higher than in control, while 59Fe concentration in the brain of iron-loaded mice was approximately 40% of that of control mice. Twenty-four hours after intravenous injection of (59)FeCl(3), brain autoradiograms also showed that (59)Fe concentrations in the brain of iron-loaded mice were approximately 40-50% of those of control mice in all brain regions tested except the choroid plexus, in which (59)Fe concentration was equal. These results suggest that the fraction of non-transferrin-bound iron is engulfed by the liver, resulting in the reduction of iron available for iron delivery to the brain in iron-loaded mice. Transferrin-bound iron may be responsible for the fraction of iron in circulation that enters the brain.     

Ferritin forms dynamic oligomers to associate with microtubules in vivo: implication for the role of microtubules in iron metabolism

Ferritin, a ubiquitously distributed iron storage protein, has been reported to interact with microtubules in vitro (Hasan et al., 2005, FEBS journal 272:822-831). Here, we demonstrate that ferritin binds with the microtubules in an oligomeric form and that the microtubule-bound ferritin contains more than two-fold amount of iron compared to the unbound ferritin fraction in vitro. Indirect immunofluorescence microscopy showed that a significant fraction of the ferritin molecules colocalized with the microtubules as oligomers in a wide variety of cell lines. These findings are consistent with the immediate oligomerization of rhodamine-labeled ferritin, microinjected in living human hepatoma cells. Ferritin oligomers were dynamic in the cytoplasm, and an anti-microtubule drug significantly inhibited their intracellular movement. Treatment of cells with an iron donor, ferric ammonium citrate, remarkably increased the number of cells containing ferritin oligomers. On the other hand, when the cells, such as mouse neuroblastoma cells, were deprived of iron, ferritin oligomers were localized in the microtubule dense, neurite shafts, but were disappeared from the microtubule deficient neurite tips. These data indicate that the microtubules provide a scaffold for the cytoplasmic distribution and transport of the iron-rich ferritin and implicate the role of microtubules in iron metabolism.     

Iron utilization in rabbit reticulocytes: A study using succinylacetone as an inhibitor of heme synthesis

We have investigated the effect of succinylacetone (4,6-dioxoheptanoic acid) on hemoglobin synthesis and iron metabolism in reticulocytes. Succinylacetone, 0.1 and 1 mM, inhibited [2-¹⁴C]glycine incorporation into heme by 91.2 and 96.4%, respectively, and into globin by 85 and 90.2%, respectively. 60 μM hemin completely prevented the inhibition of globin synthesis by succinylacetone, indicating that succinylacetone inhibits specifically the synthesis of heme. Added porphobilinogen, but not δ-aminolevulinic acid, partly overcame the inhibition of ⁵⁹Fe incorporation into heme caused by succinylacetone suggesting that the drug inhibits δ-aminolevulinic acid dehydratase in reticulocytes. Succinylacetone, 10 μM, 0.1 and 1 mM, inhibited ⁵⁹Fe incorporation into heme by 50, 90 and 93%, respectively, but stimulated reticulocyte ⁵⁹Fe uptake by about 25–30%. In succinylacetone-treated cells ⁵⁹Fe accumulates in a fraction containing plasma membranes and mitochondria as well as cytosol ferritin and an unidentified low molecular weight fraction obtained by Sephacryl S-200 chromatography. Reincubation of washed succinylacetone- and ⁵⁹Fe-transferrin-pretreated reticulocytes results in the transfer of ⁵⁹Fe from the particulate fraction (plasma membrane plus mitochondria) into hemoglobin and this process is considerably stimulated by added protoporphyrin. Although the nature of the iron accumulated in the membrane-mitochondria fraction in succinylacetone-treated cells is unknown some of it is utilizable for hemoglobin synthesis, while cytosolic ferritin iron would appear to be mostly unavailable for incorporation into heme.     

Synthesis of ferritin by neuroblastoma

Ferritin is an iron-containing protein which is a normal component of serum. The levels of ferritin are increased in the sera of some children with neuroblastoma, and this increase appears to be a potent indicator of prognosis. To determine whether synthesis of ferritin by the tumor cells contributes to these increased serum levels, we examined incorporation of radiolabeled leucine by CHP 126, a neuroblastoma derived cell line, into ferritin. Using sequential immunoprecipitation and gel electrophoresis of sonicates from cells maintained in medium containing iron in amounts standard for tissue culture, incorporation of label into ferritin was 0.04% of that into total protein synthesized over the same time period. Addition of up to 40 micrograms of iron as ferric ammonium citrate increased ferritin synthesis to a maximum of 0.16% without altering synthesis of total protein. The pattern of iron-induced enhancement in the neuroblastoma cells was similar to that which was seen using Chang liver cells, a cell line well known to be capable of ferritin synthesis. These results confirm that neuroblastoma cells can synthesize ferritin and that synthesis is regulated by exogenous iron.     

Factors involved in the regulation of iron transport through reticuloendothelial cells

The effects of various maneuvers on the handling of 59Fe-labeled heat-damaged red cells (59Fe HDRC) by the reticuloendothelial system were studied in rats. Raising the saturation of transferrin with oral carbonyl iron had little effect on splenic release of 59Fe but markedly inhibited hepatic release. Splenic 59Fe release was, however, inhibited by the prior administration of unlabeled HDRC or by the combination of carbonyl iron and unlabeled HDRC. When carbonyl iron was administered with unlabeled free hemoglobin, the pattern of 59Fe distribution was the same as that observed when carbonyl iron was given alone. 59Fe ferritin was identified in the serum after the administration of 59Fe HDRC but the size of the fraction was not affected by raising the saturation of transferrin. Sizing column analyses of tissue extracts from the spleen at various times after the administration of 59Fe HDRC revealed a progressive shift from hemoglobin to ferritin, with only small amounts present in a small molecular weight fraction. The small molecular weight fraction was greater in hepatic extracts, with the difference being marked in animals that had received prior carbonyl iron. The increased hepatic retention of 59Fe associated with a raised saturation of transferrin was reduced by a hydrophobic ferrous chelator (2,2'-bipyridine), a hydrophilic ferric chelator (desferrioxamine), and an extracellular hydrophilic ferric chelator (diethylene-triaminepentacetic acid). Transmembrane iron transport did not seem to be a rate-limiting factor in iron release, since no differences in 59Fe membrane fractions were noted in the different experimental settings. These findings are consistent with a model in which RE cells release iron from catabolized red cells at a relatively constant rate. When the saturation of transferrin is raised, a significant proportion of the iron is transported from the spleen to the liver either in small molecular weight complexes or in ferritin. Although a saturated transferrin had no effect on the release of iron from reticuloendothelial cells, prior loading with HDRC conditions them to release less iron.     

Both subunits of rat liver ferritin are regulated at a translational level by iron induction.

A few hours after administering iron to rats, liver ferritin synthesis increases several fold. However, Northern blot analysis with cDNA probes for ferritin light (L) and heavy (H) subunit mRNAs failed to show an increase in total population of either messenger. Cytoplasmic distribution of ferritin messages was therefore investigated in control and iron administered rats killed at 3.5 hours. The liver post-mitochondrial supernatant was fractionated on a sucrose gradient to separate polyribosomes, monosomes, ribosomal subunits and cell sap. RNA extracted from each fraction and analyzed using Northern blotting showed that 65% of the total mRNA population for each subunit was present in the cell sap of control rats, presumably as mRNP particles since ribosomal RNA was absent from this fraction. After iron administration, these reserves of free mRNA were recruited onto the polysomes, reducing the free mRNA pool to 15% of the total. We interpret this to be due to activation of blocked ferritin messages on entry of iron into the cell.     

A Chelator is Required for Microsomal LIPID Peroxidation Following Reductive Ferritin-Iron Mobilisation

In the past, antioxidant and chelator studies have implicated a role for iron-dependent oxidative damage in tissues subjected to ischaemia followed by reperfusion. As ferritin is a major source of iron in non-muscular organs and therefore a potential source of the iron required for oxygen radical chemistry, we have determined conditions under which ferritin iron reduction leads to the formation of a pool of iron which is capable of catalysing lipid peroxidation. Under anaerobic conditions and in the presence of rat liver microsomes, flavin mononucleotide (FMN) catalysed the reduction of ferritin iron as shown by both continuous spectrophotometric measurements of tris ferrozine-Fe(II) complex formation and post-reaction Fe(II) determination. The presence of either ferrozine or citrate was not found to alter the time course or extent of ferritin reduction. In contrast, the addition of air to the reactants after a 20 min period of anaerobic reduction resulted in peroxidation of the microsome suspension (as determined with the 2-thiobarbituric acid test) only in the presence of a chelator such as citrate, ADP or nitrilotriacetic acid. These results support the concept that reduced ferritin iron can mediate oxidative damage during reperfusion of previously ischaemic tissues, provided that chelating agents such as citrate or ADP are present.     

Characterization of Phloem iron and its possible role in the regulation of fe-efficiency reactions

`Fe-efficiency reactions' are induced in the roots of dicotyledonous plants as a response to Fe deficiency. The role of phloem Fe in the regulation of these reactions was investigated. Iron travels in the phloem of Ricinus communis L. as a complex with an estimated molecular weight of 2400, as determined by gel exclusion chromatography. The complex is predominantly in the ferric form, but because of the presence of reducing compounds in the phloem sap, there must be a fast turnover in situ between ferric and ferrous (k ≈ 1 min⁻¹). Iron concentrations in R. communis phloem were determined colorimetrically or after addition of ⁵⁹Fe to the nutrient solution. The iron content of the phloem in Fe-deficient plants was lower (7 micromolar) than in Fe-sufficient plants (20 micromolar). Administration of Fe-EDTA to leaves of Phaseolus vulgaris L. increased the iron content of the roots within 2 days, and decreased proton extrusion and ferric chelate reduction. The increase in iron content of the roots was about the same as the difference between iron contents of roots grown on two iron levels with a concomitantly different expression of Fe-efficiency reactions. We conclude that the iron content of the leaves is reflected by the iron content of the phloem sap, and that the capacity of the phloem to carry iron to the roots is sufficient to influence the development of Fe-efficiency reactions. This does not preclude other ways for the shoot to influence these reactions.     

Depot iron in the rat liver after hypertransfusion with rat erythrocytes

In the rat liver the deposition of iron was measured after hypertransfusion with rat erythrocytes. The liver iron fractions were studied during four weeks after the hypertransfusions. In the first week the haemosiderin iron fraction increased together with the ferritin iron fraction. Most iron was deposited as ferritin iron. In the last week of the experiments, while the ferritin iron fraction still increased, the haemosiderin iron fraction decreased. At the same time plasma iron was utilized when erythropoiesis, which had been suppressed by the hypertransfusion, recommenced. It is suggest that, under these experimental conditions, liver haemosiderin iron is used in haemoglobin synthesis.     

Effects of acute iron overload on Atlantic salmon (Salmo salar) and rainbow trout (Oncorhynchus mykiss)

Distribution of radioiron to various tissues after intraperitoneal injections was examined in Atlantic salmon and rainbow trout. Liver and spleen were found to be the major iron storage tissues. Injections of 1 or 5 mg iron as ferric ammonium citrate led to a fall in hemoglobin levels in both species after 2 d. Hemoglobin levels returned to normal levels in rainbow trout after 8 d, but Atlantic salmon had not recovered, and Hb levels fell below 3 g/100 mL. In both species, the fall in Hb was associated with a raise in iron levels in spleen and liver, suggesting damage to erythrocytes. Atlantic salmon liver ferritin showed a two- to threefold increase, while rainbow trout showed a sixfold increase, and a more rapid response. The toxic effect of iron in fish appears to be different from the effect in other vertebrates.     

Active Transport of Iron in Bacillus megaterium: Role of Secondary Hydroxamic Acids

Kinetics of radioactive iron transport were examined in three strains of Bacillus megaterium. In strain ATCC 19213, which secretes the ferric-chelating secondary hydroxamic acid schizokinen, ⁵⁹Fe³⁺ uptake from ⁵⁹FeCl₃ or the ferric hydroxamate Desferal-⁵⁹Fe³⁺ was rapid and reached saturation within 3 min. In strain SK11, which does not secrete schizokinen, transport from ⁵⁹FeCl₃ was markedly reduced; the two ferric hydroxamates Desferal-⁵⁹Fe³⁺ or schizokinen-⁵⁹Fe³⁺ increased both total ⁵⁹Fe³⁺ uptake and the ⁵⁹Fe³⁺ appearing in a cellular trichloroacetic acid-insoluble fraction, although 10 min was required to reach saturation. Certain characteristics of transport from both ferric hydroxamates and FeCl₃ suggest that iron uptake was an active process. The growth-inhibitory effect of aluminum on strain SK11 was probably due to the formation of nonutilizable iron-aluminum complexes which blocked uptake from ⁵⁹FeCl₃. Desferal or schizokinen prevented this blockage. A strain (ARD-1) resistant to the ferric hydroxamate antibiotic A22765 was isolated from strain SK11. Strain ARD-1 failed to grow with Desferal-Fe³⁺ as an iron source, and it was unable to incorporate ⁵⁹Fe³⁺ from this source. Growth and iron uptake in strain ARD-1 were similar to strain SK11 with schizokinen-Fe³⁺ or the iron salt as sources. It is suggested that the ferric hydroxamates, or the iron they chelate, may be transported by a special system which might be selective for certain ferric hydroxamates. Strain ARD-1 may be unable to recognize both the antibiotic A22765 and the structurally similar chelate Desferal-Fe³⁺, while retaining its capacity to utilize schizokinen-Fe³⁺.     

Iron mobilization from cultured rat bone marrow macrophages

The reticuloendothelial system is responsible for removing old and damaged erythrocytes from the circulation, allowing iron to return to bone marrow for hemoglobin synthesis. Cultured bone marrow macrophages were loaded with ⁵⁹Fe-labelled erythroblasts and iron mobilization was studied. After erythroblast digestion, iron taken up by macrophages was found in ferritin as well as in a low-molecular-weight fraction. The analysis of iron mobilization from macrophages shows: (1) the iron was mobilized as ferritin. (2) A higher mobilization was observed when apotransferrin was present in the culture medium. (3) In the presence of apotransferrin in the culture medium, part of the iron was found as transferrin iron. (4) Iron transfer from ferritin to apotransferrin was observed in a cell-free culture medium and this process was temperature independent. The results indicate that after phagocytosis of ⁵⁹Fe-labelled erythroblasts by macrophages, iron is mobilized as ferritin. In the plasma, this iron can be transferred to apotransferrin.     

Hepatic subcellular metabolism of heme from heme-hemopexin: incorporation of iron into ferritin

The subcellular distribution and metabolic fate of [⁵⁹Fe]heme-[¹²⁵I]-labeled hemopexin after receptor-mediated interaction with the liver was examined in the rat. After intravenous injection, [⁵⁹Fe]heme from the complex and ⁵⁹Fe from hepatic catabolism of this heme accumulate in the liver and undergo changes in their subcellular distribution over 2 hours. The amounts of [⁵⁹Fe]heme and particularly of ⁵⁹Fe increase in the cytosol while remaining constant or decreasing in membranous fractions. In contrast, [¹²⁵I]-labeled hemopexin associated with the liver during heme transport is always a small fraction of the dose and is not measurably catabolized under these conditions.Gel filtration of the cytosol showed that ⁵⁹Fe increased linearly with time in a high molecular weight fraction which was identified immunologically as ferritin. We conclude that heme transported by hemopexin is metabolized by the liver and the iron conserved.     

An experimental study on the pathway of iron transfer from macrophages to erythrocytes in rat liver

In order to reveal the pathway of iron release from macrophages, a 59Fe-labelled ferric hydroxide-potassium polyvinyl sulfate complex (Fe-PVS) was injected intravenously into anemic rats and the level of radioactivity in the liver, spleen, bone marrow, blood plasma and red blood cells (RBC) was estimated at various time intervals after the injection. Histochemical observation of ferric iron and ferritin in the liver was also made on anemic rats treated using unlabelled Fe-PVS. Fe-PVS injection promoted the recovery of anemia causing a rapid increase in the RBC number, with activated erythropoiesis occurring in the spleen and bone marrow. Soon after the injection, most of the radio iron was found in the liver with a small amount in the circulating erythrocytes, bone marrow and spleen. The iron level in the liver decreased gradually with a rapid increase in the iron level of the erythrocytes which reached a very high level 6 days after the 59Fe-PVS injection. Histochemical observations showed a heavy deposition of ferritin in the Kupffer cells 3 days after Fe-PVS injection. This deposition was minimized after 6 days with an increase in the level of ferritin in the parenchymal cells in the central area of acini. The level of radioferritin estimated biochemically in the nonparenchymal cell fractions of the liver revealed that the level dropped by about one third approximately 3.5 days after the Fe-PVS injection, showing the stimulated ferritin release at this stage. Results indicate that Kupffer cells in the liver play an important role in ferritin synthesis from the phagocytized iron compounds and that the iron is supplied for erythroid cell proliferation.