Uptake of iron from transferrin by isolated hepatocytes

Isolated rat hepatocytes containing 0.56-1.79 micrograms iron/10(6) cells and with an intracellular ATP concentration of 3-4 mM, accumulate iron from transferrin linearly with time for at least 3 h. At 37 degrees C the rate of uptake amounts to 0.3-0.7 pmol/mg cell protein per min. The uptake reaches a saturation level of 21-40 pmol/mg cell protein per h at 2.2 microM iron. At 5 degrees C the uptake does not increase over the time of incubation. Uptake of iron, but not binding of transferrin is increased 4-5-fold at oxygen concentrations 10-20 microM. At oxygen concentrations beyond these limits iron uptake is decreased. Iron taken up at low oxygen concentrations can be chelated by bathophenanthroline and bathophenanthroline disulphonate , but only if the chelators are present during the uptake experiments. The results suggest that iron uptake from transferrin by hepatocytes in suspension involves reductive removal of iron.     

Pathways in the binding and uptake of ferritin by hepatocytes

The binding and uptake of rat liver ferritin by primary cultures of rat liver hepatocytes was studied in order to assess the relative importance of saturable, high-affinity pathways and nonspecific processes in the incorporation of the protein by the cells. To minimize artifacts, ferritin not subjected to heat treatment and labeled in vivo with 59Fe was used. Binding to cell membranes was estimated from incubations performed at 4 degrees C. After 2 h, when a steady state in cell-associated ferritin had been achieved, approx. 4-10(4) binding sites per cell were observed, with an affinity constant for ferritin of 1 x 10(9) M-1. At 37 degrees C, the maximal uptake from these sites was 1.3 x 10(5) ferritin molecules/cell per h. For ferritin molecules bearing an average of 2400 iron atoms, this uptake amounts to 5 x 10(6) iron atoms/cell per min. Half-maximal uptake was achieved at a ferritin concentration, or KM1, of 3 x 10(-9) M. Although uptake rates at least a thousand times greater could be achieved by binding to the much larger number of low-affinity sites, the apparent KM2 for such 'nonspecific' uptake was 4 x 10(-7) M. At ferritin concentrations up to 2 nM, at least 90% of ferritin bound and taken up by hepatocytes involves saturable, high-affinity sites, presumably true ferritin receptors.     

A low-spin iron complex in human melanoma and rat hepatoma cells and a high-spin iron(II) complex in rat hepatoma cells.

Human melanoma and rat hepatoma cells cultured in the presence of low concentrations (2.5 microM) of low-molecular-weight iron (Fe) chelates and Fe-transferrin complexes have been studied with 57Fe M?ssbauer spectroscopy. The spectra show that holoferritin is only a minor fraction of the total iron present in the cells. The major form of Fe was in a low-spin state unlike the high-spin Fe(III) found in ferritin. Only about 10% of the Fe could be attributed to ferritin. In addition, the hepatoma cells had a high-spin Fe(II) spectral component which made up about 20% of the Fe present.     

Uptake of ferritin and iron bound to ferritin by rat hepatocytes: modulation by apotransferrin, iron chelators and chloroquine

Rat liver ferritin is an effective donor of iron to rat hepatocytes. Uptake of iron from ferritin by the cells is partially inhibited by including apotransferrin in the culture medium, but not by inclusion of diferric transferrin. This inhibition is dependent on the concentration of apotransferrin, with a 30% depression in iron incorporation in the cells detected at apotransferrin concentrations above 40 micrograms/ml. However, apotransferrin does not interfere with uptake of 125I-labeled ferritin, suggesting that apotransferrin decreases retention of iron taken up from ferritin by hepatocytes by sequestering a portion of released iron before it has entered the metabolic pathway of the cells. The iron chelators desferrioxamine (100 microM), citrate (10 mM) and diethylenetriaminepentaacetate (100 microM) reduce iron uptake by the cells by 35, 25 and 8%, respectively. In contrast, 1 mM ascorbate increases iron accumulation by 20%. At a subtoxic concentration of 100 microM, chloroquine depresses ferritin and iron uptake by hepatocytes by more than 50% after 3 h incubation. Chloroquine presumably acts by retarding lysosomal degradation of ferritin and recycling of ferritin receptors.     

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.     

Kinetic analysis of bovine spleen apoferritin and recombinant H and L chain homopolymers: Iron uptake suggests early stage H chain ferroxidase activity and second stage L chain cooperation

Ferritin utilizes ferroxidase activity to incorporate iron. Iron uptake kinetics of bovine spleen apoferritin (H: L = 1 : 1.1) were compared with those of recombinant H chain ferritin and L chain ferritin homopolymers. H chain ferritin homopolymer showed an iron uptake rate identical to bovine spleen apoferritin (0.19 and 0.21 mmol/min/micromol of protein, respectively), and both showed iron concentration-dependent uptake. In contrast, the L chain homopolymer, which lacks ferroxidase, did not incorporate iron and showed the same level of iron autoxidation in the absence of ferritin. Bovine spleen apoferritin was shown to have two iron concentration-dependent uptake pathways over a range of 0.02-0.25 mM ferrous ammonium sulfate (FAS) by an Eadie-Scatchard plot (v/[FAS] versus v), whereas the H chain ferritin homopolymer was found to have only one pathway. Of the two Km values found in bovine spleen apoferritin, the lower mean Km value was 9.0 microM, while that of the H chain homopolymer was 11.0 microM. H chain ferritin homopolymer reached a saturating iron uptake rate at 0.1 mM FAS, while bovine spleen apoferritin incorporated more iron even at 0.25 mM FAS. These results suggest that the intrinsic ferroxidase of ferritin plays a significant role in iron uptake, and the L chain cooperates with the H chain to increase iron uptake.     

Cellular location of rat muscle ferritins and their preferential loss during cell isolation

Heart and other muscles of the rat contain two forms of ferritin separable in polyacrylamide gel electrophoresis. The cellular location of the fast- and slow-migrating ferritins was investigated using primary cultures of hindlimb skeletal muscle, and isolated myocardial cell populations. Muscle and non-muscle cells were isolated in good yield from hearts of adult rats pretreated with large doses of iron to increase their ferritin content. In virtually all cases, the isolated muscle cells contained traces only of the fast-migrating species and the non-muscle cells contained small amounts of the slow-migrating ferritin. During cell isolation, 90-100% of both ferritins was lost and could be recovered in the perfusates and solutions employed, while one third of the total tissue protein, and a larger percentage of creatine phosphokinase, was recovered in the isolated cells. Primary cultures of thigh muscle from adult rats which had differentiated into multi-nucleated myotubes, were incubated for 1-3 days with chelated iron. These cells contained substantial amounts of the electrophoretically fast migrating ferritin, with its characteristic larger Stokes' radius (determined by quantitative polyacrylamide gel electrophoresis). None of the slow-migrating ferritin species was detected, although hindlimb muscle from iron-treated rats contained both forms. It is concluded that the fast-migrating ferritin of muscle, which is much larger and more asymmetric than other ferritins, is confined to the muscle cell population, while the other form is predominantly or exclusively in the non-muscle cells. Both ferritins are lost preferentially over other proteins during procedures which injure muscle tissue.     

Iron induces protection and necrosis in cultured cardiomyocytes: Role of reactive oxygen species and nitric oxide

We investigate here the role of reactive oxygen species and nitric oxide in iron-induced cardiomyocyte hypertrophy or cell death. Cultured rat cardiomyocytes incubated with 20 μM iron (added as FeCl₃–Na nitrilotriacetate, Fe–NTA) displayed hypertrophy features that included increased protein synthesis and cell size, plus realignment of F-actin filaments along with sarcomeres and activation of the atrial natriuretic factor gene promoter. Incubation with higher Fe–NTA concentrations (100 μM) produced cardiomyocyte death by necrosis. Incubation for 24 h with Fe–NTA (20–40 μM) or the nitric oxide donor Δ-nonoate increased iNOS mRNA but decreased iNOS protein levels; under these conditions, iron stimulated the activity and the dimerization of iNOS. Fe–NTA (20 μM) promoted short- and long-term generation of reactive oxygen species, whereas preincubation with l-arginine suppressed this response. Preincubation with 20 μM Fe–NTA also attenuated the necrotic cell death triggered by 100 μM Fe–NTA, suggesting that these preincubation conditions have cardioprotective effects. Inhibition of iNOS activity with 1400 W enhanced iron-induced ROS generation and prevented both iron-dependent cardiomyocyte hypertrophy and cardioprotection. In conclusion, we propose that Fe–NTA (20 μM) stimulates iNOS activity and that the enhanced NO production, by promoting hypertrophy and enhancing survival mechanisms through ROS reduction, is beneficial to cardiomyocytes. At higher concentrations, however, iron triggers cardiomyocyte death by necrosis.     

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.     

Prenatal and postnatal changes in the content and species of ferritin in rat liver

The iron and ferritin content of rat liver and the species of ferritin present were examined from 4 days before to 3 weeks after birth. 1. Total iron and ferritin iron accumulated rapidly during the last days of gestation and from the second postnatal day underwent a steady depletion. 2. The amount of iron deposited before birth in the liver of each pup varied inversely with litter size and could be increased moderately by injection of iron into the mother before mating. 3. Intraperitoneal injection of iron 1 day after birth doubled the concentration of total iron, ferritin iron and ferritin protein in the liver over the next 24h, but at 3 weeks after birth it raised the very low concentrations of iron and ferritin severalfold. 4. As shown by electrophoretic migration, ferritin and dissociated ferritin subunits prepared from the livers of rats from 4 days before to 3 weeks after birth differed from those of adult liver ferritin and were indistinguishable from those of adult kidney and spleen ferritin. Treatment with iron at 3 weeks of age induced formation of a ferritin with electrophoretic properties resembling those of adult liver. It is concluded that iron given at this stage of development may activate the genetic cistron for adult liver ferritin.     

Zinc deficiency-induced iron accumulation, a consequence of alterations in iron regulatory protein-binding activity, iron transporters, and iron storage proteins

One consequence of zinc deficiency is an elevation in cell and tissue iron concentrations. To examine the mechanism(s) underlying this phenomenon, Swiss 3T3 cells were cultured in zinc-deficient (D, 0.5 microM zinc), zinc-supplemented (S, 50 microM zinc), or control (C, 4 microM zinc) media. After 24 h of culture, cells in the D group were characterized by a 50% decrease in intracellular zinc and a 35% increase in intracellular iron relative to cells in the S and C groups. The increase in cellular iron was associated with increased transferrin receptor 1 protein and mRNA levels and increased ferritin light chain expression. The divalent metal transporter 1(+)iron-responsive element isoform mRNA was decreased during zinc deficiency-induced iron accumulation. Examination of zinc-deficient cells revealed increased binding of iron regulatory protein 2 (IRP2) and decreased binding of IRP1 to a consensus iron-responsive element. The increased IRP2-binding activity in zinc-deficient cells coincided with an increased level of IRP2 protein. The accumulation of IRP2 protein was independent of zinc deficiency-induced intracellular nitric oxide production but was attenuated by the addition of the antioxidant N-acetylcysteine or ascorbate to the D medium. These data support the concept that zinc deficiency can result in alterations in iron transporter, storage, and regulatory proteins, which facilitate iron accumulation.     

Lipid peroxidation and cytotoxicity of Ehrlich ascites tumor cells by ferric nitrilotriacetate

Ferric nitrilotriacetate, which causes in vivo organ injury, induced lipid peroxidation and cell death in Ehrlich ascites tumor cells in vitro. The process was inhibited by butylated hydroxyanisole and enhanced by vitamin C and linolenic acid, indicating a close relationship between cytotoxicity and the lipid peroxidizing ability of Fe3+ NTA. The cytotoxicity was suppressed by glucose and a temperature below 20 degrees C. Lipid peroxidation of Fe3+ NTA-treated cells was greater at 0 degree C than at 37 degrees C, contrary to results with Fe3+ NTA-treated plasma membranes of Ehrlich ascites tumor cell. These results suggested that metabolism and membrane fluidity are important factors in the expression of the Fe3+ NTA-induced cytotoxicity. H2O2 showed a lower cytotoxicity than did Fe3+ NTA but a greater lipid peroxidizing ability. H2O2 appeared to damage the cells less, and was quenched rapidly by cellular metabolism unlike Fe3+ NTA. In transferrin-free medium, Ehrlich ascites tumor cell readily incorporated Fe3+ NTA, and iron uptake was greater than NTA-uptake in Fe3+ NTA-treated cells, suggesting that Ehrlich ascites tumor cell incorporated iron from Fe3+NTA and metabolized it into an inert form such as ferritin.     

Susceptibility of cultured rat hepatocytes to oxidative stress by peroxides and iron. The extracellular matrix affects the toxicity of tert-butyl hydroperoxide

The aim of this study was to set up an in vitro model for studying the importance of an altered extra-cellular matrix composition and its importance for the resistance to oxidative stress, in hepatocytes from normal and iron loaded rats. Primary cultures of hepatocytes from iron loaded and normal rats were plated on a laminin rich extracellular matrix or on collagen type I, and incubated with tert-butyl hydroperoxide (TBH). Malon dialdehyde (MDA) and the activities of lactate dehydrogenase (LDH) in cell culture medium were analyzed. The protein synthesis, the concentrations of glutathione and the expression of manganese-superoxide dismutase and ferritin genes were measured. All hepatocytes contained lower concentrations of glutathione when plated on collagen than on EHS. Ferritin H and Mn-SOD gene expression showed no difference. The rate of lipid peroxidation in iron loaded hepatocytes exposed to TBH was higher on collagen than in those plated on EHS (0.95 +/- 0.28 microM MDA vs. 1.62 +/- 0.22 microM MDA, p < 0.05). Iron loaded cells were in general more susceptible to TBH than were normal hepatocytes (MDA, LDH, protein synthesis and glutathione content). Lipid peroxidation could be prevented by adding desferrioxamine. In conclusion, we show that the combination of iron overload and collagen matrix in rat hepatocytes leads to an increased susceptibility to oxidative stress. These findings may be of interest for the further studies on effects of iron overload and the altered matrix composition in liver fibrosis.     

Differential regulation of iron regulatory element-binding protein(s) in cell extracts of activated lymphocytes versus monocytes-macrophages.

The intracellular iron level exerts a negative feedback on transferrin receptor (TfR) expression in cells requiring iron for their proliferation, in contrast to the positive feedback observed in monocytes-macrophages. It has been suggested recently that modulation of TfR and ferritin synthesis by iron is mediated through a cytoplasmic protein(s) (iron regulatory element-binding protein(s) (IRE-BP)), which interacts with ferritin and TfR mRNA at the level of hairpin structures (IRE), thus leading to inhibition of transferrin mRNA degradation and repression of ferritin mRNA translation. In the present study we have evaluated in parallel the level of TfR expression, ferritin, and IRE-BP in cultures of: (i) circulating human lymphocytes stimulated to proliferate by phytohemagglutinin (PHA) and (ii) circulating human monocytes maturing in vitro to macrophages. The cells were grown in either standard or iron-supplemented culture. TfR and ferritin expression was evaluated at both the protein and mRNA level. IRE-BP activity was measured by gel retardation assay in the absence or presence of beta-mercaptoethanol (spontaneous or total IRE-BP activity, respectively). Spontaneous IRE-BP activity, already present at low level in quiescent T lymphocytes, shows a gradual and marked increase in PHA-stimulated T cells from day 1 of culture onward. This increase is directly and strictly correlated with the initiation and gradual rise of TfR expression, which is in turn associated with a decrease of ferritin content. Both the rise of TfR and spontaneous IRE-BP activity are completely inhibited in iron-supplemented T cell cultures. In contrast, the total IRE-BP level is similar in both quiescent and PHA-stimulated lymphocytes, grown in cultures supplemented or not with iron salts. Monocytes maturing in vitro to macrophages show a sharp increase of spontaneous and, to a lesser extent, total IRE-BP; the addition of iron moderately stimulates the spontaneous IRE-BP activity but not the total one. Here again, the rise of spontaneous IRE-BP from very low to high activity is strictly related to the parallel increase of TfR expression and, suprisingly, also with a very pronounced rise of ferritin expression observed at both the mRNA and protein level. It is noteworthy the effect of beta-mercaptoethanol is cell specific, i.e. the ratio of total versus spontaneous IRE-BP activity is different in activated lymphocytes and maturing monocytes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Glutathione conjugates of 4-hydroxy-2(E)-nonenal as biomarkers of hepatic oxidative stress-induced lipid peroxidation in rats

Here we present a simple, specific, and sensitive liquid chromatography/mass spectrometry method to measure 4-hydroxy-2(E)-nonenal-glutathione (HNE-GSH), the major stable hepatic metabolite of HNE after GSH conjugation, as a marker of oxidative stress in rat liver and hepatocytes. Commonly employed methods for the measurement of lipid peroxidation-derived free aldehydes or modified proteins suffer from the artificial formation of HNE or HNE adducts to cellular molecules during sample preparation and derivatization, resulting in an overestimation of background levels. Basal levels of HNE-GSH in liver tissue from untreated rats were detected in amounts of 20 pmol/g liver. Rats exposed to a single dose of iron nitrilotriacetate (Fe(III)NTA; 15 mg Fe/kg bw, ip), a model compound for the induction of oxidative stress, revealed a fivefold increase in the hepatic HNE-GSH levels compared to controls 5 h after dosing. Moreover, a significant increase in HNE-mercapturic acid (HNE-MA) and its reduced metabolite DHN-MA was evident at 5 or 24 h after treatment, which was also reflected in increased plasma concentrations of these secondary HNE-GSH metabolites. In agreement with the in vivo data, a time-dependent increase in the levels of HNE-GSH from <1 to 123 +/- 16 pmol/10(6) cells over 5 h was detected in rat hepatocytes treated with Fe(III)NTA (150 microM). An increase in cellular HNE-GSH from <1.0 to 7.2 +/- 0.3 pmol/10(6) cells could be observed in rat hepatocytes treated with allyl alcohol (500 microM, 3 h), known for generation of HNE in hepatocytes. These data suggest that the direct measurement of the stable GSH conjugation product of cellular HNE in rat primary hepatocytes or its secondary metabolites may represent a reliable biomarker of oxidative stress-induced lipid peroxidation in rat liver in vivo.     

Secreted ferritin: Mosquito defense against iron overload?

The yellow fever mosquito, Aedes aegypti, must blood feed in order to complete her life cycle. The blood meal provides a high level of iron that is required for egg development. We are interested in developing control strategies that interfere with this process. We show that A. aegypti larval cells synthesize and secrete ferritin in response to iron exposure. Cytoplasmic ferritin is maximal at low levels of iron, consists of both the light chain (LCH) and heavy chain (HCH) subunits and reflects cytoplasmic iron levels. Secreted ferritin increases in direct linear relationship to iron dose and consists primarily of HCH subunits. Although the messages for both subunits increase with iron treatment, our data indicate that mosquito HCH synthesis could be partially controlled at the translational level as well. Importantly, we show that exposure of mosquito cells to iron at low concentrations increases cytoplasmic iron, while higher iron levels results in a decline in cytoplasmic iron levels indicating that excess iron is removed from mosquito cells. Our work indicates that HCH synthesis and ferritin secretion are key factors in the response of mosquito cells to iron exposure and could be the primary mechanisms that allow these insects to defend against an intracellular iron overload.     

Purification and properties of a folate-catabolizing enzyme

We have identified and purified to homogeneity an enzyme from rat liver that catalyzes the oxidative catabolism of 5-formyltetrahydrofolate to p-aminobenzoylglutamate and a pterin derivative. Purification of the enzyme utilized six column matrices, including a pterin-6-carboxylic acid affinity column. Treatment of crude rat liver extracts with EDTA or heat decreased the specific activity of the enzyme by up to 85%. Peptides generated from the purified protein were sequenced and found to be identical to primary sequences present within rat light chain or heavy chain ferritin. Commercial rat ferritin did not display catabolic activity, but activity could be acquired with iron loading. The purified enzyme contained 2000 atoms of iron/ferritin 24-mer and displayed similar electrophoretic properties as commercial rat liver ferritin. The ferritin-catalyzed reaction displayed burst kinetics, and the enzyme catalyzed only a single turnover in vitro. Expression of rat heavy chain ferritin cDNA resulted in increased rates of folate turnover in cultured Chinese hamster ovary cells and human mammary carcinoma cells and reduced intracellular folate concentrations in Chinese hamster ovary cells. These results indicate that ferritin catalyzes folate turnover in vitro and in vivo and may be an important factor in regulating intracellular folate concentrations.