Association of HFE protein with transferrin receptor in crypt enterocytes of human duodenum

In hereditary hemochromatosis (HH), intestinal absorption of dietary iron is increased, leading to excessive iron accumulation in tissues and resultant organ damage. The HFE protein, which is defective in HH, normally is expressed in crypt enterocytes of the duodenum where it has a unique, predominantly intracellular localization. In placenta, the HFE protein colocalizes with and forms a stable association with the transferrin receptor (TfR), providing a link between the HFE protein and iron transport. In the present study, we examined the relationship of the HFE protein to the TfR in enterocytes of the human duodenum and measured the uptake of transferrin-bound iron and ionic iron by isolated crypt and villus enterocytes. Immunocytochemistry showed that the HFE protein and TfR both are expressed in the crypt enterocytes. Western blots showed that, as was the case in human placenta, the HFE protein in crypt enterocytes is physically associated with the TfR and with beta2-microglobulin. The crypt cell fraction exhibited dramatically higher transferrin-bound iron uptake than villus cells. On the other hand, the villus cells showed 2-3 times higher uptake of ionic iron than crypt cells. We propose that the HFE protein modulates the uptake of transferrin-bound iron from plasma by crypt enterocytes and participates in the mechanism by which the crypt enterocytes sense the level of body iron stores. Impairment of this function caused by HFE gene mutations in HH could provide a paradoxical signal in crypt enterocytes that programs the differentiating enterocytes to absorb more dietary iron when they mature into villus enterocytes.     

Right to left differences in the ankle joint complex range of motion

In most eukaryotic cells, synthesis of the iron storage protein, ferritin is regulated by iron levels and redox conditions. Proper iron storage is important to protect against damaging iron-catalysed free radical reactions. Although iron-catalysed reactions are believed to contribute to oxidative damage and cataractogenesis, little is known about iron storage in the lens. In this study, ferritin concentration was measured in cultured canine lens epithelial cells. Baseline ferritin concentration ranged from 76-163 ng (mg protein)-1; cells cultured in low-iron media had significantly lower ferritin levels than cells cultured in iron-supplemented media. Addition of a large excess of iron as hemin resulted in an eight-fold increase in ferritin concentration. The iron chelator, Desferal, significantly decreased ferritin concentration. The reducing agent dithiothreitol decreased the hemin-induced increase in ferritin levels, but not baseline levels. In contrast, ascorbic acid induced a large increase in ferritin content. Other studies have shown that induction of ferritin synthesis can protect against oxidative damage. Regulation of ferritin levels may represent a mechanism by which the lens epithelium is protected from oxidative damage. In vivo, epithelial cells are normally exposed to much lower iron concentrations than the cultured lens epithelial cells in this study. However, in pathological circumstances, the iron content and redox state of the aqueous humor is dramatically altered and may affect the steady state levels of ferritin within the lens. This remains to be determined.     

Pore formation and translocation of melittin

Ferritin (Ft) plays an important role in cellular iron metabolism. It can store substantial amounts of iron in a nontoxic soluble form. However, its ability to donate iron for cellular needs, in particular for hemoglobin (Hb) synthesis in human erythroid cells, is still controversial. We studied the role of intracellular Ft-iron in Hb synthesis and the involvement of lysosomal proteolysis in iron release from Ft. Ft-iron release and its subsequent incorporation into heme was investigated in normal human erythroid precursors developing in culture. Dual staining flow cytometry with antibody (Ab)-specific for Ft and for Hb showed a decrease in cellular Ft content in erythroid cells during their maturation. Cellular Ft-iron participation in heme synthesis was studied by labeling cells with 59Fe. Cells were incubated with 59Fe-labeled human diferric transferrin (Tf), then chased, and intracellular radioiron distribution between Ft and Hb was determined on subsequent days by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and/or Ft immunoprecipitation and heme extraction. On day 6, most of the 59Fe accumulated in Ft. Thereafter, a progressive decrease of radioiron in Ft and a corresponding increase of the label in Hb was observed. Inhibition of heme synthesis with succinylacetone caused radioiron to remain in Ft and prevented its redistribution. Addition of unlabeled diferric Tf to the culture medium did not prevent radioiron from appearing in Hb. Chloroquine repression of lysosomal function prevented radio-iron redistribution between Ft and Hb. Inhibition of proteolysis by chymostatin and/or leupeptin led to Ft-protein accumulation in the cells and also prevented radioiron transfer from Ft to Hb. The results of the present study suggest that intracellular Ft donates iron for heme synthesis and that proteolytic Ft degradation in a lysosomal-like compartment is necessary for iron release and its transfer to heme.     

The onset of diffuse noxious inhibitory controls in postnatal rat pups: a C-Fos study

Excessive brain iron has been found in several neurodegenerative diseases. However, little information is available about mechanism of iron uptake by different types of brain cells including neurons. In this study, transferrin-bound iron (Tf-Fe) accumulation in the cultured cerebellar granule cell was investigated in vitro. After 5 days of culture, the cells were incubated with 1 microM of double-labelled transferrin (1251-Tf-59Fe) at 37 degrees C for 60 min. The cellular Tf-Fe and transferrin (Tf) uptake was analysed. The result showed (1) Tf uptake by the cells increased rapidly at the first 5 min, reaching its maximum after about 20 min of incubation; (2) Tf-Fe uptake kept increasing in a linear manner during the whole period of incubation; (3) the addition of either NH4Cl or CH3NH2, the blockers of Tf-Fe uptake via inhibiting iron release from Tf within endosomes, decreased the cellular Tf-Fe uptake but had no significant effect on Tf uptake; (4) trypsin and unlabelled Tf-Fe inhibited the uptake rate of Tf-Fe as well as Tf. The results suggested that Tf-Fe transport across the membrane of this type of neuron, much like other mammalian cells, was mediated by Tf-TfR endocytosis. Dysfunction of Tf or TfR would possibly lead to iron irregulation in the brain and consequently cause damage to neuronal functions.     

Study of intracellular localization and traffic of newly synthesized ceruloplasmin receptor in cultured human fibroblasts

Ceruloplasmin (Cp) receptor in cells of non-hepatocyte lineage (human HT-1080 fibroblasts) is synthesized by membrane-bound polyribosomes and then becomes a resident of the plasma membrane. The intracellular traffic of [14C]Cp receptor was followed in pulse-chase experiments using specific antibodies. It was shown that pulse-labeled Cp receptor, after reaching the place of its residence in the plasma membrane, is retained there for 90 min and then appears in the cytosol. Immunoactive 20-kD fragments of Cp receptor were found in the culture medium 1.5 h later. The intracellular traffic of 125I-labeled Cp bound to the fibroblast cell surface was traced in parallel chase experiments. It was shown that the internalized Cp receptor was recovered from the floating fraction of the cytosol. Comparison of the dynamics of the retention of internalized [14C]Cp receptor and 125I-labeled Cp in the subcellular compartments demonstrated that the traffic of both proteins within the fibroblasts is coordinated in time and proceeds via a common route. The role of Cp receptor in copper uptake by non-hepatocyte cells is discussed.     

Molecular regulation of iron proteins

Cellular iron metabolism comprises pathways of iron-protein synthesis and degradation, iron uptake via transferrin receptor (TfR) or release to the extracellular space, as well as iron deposition into ferritin and remobilization from such stores. Different cell types, depending on their rate of proliferation and/or specific functions, show strong variations in these pathways and have to control their iron metabolism to cope with individual functions. Studies with cultured cells have revealed a specific cytoplasmic protein, called 'iron regulatory protein' (IRP) (previously known as IRE-BP or IRF), that plays a key role in iron homoeostasis by regulating coordinately the synthesis of TfR, ferritin, and erythroid 5-aminolevulinate synthase (eALAS). Present in all tissues analysed, IRP is identical with the [4Fe-4S] cluster containing cytoplasmic aconitase. Under conditions of iron chelation, IRP is an apo-protein which binds with high affinity to specific RNA stem-loop elements (IREs) located 5' of the initiation codon in ferritin and eALAS mRNA, and 3' in the untranslated region of TfR mRNA. At 5' sites IRF blocks mRNA translation, whereas 3' it inhibits TfR mRNA degradation. Both effects compensate for low intracellular iron concentrations. Under high iron conditions, IRP is converted to the holo-protein and dissociates from mRNA. This reverses the control towards less iron uptake and more iron storage. Iron can therefore be considered as a feedback regulator of its own metabolism. It has recently become evident that nitric oxide, produced by macrophages and other cell types in response to interferon-gamma, induces the IRE-binding activity of IRF. Moreover measurements of the RNA-binding activity of IRP in tissue extracts may provide valuable information on iron availability.     

Non-transferrin-bound iron uptake in Belgrade and normal rat erythroid cells

Belgrade (b) rats have an autosomal recessive, microcytic, hypochromic anemia. Transferrin (Tf)-dependent iron uptake is defective because of a mutation in DMT1 (Nramp2), blocking endosomal iron efflux. This experiment of nature permits the present study to address whether the mutation also affects non-Tf-bound iron (NTBI) uptake and to use NTBI uptake compared to Tf-Fe utilization to increase understanding of the phenotype of the b mutation. The distribution of 59Fe2+ into intact erythroid cells and cytosolic, stromal, heme, and nonheme fractions was different after NTBI uptake vs. Tf-Fe uptake, with the former exhibiting less iron into heme but more into stromal and nonheme fractions. Both reticulocytes and erythrocytes exhibit NTBI uptake. Only reticulocytes had heme incorporation after NTBI uptake. Properly normalized, incorporation into b/b heme was approximately 20% of +/b, a decrease similar to that for Tf-Fe utilization. NTBI uptake into heme was inhibited by bafilomycin A1, concanamycin, NH4Cl, or chloroquine, consistent with the endosomal location of the transporter; cellular uptake was uninhibited. NTBI uptake was unaffected after removal of Tf receptors by Pronase or depletion of endogenous Tf. Concentration dependence revealed that NTBI uptake into cells, cytosol, stroma, and the nonheme fraction had an apparent low affinity for iron; heme incorporation behaved like a high-affinity process, as did an expression assay for DMT1. DMT1 serves in both apparent high-affinity NTBI membrane transport and the exit of iron from the endosome during Tf delivery of iron in rat reticulocytes; the low-affinity membrane transporter, however, exhibits little dependence on DMT1.     

Evidence for non-transferrin-mediated uptake and release of iron and manganese in glial cell cultures from hypotransferrinemic mice

Transferrin (Tf) is accepted as the iron mobilization protein, but its role in transport of other metals is controversial. In this study, we used mixed glial cultures from hypotransferrinemic (Hp) mice to determine the dependence of these cells on transferrin for iron and manganese delivery and release. Hp mice have a splicing defect in the transferrin (Tf) gene, resulting in < 1% of the normal plasma levels of Tf. Cellular iron and manganese uptake increases over 24 hr in cultures of normal and Hp glial cells in the presence of standard concentrations of Tf in the media; although total 59iron uptake in the Hp mouse cultures was 2X greater than normal, 54Mn uptake was similar between the two groups. The absence of Tf in the media resulted in a significant increase in 59iron uptake in both normal and Hp glial but did not affect Mn uptake. Elevated Tf (10X normal) in the media reduced both 59iron and 54Mn uptake. Efflux of 59Iron and 54Mn occurred in normal and Hp cultures, indicating the existence of a dynamic exchange of metals, and that intracellular Tf is not necessary for metal release. However, in the absence of Tf in the media, significantly more iron was retained in the cells than if Tf were present in both normal and Hp glial cultures. 54Mn release was minimally affected by extracellular Tf. The data demonstrate that Tf is not required for iron and Mn uptake into glial cells. These data further demonstrate a dynamic metal exchange system for glial cells which is not dependent on intracellular Tf.     

The dynamics of collagen deposition in liver damaged by CCl4

The rates of synthesis and catabolism of collagen are determined in the livers of normal rats and of rats treated with carbon tetrachloride. Several experimental conditions are applied with the intention of investigating the dynamic processes separately, in order to determine the relevant values. The deposition of collagen in liver after damage by CCl4 is a consequence of the reduction of turnover with a simultaneous increase in collagen-production. Together with the increase in synthesis, which seems to be a consequence of a numerical increase in cells, there is a reduction in catabolism of collagen: the more severe the damage, the more marked is the decrease of specific catabolism. Collagen-deposition in the liver is thus the result of accumulation. The results indicate the possibility that collagen-catabolism is effected by enzymes produced by adjacent parenchymal cells, so that their destruction enhances the accumulation of collagen material. The findings mentioned above are discussed in the context of the general criteria of scar-formation and the repair of damaged tissues.     

Dinitrosyl iron complexes and S-nitrosothiols are two possible forms for stabilization and transport of nitric oxide in biological systems

The physicochemical properties, mechanisms of synthesis and decomposition of dinitrosyl iron complexes (DNICs) with thiol-containing ligands and of S-nitrosothiols (RS-NO), and the potential role of these compounds in storage and transport of NO in biological systems are reviewed. Special attention is given to the phenomenon of mutual transformation of DNIC and RS-NO catalyzed by Fe2+. Each Fe2+ binds two neutral NO molecules in the DNICs, catalyzes their mutual oxidation--reduction with formation of nitrous oxide and nitrosonium ions appearing in the DNICs. These ions S-nitrosate thiol-compounds with RS-NO formation. Fe2+ binds two RS-NO molecules and catalyzes their mutual oxidation--reduction followed by decomposition of the resulting molecules. Mutual conversion of DNICs and RS-NO regulated by iron, thiol, and NO levels is suggested to provide NO transport in cells and tissues.     

Iron-dependent oxidation, ubiquitination, and degradation of iron regulatory protein 2: implications for degradation of oxidized proteins

The ability of iron to catalyze formation of reactive oxygen species significantly contributes to its toxicity in cells and animals. Iron uptake and distribution is regulated tightly in mammalian cells, in part by iron regulatory protein 2 (IRP2), a protein that is degraded efficiently by the proteasome in iron-replete cells. Here, we demonstrate that IRP2 is oxidized and ubiquitinated in cells before degradation. Moreover, iron-dependent oxidation converts IRP2 into a substrate for ubiquitination in vitro. A regulatory pathway is described in which excess iron is sensed by its ability to catalyze site-specific oxidations in IRP2, oxidized IRP2 is ubiquitinated, and ubiquitinated IRP2 subsequently is degraded by the proteasome. Selective targeting and removal of oxidatively modified proteins may contribute to the turnover of many proteins that are degraded by the proteasome.     

Cell movement and cell cycle dynamics in the retina of the adult teleost Haplochromis burtoni

We showed previously that treatment of cultured rabbit lens epithelial cells (LECs) with hyperbaric oxygen (HBO) produced DNA strand-breaks, caused reversible inhibition of protein synthesis and induced the synthesis of a 32 kD protein. In the present work, we employed immunostaining procedures to identify the 32 kD protein as heme oxygenase-1 (HO-1). Increased synthesis of the enzyme was observed as early as 12 hr after HBO-treatment, reached a maximum at 18 hr and was not detectable at 36 hr. Exposure of the cells to hemin also increased the synthesis of HO-1. An HBO-induced inhibition of protein synthesis and the subsequent induction of HO-1 was also observed in the capsule-epithelium of cultured rabbit lenses. For both LECs and the cultured lens, only HO-1 and not heme oxygenase-2 was HBO-inducible. Use of the antioxidant dimethylthiourea with HBO-treated lenses or LECs did not alter the observed effects on protein synthesis or the induction of HO-1. In contrast to results obtained with 50 atm O2, a pressure of 25 atm O2 inhibited protein synthesis only slightly and failed to induce synthesis of the 32 kD protein (although, as shown previously, identical exposure of LECs to 25 atm O2 significantly damaged DNA). Inhibition of protein synthesis in LECs and cultured lenses with the use of puromycin also induced synthesis of HO-1. Both hemin (10 micron), a source of iron, and 50 atm O2 produced a three-fold increase in the concentration of ferritin, a natural iron chelator, in LECs two days after exposure; no effects on ferritin levels were observed after 1 or 3 days. The finding that the increase in ferritin concentration occurred in the cells significantly after hemin- or HBO-induced synthesis of heme oxygenase indicates that chelatable iron rather than the heme molecule itself may have been the primary agent responsible for inducing ferritin synthesis. The data suggest that HBO-induced synthesis of HO-1 in the lens epithelium may be the result of an inhibition of protein synthesis, possibly leading to an accumulation of heme, rather than a direct protective response against oxidative stress.     

Transferrin receptor-dependent and -independent iron transport in gallium-resistant human lymphoid leukemic cells

Recent studies showed that gallium and iron uptake are decreased in gallium-resistant (R) CCRF-CEM cells; however, the mechanisms involved were not fully elucidated. In the present study, we compared the cellular uptake of 59Fe-transferrin (Tf) and 59Fe-pyridoxal isonicotinoyl hydrazone (PIH) to determine whether the decrease in iron uptake by R cells is caused by changes in Tf receptor (TfR)-dependent or TfR-independent iron uptake. We found that both 59Fe-Tf and 59Fe-PIH uptake were decreased in R cells. The uptake of 59Fe-Tf but not 59Fe-PIH could be blocked by an anti-TfR monoclonal antibody. After 59Fe-Tf uptake, R cells released greater amounts of 59Fe than gallium-sensitive (S) cells. However, after 59Fe-PIH uptake 59Fe release from S and R cells was similar. 125I-Tf exocytosis was greater in R cells. At confluency, S and R cells expressed equivalent amounts of TfR; however, at 24 and 48 hours in culture, TfR expression was lower in R cells. Our study suggests that the decrease in Tf-Fe uptake by R cells is caused by a combination of enhanced iron efflux from cells and decreased TfR-mediated iron transport into cells. Furthermore, because TfR-dependent and -independent iron uptake is decreased in R cells, both uptake systems may be controlled at some level by similar regulatory signal(s).     

Reconstitution of insulin signaling pathways in rat 3Y1 cells lacking insulin receptor and insulin receptor substrate-1. Evidence that activation of Akt is insufficient for insulin-stimulated glycogen synthesis or glucose uptake in rat 3Y1 cells

Rat 3Y1 cells have endogenous insulin-like growth factor-1 receptors and insulin receptor substrate (IRS)-2, but lack both insulin receptor (IR) and IRS-1. To investigate the role of IR and IRS-1 in effects of insulin, we transfected IR and IRS-1 expression plasmids into cells and reconstituted the insulin signaling pathways. 3Y1 cells stably expressing the c-myc epitope-tagged glucose transporter type 4 (3Y1-GLUT4myc) exhibit no effects of insulin, at physiological concentrations. The 3Y1-GLUT4myc-IR cells expressing GLUT4myc and IR responded to phosphatidylinositol 3,4, 5-trisphosphate (PI-3,4,5-P3) accumulation, Akt activation, the stimulation of DNA synthesis, and membrane ruffling but not to glycogen synthesis, glucose uptake, or GLUT4myc translocation. The further expression of IRS-1 in 3Y1-GLUT4myc-IR cells led to stimulation of glycogen synthesis but not to glucose uptake or GLUT4myc translocation in response to insulin, although NaF or phorbol 12-myristate 13-acetate did trigger GLUT4myc translocation in the cells. These results suggest that, in rat 3Y1 cells, (i) IRS-1 is essential for insulin-stimulated glycogen synthesis but not for DNA synthesis, PI-3,4,5-P3 accumulation, Akt phosphorylation, or membrane ruffling, and (ii) the accumulation of PI-3,4,5-P3 and activation of Akt are insufficient for glycogen synthesis, glucose uptake or for GLUT4 translocation.     

Ferritin in cultured human cytotrophoblasts: synthesis and subunit distribution

The present study aims at the role of ferritin in the regulation of syncytiotrophoblast free iron levels. The differentiated cytotrophoblast cell in culture is used as a model for this maternal-fetal interface. Cytotrophoblast cells isolated from term placentae are cultured in iron-poor (Medium 199), iron-depleted [desferrioxamine(DFO)] and iron-supplemented [diferric transferrin (hTF-2Fe), ferric ammonium citrate (FAC)] medium. Distribution and de novo synthesis of isoferritins is studied, together with the cellular iron concentration and the ferritin iron saturation. Compared to ferritin isolated from total placenta, ferritin obtained from villous tissue is enriched with acidic isoforms. This observation is in agreement with measured light (L) to heavy (H) subunit ratios < 1 of de novo synthesized ferritin in cultured cytotrophoblast cells. Neither iron-poor culture medium, nor hTf-2Fe supplemented medium affects the cellular iron or ferritin concentration. FAC increased the cellular ferritin iron saturation and (by synthesis) the acidic isoferritin concentrations. The results strongly suggest, that the term syncytiotrophoblast is able to balance transferrin-mediated iron uptake and iron release. In case of FAC supplementation, the syncytiotrophoblast is unable to keep intracellular iron low, and ferritin synthesis is stimulated. The predominance of acidic ferritins and the preferential synthesis of H subunits can be functionally explained by the established fact that iron incorporation in acidic ferritins is faster due to the presence of ferroxidase centres. Damage by free iron catalysed hydroxyl radical formation is therefore minimized.     

Evaluation of sex difference in tissue repair following acute carbon tetrachloride toxicity in male and female Sprague-Dawley rats

The formation of zinc protoporphyrin in response to lead or iron depletion has previously been investigated in erythroid systems. Because of its possible metabolic role in non-erythroid tissue, we investigated the formation of zinc protoporphyrin in cultured hepatocytes. The effects of lead and inhibitors of ferrochelatase, the iron insertion step of heme synthesis, on the conversion of 5-aminolevulinic acid to zinc protoporphyrin, protoporphyrin and heme were compared in rat and chick embryo hepatocyte cultures. In rat cultures, zinc protoporphyrin was synthesized enzymatically by ferrochelatase, since N-methylmesoporphyrin, an inhibitor of ferrochelatase. caused 40% or greater decreases in both heme and zinc protoporphyrin accumulation and markedly stimulated protoporphyrin accumulation. In addition, chelation of ferrous iron with 2,2'-dipyridyl decreased heme accumulation by 50%, but increased ZPP accumulation by 200%. Zinc protoporphyrin formation in chick embryo hepatocytes required the addition of zinc as well as 5-aminolevulinic acid and apparently was non-enzymatic, since it was not inhibited by N-methylmesoporphyrin nor increased by iron chelation. In the presence of 5-aminolevulinic acid, lead had no effect on zinc protoporphyrin, protoporphyrin or heme accumulation in chick hepatocytes, but decreased all three in rat hepatocytes, with the decrease in protoporphyrin being far greater than that of zinc protoporphyrin or heme. These findings indicate that, in contrast to the effect of lead in erythroid tissue, it did not specifically increase zinc protoporphyrin accumulation or alter iron availability in cultured hepatocytes.