Human leukemic K562 cells: suppression of hemoglobin accumulation by a monoclonal antibody to human transferrin receptor

The receptor for transferrin plays an important role both in tumor cell growth and in hemoglobin synthesis. In this paper, we demonstrate that the monoclonal antibody 42/6 to human transferrin receptor inhibits iron uptake in the human leukemic K562 cell line and suppresses hemoglobin accumulation in K562 cells induced to erythroid differentiation by butyric acid. In contrast, only slight inhibitory effects were observed on cell proliferation of both uninduced and erythroid-induced K562 cells treated with the 42/6 monoclonal antibody. In addition, the 42/6 monoclonal antibody to human transferrin receptor does not inhibit butyric acid-induced accumulation of gamma-globin mRNA. The effect of the 42/6 monoclonal antibody on hemoglobin synthesis appears to be restricted to human cell lines, as murine Friend erythroleukemic cells undergo erythroid differentiation when cultured in the presence of hexamethylenebisacetamide plus the 42/6 monoclonal antibody. The findings reported in this paper suggest (a) a dissociation of iron transport and accumulation of heme molecules from the expression of globin genes and (b) a different requirement of iron uptake by different iron-dependent functions such as cell proliferation and hemoglobin expression.     

Non-transferrin donors of iron for heme synthesis in immature erythroid cells

The mechanism of iron uptake from several iron-containing compounds by transferrin-depleted rabbit reticulocytes and mouse spleen erythroid cells was investigated. Iron complexes of DL-penicillamine, citrate and six different aroyl hydrazones may be utilized by immature erythroid cells for hemoglobin synthesis, although less efficiently than iron from transferrin. HTF-14, a monoclonal antibody against human transferrin, reacts with rabbit transferrin and inhibits iron uptake and heme synthesis by rabbit reticulocytes. HTF-14 had no significant effect on iron uptake and heme synthesis when non-transferrin donors of iron were examined. Ammonium chloride (NH4Cl) increases intracellular pH and blocks the release or utilization of iron from the internalized transferrin. NH4Cl only slightly affected iron incorporation and heme synthesis from non-transferrin donors of iron. Hemin inhibited transferrin iron uptake and heme synthesis, but had a much lesser effect on iron incorporation and heme synthesis from non-transferrin donors of iron. These results allow us to conclude that transferrin-depleted reticulocytes take up iron from all of the examined non-transferrin iron donors without the involvement of the transferrin/transferrin receptor pathway.     

Inhibition of heme synthesis decreases transferrin receptor expression in mouse erythroleukemia cells.

The coordination of transferrin receptor (TfR) expression and heme synthesis was investigated in mouse erythroleukemia (MEL) cells of line 707 treated with heme synthesis inhibitors or in a variant line Fw genetically deficient in heme synthesis. Cells of line 707 were induced for differentiation by 5 mM hexamethylene bisacetamide (HMBA). TfR expression increased in the course of induction, as judged by increased TfR mRNA synthesis, increased cytoplasmic TfR mRNA level, and by the increased number of cellular 125I-Tf binding sites. Addition of 0.1 mM succinylacetone (SA) decreased cellular TfR to the level comparable with the uninduced cells. The decrease was reverted by the iron chelator desferrioxamine (DFO) but not by exogenous hemin. In short-term (1-2 hours) incubation, SA inhibited 59Fe incorporation from transferrin into heme, whereas total cellular 59Fe uptake was increased. A decrease in TfR mRNA synthesis was apparent after 2 hours of SA treatment. Conversely, glutathione peroxidase mRNA synthesis, previously shown to be inducible by iron, was increased by SA treatment. Cells of heme deficient line Fw did not increase the number of Tf binding sites after the induction of differentiation by 5 mM sodium butyrate. SA had no effect on TfR expression in Fw cells. The results suggest that the depletion of cellular non-heme iron due to the increase in heme synthesis maintains a high level of transferrin receptor expression in differentiating erythroid cells even after the cessation of cell division.     

Transferrin receptors and iron utilization in DMSO-inducible and -uninducible friend erythroleukemia cells

Dimethylsulfoxide (DMSO) induces hemoglobin synthesis and erythroid differentiation of Friend erythroleukemia cells in vitro. Induction is accompanied by increased transferrin-binding activity which is necessary for the cellular acquisition of iron from transferrin for hemoglobin synthesis. There are Friend cell variants in which hemoglobin synthesis is not induced by DMSO unless exogenous hemin is also present. In this study we have compared the inducibility of transferrin receptors and iron incorporation in DMSO-inducible (745) and -uninducible (M-18 and TG-13) Friend cell lines. Cellular transferrin-binding sites were estimated by Scatchard analysis of data obtained from specific binding of [125I]transferrin by the cells. Our results show that unlike 745, DMSO treatment of the variant cell lines M-18 and TG-13 does not result in increased transferrin-binding activity. The number of transferrin-binding sites and the rate of iron uptake is similar in uninduced 745 and DMSO-treated M-18 and TG-13 cells. Although exposure of M-18 cells to DMSO and hemin induces hemoglobinization, this treatment does not cause induction of transferrin receptors. These results indicate that the primary defect in M-18 cells may be the uninducibility of transferrin receptors. We have also shown that exposure of 745 cells to hemin during DMSO treatment prevents the induction of transferrin receptors, suggesting that hemin may control the expression of transferrin receptors in erythroid cells.     

Effect of extracellular hemin on hemoglobin and ferritin content of erythroleukemia cells

Mouse (MEL) and human (K-562) erythroleukemia cell lines can be induced to undergo erythroid differentiation, including hemoglobin (Hb) synthesis, by extra cellular hemin. In order to study the effect of extracellular hemin on intracellular ferritin and Hb content, we have used Mossabauer spectroscopy to measure the amount of 57Fe incorporated into ferritin or Hb and a fluorescent enzyme-linked immunosorbent assay (ELISA) to measure the ferritin protein content. When K-562 cells were cultured in the presence of a 57Fe source either as transferrin or citrate, in the absence of a differentiation inducer, all the intracellular 57Fe was detected in ferritin. When the cells were cultured in the presence of 57Fe-hemin, 57Fe was found in both ferritin and Hb. 57Fe in ferritin increased rapidly, and after 2 days it reached a plateau at 5 X 10(-14) g/cell. 57Fe in Hb increased linearly with time and reached the same value after 12 days. Addition of other iron sources such as iron-saturated transferrin, iron citrate, or iron ammonium citrate caused a much lower increase in ferritin protein content as compared to hemin. When K-562 cells were induced by 57Fe-hemin in the presence of 56Fe-transferrin, 57Fe was found to be incorporated in equal amounts into both ferritin and Hb. However, when the cells were induced by 56Fe-hemin in the presence of 57Fe-transferrin, 57Fe was incorporated only into ferritin, but not into Hb, which contained 56Fe iron. These results indicate that in K-562 cells, when hemin is present in the culture medium it is preferentially incorporated into Hb, regardless of the availability of other extra- or intracellular iron sources such as transferrin or ferritin. In MEL cells induced to differentiate by dimethylsulfoxide (DMSO) a different pattern of iron incorporation was observed; 57Fe from both transferrin and hemin was found to incorporate in ferritin as well as in Hb.     

Transferrin receptors and iron uptake during erythroid cell development

Experiments were performed to determine the level of transferrin receptors and rate of transferrin-bound iron uptake by various immature erythroid cell populations. Developing erythroid cells from the rat and mouse foetal liver at various stages of gestation were studied. In addition Friend leukaemic cells grown in culture were examined. The transferrin receptor level of Friend cells was similar to that of erythroid cells from the mouse foetal liver. During erythroid cell development the transferrin receptor level increased from about 300,000 per cell at the early normoblast stage to reach a maximum of about 8000,000 per cell on intermediate normoblasts. Further maturation of intermediate normoblasts was accompanied by a decline in the number of transferrin receptors, reaching a level of 105,000 in the circulating reticulocyte. The rate of iron uptake from transferrin during erythroid cell development was found to correlate closely with the number of transferrin receptors. In each of the immature erythroid cell populations studied the rate of iron uptake was about 36 iron atoms per receptor per hour. These results indicate that the level of transferrin receptors may be the major factor which determines the rate of iron uptake during erythroid cell development.     

Transferrin and iron uptake by human lymphoblastoid and K-562 cells

Two human lymphoblastoid cell lines and K-562 cells were found to take up radioiodinated transferrin and transferrin-bound iron in amounts comparable to reticulocytes. These cell lines were also shown to possess transferrin receptors whose numbers and affinity for transferrin were similar to those of reticulocytes. However, unlike reticulocytes, in which at least 90% of the iron taken up is incorporated into heme, in the lymphoblastoid and K-562 cells only around 10% of the incorporated iron is found in heme. In addition, in contrast to the hemoglobin synthesizing cells, excess heme does not inhibit the removal of iron from transferrin by the lymphoblastoid and K-562 cells, suggesting that only during erythroid differentiation do cells acquire a specific mechanism for removing iron from transferrin which is subject to feedback inhibition by heme.     

Biosynthesis of heme in immature erythroid cells. The regulatory step for heme formation in the human erythron

Heme formation in reticulocytes from rabbits and rodents is subject to end product negative feedback regulation: intracellular "free" heme has been shown to control acquisition of transferrin iron for heme synthesis. To identify the site of control of heme biosynthesis in the human erythron, immature erythroid cells were obtained from peripheral blood and aspirated bone marrow. After incubation with human 59Fe transferrin, 2-[14C]glycine, or 4-[14C]delta-aminolevulinate, isotopic incorporation into extracted heme was determined. Addition of cycloheximide to increase endogenous free heme, reduced incorporation of labeled glycine and iron but not delta-aminolevulinate into cell heme. Incorporation of glycine and iron was also sensitive to inhibition by exogenous hematin (Ki, 30 and 45 microM, respectively) i.e. at concentrations in the range which affect cell-free protein synthesis in reticulocyte lysates. Hematin treatment rapidly diminished incorporation of intracellular 59Fe into heme by human erythroid cells but assimilation of 4-[14C]delta-aminolevulinate into heme was insensitive to inhibition by hematin (Ki greater than 100 microM). In human reticulocytes (unlike those from rabbits), addition of ferric salicylaldehyde isonicotinoylhydrazone, to increase the pre-heme iron pool independently of the transferrin cycle, failed to promote heme synthesis or modify feedback inhibition induced by hematin. In human erythroid cells (but not rabbit reticulocytes) pre-incubation with unlabeled delta-aminolevulinate or protoporphyrin IX greatly stimulated utilization of cell 59Fe for heme synthesis and also attenuated end product inhibition. In human erythroid cells heme biosynthesis is thus primarily regulated by feedback inhibition at one or more steps which lead to delta-aminolevulinate formation. Hence in man the regulatory process affects generation of the first committed precursor of porphyrin biosynthesis by delta-aminolevulinate synthetase, whereas in the rabbit separate regulatory mechanisms exist which control the incorporation of iron into protoporphyrin IX.     

Control of heme synthesis during Friend cell differentiation: role of iron and transferrin

In many types of cells the synthesis of delta-aminolevulinic acid (ALA) limits the rate of heme formation. However, results from our laboratory with reticulocytes suggest that the rate of iron uptake from transferrin (Tf), rather than ALA synthase activity, limits the rate of heme synthesis in erythroid cells. To determine whether changes occur in iron metabolism and the control of heme synthesis during erythroid cell development Friend erythroleukemia cells induced to erythroid differentiation by dimethylsulfoxide (DMSO) were studied. While added ALA stimulated heme synthesis in uninduced Friend cells (suggesting ALA synthase is limiting) it did not do so in induced cells. Therefore the possibility was investigated that, in induced cells, iron uptake from Tf limits and controls heme synthesis. Several aspects of iron metabolism were investigated using the synthetic iron chelator salicylaldehyde isonicotinoyl hydrazone (SIH). Both induced and uninduced Friend cells take up and utilize Fe for heme synthesis directly from Fe-SIH without the involvement of transferrin and transferrin receptors and to a much greater extent than from saturating levels of Fe-Tf (20 microM). Furthermore, in induced Friend cells 100 microM Fe-SIH stimulated 2-14C-glycine incorporation into heme up to 3.6-fold as compared to the incorporation observed with saturating concentrations of Fe-Tf. In contrast, Fe-SIH, even when added in high concentrations, did not stimulate heme synthesis in uninduced Friend cells but was able to do so as early as 24 to 48 h following induction. In addition, contrary to previous results with rabbit reticulocytes, Fe-SIH also stimulated globin synthesis in induced Friend cells above the level seen with saturating concentrations of transferrin. These results indicate that some step(s) in the pathway of iron from extracellular Tf to protoporphyrin, rather than the activity of ALA synthase, limits and controls the overall rate of heme and possibly hemoglobin synthesis in differentiating Friend erythroleukemia cells.     

Transferrin binding capacity as a marker of differentiation and maturation of rat erythroid cells fractionated by counter current distribution in aqueous polymer two-phase systems

Rat bone marrow cell populations, containing different proportions of erythroid cells, have been fractionated by counter-current distribution in the non-charge-sensitive dextran/polyethyleneglycol two-phase systems on the basis of hydrophobic cell surface properties. Cell fractions with a low distribution coefficient, which contain non-erythroid cells and early erythoblasts, showed a low transferrin binding capacity and a low haemoglobin/cell ratio whereas cell fractions with a high distribution coefficient, which contain intermediate-late erythroblasts and mature red cells, showed an elevated transferrin binding capacity and the highest haemoglobin/cell ratio. These results support transferrin binding capacity as a good marker parameter for the erythroid bone marrow cell differentiation and maturation processes.     

Iron uptake studies on erythroid cells.

Iron uptake from 55Fe-labelled transferrin, ferric citrate and the two fungal sideramines, ferricrocin and fusigen was studied using four erythroid cell cultures: Friend virus-transformed erythroleukemic cells (mouse), transformed bone marrow cells, Detroit-98 (human), reticulocytes (bovine), bone marrow cells (rabbit). The present comparative study reveals pronounced differences in iron uptake behaviour. Compared to transferrin, ferric citrate and the sideramines are preferred in transformed erythroid cells. In reticulocytes transferrin and ferric citrate showed a better uptake as compared to the two sideramines. Primary bone marrow cells showed nearly equal iron uptake rates using transferrin or ferricrocin.     

The effect of lysosomotrophic bases and inhibitors of transglutaminase on iron uptake by immature erythroid cells

The mechanism by which weak bases block iron uptake by immature erythroid cells was investigated using rabbit and rat reticulocytes and erythroblasts from the fetal rat liver. A large variety of bases was found to inhibit iron uptake but to have a much smaller or no effect on transferrin uptake by the cells. Quinacrine and chloroquine were active at the lowest concentrations. Dansylcadaverine, an inhibitor of transglutaminase, was also active at low concentration. However, the results do not indicate a role for transglutaminase in the iron uptake process. Instead they show that the major effect of the bases is to inhibit iron release from transferrin molecules on or within the cells. The possible mechanism of this effect was investigated by measurement of intracellular ATP levels, intracellular pH and by morphological studies utilizing fluorescent and electron microscopy. The bases caused little change in ATP levels, but elevated intracellular pH, probably due to accumulation within intracellular vesicles, which were shown to accumulate fluorescent weak bases, to swell under the action of the bases and to be the site of intracellular localization of transferrin. It is concluded that the bases tested in this work inhibit iron release from transferrin in intracellular vesicles by increasing their pH rather than by blocking transglutaminase and thereby restricting endocytosis. Reduction of transferrin uptake by the cells when it occurs is probably due to inhibition of recycling of transferrin receptors to the outer cell membrane.     

Iron uptake studies on erythroid cells

Iron uptake from ⁵⁵Fe-labelled transferrin, ferric citrate and the two fungal sideramines, ferricrocin and fusigen was studied using four erythroid cell cultures: Friend virus-transformed erythroleukemic cells (mouse), transformed bone marrow cells, Detroit-98 (human), reticulocytes (bovine), bone marrow cells (rabbit). The present comparative study reveals pronounced differences in iron uptake behaviour. Compared to transferrin, ferric citrate and the sideramines are preferred in transformed erythroid cells. In reticulocytes transferrin and ferric citrate showed a better uptake as compared to the two sideramines. Primary bone marrow cells showed nearly equal iron uptake rates using transferrin or ferricrocin.     

The effect of heterologous transferrin on the uptake of iron and haem synthesis by bone marrow cells

The initial process of transfer of extracellular iron to the haem-synthesizing mitochondria of immature erythroid cells is the association of iron-transferrin with the cell membrane. When rat bone marrow cells were incubated in the presence of iron bound to rat transferrin, iron uptake was higher than in the presence of iron bound to heterologous transferrin. The relative activities of the various isolated transferrins towards rat transferrin were found to be approximately 0.3, 0.8, 0.1 and 0.04 for rabbit, human, bovine and fish (tench, Tinca tinca) transferrin, respectively, and 0.7, 0.7 and 0.15 for mouse, guinea pig and calf serum, respectively, as compared with rat serum. Although great difference exist in cellular uptake of iron bound to different species of transferrin, the subcellular distribution of ⁵⁹Fe was quite similar. In all cases about 60% of the radioactivity taken up by the cells could be recovered in the haemin fraction and only about 15% in each the membrane and the non-haem soluble cell fraction. Similar results were obtained with guinea pig bone marrow cells.From the results of the experiments presented it might be concluded that the species of transferrin plays an important role during the initial stages of iron uptake by bone marrow cells, whereas the intracellular iron transfer process is not influenced by the species of transferrin.     

Globin synthesis in friend-erythroleukemia mouse cells in protein- and lipid-free medium : Effects of dimethyl-sulfoxide, iron and erythropoietin

A cell clone of erythroleukemic mouse cells transformed by the spleen focus forming virus (SFFV) was adapted to growth in serum-free medium. The cells show induced erythroid differentiation if dimethylsulfoxide (DMSO) and iron are added to the serum-free medium. No serum constituents or macromolecules are required for induced differentiation. Serum enhances the capacity of the cells to differentiate. Erythropoietin is ineffective in promoting erythroid differentiation or an increased rate of cell division. Transferrin is not necessary for transport of iron into these cells.     

Control of hemoglobin synthesis in erythroid differentiating K562 cells: II. Studies of iron mobilization in erythroid cells by high-performance liquid chromatography–electrochemical detection

We have demonstrated that iron controls hemoglobin (Hb) synthesis in erythroid differentiating K562 cells by enhancing the activity of a key enzyme of the Hb synthesis, δ-aminolevulinate synthase (ALAS). In the present study, we studied iron mobilization and the role of iron in erythroid differentiating cells by measuring the level of iron by means of high-performance liquid chromatography using electrochemical detection (HPLC–ED). After treatment of K562 cells with sodium butyrate, the expression of transferrin receptor (TfR) increased initially, followed by an increase in the levels of both total iron and Hb as well as the ALAS activity. However, no increase could be found in the levels of non-heme iron, low-molecular-mass iron (LMMFe) and ferritin. Addition of diferric transferrin (FeTf) enhanced both δ-aminolevulinic acid (ALA) and Hb synthesis. In contrast, addition of hemin elevated the levels of all iron species as well as the Hb synthesis but reduced the TfR expression and ALA contents in both butyrate treated and untreated cells. These results suggest that Hb synthesis is controlled by TfR expression, and that the ALA synthesis is suppressed by iron released from heme and/or Hb due to lowered expression of TfR.     

Transferrin endocytosis and iron uptake by developing erythroid cells in the chicken (Gallus domesticus)

Summary The mechanism of iron uptake by avian erythroid cells was investigated using cells from 7 and 15-day chicken embryos, and chicken serum transferrin and conalbumin (ovotransferrin) labelled with¹²⁵I and⁵⁹Fe. Endocytosis of the protein was determined by incubation of the cells with Pronase at 4°C to distinguish internalized from surface-bound protein.Iron was taken up by the cells by receptor-mediated endocytosis of transferrin or conalbumin. The receptors had the same affinity for serum transferrin and conalbumin. Endocytosis of diferric transferrin and conalbumin and exocytosis of apo-protein occurred at the same rates, indicating that iron donation to the cells occurred during the process of intracellular cycling of the protein. The recycling time was approximately 4 min. The rate of endocytosis of diferric protein varied with incubation temperature and at each temperature the rate of endocytosis was sufficient to account for the iron accumulated by the cells. These results and experiments with a variety of inhibitors confirmed the role of endocytosis in iron uptake.The mean cell volumes, receptor numbers and iron uptake rates of 7-day embryo cells were approximately twice those of 15-day embryo cells but the protein recycling times were approximately the same. Hence, the level of transferrin receptors is probably the main determinant of the rate of iron uptake during development of chicken erythroid cells.Transferrins from a variety of mammalian species were unable to donate iron to the chicken cells, but toad (Bufo marinus) transferrin could do so at a slow rate. The mechanism of iron uptake by developing chicken erythroid cells appears to be similar to that described for mammalian cells, although receptor numbers and iron uptake rates are lower than those reported for mammalian cells at a similar stage of development.Abbreviations BSS Hanks balanced salt solution - PBS phosphate buffered saline - MCV mean corpuscular volume - CCCP carbonyl cyanide-M-chlorophenyl hydrazone