Transferrin binding and iron uptake in mouse hepatocytes

Methods were developed for obtaining highly viable mouse hepatocytes in single cell suspension and for maintaining the hepatocytes in adherent static culture. The characteristics of transferrin binding and iron uptake into these hepatocytes was investigated. (1) After attachment to culture dishes for 18–24 h hepatocytes displayed an accelerating rate of iron uptake with time. Immediately after isolation mouse hepatocytes in suspension exhibited a linear iron uptake rate of 1.14·10⁵molecules/cell per min in 5 μM transferrin. Iron uptake also increased with increasing transferrin concentration both in suspension and adherent culture. Pinocytosis measured in isolated hepatocytes could account only for 10–20% of the total iron uptake. Iron uptake was completely inhibited at 4°C. (2) A transferrin binding component which saturated at 0.5 μM diferric transferrin was detected. The number of specific, saturable diferric transferrin binding sites on mouse hepatocytes was 4.4·10⁴±1.9·10⁴ for cells in suspension and 6.6·10⁴±2.3·10⁴ for adherent cultured cells. The apparent association constants were 1.23·10⁷ 1·mol^?1 and 3.4·10⁶ 1·mol^?1 for suspension and cultured cells respectively. (3) Mouse hepatocytes also displayed a large component of non-saturable transferrin binding sites. This binding increased linearly with transferrin concentration and appeared to contribute to iron uptake in mouse hepatocytes. Assuming that only saturable transferrin binding sites donate iron, the rate of iron uptake is about 2.5 molecules iron/receptor per min at 5 μM transferrin in both suspension and adherent cells and increases to 4 molecules iron/receptor per min at 10 μM transferrin in adherent cultured cells. These rates are considerably greater than the 0.5 molcules/receptor per min observed at 0.5 μM transferrin, the concentration at which the specific transferrin binding sites are fully occupied. The data suggest that either the non-saturable binding component donates some iron or that this component stimulates the saturable component to increase the rate of iron uptake. (4) During incubations at 4°C the majority of the transferrin bound to both saturable and nonsaturable binding sites lost one or more iron atoms. Incubations including 2 mM α,α′-dipyridyl (an Fe¹¹ chelator) decreased the cell associated ⁵⁹Fe at both 4 and 37°C while completely inhibiting iron uptake within 2–3 min of exposure at 37°C. These observations suggest that most if not all iron is loosened from transferrin upon interaction of transferrin with the hepatocyte membrane. There is also greater sensitivity of ⁵⁹Fe uptake compared to transferrin binding to pronase digestion, suggesting that an iron acceptor moiety on the cell surface is available to proteolysis.     

Iron uptake from transferrin and transferrin endocytic cycle in Friend erythroleukemia cells

Several aspects of iron metabolism were studied in cultured Friend erythroleukemia cells before and after induction of hemoglobin synthesis by dimethyl sulfoxide. The maximal rate of iron uptake from 59Fe-labeled transferrin, 1.5 X 10(6) atoms of Fe/cell per 30 min in uninduced cells, increased to 3 X 10(6) atoms/cell after 5 days of induction. The increase in iron uptake was not accompanied by a proportional increase in the number of transferrin receptors detected by 125I-labeled transferrin binding, suggesting a more efficient iron uptake by transferrin receptors in induced cells, with the rate of about 26 iron atoms per receptor per hour, compared to 15 atoms in uninduced cells. In agreement with this conclusion are results of the study of cellular 125I or 59Fe labeled transferrin kinetics. In the induced cells transferrin endocytosis and release proceeded with identical rates and all the endocytosed iron was retained inside the cell. On the other hand, transferrin release by uninduced cells was significantly slower and a substantial part of internalized 59Fe was released. On the basis of these results, different efficiency of iron release from internalized transferrin, accompanied by changes in cellular transferrin kinetics, is proposed as one of the factors determining the rate of iron uptake by developing erythroid cells.     

Erythropoietin effects on iron metabolism in rat bone marrow cells

This paper describes a study of the incorporation of ^{5 9}Fe from ^{5 9}Fe-labelled rat transferrin into rat bone marrow cells in culture. ^{5 9}Fe was found in both stroma and cytoplasm of marrow cells, and the cytoplasmic ^{5 9}Fe separated by polyacrylamide gel electrophoresis, into ferritin, haemoglobin and a low molecular weight fraction.The incorporation of ^{5 9}Fe into all three cytoplasmic fractions, but not into the stroma, increased progressively with time. Erythropoietin stimulated the increase of ^{5 9}Fe in ferritin within 1 h, the earliest time examined, and more than 3 h later in the stroma and haemoglobin.A proportion of the ⁵⁹Fe incorporated into the stroma and low molecular weight iron fractions during a 1 h incubation with ⁵⁹Fe-labelled transferrin was mobilised into ferritin and haemoglobin during a subsequent 4-h “cold-chase”. Erythropoietin, when present during the “cold-chase”, did not influence these ⁵⁹Fe fluxes. The erythropoietin stimulation of ⁵⁹Fe incorporation into ferritin, one of the earliest erythropoietin effects to be recorded, was therefore considered to be due to an increase of ⁵⁹Fe uptake by the hormone-responsive cells rather than a direct effect on ferritin synthesis.20-h cultures containing erythropoietin when incubated with ⁵⁹Fe-labelled transferrin for 4 h, showed dose-related erythropoietin stimulation of ⁵⁹Fe incorporation into haemoglobin only.In the presence of 10 mM isonicotinic acid hydrazide, ⁵⁹Fe incorporation into haemoglobin was inhibited, as in reticulocytes (Ponka, P. and Neuwirt, J. (1969) Blood 33, 690–707), while that into the stroma, ferritin and low molecular weight iron fractions, was stimulated; there were no reproducible effects of erythropoietin.     

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.     

Dimethyl sulfoxide (DMSO) stimulates heme synthesis in quail embryonic yolk sac cells

Dissociated yolk sac cells from quail embryos at the definitive primitive streak stage were reaggregated, using a gyratory shaker with or without dimethyl sulfoxide (DMSO). After 24 h of incubation in the shaker, the aggregates were transferred onto a whole egg agar medium containing ⁵⁹Fe, and incubation was continued for an additional 48 h. It was clearly shown that DMSO-treated yolk sac aggregates showed a higher incorporation of radioactive iron into heme than the control culture without DMSO. The maximal stimulatory effect was observed at around 0.75% DMSO.     

Acquisition of iron from transferrin regulates reticulocyte heme synthesis

Fe-salicylaldehyde isonicotinoylhydrazone (SIH), which can donate iron to reticulocytes without transferrin as a mediator, has been utilized to test the hypothesis that the rate of iron uptake from transferrin limits the rate of heme synthesis in erythroid cells. Reticulocytes take up 59Fe from [59Fe]SIH and incorporate it into heme to a much greater extent than from saturating concentrations of [59Fe]transferrin. Also, Fe-SIH stimulates [2-14C]glycine into heme when compared to the incorporation observed with saturating levels of Fe-transferrin. In addition, delta-aminolevulinic acid does not stimulate 59Fe incorporation into heme from either [59Fe]transferrin or [59Fe]SIH but does reverse the inhibition of 59Fe incorporation into heme caused by isoniazid, an inhibitor of delta-aminolevulinic acid synthase. Taken together, these results suggest the hypothesis that some step(s) in the pathway of iron from extracellular transferrin to intracellular protoporphyrin limits the overall rate of heme synthesis in reticulocytes.     

The mechanism of hepatic iron uptake from native and denatured transferrin and its subcellular metabolism in the liver cell.

Hepatic iron uptake and metabolism were studied by subcellular fractionation of rat liver homogenates after injection of rats with a purified preparation of either native or denatured rat transferrin labelled with 125I and 59Fe. (1) With native transferrin, hepatic 125I content was maximal 5 min after injection and then fell. Hepatic 59Fe content reached maximum by 16 h after injection and remained constant for 14 days. Neither label appeared in the mitochondrial or lysosomal fractions. 59Fe appeared first in the supernatant and, with time, was detectable as ferritin in fractions sedimented with increasingly lower g forces. (2) With denatured transferrin, hepatic content of both 125I and 59Fe reached maximum by 30 min. Both appeared initially in the lysosomal fraction. With time, they passed into the supernatant and 59Fe became incorporated into ferritin. The study suggests that hepatic iron uptake from native transferrin does not involve endocytosis. However, endocytosis of denatured transferrin does occur. After the uptake process, iron is gradually incorporated into ferritin molecules, which subsequently polymerize; there is no incorporation into other structures over 14 days.     

Iron metabolism of established human hematopoietic cell lines in vitro

Three malignant hematopoietic cell lines were used in studies on cellular iron metabolism. Our results show that iron-carrying transferrin became bound to specific dimeric cell surface receptors. Iron accumulated within the cell with time, whereas intact transferrin was released back to the medium. Chloroquine and NH₄Cl, known as pH-raising agents in vesicles of the lysosomal system, inhibited iron accumulation and transferrin binding in a dose-dependent manner. This suggests that the acid pH in endosomes leads to the cleavage of the iron-transferrin bonds. Transferrin degradation was not found, which leads us to suggest a process of ‘acid flushing’ for the dissociation of iron from transferrin without the involvement of endosome-lysosome fusion. Taken together, the data agree with the concept of receptor-mediated endocytosis, as described for many macromolecules. Iron was stored in ferritin in the cell types tested. Only a minor part (less than 15%) of the iron was bound in hemoglobin in the K-562 cell line. The relationship between iron stores and exogenously added iron in heme synthesis was investigated using a double labelling (⁵⁵Fe/⁵⁹Fe) technique. The results showed that exogenous iron was preferentially used before the iron stored in ferritin. The results are discussed in relation to various hypotheses on cellular iron uptake and transport.     

The nature of iron released by resident and stimulated mouse peritoneal macrophages

Mouse peritoneal macrophages were allowed to ingest ⁵⁹Fe, ¹²⁵I-labelled transferrin-antitransferrin immune complexes, and the release of ⁵⁹Fe and degraded transferrin was studied. Some iron was released as ferritin, but a major portion was bound by bovine transferrin present in the culture medium, which contained fetal calf serum. If the medium was saturated with iron prior to incubation with the cells, little of the released iron was then bound by transferrin but appeared either as a high molecular weight fraction or, if nitrilotriacetate was present in the medium, some also appeared as a low molecular weight fraction. The release of non-ferritin iron was biphasic, the early, rapid phase being more prolonged with resident cells than with stimulated cells. The rate of release in the late phase did not differ significantly between resident and stimulated cells. Incubation at 0°C completely suppressed the release of degraded transferrin, but iron release continued at about 30% of the rate seen in control cultures at 37°C. A model for the intracellular handling of ingested iron is proposed to take account of the different release patterns of resident and stimulated macrophages.     

Iron and transferrin distribution in reticulocytes incubated with heme synthesis inhibitors

A high level of non-heme iron (either labelled or unlabelled) in mitochondria, ferritin and low-molecular-weight pool of reticulocytes was induced by preincubation with isonicotinic acid hydrazide or penicillamine together with either ⁵⁹Fe- or ⁵⁶Fe-labelled transferrin. Addition of apotransferrin during reincubation of ⁵⁹Fe-labelled reticulocytes was accompanied by the transfer of ⁵⁹Fe from low-molecular-weight pool to transferrin, which was found in the reticulocyte cytosol both free and bound to a carrier. Similarly, when cells were reincubated with ¹²⁵I-labelled transferrin, more ¹²⁵I-labelled radioactivity was found, in both free and carrier-bound transferrin peaks, in reticulocytes with a high level of low-molecular-weight cold iron than in control ones. These results suggest that transferrin enters reticulocytes takes up iron from low-molecular-weight pool.     

LOSS OF IRON FROM MOUSE PERITONEAL MACROPHAGES IN VITRO AFTER UPTAKE OF [55FE]FERRITIN AND [55FE]FERRITIN RABBIT ANTIFERRITIN COMPLEXES

Mouse peritoneal macrophages in culture for 24 h were exposed to horse [⁵⁵Fe]ferritin and rabbit antihorse [⁵⁵Fe]ferritin antibody complex and the amount of ⁵⁵Fe in the medium was assayed up to 2 days after the pulse uptake. Cell survival was assayed by photographing the same areas of the tissue culture Petri dish on successive days and by counting cell numbers per unit area. In experiments in which quantitative assay for cell death is negligible, about 10–20% of the iron ingested by pinocytosis or phagocytosis is released to iron-free medium containing either freshly dialyzed or deironized newborn calf serum (10%). Over the 2-day postpulse period, iron loss is linear. This loss of iron to the medium is significantly reduced by adding iron-saturated newborn calf serum in the postpulse recovery period. A significant portion of the iron released to the medium is bound to transferrin. When human serum is used in the tissue culture system, similar quantities (10–25%) of the ingested iron are lost to the medium 2 days after the pulse.     

Ferritin iron kinetics and protein turnover in K562 cells

The binding, incorporation, and release of iron by ferritin were investigated in K562 cells using both pulse-chase and long term decay studies with 59Fe-transferrin as the labeled iron source. After a 20-min pulse of labeled transferrin, 60% of the 59Fe was bound by ferritin with the proportion increasing to 70% by 4 h. This initial binding was reduced to 35% when the cells were exposed to the chelator desferrioxamine (5 mM) for an additional 30 min. By 4 h the association of 59Fe with ferritin was unaffected by the presence of the chelator, and levels of 59Fe-ferritin were identical to those in control cells (70%). Between 4-10h there was a parallel decline in 59Fe-ferritin in both control and desferrioxamine-treated cells. When incoming iron was bound by ferritin it was, therefore, initially chelatable but with time progressed to a further, nonchelatable compartment. In turnover studies where ferritin was preloaded with 59Fe by overnight incubation, 50% of the label was released from the protein by 18 h, contrasting with a t 1/2 for cellular iron release of approximately 70 h. The half-time of 59Fe release from ferritin was accelerated to 11 h by the presence of desferrioxamine. The half-time for ferritin protein turnover determined by [35S]methionine labeling was approximately 12 h in the presence or absence of the chelator. Thus, when the reassociation of iron with ferritin was prevented by the exogenous chelator there was a concordant decay of both protein and iron moieties. The direct involvement of lysosomes in this turnover was demonstrated by the use of the inhibitors leupeptin and methylamine which stabilized both 59Fe (t 1/2 = 24 h) and 35S (t 1/2 = 25.6 h) labels. We conclude that in this cell type the predominant mechanism by which iron is released from ferritin is through the constitutive degradation of the protein by lysosomes.     

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.     

Ferric pyridoxal isonicotinol hydrazone can provide iron for heme synthesis in reticulocytes

We have examined whether reticulocytes depleted of transferrin might incorporate ⁵⁹Fe from ⁵⁹Fe-labelled pyridoxan isonicotinoyl hydrazone (PIH). Transferrin-depleted reticulocytes showed a time-, temperature- and concentration-dependent incorporation of ⁵⁹Fe when incubated with 20–200 μM ⁵⁹Fe-PIH. The amount of ⁵⁹Fe incorporated with 200 μM ⁵⁹Fe-PIH is equal to or higher than that taken up from transferrin at 20 μM ⁵⁹Fe concentration. After 60 min about 60% of the ⁵⁹Fe taken up by the cells is recovered in heme while the remainder is probably still bound to PIH. 1 mM succinyl acetone (a specific inhibitor of heme synthesis) inhibits PIH-mediated incorporation of ⁵⁹Fe into heme by about 79% indicating that ⁵⁹Fe from ⁵⁹Fe-PIH is incorporated into de novo synthesized protoporphyrin. As is the case with transferrin, erythrocytes do not incorporate ⁵⁹Fe from ⁵⁹Fe-PIH. Pretreatment of reticulocytes with pronase does not inhibit their ability to incorporate ⁵⁹Fe from ⁵⁹Fe-PIH, suggesting that, unlike the uptake of Fe from transferrin, membrane receptors are not involved in the uptake of Fe-PIH by the cells.     

Mobilization of ferritin iron in erythroblasts by chelating agents

Intracellular ferritin in newt (Triturus cristatus) erythroblasts was accessible to the chelating effects of EDTA and pyridoxal phosphate. EDTA (0.5-1 mM) promoted release of radioactive iron from ferritin of pulse-labelled erythroblasts during chase incubation, but its continuous presence was not necessary for ferritin iron mobilization. Brief exposure to EDTA was sufficient to release 60-70% of ferritin 59Fe content during ensuing chase in EDTA-free medium. EDTA also suppressed cellular iron uptake and utilization for heme synthesis, but these activities were restored upon its removal. Pyridoxal-5'-phosphate (0.5-5 mM) also stimulated loss of radioactive iron from ferritin; however, ferritin iron release by pyridoxal phosphate required its continued presence. Unlike EDTA, pyridoxal phosphate did not interfere with iron uptake or its utilization for heme synthesis. Chelator-mobilized ferritin iron accumulated initially in the hemolysate as a low-molecular-weight component and appeared to be eventually released into the medium. No radioactive ferritin was found in the medium of chelator-treated cells, indicating that secretion or loss of ferritin was not responsible for decreasing cellular ferritin 59Fe content. Moreover, there was no transfer of radioactive iron between the low-molecular-weight component released into the medium and plasma transferrin. These results indicate that chelator-released ferritin iron is not available for cellular utilization in heme synthesis and that ferritin iron released by this process is not an alternative or complementary iron source for heme synthesis. Correlation of these data with effects of succinylacetone inhibition of heme synthesis and with previous studies indicates that the main role of erythroid cell ferritin is absorption and storage of excess iron not used for heme synthesis.     

Species specificity of transferein binding,endocytosis and iron internalization by cultured chick myogenic cells

Summary The ability of unlabelled heterologous transferrin to interact with transferrin receptors on developing chick myogenic cells was investigated by measuring their capacity to inhibit the surfacebinding and internalization of¹²⁵I-and⁵⁹Fe-labelled ovotransferrin. Transferrins from rat, rabbit, human, and a species of kangaroo (Macropus fuliginosus) were unable to inhibit either surfacebinding or internalization of labelled ovotransferrin even at concentrations ten times the molar concentration of the ovotransferrin. Transferrins isolated from the serum of a toad (Bufo marinus) and a lizard (Teliqua rugosa), when added at high concentrations, were found to reduce surface-binding of¹²⁵I-Tf by 20–25% but did not inhibit internalization of either¹²⁵I-Tf or⁵⁹Fe. This suggests that the effects of toad and lizard transferrins are due to non-specific binding to the myogenic cells. In contrast, inhibition of both surface-binding and internalization of labelled ovotransferrin was found when myogenic cells were incubated in the presence of the homologous transferrin (ovotransferrin). The species-specificity of transferrin binding, endocytosis and iron internalization did not vary with the state of proliferation or differentiation of the myogenic cells. However, the intracellular iron utilization was found to differ between differentiating presumptive and terminally differentiated myotubes. Internalized⁵⁹Fe was fractioned by gel filtration. In dividing and non-dividing presumptive myoblasts⁵⁹Fe was found to elute in three peaks, two with elution volumes corresponding to ferritin and transferrin and one at greater elution volume than that of myoglobin. In myotubes the same fractions occurred, and in addition some⁵⁹Fe was eluted at the same volume as myoglobin.Abbreviations Tf-Fe ₂ differic transferrin - BSA bovine serum albumin - BSS balanced salt solution - MEM Eagle's modified minimum essential medium - MW molecular weight - BUdR bromodeoxyuridine - Ara-C cytosine arabinoside     

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.     

Iron metabolism in K562 erythroleukemic cells

Iron delivery to K562 cells is enhanced by desferrioxamine through induction of transferrin receptors. Experiments were performed to further characterize this event with respect to iron metabolism and heme synthesis. In control cells, up to 85% of the iron taken up from iron-transferrin was incorporated into ferritin, 7% into heme, and the remainder into compartments not yet identified. In cells grown with desferrioxamine, net accumulation of intracellular desferrioxamine (14-fold) was observed and iron incorporation into ferritin and heme was inhibited by 86% and 75%, respectively. In contrast, complete inhibition of heme synthesis in cells grown with succinylacetone had no effect on transferrin binding or iron uptake. Exogenous hemin (30 microM) inhibited transferrin binding and iron uptake by 70% and heme synthesis by 90%. These effects were already evident after 2 h. Thus, although heme production could be reduced by desferrioxamine, succinylacetone, and hemin, cell iron uptake was enhanced only by the intracellular iron chelator. The effects of exogenous heme are probably unphysiologic and the greater inhibition of iron flow into heme can be explained by effects on early steps of heme synthesis. We conclude that in this cell model a chelatable intracellular iron pool rather than heme synthesis mediates regulation of iron uptake.     

Assay and characteristics of the iron binding moiety of reticulocyte endocytic vesicles

Summary A⁵⁹Fe assay was designed to detect an Fe(III) binding capacity in NP-40 solubilized proteins from rabbit reticulocyte endocytic vesicles. The iron binding capacity had an apparent molecular weight as determined by gel exclusion chromatography of 450,000 daltons. The iron binding moiety coincided with the major nontransferrin iron-containing material of endocytic vesicles labeled in vivo by incubation of cells with⁵⁹Fe,¹²⁵I-labeled transferrin. The material solubilized from vesicles with NP-40 exhibited two classes of saturable binding sites, one with an association constant for⁵⁹Fe-citrate of 3.63×10⁹ m ^–1 and with 6.6×10^–12 moles of iron bound per mg protein and the other with a constant of 3.96×10⁸ m ^–1 and 1.0×10^–12 moles of iron bound per mg protein. These affinities are sufficient to satisfy the sobulility characteristics of Fe(III) at pH 5.0. Most of the⁵⁹Fe bound both in vivo and in vitro to the iron binding moiety could be displaced with⁵⁶Fe and an equivalent amount of⁵⁹Fe could subsequently be rebound in vitro. The iron binding assay was adopted to vesicle proteins separated by SDS-polyacrylamide gel electrophoresis with subsequent transfer to nitrocellulose and revealed an iron binding activity of molecular weight approximately 95,000 daltons.