Uptake of Transferrin-Bound Iron by Rat Cells in Tissue Culture

The in vitro uptake of transferrin-bound iron by rat liver cells and rat embryo cells in culture, and by rat reticulocytes, was studied using labelled rat serum. The uptake of iron by rat liver cells was linear with time and showed a curvilinear relationship with the serum iron concentration. Over 40% of the cell radioactivity was found to be ferritin associated. Incubation of rat transferrin doubly labelled with ⁵⁹Fe and ¹²⁵l showed a difference between the uptakes of the two isotopes suggesting reflux of transferrin from the cell after iron uptake. In order to compare iron uptake from half saturated (Tf-Fe 1) and fully saturated (Tf-Fe2) transferrin, the three cell systems were each incubated in sera labelled with ⁵⁵Fe at 10% saturation and with ⁵⁹Fe at varying iron saturations ranging from 10% to 90%. Similar experiments were performed with sera having been randomly labelled with ⁵⁵Fe and labelled with ⁵⁹Fe but preincubated with reticulocytes in order to produce iron bound to non-reticulocyte orientated transferrin binding sites. The data obtained confirms the presence of a functional heterogeneity with respect to the half and fully saturated transferrin. Thus iron uptake from fully saturated transferrin was almost twice that for the half saturated molecule with rat liver cells or reticulocytes, and over three times that of the half saturated molecule with rat embryo cells. In contrast no such differences could be detected when iron uptake from serum randomly labelled with iron and serum with labelled non-reticulocyte orientated binding sites were compared. Finally, the effect of pre-incubating each of the three cell systems in unlabelled sera of varying percentage iron saturations on subsequent radio-iron uptake was studied. An inverse relationship between percentage saturation of the preincubation serum and subsequent uptake was demonstrated indicating that cellular mechanisms also influence cell iron uptake.     

Non-transferrin dependent 59Fe uptake in phytohemagglutinin-stimulated human peripheral lymphocytes.

Human peripheral lymphocytes stimulated by phytohemagglutinin (PHA) have been used to demonstrate the characteristics of iron uptake from non-transferrin iron donors. When incubated with 59Fe(II)-ascorbate or 59Fe(III)-nitrilotriacetate (Fe-NTA), stimulated lymphocytes (2 micrograms/ml PHA) showed a tenfold increase in uptake of 59Fe as compared with the resting cells. The uptake of 59Fe from these iron donors was time and concentration dependent, showed saturation kinetics, and was not influenced by the addition of a tenfold excess of unlabeled Fe(III)2-transferrin (Fe-Tf). The amount of 59Fe accumulated from 59Fe-NTA was about one-third of that from 59Fe2-Tf, whereas the uptake of 59Fe from 59Fe-ascorbate was about tenfold higher. When stimulated with varying doses of PHA, lymphocytes showed maximal uptake of 59Fe from 59Fe2-Tf at the concentration of PHA (1 microgram/ml) optimal for 3H-thymidine incorporation. Lymphocytes stimulated with supraoptimal concentrations (5-20 micrograms/ml) of PHA showed slightly less iron uptake from 59Fe-Tf and had a longer transferrin cycle time, as compared with the cells under optimal stimulation. In contrast, the uptake of 59Fe from non-transferrin 59Fe donors in cells stimulated with 5-20 micrograms/ml PHA was greater than that in cells grown with 1 or 2 micrograms/ml PHA. It is suggested that lymphocytes take up iron from non-transferrin iron donors by processes different from the iron uptake pathway used by transferrin.     

The mechanisms of iron uptake by fetal rat hepatocytes in culture

The mechanisms of iron accumulation by cultured hepatocytes isolated from fetal rat liver (19 days gestation) were investigated using rat transferrin labeled with 125I and 59Fe. The rates of iron and transferrin internalization by the cells were measured by incubating the hepatocytes with the labeled transferrin at 37 degrees C followed by treatment with pronase at 4 degrees C to remove surface-bound transferrin and iron. Iron internalization increased linearly with time. Approximately 65% of the internalized iron was incorporated into ferritin. In contrast to iron, the rate of transferrin internalization was biphasic, with a rapid phase during the first 10 to 15 min and a second slower phase which becomes more apparent after that time. Iron and transferrin internalization were temperature-dependent. Chase experiments showed that the internalized transferrin donated all of its iron to the cell and was then released in a biphasic manner which was dependent on the time of preincubation with radiolabeled transferrin. These experiments showed that iron uptake occurs by at least three processes. The first mechanism involves the specific receptor-mediated endocytosis of transferrin. Each cell has an average of 7.8 +/- 1.0 X 10(5) (mean +/- SE, n = 5) transferrin binding sites with an apparent association constant of 2.0 +/- 0.4 X 10(6) M-1. The second process is nonsaturable up to a transferrin concentration of at least 6 microM but like the specific process, also leads to accumulation of iron in excess of transferrin. It involves the endocytosis of transferrin mediated by 4.2 X 2.6 X 10(5) M-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Uptake of transferrin-bound and nontransferrin-bound iron by reticulocytes from the Belgrade laboratory rat: comparison with Wistar rat transferrin and reticulocytes.

The mechanism underlying the impaired uptake of iron from transferrin by reticulocytes from the Belgrade laboratory rat was investigated using 125I- and 59Fe-labeled transferrin isolated from homozygous Belgrade rats and from Wistar rats, nontransferrin-bound Fe(II) in an isotonic sucrose solution, and reticulocytes from Belgrade and Wistar rats. The Belgrade rat transferrin had the same molecular weight and net charge as Wistar rat transferrin, donated iron equally well to both types of reticulocytes, and competed equally for transferrin binding sites on the cells. Hence, the defect in iron uptake by Belgrade rat reticulocytes could not be attributed to an abnormality of the transferrin molecule. The rate of uptake of Fe(II) from sucrose into the cytosolic and stromal fractions of Belgrade rat reticulocytes was only about 35% as great as that by Wistar rat reticulocytes. With both types of cells, the uptake process was saturable, suggesting the presence of a carrier-mediated process. It was therefore concluded that the defect in iron uptake by Belgrade rat erythroid cells is probably the consequence of a deficiency in a membrane carrier for iron.     

Uptake and release of transferrin and iron by mitogen-stimulated human lymphocytes

Phytohaemagglutinin stimulation of human peripheral blood lymphocytes resulted in the expression of transferrin receptors and the uptake of iron into the cells. As assessed from the resistance of the ¹²⁵I label to pronase, transferrin was rapidly bound and internalized at 37°C, while at 4°C 85% of the ¹²⁵I label remained on the cell surface and was degraded by the pronase. Over 94% of the ¹²⁵I label associated with and subsequently released from the cells was acid precipitable, indicating that transferrin was not degraded during its uptake and release. After reincubation for 1 h in fresh medium 70% of the cell associated ¹²⁵I-transferrin was released. In contrast, less than 30% of the ⁵⁹Fe was released, showing that iron was removed from transferrin and retained by the cells.
Concentration dependent binding of ¹²⁵I-transferrin estimated at 37°C occurred with an apparent K_a of 5·7±1·1 × 10⁷l mol⁻¹ (mean ± SD, n = 4) indicating little variation between cells from different individuals, although the number of transferrin molecules associated with the cells varied greatly from 6·2 × 10⁴/cell to 1·4 × 10⁵/cell. The rate of iron uptake from ⁵⁹Fe and ¹²⁵I labelled transferrin at 37°C by the cells from different subjects was also very variable, with a range between 0·46 and 2·27 pg Fe/min/10⁶ cells ( n = 6). However, iron uptake did not correlate with the amount of transferrin bound. This suggests that transferrin uptake and the release of iron from the transferrin to the interior of the cell are controlled independently.     

Desferrithiocin is an effective iron chelator in vivo and in vitro but ferrithiocin is toxic

The efficacy and toxicity of the siderophore desferrithiocin (DFT), which has shown potential application in iron chelation therapy, were assessed in vivo and in vitro. DFT was evaluated in vivo in two ways: firstly, by measuring the effect of a single dose of DFT (10-100 mg/kg) on 59Fe excretion in iron-loaded rats labelled with 59Fe; and secondly, by examining the effect of the daily oral administration for 2 weeks of DFT (10-25 mg/kg/d) on the growing rat. DFT and its ferric complex, ferrithiocin (FT), were assessed in vitro from their effects on transferrin and iron uptake and mobilization from rat hepatocytes in culture using transferrin doubly labelled with 125I and 59Fe. Both oral and subcutaneous DFT were highly effective in promoting iron excretion in vivo, but showed evidence of toxicity after oral administration for 2 weeks at 25 mg/kg/d. In addition, DFT was much more effective than desferrioxamine or pyridoxal isonicotinyl hydrazone in reducing hepatocyte iron in vitro. However, FT was cytotoxic, causing membrane disruption and release of intracellular aspartate aminotransferase. It was concluded that DFT should not be considered for chronic iron chelation therapy without extensive further evaluation.     

Diminished acquisition of iron by reticulocytes from mice with hemoglobin deficit

Reticulocyte iron and transferrin uptake was studied in hemoglobin deficit (gene symbol, hbd), an autosomal recessive trait in the mouse characterized by hypochromic microcytic anemia, reticulocytosis, hyperferremia, and increased red-cell-free protoporphyrin. Reticulocyte-rich red cells were incubated in vitro in a mixture of 125I-labeled diferric mouse transferrin and 59Fe-labeled iron-saturated mouse plasma. At 37 degrees C, the uptake of transferrin by reticulocytes from affected animals (15 ng/micrograms RNA) was the same as that of reticulocytes from control animals. However, the uptake of iron by affected reticulocytes (0.11 ng/micrograms RNA) was significantly lower than that by control reticulocytes (0.24). At 4 degrees C, transferrin binding by affected and control reticulocytes was again indistinguishable. The deficiency in the uptake of iron by affected reticulocytes was not observed on incubation at 4 degrees C. Scatchard analysis of transferrin receptors on hbd/hbd and control reticulocytes showed no difference in pKD and a slight elevation in number of receptors per reticulocyte for hbd/hbd animals. These findings suggest that hbd/hbd reticulocytes have a defect in iron acquisition that is distal to the binding of transferrin to the cell membrane receptor. This defect is similar to one already described in the anemia of the Belgrade laboratory rat.     

Fluorescence probe measurement of the pH of the transferrin microenvironment during iron uptake by rat bone marrow erythroid cells

Fluorescence probe measurements of the transferrin micro-environment during iron uptake by rat erythroid cells revealed that part of the transferrin is taken up in an acidic environment. The pH of this intracellular transferrin environment is 5.7. When rat erythroid cell precursors are incubated with diferric transferrin then in the incubation medium monoferric transferrins TfNFe and TfFeC appear. In view of the known instability of TfNFe at acidic pH, TfNFe cannot arise after endocytosis of Tf2Fe in acid vesicles at pH below 6.0. The results support the existence of a mechanism other than endocytosis in the iron uptake process in rat erythroid cells.     

Cytosol intermediates in the transport of iron

Three 59Fe-labeled nonheme components of the cytosol were identified when rabbit reticuloyctes were incubated with 59Fe-labeled plasma under conditions in which the iron supply was not limiting. Two of these components were identified as ferritin and transferrin. The latter was characterized by gel filtration as having apparent molecular weight higher than transferrin, indicating that the transferrin may be complexed to another moiety. The third component, referred to as iron- binding protein-I (IBP-I), is as yet uncharacterized. When the reticulocytes were incubated with unlabeled plasma after pulse-labeling with 59Fe-labeled plasma, 59Fe radioactivity in these cytosol components decreased; after 15 min of chase, the 59Fe in ferritin, transferrin, and IBP-I fell to 64.6%, 26.5%, and 65.8% of the initial values, respectively. A good correlation existed between the decrease of 59Fe in these three nonheme compartments and the associated increase in 59Fe-heme. The data presented suggest that cytosol ferritin, transferrin, and IBP-I are intermediates in the transport of 59Fe from the plasma membrane to the mitochondria.     

Subcellular distribution of desferrioxamine and hydroxypyridin-4-one chelators in K562 cells affects chelation of intracellular iron pools

Summary The interactions of iron chelators with intracellular iron pools have been examined by measuring the subcellular distribution of radiolabelled desferrioxamine (DFO) and the orally active hydroxypyridinone (HPO) chelator 1, 2-diethyl-3-hydroxypyridin-4-one (CP94), as well as the ability of these chelators to modify the subcellular distribution of ⁵⁹Fe delivered by the receptor mediated endocytosis of transferrin. K562 cells were pulsed with ⁵⁹Fe transferrin and challenged with DFO or CP94 (100 μm IBE) for 20 or 240 min and then subjected to subcellular fractionation. At 20 min there was a significant decrease (P <0.45) in both lysosomal/particulate ⁵⁹Fe (75% of control) and cytosolic ⁵⁹Fe ferritin (50% of control) in cells incubated with CP94, unlike cells treated with DFO where no decrease was observed. By 240 min, in addition to the above, ⁵⁹Fe accumulation was significantly decreased in the nuclear, mitochondrial, and low molecular weight cytosolic fractions with CP94 (P < 0.05). With DFO a significant decrease in ⁵⁹Fe in only the lysosomal/particulate and cytosolic ferritin compartments was observed at 240 min (P <045). At this time, however, there was a significant accumulation of both cytosolic low molecular weight ⁵⁹Fe and cytosolic DFO. The relatively rapid decrease of ⁵⁹Fe within intracellular compartments seen with CP94 compared to DFO was paralleled by a significantly higher accumulation of CP94 than DFO in nuclear, lysosomal/particulate and low molecular weight cytosolic compartments at 20 min (P <0 05). These results suggest that transferrin derived endosomal iron may be chelated by HPOs, unlike DFO, due to their faster uptake into these organelles. The more rapid access of HPOs than DFO to certain intracellular iron pools may explain the greater possibility of HPOs to inhibit proliferation of cells in vivo.     

Anemia of the Belgrade rat: evidence for defective membrane transport of iron

The mechanisms underlying the impaired utilization of transferrin-bound iron by erythroid cells in the anemia of the Belgrade laboratory rat were investigated using reticulocytes from homozygous anemic animals and transferrin labeled with 59Fe and 125I. The results were compared with those obtained using reticulocytes from phenylhydrazine-treated rats and iron-deficient rats. Each step in the iron uptake mechanism was investigated, ie, transferrin-receptor interaction, transferrin endocytosis, iron release from transferrin, and transferrin exocytosis. Although there were quantitative differences, no fundamental difference was found in any of the abovementioned aspects of cellular function when the reticulocytes from Belgrade rats were compared with those from iron-deficient animals. The basic defect in the Belgrade reticulocytes must therefore reside in subsequent steps in iron uptake, after it is released from transferrin within endocytotic vesicles, ie, in the mechanism by which it is transferred across the lining membrane of the vesicles into the cell cytosol. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of reticulocyte ghosts extracts demonstrated a prominent protein band of mol wt 69,000 that was absent or present only in low concentration extracts from the other two types of reticulocytes. This may be a result of the genetic defect.     

Inhibition of cellular iron uptake by haem in mouse erythroleukaemia cells

Haemin inhibited iron uptake from transferrin (Tf) by mouse erythroleukaemia cells (MELC) induced for differentiation by hexamethylene bisacetamide (HMBA). The rate of 59Fe internalization was decreased, but the rate and the extent of 125I-Tf endocytosis was unaffected by the addition of haemin. Haemin inhibited 59Fe incorporation into haem by a greater proportion than the overall uptake of 59Fe from Tf. The reduction of total cellular 59Fe uptake was more pronounced at 59Fe-Tf concentrations closer to saturation. Exogenous 5-aminolaevulinic acid stimulated 59Fe utilization for haem synthesis in MELC but did not revert the inhibition induced by haemin. Haem synthesis measured by 14C-glycine incorporation into haem was maintained for at least 1 h without an external transferrin iron source and was inhibited by the addition of haemin equally over the whole range of Tf concentrations studied. Desferrioxamine (DFO) stimulated cellular uptake of 59Fe by the uninduced cells and reverted the inhibition of 59Fe transport into HMBA treated cells caused by haemin. Addition of DFO within a short-term incubation had no effect on haem synthesis measured by 14C-glycine incorporation into haem. No evidence for a direct effect of haem on the transferrin cycle or iron release was found. It was concluded that the reduction of iron uptake by haemin treated MELC is secondary to the decrease in iron utilization for haem synthesis.     

Transferrin uptake by bone marrow macrophages is independent of the degree of iron saturation

The uptake of transferrin by macrophages was studied in relation to the degree of iron saturation. Rat bone marrow derived macrophages were incubated with transferrin labelled with 59Fe and 3H. At 37 degrees C the amount of 59Fe incorporated by macrophages was dependent on the time of incubation. 3H labelled transferrin was found degraded in the supernatants of the cell culture (material not precipitated by trichloroacetic acid) in a time dependent fashion. Taking into account the specific activity of 59Fe-3H labelled transferrin, we found that 95% of the transferrin uptake was degraded. This suggests that most of the uptake of transferrin was not mediated by a receptor-dependent mechanism, but by a phase fluid endocytosis. 3H-labelled apotransferrin appears in the supernatant of the cell culture at the same rate as 59Fe-3H labelled diferric transferrin, showing an identical uptake for the two types of transferrin. Uptake of apo- or diferric transferrin by macrophages was identical in relation to time of incubation and the amount of transferrin used. These studies suggest that most of the transferrin uptake by bone marrow macrophages (non-activated or non-elicited cells) is mediated by a non-receptor mechanism that is independent of the degree of transferrin saturation.     

Tissue distribution and clearance kinetics of non-transferrin-bound iron in the hypotransferrinemic mouse: a rodent model for hemochromatosis.

Genetically hypotransferrinemic mice accumulate iron in the liver and pancreas. A similar pattern of tissue iron accumulation occurs in humans with hereditary hemochromatosis. In both disorders, there is a decreased plasma concentration of apotransferrin. To test the hypothesis that nontransferrin-bound iron exists and is cleared by the parenchymal tissues, the tissue distribution of 59Fe was studied in animals lacking apotransferrin. Two groups of animals were used: normal rats and mice whose transferrin had been saturated by an intravenous injection of nonradiolabeled iron, and mice with congenital hypotransferrinemia. In control animals, injected 59Fe was found primarily in the bone marrow and spleen. In the transferrin iron-saturated animals, injected 59Fe accumulated in the liver and pancreas. Gastrointestinally absorbed iron in hypotransferrinemic or transferrin iron-saturated mice was deposited in the liver. This indicates that newly absorbed iron is released from mucosal cells not bound to transferrin. Clearance studies demonstrated that transferrin-bound 59Fe was removed from the circulation of rats with a half-time of 50 min. In transferrin iron-saturated animals, injected 59Fe was removed with a half-time of less than 30 s. Analysis of the distribution of 59Fe in serum samples by polyacrylamide gel electrophoresis demonstrated the presence of 59Fe not bound to transferrin. These results demonstrate the existence of and an uptake system for non-transferrin-bound iron. These observations support the hypothesis that parenchymal iron overload is a consequence of reduced concentrations of apotransferrin.     

The role of Hfe in transferrin-bound iron uptake by hepatocytes

HFE-related hereditary hemochromatosis results in hepatic iron overload. Hepatocytes acquire transferrin-bound iron via transferrin receptor (Tfr) 1 and Tfr1-independent pathways (possibly Tfr2-mediated). In this study, the role of Hfe in the regulation of hepatic transferrin-bound iron uptake by these pathways was investigated using Hfe knockout mice. Iron and transferrin uptake by hepatocytes from Hfe knockout, non-iron-loaded and iron-loaded wild-type mice were measured after incubation with 50 nM (125)I-Tf-(59)Fe (Tfr1 pathway) and 5 microM (125)I-Tf-(59)Fe (Tfr1-independent or putative Tfr2 pathway). Tfr1 and Tfr2 messenger RNA (mRNA) and protein expression were measured by real-time polymerase chain reaction and western blotting, respectively. Tfr1-mediated iron and transferrin uptake by Hfe knockout hepatocytes were increased by 40% to 70% compared with iron-loaded wild-type hepatocytes with similar iron levels and Tfr1 expression. Iron and transferrin uptake by the Tfr1-independent pathway was approximately 100-fold greater than by the Tfr1 pathway and was not affected by the absence of Hfe. Diferric transferrin increased hepatocyte Tfr2 protein expression, resulting in a small increase in transferrin but not iron uptake by the Tfr1-independent pathway. Conclusion: Tfr1-mediated iron uptake is regulated by Hfe in hepatocytes. The Tfr1-independent pathway exhibited a much greater capacity for iron uptake than the Tfr1 pathway but it was not regulated by Hfe. Diferric transferrin up-regulated hepatocyte Tfr2 protein expression but not iron uptake, suggesting that Tfr2 may have a limited role in the Tfr1-independent pathway.     

The fate of intravenously injected tissue ferritin in pregnant guinea-pigs

The organ distribution of intravenously injected hepatic ferritin either labelled with 59Fe or with 59Fe and 125I, was studied in pregnant guinea-pigs. At 5 h 71.2% of injected 59Fe was present in the placenta and fetus. Transfer of 59Fe to the fetus was slow, with 11.2% present at 5 h and 38.6% at 21 h. Analysis of a placental cellular lysate for 59Fe and 125I revealed that the injected iron was present as intact ferritin at 2 h but by 21 h the ferritin had been catabolized, the 125I excreted and the 59Fe incorporated into endogenous ferritin. Most of the fetal 59Fe counts were detected in the liver, with 35.3% of the transferred 59Fe in ferritin, 30.4% in haemoglobin and 10.6% in a low molecular weight pool. The uptake of labelled ferritin by the placenta was inhibited by a 300-fold molar excess of unlabelled ferritin but not by albumin, asialofetuin or by the injection of carbon particles. A nonsignificant reduction in uptake was noted after injection of mannosylated bovine serum albumin. The mannosidase inhibitor swainsonine had no effect. Iron transfer to the fetus was not affected by various microtubular inhibitors. Presaturation of endogenous transferrin with oral carbonyl iron prevented iron release from the feto-placental unit back into the maternal circulation. In consequence, marrow 59Fe uptake by the maternal marrow was reduced. The ferrous chelator 2,2'-bipyridine significantly reduced 59Fe transfer to the fetus and this occurred irrespective of whether the chelator was given prior to or after 59Fe ferritin administration. The ferric chelator desferrioxamine had no such effect. Electron microscopy of placental tissues revealed endocytosis of ferritin molecules. These results indicate that the guinea-pig placenta takes up homologous tissue ferritin and transfers the iron slowly to the fetus after reductive mobilization. The process is compatible with a receptor-mediated pathway.     

The effect of chelating agents on iron mobilization in Chang cell cultures.

The investigation of chelating agents with potential therapeutic value in patients with transfusional iron overload has been facilitated by the use of Chang cell cultures. These cells have been incubated with [59Fe]transferrin for 22 hr, following which most of the intracellular radioiron is found in the cytosol, distributed between a ferritin and a nonferritin form. Iron release from the cells depends on transferrin saturation in the medium, but when transferrin is 100% saturated, which normally does not allow iron release, desferrioxamine, 2,3-dihydroxybenzoic acid, rhodotorulic acid, cholythydroxamic acid, and tropolone all promote the mobilization of ferritin iron and its release from cells. They are effective to an approximately equal degree. The incubation of [59Fe]transferrin with tropolone in vitro at a molar ratio of 1:500 results in the transfer of most of the labeled iron to the chelator, reflecting the exceptionally high binding constant of this compound. How far these phenomena relate to therapeutic potentially remains to be seen.     

Iron distribution in Belgrade rat reticulocytes after inhibition of heme synthesis with succinylacetone

We have used succinylacetone (4,6-dioxoheptanoic acid), a specific inhibitor of delta-aminolevulinic acid dehydrase, to gain insight into the defect in iron metabolism in the Belgrade anemia. The Belgrade rat has an inherited microcytic, hypochromic anemia associated with poor iron uptake into developing erythroid cells. Succinylacetone inhibits heme synthesis, leading to nonheme iron accumulation in mitochondria and cytosol of normal reticulocytes. When succinylacetone is used to inhibit Belgrade heme synthesis, iron from diferric transferrin does not accumulate in the stromal fraction that contains mitochondria, nor does 59Fe accumulate in the nonheme cytosolic fraction. Hence, the defect in the Belgrade rat reticulocyte occurs in the endocytic vesicle or in a step subsequent to iron transit from the vesicle but before the nonheme cytosolic or mitochondrial iron fractions. Therefore, the mutation affects either the release of iron from transferrin or iron transport from the vesicle to the mitochondrion.     

Transferrin Glycans

The hepatic uptake of 59Fe from diferric rat and rabbit asialotransferrins and from human transferrin lacking two sialyl residues was investigated in rats in experiments lasting for 1 hr. The 59Fe attached to either of these preparations disappeared from the plasma more rapidly than the 59Fe introduced with the unmodified respective parent proteins. Most of the 59Fe activity that had disappeared from the circulation could be recovered with the liver. Studies with double-labeled (125I, 59Fe) preparations showed that the enhanced 59Fe clearance was not associated with increased catabolism of the modified transferrins. Prolonged, heavy alcohol consumption, as shown by others, results in the appearance of sialic acid-deficient transferrin (two residues missing) in human serum. We suggest that the increased capacity of transferrin deficient in sialic acid to selectively deposit iron in the hepatocyte may be of significance for the development of the hepatic siderosis observed in alcoholism.     

Effect of Chronic Alcohol Feeding on Hepatic Iron Status and Ferritin Uptake by Rat Hepatocytes

Alcohol abuse is known to cause disturbances to iron homeostasis in man and is associated with elevated serum ferritin levels. We have previously shown that ethanol metabolism in the rat hepatocyte is associated with an immediate reduction in ferritin uptake by this cell. In this study we have examined the effect of pair-feeding the Lieber-DeCarli liquid alcohol diet on ferritin uptake by rat hepatocytes. Rat liver ferritin was radiolabeled with ⁵⁹Fe in vivo and isolated by conventional techniques. Rats were pair-fed the Lieber-DeCarli liquid alcoholic diet for 4–6 weeks. Hepatocytes, isolated from their livers by collagenase perfusion, were incubated with [⁵⁹Fe]ferritin in L-15 medium at 37°C and 4° to measure ferritin uptake and binding. The in vitro effect of ethanol on these hepatocytes was also studied. Ferritin and iron parameters were measured in the sera and hepatocytes of these animals and a comparable group of normal chowfed rats. The rate of ferritin uptake by hepatocytes from alcohol-fed rats was significantly faster than that of their pair-fed controls (0.743 ± 0.061 vs. 0.540 ± 0.042 ng/min/10⁶ cells, p < 0.05). However, the rats on Lieber-DeCarli control diet exhibited a lower hepatocyte ferritin uptake rate than chow-fed animals (79.3 ± 8.1% of the control values, p < 0.01). In vitro incubation of cells in 100 mm ethanol resulted in less inhibition of ferritin uptake by hepatocytes from alcoholic rats than from their pair-fed controls (11 ± 7.1% inhibition vs. 43.6 ± 10.7% for controls, p < 0.05). Receptor-mediated binding of ferritin to hepatocytes showed a 61% increase in saturable binding capacity for alcoholic rats (15,820 ± 4950 molecules/cell vs. 9798 ± 3622, p= 0.05). The presence of ethanol in the medium did not affect ferritin binding significantly. Although there was no significant difference in the serum iron values between all three groups, transferrin concentrations were markedly elevated in the alcohol-fed rats, resulting in a much lower transferrin iron saturation than for the control animals. Because the corresponding serum values for the diet controls were intermediate between those for the alcohol-fed rats and the chow-fed animals, these findings may reflect dietary restriction by the liquid diet, which is exacerbated by the addition of alcohol. These findings suggest that there is increased iron uptake by the hepatocyte following chronic alcohol administration, which may be due to the increased ferritin receptors. This is supported by the observation that this alcohol treatment also causes a depletion of serum ferritin. However, the decreased iron content in the alcohol-fed rats indicate that this may be due to a response to changes in iron homeostasis by the hepatocyte and/or redistribution in the body.