Uptake and release of iron from human transferrin.

Purified fractions of human apotransferrin, monoferric transferrins with iron on the acid-labile binding site and on the acid-stable binding site, and diferric transferrin have been prepared. The iron loading and unloading behavior of these preparations has been examined by isoelectric focusing. Iron release from the two monoferric transferrin preparations to human reticulocytes was of similar magnitude. In a mixture containing equal amounts of diferic and monoferric iron, approximately 4 times the amount of iron delivered by the monoferric species was delivered by the diferric species. Iron loading of transferrin in vitro showed a random distribution between monoferric and diferric transferrin. Among the monoferric transferrins, loading of the acid-labile binding sites was greater than that of the acid-stable binding sites. In vivo iron distribution in normal subjects, as evaluated by in vitro-added 50Fe, gave similar results. Absorption of a large dose of orally administered iron in iron-deficient subjects resulted in a somewhat greater amount of diferric transferrin at low saturation and a somewhat smaller amount of diferric transferrin at higher saturations than would have been anticipated by random loading. These data would indicate that in the human, iron loading of transferrin may be considered essentially random. Unloading from the two monoferric transferrin species is of similar magnitude but far less than that delivered by diferric transferrin.     

Interaction of human diferric transferrin with reticulocytes.

Methods have been devised for preparing human transferrin with a different isotope of iron selectively labeling each of the two iron binding sites and for determining the distribution of radioiron among transferrin molecules. When diferric human transferrin was exposed to human or animal reticulocytes, there was an equal contribution of radioiron from the acid-stable and acid-labile sites. In this delivery, both atoms of iron were removed simultaneously from the diferric transferrin molecule, converting it to apotransferrin. At similar iron concentrations the amount of iron delivered by diferric transferrin was twice that delivered by monoferric transferrin.     

The behavior of transferrin iron in the rat

The behavior of rat transferrin has been investigated employing acrylamide gel electrophoresis and isoelectric focusing. In vitro trace labeling with iron chelates at 30 min was 93%-98% effective, whereas binding by simple ferric salts was reduced to 71%-76%. Complete and specific binding of 59FeSO4 by the iron binding sites of transferrin was demonstrated after in vitro or in vivo addition of ferrous ammonium sulfate in pH 2 saline up to the point of iron saturation. In vitro the radioriron transferrin complex in plasma was stable and its iron had a negligible exchange with other transferrin binding sites over several hours. The distribution of radioiron added in vitro or through absorption was shown to be random between the binding sites of slow and fast transferrin molecule. Iron distribution among body tissues was similar for mono- and diferric transferrin iron and was not affected by the site distribution of iron on the transferrin molecule. The only important aspect of transferrin iron binding was the more rapid tissue uptake of iron in the diferric form was compared to monoferric transferrin. Additional in vivo effects on internal iron exchange were produced by changes in the iron balance of the animal. In the iron loaded animal, monoferric transferrin injected into the plasma was rapidly loaded by iron from tissue and thereby converted to diferric transferrin. Injection of diferric transferrin in the iron deficient animal was associated with a rapid disappearance from circulation of the original complex and a subsequent appearance of monoferric transferrin as a result of iron returning from tissues. These observations support the concept that plasma iron behaves as a single pool except that diferric iron exchange occurs at a more rapid rate than dose monoferric iron exchange.     

Evidcnce for the Functional Heterogeneity of the Two Sites of Transferrin in Vitro

A recently developed crossed immunoelectrophoretic method for displaying and quantitating the four possible molecular species of transferrin has been utilized to assess the relative effectiveness of each site of rabbit and human diferric transferrin in providing iron to rabbit reticulocytes. The site which appears to reside in the N-terminal half of the rabbit protein was found to be at least 5 times more effective than its counterpart. However, both sites may serve as iron donors in monoferric as well as diferric rabbit transferrins. It is also possible that iron may be removed from rabbit transferrin in pairwise as well as sequential fashion. In human diferric transferrin, the site in the C-terminal domain functions as the better iron donor for rabbit reticulocytes.     

Plasma radioiron kinetics in man: explanation for the effect of plasma iron concentration.

The plasma iron turnover was measured in 19 normal subjects. A correlation was found between plasma iron concentration and plasma iron turnover. In addition to the turnover of 55Fe at normal plasma iron concentration (predominantly monoferric transferrin), a second turnover in which the labeled plasma was saturated with iron (to produce predominantly diferric transferrin) was studied with 50Fe. It was demonstrated that diferric transferrin had a greater rate of iron turnover but that the distribution between erythroid and non-erythroid tissues was unchanged. It was concluded that plasma iron turnover is dependent on the monoferric/diferric transferrin ratio in the plasma but that the internal distribution of iron is unaffected.     

Functional heterogeneity of transferrin-bound iron: iron uptake by cell suspensions from bone marrow and liver and by cell cultures of fibroblasts and lymphoblasts.

According to the hypothesis of Fletcher and Huehns, functional differences exist between both iron-binding sites of transferrin. The site designated A should mainly be involved in the delivery of iron to erythroid cells, whereas site B should donate its iron preferentially to cells involved in the absorption and storage of iron. In the present study this hypothesis could be confirmed by in vitro experiments with various cell types. Iron transferrin preincubated with rat bone marrow cells donates less iron to rat bone marrow cells, Chinese hamster fibroblasts, human fibroblasts and human lymphoblasts than freshly prepared iron transferrin equal in iron and transferrin concentraion. Rat liver parenchymal cells, however, take up more iron from preincubated than from freshly prepared iron transferrin. Obviously, site A not only donates iron preferentially to erythroid cells but also to (rapidly) dividing nonerythroid cells in culture. From experiments with iron transferrin mixtures in which radioiron was present at low or high iron saturation, it could be concluded that rat bone marrow cells take up iron equally well from monoferric as from diferric transferrin. The observed functional heterogeneity could, therefore, not be ascribed to differences between monoferric and diferric transferrin.     

Molecular ferrokinetics in the rabbit

S ummary . Using urea-polyacrylamide gel electrophoresis it has been possible to distinguish the molecular forms of transferrin in rabbit serum. When ⁵⁹Fe-labelled diferric transferrin is injected into normal, anaemic or hypertransfused, polycythaemic rabbits, iron is removed from diferric transferrin in essentially pairwise fashion. Exchange of iron between transferrin and tissues was also studied using predominantly monoferric transferrin labelled with ⁵⁹Fe or ¹²⁵I, and with ¹²⁵I-labelled apotransferrin. The return of iron from tissue stores to circulating transferrin occurs one atom at a time to either site of the protein and, possibly, in pairwise fashion as well. The rate of clearance of iron from diferric transferrin differs from that of monoferric transferrins, and the rates at which iron is returned to empty sites of transferrin also differ, so that serum iron is not a kinetically homogeneous pool in the rabbit.     

Transferrin saturation, plasma iron turnover, and transferrin uptake in normal humans

The relationship between plasma iron, transferrin saturation, and plasma iron turnover was studied in 53 normal subjects whose transferrin saturation varied between 17% and 57%, in 25 normal subjects whose transferrin saturation was increased by iron infusion to between 67% and 100%, and in five subjects with early untreated idiopathic hemochromatosis whose transferrin saturation was continually elevated to between 61% and 86%. The plasma iron turnover of all of these subjects ranged from 0.45 to 1.22 mg/dL whole blood/d. The mean values for the above-mentioned three groups were 0.71 +/- 0.17, 1.01 +/- 0.11, and 1.01 +/- 0.13 mg/dL whole blood/d, respectively. Most of this variation, estimated at 72% by regression analysis, was due to a direct relationship between transferrin saturation and plasma iron turnover. This effect was attributed to a competitive advantage of diferric over monoferric transferrin in delivering iron to tissues. This was confirmed by the demonstration of a more rapid clearance of diferric as compared to monoferric transferrin in an additional group of eight normal subjects. Calculations were made of the amount of transferrin reacting with membrane receptors per unit time. Allowance was made for the noncellular (extravascular) exchange and for the 4.2:1 preference of diferric over monoferric transferrin demonstrated in vitro. The amount of iron-bearing transferrin leaving the plasma to bind to tissue receptors for 53 subjects with a transferrin saturation between 17% and 57% was 71 +/- 13; for 25 subjects with a saturation from 67% to 100%, 72 +/- 12; and for five subjects with early idiopathic hemochromatosis, 82 +/- 11 mumol/L whole blood/d. There were no significant differences among these groups. These studies indicate that while the number of iron atoms delivered to the tissues increases with increasing plasma iron and transferrin saturation, the number of iron-bearing transferrin molecules that leave the plasma per unit time to bind to tissue receptors is relatively constant and within the limits studied, independent of transferrin saturation.     

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.     

A reversible defect of platelet PDGF content in myeloproliferative disorders

The transport of iron through erythroid cell membrane was studied in a model system, measuring ferrous iron uptake by reticulocytes. It was found that these cells were able to take up ferrous iron and to incorporate it into haem at a rate similar to that observed when diferric transferrin was the iron donor. No comparable iron uptake could be measured when the metal was provided as Fe3+-citrate or when reticulocytes were replaced by mature erythrocytes. The involvement of endogenous transferrin in the Fe2+ uptake by reticulocytes could be excluded, since proteolytic treatment of the cells had no significant effect on the process. Fe2+ uptake by reticulocytes followed saturation kinetics, characteristic to carrier mediated transport processes. Kinetic analysis of the data revealed the following apparent transport parameters: Km = 8.8 +/- 3.8 microM; Vmax = 1.1 +/- 0.2 ng/10(8) reticulocytes/min. These results indicate that a high affinity, carrier mediated iron transport system is present in the reticulocyte membrane, ensuring the efficient translocation of the metal through the membrane barrier between the site of its release from transferrin and the site of its utilization.     

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.     

Distribution of iron between the binding sites of transferrin in serum: methods and results in normal human subjects.

When it is incompletely saturated with iron, transferrin may exist in four molecular forms: apotransferrin, monoferric (A) transferrin (with iron occupying only the A site of the protein), monoferric (B) transferrin, and diferric transferrin. By combining electrophoresis in urea-polyacrylamide gels with crossed immunoelectrophoresis using specific antihuman transferin antiserum, it is possible to display and estimate the concentration of each of these four forms in normal human serum. The distribution of iron between the binding sites of transferrin is neither random nor determined by the relative binding strengths of transferrin's two sites. Rather, the more weakly binding and acid-labile B site of the protein is predominantly occupied.     

Transferrin-reticulocyte cycle time in rat reticulocytes

Summary The uptake and release of¹³¹I-labelled diferric transferrin by rat reticulocytes was examined both in vitro and in vivo. Cycle time in vitro was estimated to be 2.5 min in iron-deficient reticulocytes and 2.3 min in phenylhydrazine-produced reticulocytes. In vivo reticulocyte uptake and release of labelled diferric transferrin injected in the iron-deficient rat averaged 1.7 min.     

Iron uptake by human reticulocytes at physiologic and sub-physiologic concentrations of iron transferrin: the effect of interaction with aluminum transferrin

We have studied the interaction, in vitro, between diferric transferrin (FeTr), aluminum transferrin (AlTr), and human reticulocytes harvested from human placental blood. In particular, we aimed to determine the extent to which the kinetics of AlTr and FeTr differed. Using transferrin labeled with either 59Fe or 125I, the association of radiotracer with reticulocytes, as a function both of time and of transferrin concentration, was examined. Under the conditions of the experiments, the data are consistent with a mechanism involving at least three processes. Two early processes acting in parallel behave as a high-affinity saturable receptor and a low-affinity non-saturable receptor, neither of which distinguish between AlTr and FeTr. In a subsequent process, AlTr and FeTr exhibit different kinetics. This third process may be saturated by FeTr but not by AlTr. Interpreted in terms of a current conventional view of metallo-transferrin uptake, we conjecture that the early parallel processes involve cell surface phenomena including classical transferrin-receptor binding, and that the subsequent process represents events, possibly intracellular, involved in metallo-transferrin dissociation or further iron transport. The extent to which AlTr influences the interaction of FeTr with reticulocytes offers insight into both the normal physiology of iron uptake and the potential for toxicity by aluminum.     

Nontransferrin-bound iron uptake by hepatocytes is increased in the Hfe knockout mouse model of hereditary hemochromatosis

Hereditary hemochromatosis (HH) is an iron-overload disorder caused by a C282Y mutation in the HFE gene. In HH, plasma nontransferrin-bound iron (NTBI) levels are increased and NTBI is bound mainly by citrate. The aim of this study was to examine the importance of NTBI in the pathogenesis of hepatic iron loading in Hfe knockout mice. Plasma NTBI levels were increased 2.5-fold in Hfe knockout mice compared with control mice. Total ferric citrate uptake by hepatocytes isolated from Hfe knockout mice (34.1 +/- 2.8 pmol Fe/mg protein/min) increased by 2-fold compared with control mice (17.8 +/- 2.7 pmol Fe/mg protein/min; P <.001; mean +/- SEM; n = 7). Ferrous ion chelators, bathophenanthroline disulfonate, and 2',2-bipyridine inhibited ferric citrate uptake by hepatocytes from both mouse types. Divalent metal ions inhibited ferric citrate uptake by hepatocytes, as did diferric transferrin. Divalent metal transporter 1 (DMT1) mRNA and protein expression was increased approximately 2-fold by hepatocytes from Hfe knockout mice. We conclude that NTBI uptake by hepatocytes from Hfe knockout mice contributed to hepatic iron loading. Ferric ion was reduced to ferrous ion and taken up by hepatocytes by a pathway shared with diferric transferrin. Inhibition of uptake by divalent metals and up-regulation of DMT1 expression suggested that NTBI uptake was mediated by DMT1.     

In vitro and in vivo studies of iron delivery by human monoferric transferrins

S ummary . According to the Fletcher-Huehns hypothesis there exists a functional difference between the two iron-binding sites of transferrin. In this study we present the results of an evaluation of this hypothesis in vitro and in vivo with human pure monoferric transferrins obtained by preparative isoelectric focusing in granulated gels. The uptake of iron from monoferric transferrins TfFe_c and Fe_NTf by erythroid bone marrow cells, hepatocytes and stimulated T-lymphocytes in vitro was equal, even when both monoferric transferrins were present together in the incubation medium. Ferrokinetic studies in vivo , performed with both pure monoferric transferrins, showed that transferrin TfFe_c, as well as transferrin Fe_NTf, mainly deliver their iron to the erythron. As red cell ⁵⁹Fe utilization, red cell iron turnover and other ferrokinetic parameters, obtained from this study, were identical too it is evident that both iron-binding sites of transferrin are functionally homogeneous in vivo , with respect to iron delivery.     

Transferrin: physiologic behavior and clinical implications

The transferrin iron transport system, along with its procurement sites and delivery receptors, provides a highly effective means of satisfying internal iron requirements. Iron uptake by individual tissues is determined by their receptor number, by the relative amounts of monoferric and diferric transferrin in circulation, and by the amount of available iron in donor tissues. Although the modus operandi of this system under basal conditions has been characterized, its exquisite regulation remains an enigma. In some manner, the procurement of iron is determined by iron requirements. What seems to be an inappropriate behavior of the absorptive mechanism in thalassemia and certain other erythroid overload states may actually be life-saving in the absence of transfusion, since it results in higher levels of plasma iron and thereby higher levels of erythropoiesis. The definition of the regulatory mechanism in such conditions may well lead to an understanding of the molecular defect in idiopathic hemochromatosis.     

Iron Uptake by Rabbit Reticulocytes

S ummary . In keeping with present concepts of internal iron exchange, it is thought that the two iron binding sites of transferrin molecules bind and donate iron in a similar manner. Since recent data, however, have suggested that iron attached at one iron binding site may be more readily available to cells than iron bound to the other site, a further study of in vitro iron exchange between transferrin and reticulocytes has been undertaken.
Transferrin samples were first incubated with reticulocytes to reduce the transferrin iron saturation; rates of iron uptake from incubated transferrin samples and appropriate non-incubated controls with the same iron saturation were then compared. At 24% transferrin iron saturation, iron uptake from incubated transferrin was significantly less than from the control; at 48% transferrin iron saturation, iron uptake was the same from incubated transferrin and controls.
Two transferrin samples of equal protein concentration were prepared; each was 50% iron saturated. One sample contained twice the proportion of iron saturated transferrin molecules (2Fe-transferrin) present in the other sample. Iron uptake by reticulocytes was decreased by 22–25% from the sample with less 2Fe-transferrin molecules. Thus iron was exchanged very rapidly between 2Fe-transferrin and reticulocytes.
It is proposed that the preliminary incubation of transferrin samples with reticulocytes caused a marked reduction in their 2Fe-transferrin molecules which, at low levels of transferrin iron saturation, resulted in the incubated samples containing less 2Fe-transferrin than the controls. In these circumstances, iron uptake from incubated transferrin was decreased when compared with the control.     

Biologic and clinical significance of red cell ferritin

Red cell ferritin was measured in normal subjects and patients with disorders of iron metabolism, inflammation, liver dysfunction, impaired hemoglobin synthesis, and increased red cell turnover by means of radioimmunoassays with antibodies to liver (basic) and heart (acidic) ferritins. The normal mean values for basic and acidic ferritin were 8.9 and 22.7 altogram (ag)/cell, respectively. The red cell ferritin content reflected changes occurring in tissues both in iron deficiency and iron overload. Basic ferritin was more closely related to the body iron status than acidic ferritin, and the acidic/basic ferritin ratio was increased in iron deficiency and decreased in iron overload. The major factor determining the red cell ferritin content appeared to be the transferrin saturation, that is, the distribution of iron between monoferric and diferric transferrin. This is in keeping with recent data indicating a competitive advantage of diferric transferrin in delivering iron to erythroid cells. In addition, the red cell ferritin content was increased in thalassemic patients with normal iron status, appearing to be inversely related to the rate of hemoglobin synthesis. The determination of red cell ferritin, based on a commercially available basic ferritin assay, can have clinical application. It can be used for evaluating the adequacy of the iron supply to the erythroid marrow, particularly in patients with increased red cell turnover. Moreover, it may be useful in evaluating the body iron status in patients with hemochromatosis and liver disease.     

Occupancy of the iron binding sites of human transferrin.

The in vivo distribution of iron between the binding sites of transferrin was examined. Plasma was obtained from normal subjects under basal conditions and after in vitro and in vivo iron loading. Independent methods, including measurement of the transferrin profile after isoelectric focusing and cross immunoelectrophoresis, and determination of the iron content in the separated fractions were in agreement that there was a random distribution of iron on binding sites. This held true with in vitro loading, when iron was increased by intestinal absorption and with loading from the reticuloendothelial system. The data indicate that the distribution of apo-, monoferric, and diferric transferrins is predictable on the basis of the plasma transferrin saturation and negate the concept that iron loading of transferrin in vitro is a selective process with possible functional consequences in tissue iron delivery.