Studies on the forms of iron-transferrin released from rabbit reticulocytes

Measurement of the distribution of the four species of transferrin, viz, apotransferrin, diferric transferrin and the two monoferric transferrin, before and after incubation of iron-rich rabbit transferrin with rabbit reticulocytes showed that not all transferrin released from the cells were in the form of apotransferrin. Instead, a mixture of all four species of the protein was released with apotransferrin and C-terminal monoferric transferrin being the major fractions. The buffer solution containing 125I-labelled transferrin showed a continuous gain in percentages in apotransferrin and C-terminal monoferric transferrin after each incubation with reticulocytes. The N-terminal monoferric transferrin, however, remained unchanged suggesting that in the process of transferrin uptake by cells, the diferric transferrin releases its iron from the acid-labile site at N-domain first before the other iron from the acid-stable site.     

The effect of the iron saturation of transferrin on its binding and uptake by rabbit reticulocytes.

Polyacrylamide-gel electrophoresis in urea was used to prepare the four molecular species of transferrin:diferric transferrin, apotransferrin and the two monoferric transferrins with either the C-terminal or the N-terminal metal-binding site occupied. The interaction of these 125I-labelled proteins with rabbit reticulocytes was investigated. At 4 degrees C the average value for the association constant for the binding of transferrin to reticulocytes was found to increase with increasing iron content of the protein. The association constant for apotransferrin binding was 4.6 X 10(6)M-1, for monoferric (C-terminal iron) 2.5 X 10(7)M-1, for monoferric (N-terminal iron) 2.8 X 10(7)M-1 and for diferric transferrin, 1.1 X 10(8)M-1. These differences in the association constants did not affect the processing of the transferrin species by the cells at 37 degrees C. Accessibility of the proteins to extracellular proteinase indicated that the transferrin was internalized by the cells regardless of the iron content of the protein, since in each case 70% was inaccessible. Cycling of the cellular receptors may also occur in the absence of bound transferrin.     

Evidence for the functional equivalence of the iron-binding sites of rat transferrin

The role of the two iron-binding sites of rat transferrin in the exchange of iron with cells has been assessed using urea polyacrylamide gel electrophoresis to separate and quantitate the four possible molecular species of transferrin generated during the incubation of ¹²⁵I-labelled transferrin with rat reticulocytes and hepatocytes. Addition of diferric transferrin to reticulocytes led directly to the appearance of apotransferrin together with small and comparable amounts of the two monoferric transferrins. After 2 h 44.8% of the iron had been removed by the cells, and of the iron-depleted transferrin 71.8% was apotransferrin, the remainder being monoferric transferrin, 16.1% with N-terminal iron and 12.1% with C-terminal iron. A similar pattern emerged with hepatocytes, but the rate of iron removal was slower and the proportion of apotransferrin generated was lower. After 4 h 10.9% of the iron had been removed from the transferrin and the distribution of the iron-depleted protein was: apotransferrin 26.9% and monoferric (N-terminal) 39.2%, (C-terminal) 33.9%. The appearance of apotransferrin during each incubation and the generation of both monoferric transferrins suggest that both cell types are able to remove iron from differic transferrin in pairwise fashion and that they do not appreciably distinguish between the two iron-binding sites of the protein. Release of iron from hepatocytes to apotransferrin lead to the appearance of both monferric species and then to increasing amounts of diferric transferrin. The process of iron release did not seem to distinguish between the vacant iron-binding sites of transferrin.     

Receptor-modulated iron release from transferrin: differential effects on N- and C-terminal sites

Iron release to PPi from N- and C-terminal monoferric transferrins and their complexes with transferrin receptor has been studied at pH 7.4 and 5.6 in 0.05 M HEPES or MES/0.1 M NaCl/0.01 M CHAPS at 25 degrees C. The two sites exhibit kinetic heterogeneity in releasing iron. The N-terminal form is slightly less labile than its C-terminal counterpart at pH 7.4, but much more facile in releasing iron at pH 5.6. At pH 7.4, iron removal by 0.05 M pyrophosphate from each form of monoferric transferrin complexed to the receptor is considerably slower than from the corresponding free monoferric transferrin. However, at pH 5.6, complexation of transferrin to its receptor affects the two forms differently. The rate of iron release to 0.005 M pyrophosphate by the N-terminal species is substantially the same whether transferrin is free or bound to the receptor. In contrast, the C-terminal form releases iron much faster when complexed to the receptor than when free. Urea/PAGE analysis of iron removal from free and receptor-complexed diferric transferrin at pH 5.6 reveals that its C-terminal site is also more labile in the complex, but its N-terminal site is more labile in free diferric transferrin. Thus, the newly discovered role of transferrin receptor in modulating iron release from transferrin predominantly involves the C-terminal site. This observation helps explain the prevalence of circulating N-terminal monoferric transferrin in the human circulation.     

Preferential utilization in vitro of iron bound to diferric transferrin by rabbit reticulocytes.

59Fe uptake by rabbit reticulocytes from human transferrin-bound iron was studied by using transferrin solutions (35, 50, 65, 80 and 100% saturated with iron) whose only common characteristic was their content of diferric transferrin. During the early incubation period, 59Fe uptake from each preparation by reticulocytes was identical despite wide variations in amounts of total transferrin, total iron, monoferric transferrin and apotransferrin in solution. During the later phase of incubation, rate of uptake declined and was proportional to each solution's monoferric transferrin content. Uptake was also studied in a comparative experiment which used two identical, partially saturated transferrin preparations, one uniformly 59Fe-labelled and the other tracer-labelled with [59Fe]diferric transferrin. In both experiments, iron uptake by reticulocytes corresponded to utilization of a ferric ion from diferric transferrin before utilization of iron from monoferric transferrin.     

Amonabactin-mediated iron acquisition from transferrin and lactoferrin by <Emphasis Type="Italic">Aeromonas hydrophila</Emphasis> : direct measurement of individual microscopic rate constants

 The effectiveness and mechanism of iron acquisition from transferrin or lactoferrin by Aeromonas hydrophila has been analyzed with regard to the pathogenesis of this microbe. The ability of A. hydrophila's siderophore, amonabactin, to remove iron from transferrin was evaluated with in vitro competition experiments. The kinetics of iron removal from the three molecular forms of ferric transferrin (diferric, N- and C-terminal monoferric) were investigated by separating each form by urea gel electrophoresis. The first direct determination of individual microscopic rates of iron removal from diferric transferrin is a result. A. hydrophila 495A2 was cultured in an iron-starved defined medium and the growth monitored. Addition of transferrin or lactoferrin promoted bacterial growth. Growth promotion was independent of the level of transferrin or lactoferrin iron saturation (between 30 and 100%), even when the protein was sequestered inside dialysis tubing. Siderophore production was also increased when transferrin or lactoferrin was enclosed in a dialysis tube. Cell yield and growth rate were identical in experiments where transferrin was present inside or outside the dialysis tube, indicating that binding of transferrin was not essential and that the siderophore plays a major role in iron uptake from transferrin. The rate of iron removal from diferric transferrin shows a hyperbolic dependence on amonabactin concentration. Surprisingly, amonabactin cannot remove iron from the more weakly binding N-terminal site of monoferric transferrin, while it is able to remove iron from the more strongly binding C-terminal site of monoferric transferrin. Iron from both sites is removed from diferric transferrin and it is the N-terminal site (which does not release iron in the monoferric protein) that releases iron more rapidly! It is apparent that there is a significant interaction of the two lobes of the protein with regard to the chelator access. Taken together, these results support an amonabactin-dependent mechanism for iron removal by A. hydrophila from transferrin and lactoferrin. The implications of these findings for an amonabactin-dependent mechanism for iron removal by A. hydrophila from transferrin and lactoferrin are discussed. Received: 8 August 1999 / Accepted: 22 October 1999     

Uptake of ferritin and iron bound to ferritin by rat hepatocytes: modulation by apotransferrin, iron chelators and chloroquine

Rat liver ferritin is an effective donor of iron to rat hepatocytes. Uptake of iron from ferritin by the cells is partially inhibited by including apotransferrin in the culture medium, but not by inclusion of diferric transferrin. This inhibition is dependent on the concentration of apotransferrin, with a 30% depression in iron incorporation in the cells detected at apotransferrin concentrations above 40 micrograms/ml. However, apotransferrin does not interfere with uptake of 125I-labeled ferritin, suggesting that apotransferrin decreases retention of iron taken up from ferritin by hepatocytes by sequestering a portion of released iron before it has entered the metabolic pathway of the cells. The iron chelators desferrioxamine (100 microM), citrate (10 mM) and diethylenetriaminepentaacetate (100 microM) reduce iron uptake by the cells by 35, 25 and 8%, respectively. In contrast, 1 mM ascorbate increases iron accumulation by 20%. At a subtoxic concentration of 100 microM, chloroquine depresses ferritin and iron uptake by hepatocytes by more than 50% after 3 h incubation. Chloroquine presumably acts by retarding lysosomal degradation of ferritin and recycling of ferritin receptors.     

Site-specific rate constants for iron acquisition from transferrin by the Aspergillus fumigatus siderophores N′,N′′,N′′′-triacetylfusarinine C and ferricrocin

Aspergillus fumigatus is an opportunistic fungal pathogen that causes life-threatening infections in immunocompromised patients. Despite low levels of free iron, A. fumigatus grows in the presence of human serum in part because it produces high concentrations of siderophores. The most abundant siderophores produced by A. fumigatus are N',N',N'-triacetylfusarinine C (TAF) and ferricrocin, both of which have thermodynamic iron binding constants that theoretically allow them to remove transferrin (Tf)-bound iron. Urea-polyacrylamide gel electrophoresis was used to measure the change in concentration of Tf species incubated with TAF or ferricrocin. The rate of removal of iron from diferric Tf by both siderophores was measured, as were the individual microscopic rates of iron removal from each Tf species (diferric Tf, N-terminal monoferric Tf and C-terminal monoferric Tf). TAF removed iron from all Tf species at a faster rate than ferricrocin. Both siderophores showed a preference for removing C-terminal iron, evidenced by the fact that k(1C) and k(2C) were much larger than k(1N) and k(2N). Cooperativity in iron binding was observed with TAF, as the C-terminal iron was removed by TAF much faster from monoferric than from diferric Tf. With both siderophores, C-terminal monoferric Tf concentrations remained below measurable levels during incubations. This indicates that k(2C) and k(1C) are much larger than k(1N). TAF and ferricrocin both removed Tf-bound iron with second-order rate constants that were comparable to those of the siderophores of several bacterial pathogens, indicating they may play a role in iron uptake in vivo and thereby contribute to the virulence of A. fumigatus.     

The influence of pH on the equilibrium distribution of iron between the metal-binding sites of human transferrin.

The dependence of the metal-binding properties of transferrin on pH in the pH 6--9 range was investigated by urea/polyacrylamide-gel electrophoresis. Equations are presented for calculating the relative values of the four conditional site constants for the stepwise binding of iron to the two sites of transferrin and for calculating the equilibrium distribution of the protein among the four principal forms, apotransferrin, the C-terminal and N-terminal monoferric transferrins and diferric transferrin. The relative affinity of iron for the two sites and the co-operativity of iron-binding follow characteristic "pH titration' curves. A mathematical model that can account for the former behaviour is presented. In both cases the metal-binding sites are affected by the ionization of functional groups with apparent pKa values near physiological pH approx. 7.4. There is strong positive co-operatively in the release of protons from these groups. The results indicate that pH must be accurately controlled in studies of the differential properties of the two sites of the transferrin molecule.     

The interaction of transferin with isolated hepatocytes

Freshly isolated rat heptocytes display about 36 700 high-affinity sites to which deferric transferrin may bind with an apparent association constant of 1.62·10⁷ 1·mol^?1.Uptake of iron from diferric transferrin by hepatocytes is linear with time and is accelerated at increased differric transferrin concentrations.Apotransferrin is able to decrease net iron uptake by hepatocytes from diferric transferrin by a process not dependent on the apotransferrin concentrations used or on the rate at which the cells take up iron. Immunoprecipitation of the apotransferrin during these incubations indicates that iron is being released from the cells to apotransferrin at the same time as iron is being taken up from diferric transferrin. The simultaneous uptake and release of iron, and the insensitivity to apotransferrin concentration, suggest that the processes of iron uptake and release occur via separate mechanisms. The effect of apotransferrin on net retention of iron may be one way in which the in vivo distribution of iron between sites of storage and utilization is controlled.     

Characterization of transferrin binding and specificity of the placental transferrin receptor

This study systematically examined the characteristics of specific binding of adult diferric transferrin to its receptor using a Triton X-100 solubilized preparation from human placentas as the receptor source. The following information was obtained. The ionic strength for maximal binding is in the range of 0.1-0.3 M NaCl. The pH optimum for specific binding extends over the range, from pH 6.0-10.0. Specific binding of diferric transferrin is not affected by 2.5 approximately 50 mM CaCl2 or by 10 mM EDTA. Triton X-100 in the concentration range of 0.02-3.0% does not affect specific binding. Specific binding is saturated within 10 min at 25 or 37 degrees C in the presence of excess amounts of diferric transferrin. The binding is reversible and the dissociation of diferric transferrin from the transferrin receptor is complete within 40 min at 25 degrees C. Apotransferrin, both adult and fetal, showed less binding than the holotransferrin species by competitive binding assay in the presence of 10 mM EDTA independent of up to 20 mM CaCl2. A 1500-fold molar excess of adult and fetal apotransferrin is required to give 40% inhibition for 125I-labeled diferric transferrin binding. Since calcium ion is not a factor, and since apotransferrin has such high binding affinity for iron (Ka = 1 X 10(24], this experiment suggests that the EDTA was necessary to prevent conversion of apotransferrin to holotransferrin from available iron in the reaction system. The specificity of the transferrin receptor for transferrin was examined by competitive binding studies in which 125I-diferric transferrin binding was measured in the presence of a series of other proteins. The proteins tested in the competitive binding studies were classified into three groups; in the first group were human serum albumin and ovalbumin; in the second group were proteins containing iron ions, such as hemoglobin, hemoglobin-haptoglobin complex, heme-hemopexin complex, ferritin, and diferric lactoferrin; in the third group were the metal-binding serum proteins, ceruloplasmin and metallothionein. None of these proteins except ferritin showed inhibition of diferric transferrin binding to the receptor. The effect of ferritin was small since a 700- to 1500-fold molar excess of ferritin is required for 50% inhibition of binding of diferric transferrin to the receptor.     

Terephthalamide-containing ligands: fast removal of iron from transferrin

The mechanism and effectiveness of iron removal from transferrin by three series of new potential therapeutic iron sequestering agents have been analyzed with regard to the structures of the chelators. All compounds are hexadentate ligands composed of a systematically varied combination of methyl-3,2-hydroxypyridinone (Me-3,2-HOPO) and 2,3-dihydroxyterephthalamide (TAM) binding units linked to a polyamine scaffold through amide linkers; each series is based on a specific backbone: tris(2-aminoethyl)amine, spermidine, or 5-LIO(TAM), where 5-LIO is 2-(2-aminoethoxy)ethylamine. Rates of iron removal from transferrin were determined spectrophotometrically for the ten ligands, which all efficiently acquire ferric ion from diferric transferrin with a hyperbolic dependence on ligand concentration (saturation kinetics). The effect of the two iron-binding subunits Me-3,2-HOPO and TAM and of the scaffold structures on iron removal ability is discussed. At the low concentrations corresponding to therapeutic dose, TAM-containing ligands exhibit the fastest rates of iron removal, which correlates with their high affinity for ferric ion and suggests the insertion of such binding units into future therapeutic chelating agents. In addition, urea polyacrylamide gel electrophoresis was used to measure the individual microscopic rates of iron removal from the three iron-bound transferrin species (diferric transferrin, N-terminal monoferric transferrin, C-terminal monoferric transferrin) by the representative chelators 5-LIO(Me-3,2-HOPO)(2)(TAM) and 5-LIO(TAMmeg)(2)(TAM), where TAMmeg is 2,3-dihydroxy-1-(methoxyethylcarbamoyl)terephthalamide. Both ligands show preferential removal from the C-terminal site of the iron-binding protein. However, cooperative effects between the two binding sites differ with the chelator. Replacement of hydroxypyridinone moieties by terephthalamide groups renders the N-terminal site more accessible to the ligand and may represent an advantage for iron chelation therapy.     

The kinetics of transferrin endocytosis and iron uptake from transferrin in rabbit reticulocytes

The endocytosis of diferric transferrin and accumulation of its iron by freshly isolated rabbit reticulocytes was studied using 59Fe-125I-transferrin. Internalized transferrin was distinguished from surface-bound transferrin by its resistance to release during treatment with Pronase at 4 degrees C. Endocytosis of diferric transferrin occurs at the same rate as exocytosis of apotransferrin, the rate constants being 0.08 min-1 at 22 degrees C, 0.19 min-1 at 30 degrees C, and 0.45 min-1 at 37 degrees C. At 37 degrees C, the maximum rate of transferrin endocytosis by reticulocytes is approximately 500 molecules/cell/s. The recycling time for transferrin bound to its receptor is about 3 min at this temperature. Neither transferrin nor its receptor is degraded during the intracellular passage. When a steady state has been reached between endocytosis and exocytosis of the ligand, about 90% of the total cell-bound transferrin is internal. Endocytosis of transferrin was found to be negligible below 10 degrees C. From 10 to 39 degrees C, the effect of temperature on the rate of endocytosis is biphasic, the rate increasing sharply above 26 degrees C. Over the temperature range 12-26 degrees C, the apparent activation energy for transferrin endocytosis is 33.0 +/- 2.7 kcal/mol, whereas from 26-39 degrees C the activation energy is considerably lower, at 12.3 +/- 1.6 kcal/mol. Reticulocytes accumulate iron atoms from diferric transferrin at twice the rate at which transferrin molecules are internalized, implying that iron enters the cell while still bound to transferrin. The activation energies for iron accumulation from transferrin are similar to those of endocytosis of transferrin. This study provides further evidence that transferrin-iron enters the cell by receptor-mediated endocytosis and that iron release occurs within the cell.     

Effects of spermine on transferrin and iron uptake by reticulocytes: II. Changes in intravesicular pH

An increase in extracellular spermine concentration brought about a progressive rise in intralysosomal pH in rabbit reticulocytes. Since intracellular release of iron from transferrin is believed to involve the protonation of the iron-transferrin complex, the rise in intralysomal pH could account for the inhibitory effect of spermine on iron uptake. The inhibition could be reversed if spermine was removed by washing. As a result of spermine treatment, more acid-labile N-terminal monoferric transferrin and less apotransferrin were released from the cell. These results are consistant with the protonation theory of iron release.     

The effect of iron binding on the conformation of transferrin. A small angle x-ray scattering study.

Distance distribution functions, p(r), radii of gyration, Rg, and radii of gyration of cross section, Rq, of apotransferrin, monoferric transferrin, and diferric transferrin have been compared. The alteration of Rg and Rq upon iron binding has been determined by a difference method. An unusual feature of the stepwise structural changes of transferrin upon iron saturation is that binding of the first ferric ion is responsible for more than half of the whole change in Rq, whereas Rg alters significantly only after the binding of the second ferric ion.     

Regulation of HeLa cell transferrin receptors

HeLa cells were found to have a single class of non-interacting receptors specific for transferrin. Both apotransferrin and diferric transferrin competed equally with 125I-diferric transferrin for receptor binding. Transferrin binding was temperature-dependent and reversible. Binding of transferrin to cells exhibited a KD of 27 nM with a maximum binding capacity of 1.8-3.7 x 10(6) molecules/cell. Cells grown in the presence of diferric transferrin or in the presence of ferric ammonium citrate exhibited a concentration- and time-dependent decrease in 125I-diferric transferrin binding. The decrease in binding activity reflected a reduction in receptor number rather than an alteration in ligand receptor affinity. Growth of cells in saturating concentrations of apotransferrin did not cause a decrease in receptor number. When iron-treated cells were removed to media free of ferric ammonium citrate, the receptor number returned to control values by 40 h. When receptors were removed with trypsin, cells grown and maintained in ferric ammonium citrate-supplemented media demonstrated a rate of receptor reappearance 47% that of control cells grown in ferric ammonium citrate-free media. Cells grown in media supplemented with diferric transferrin or ferric ammonium citrate exhibited an increase in cytosolic iron content. The transferrin receptor number returned to normal after cells were removed to unsupplemented media, despite persistent elevation of cytosolic iron content. Increased iron content did not appear to be the sole factor determining receptor number.     

Binding of phosphonate chelating agents and pyrophosphate to apotransferrin.

Difference ultraviolet spectroscopy has been used to monitor the binding of a series of phosphonate ligands to human apotransferrin. The ligands consist of pyrophosphate as well as the phosphonic acids (aminomethyl)phosphonic acid (AMPA), (hydroxymethyl)phosphonic acid (HMP), (phosphonomethyl)-iminodiacetic acid (PIDA), N,N-bis(phosphonomethyl)glycine (DPG), and nitrilotris(methylenephosphonic acid) (NTP). Equilibrium constants have been measured for the sequential binding of two ligands per molecule of apotransferrin. In addition, site-specific equilibrium constants have been measured for the binding of AMPA, HMP, and PIDA to the vacant binding site of both forms of monoferric transferrin. Since titrations of diferric transferrin produce no difference UV spectrum, it is proposed that the primary binding site for phosphonic acids includes the protein groups that bind the synergistic bicarbonate anion that is required for formation of a stable ferric transferrin complex. It is further proposed that those ligands with two phosphonate groups can simultaneously bind to cationic amino acid side chains that extend into the cleft between the two domains of each lobe of transferrin. From an inspection of the ferric transferrin crystal structure, the most likely anion binding residues in the cleft are Arg-632 and Lys-534 in the C-terminal lobe and Lys-206 and Lys-296 in the N-terminal lobe.     

Release of iron from transferrin by phosphonocarboxylate and diphosphonate chelating agents

The rates at which phosphonocarboxylate and diphosphonate ligands remove iron from the serum iron transport protein transferrin at 25 degrees C and pH 7.4 have been evaluated. These ligands show a combination of saturation and first-order kinetics with respect to the free ligand concentrations. The ability of the ligands to remove iron from transferrin appears to be subject to steric restrictions that are essentially identical to those associated with the ability of a ligand to substitute for the synergistic carbonate anion. This observation supports the hypothesis that the first-order component for iron removal involves a mechanism in which the rate-limiting step is the slow substitution of the synergistic carbonate by the incoming chelating agent. Studies on monoferric transferrins indicate that phosphonocarboxylates are unusually effective at removing iron from the C-terminal site of the protein. Difference UV spectroscopy has been used to show that the phosphonocarboxylates bind strongly to apotransferrin. It is suggested that the rapid release of iron from the C-terminal site may be due to the binding of the ligand to an allosteric anion-binding site in the C-terminal lobe of the protein.     

Failure to release iron from transferrin in a Chinese hamster ovary cell mutant pleiotropically defective in endocytosis

A Chinese hamster ovary cell mutant defective in the receptor-mediated endocytosis of several unrelated ligands (Robbins, A. R., S. S. Peng, and J. L. Marshall, 1983, J. Cell Biol., 96:1064-1071) failed to accumulate iron provided in the form of diferric transferrin. Analysis of the steps of the transferrin cycle indicated that binding and internalization of transferrin proceeded normally in mutant cells. However, the mutant appeared unable to dissociate iron from transferrin, as evidenced by release of diferric transferrin from the mutant versus apotransferrin from the parent. Uptake of ferric ions from the growth medium was enhanced in the mutant.