Erica Baker

The uptake of iron and transferrin by the human malignant melanoma cell

The role of the transferrin homologue, melanotransferrin (p97), in iron metabolism has been studied using the human melanoma cell line, SK-MEL-28, which expresses this antigen in high concentrations. The mechanisms of iron and transferrin uptake were investigated using human transferrin labelled with iodine-125 and iron-59. Internalised and membrane-bound iron and transferrin were separated using the proteinase, pronase. The uptake of iron from transferrin occurred by at least two processes. The first process was saturable and consistent with receptor-mediated endocytosis, involving internalisation of transferrin bound to specific binding sites. Uptake of iron also occurred by a second process which was non-saturable up to 0.06 mg/ml (0.75 microM) and was of higher efficiency than the saturable process. This process of iron uptake may be the dominant one at physiological serum transferrin concentrations. A membrane-bound, pronase-sensitive, temperature-dependent, iron-binding component was also identified. The number of binding sites was estimated to be approx. 340,000 per cell (assuming 2 atoms of iron per site) and it is suggested that this binding component may be melanotransferrin.

Transferrin receptor 2: a new molecule in iron metabolism

Transferrin receptor 1 (TfR1) which mediates uptake of transferrin-bound iron, is essential for life in mammals. Recently, a close homologue of human transferrin receptor 1 was cloned and called transferrin receptor 2 (TfR2). A similar molecule has been identified in the mouse. Human transferrin receptor 2 is 45% identical with transferrin receptor 1 in the extracellular domain, but contains no iron responsive element in its mRNA and is apparently not regulated by intracellular iron concentration nor by interaction with HFE. Transferrin receptor 2, like transferrin receptor 1, binds transferrin in a pH-dependent manner (but with 25 times lower affinity) and delivers iron to cells. However, transferrin receptor 2 distribution differs from transferrin receptor 1, increasing in differentiating hepatocytes and decreasing in differentiating erythroblasts. Expression of both receptors is cell cycle dependent. Mutations in the human transferrin receptor 2 gene cause iron overload disease, suggesting it has a role in iron homeostasis.

The effect of metabolic inhibitors on transferrin and iron uptake and transferrin release from reticulocytes

Abstract Metabolic inhibitors were broadly classified into three groups on the basis of their effect on the uptake of [ 125 I]transferrin and 59 Fe and the release of [ 125 I]transferrin by rabbit reticulocytes in vitro : 1. 1. Inhibitors which had no effect on transferrin or iron uptake (sodium malonate and ouabain). 2. 2. Those which blocked iron uptake more than transferrin uptake (retonone, 2,4-dinitrophenol, oligomycin, NaCN, NaN 3 , NaF and cycloheximide). The effect of these compounds was attributed to inhibition of the mitochondrial electron transfer chain. 3. 3. Those which inhibited iron and transferrin uptake to approximately the same degree (sodium arsenite, iodoacetamide, N -ethylmaleimide, p -chloromercuribenzoate (PCMB), p -chloromercuribenzenesulfonate (PCMBS) and lead acetate). The onset of inhibition by all the inhibitors studied was immediate, but the effects of iodoacetamide, N -ethylmaleimide, PCMB and PCMBS were largely prevented by prior addition of cysteine in 1–4 times the molar concentration of inhibitor. Sodium arsenite, iodoacetamide and N -ethylmaleimide also inhbited transferrin release. These compounds (all sulfhydryl reagents) may act by altering reticulocyte membrane structure, reducing transferrin and hence iron uptake.

Characterisation of non-transferrin-bound iron (ferric citrate) uptake by rat hepatocytes in culture

Under conditions of iron overload plasma transferrin can be fully saturated and the plasma can transport non-transferrin-bound Fe which is rapidly cleared by the liver. Much of this Fe is complexed by citrate. The aim of the present work was to characterise the mechanisms by which Fe-citrate is taken up by hepatocytes using a rat hepatocyte cell culture model. The cells, after one day in culture, were incubated with 59Fe-labelled Fe-citrate for varying time periods, then washed and Fe uptake to the membrane and intracellular compartments of the cell was determined by radioactivity measurements. Maximal rates of internalisation of Fe occurred at a Fe:citrate molar ratio of 1:100 or greater, a pH of approximately 7.4 and an extracellular Ca2+ concentration of 1.0 mM. Fe uptake showed Michaelis-Menten kinetics and was a temperature-dependent process. The K(m) and Vmax for Fe internalisation by the cells at 37 degrees C were approximately 7 microM and 2 nmol/mg DNA/min (25 x 10(6) atoms/cell/min), respectively; and the Arrhenius activation energy was 35 kJ/mol. The transition metals, Zn2+, Co2+ and Ni2+, inhibited Fe uptake when used at 10 and 100 times the concentration of Fe. The rate of Fe internalisation from Fe-citrate was found to be approximately 20 times as great as that from Fe-transferrin with Fe concentrations of 1 and 2.5 microM for both forms of Fe. The rate of Fe uptake by iron-loaded hepatocytes obtained from rats which had been fed carbonyl Fe was not significantly different from that by normal hepatocytes. These experiments show that rat hepatocytes in primary culture have a high capacity to take up non-transferrin-bound Fe in the form of Fe-citrate and that uptake occurs by facilitated diffusion. The iron transport process does not appear to be regulated by cellular Fe levels.

Effect of pyridoxal isonicotinoyl hydrazone and other hydrazones on iron release from macrophages, reticulocytes and hepatocytes

A model consisting of 59Fe-labelled macrophages was developed for screening potential iron-chelating drugs. Mouse peritoneal macrophages, induced by previous intraperitoneal injections of 3% thioglycollate, were labelled in vitro by their exposure to immune complexes of 59Fe-transferrin-antitransferrin antibody. Optimal conditions for macrophage labelling and subsequent 59Fe release were established. Sixty-two aromatic hydrazones, the majority of which had iron binding structures similar to pyridoxal isonicotinoyl hydrazone, were synthesized by condensation of aromatic aldehydes (pyridoxal, salicylaldehyde, 2-hydroxy-1-naphthylaldehyde and 2-furaldehyde) with various acid hydrazides prepared by systematic substitutions on the benzene ring. These compounds were examined for their potential to stimulate 59Fe release from 59Fe-labelled macrophages and also from reticulocytes and hepatocytes loaded with non-heme 59Fe. The majority of hydrazones derived from pyridoxal, salicylaldehyde and 2-hydroxy-1-naphthylaldehyde seemed to be equally effective in both the macrophage and reticulocyte testing systems. However, the pyridoxal hydrazones were much more active in hepatocytes than the other groups of hydrazones. Several compounds proved to be very potent in mobilizing 59Fe. These included hydrazones derived from 2-hydroxy-1-naphthylaldehyde and benzoic acid hydrazide, p-hydroxybenzoic acid hydrazide, 2-thiophenecarboxylic acid hydrazide, and also pyridoxal benzoyl hydrazone, pyridoxal m-fluorobenzoyl hydrazone and pyridoxal 2-thiophenecarboxyl hydrazone.

The uptake of inorganic iron complexes by human melanoma cells.

The human melanoma cell line, SK-MEL-28, expresses high levels of melanotransferrin. The uptake of inorganic iron (Fe) complexes compared to transferrin-bound Fe by these cells has been investigated to determine whether melanotransferrin has a role in Fe uptake. The mechanisms of Fe uptake have been characterised using 59Fe complexes of citrate, nitrilotriacetate, desferrioxamine, and 59Fe added to Eagles minimum essential medium (MEM) and compared with human transferrin (Tf) labelled with 59Fe and iodine-125. Iron uptake from the Fe complexes of citrate, nitrilotriacetate and MEM were similar, and far greater than that from Tf at the same Fe concentration (2.5 microM). Ammonium chloride and a monoclonal antibody to the transferrin receptor (42/6), had no effect on the uptake of Fe from inorganic Fe complexes, suggesting that receptor-mediated endocytosis of Tf was not involved. The monoclonal antibody, 96.5, specific for melanotransferrin did not alter total Fe uptake but slightly increased the proportion of Fe internalised, possibly due to the modulation of the antigen by the antibody. However, from the time required for modulation to occur (approximately 2 h), the small increase in internalisation observed and the fact that no increase in total cell Fe occurred, it is suggested that melanotransferrin has little role in Fe uptake.

Iron chelators of the pyridoxal isonicotinoyl hydrazone class. III. Formation constants with calcium(II), magnesium(II) and zinc(II).

SummaryFormation constants for the calcium(II), magnesium(II) and zinc(II) complexes of the orally effective iron chelator, pyridoxal isonicotinoyl hydrazone (PIH) and three analogues, pyridoxal benzoyl hydrazone (PBH), pyridoxalp-methoxybenzoyl hydrazone (PpMBH) and pyridoxalm-fluorobenzoyl hydrazone (PmFBH) have been determined by potentiometry at 25\dg C andI=0.1 M [KNO3]. The four ligands bind calcium(II) weakly and magnesium(II) only slightly more strongly, as a l: l complex which is formed at pH \s> 8. The chelation of zinc(II) for all the ligands studied was greater than that for calcium(II) and magnesium(II), with complexation generally becoming significant at about pH 5. Thus, chelation of zinc(II) but not calcium(II) or magnesium(II) at physiological pH, 7.4 may be expected. Calculated values of the concentration of uncomplexed metal ion indicate that the selectivity of these ligands towards Fe(III) is comparable to that of the clinically used chelator desferrioxamine.

The release of iron and transferrin from the human melanoma cell

The role of the transferrin homologue, melanotransferrin (p97), in iron metabolism has been studied using the human melanoma cell line, SK-MEL-28, which expresses this antigen in high concentrations. The release of iron and transferrin were studied after prelabelling cells with human transferrin doubly labelled with iron-59 and iodine-125. Approx. 45% of internalised iron was in ferritin with little redistribution during reincubation. Iron release was linear with time, while transferrin release was biphasic, suggesting that iron was leaving the cell independently of transferrin. Unlabelled diferric transferrin increased transferrin release, implying a degree of coupling between cell surface binding, internalisation and release of transferrin. Increasing the preincubation time increased the amount of transferrin which remained internalised within the cell. A membrane-bound, iron-binding component with properties consistent with melanotransferrin was observed. Desferrioxamine or pyridoxal isonicotinoyl hydrazone could not remove iron from this compartment, suggesting a high affinity for iron. The number of membrane iron-binding molecules per cell was estimated to be 387,000 +/- 7000 . The non-transferrin-bound membrane Fe did not decrease during reincubation periods up to 5 h, suggesting that the cell was not utilising it. Hence, melanotransferrin may not have a role in internalising iron in melanoma cells.

The effects of an antibody to the rat transferrin receptor and of rat serum albumin on the uptake of diferric transferrin by rat hepatocytes.

The role of high-affinity specific transferrin receptors and low-affinity, non-saturable processes in the uptake of transferrin and iron by hepatocytes was investigated using fetal and adult rat hepatocytes in primary monolayer culture, rat transferrin, rat serum albumin and a rabbit anti-rat transferrin receptor antibody. The intracellular uptake of transferrin and iron occurred by saturable and non-saturable mechanisms. Treatment of the cells with the antibody almost completely eliminated the saturable uptake of iron but had little effect on the non-saturable process. Addition of albumin to the incubation medium reduced the endocytosis of transferrin by the cells but had no significant effect on the intracellular accumulation of iron. The maximum effect of rat serum albumin was observed at concentrations of 3 mg/ml and above. At a low incubation concentration of transferrin (0.5 microM), the presence of both rat albumin and the antibody decreased the rate of iron uptake by the cells to about 15% of the value found in their absence, but to only 40% when the diferric transferrin concentration was 5 microM. These results confirm that the uptake of transferrin-bound iron by both fetal and adult rat hepatocytes in culture occurs by a specific, receptor-mediated process and a low-affinity, non-saturable process. The low-affinity process increases in relative importance as the iron-transferrin concentration is raised.

Characterisation of citrate and iron citrate uptake by cultured rat hepatocytes

BACKGROUND/AIMS The endogenous low molecular weight iron chelator, citrate, is considered to be an important contributor to iron transport and the liver the main site of uptake of iron citrate in subjects suffering from diseases of iron overload. Moreover, the citrate-metabolising enzyme, aconitase, is implicated in the regulation of cellular iron metabolism. This study was undertaken to determine the role of citrate and ferric citrate in the uptake of iron by rat hepatocytes. METHODS Cultured rat hepatocytes were incubated (37 degrees C, 15 min) with 100 microM [14C]-citrate in the presence or absence of 1.0 microM 55Fe. Membrane-bound and intracellular radiolabel were separated by incubation with the general protease, Pronase. RESULTS Our results suggest that ferric citrate uptake is mediated by a specific citrate binding site which exhibits a higher affinity for citrate in the presence of iron than in its absence. Citrate was internalised by hepatocytes, with at least 70% being oxidised to CO2 within 15 min. Citrate uptake was pH-dependent, did not require the presence of sodium and increased with increasing iron concentration. Metabolic energy, anion channels, the Na+, K+-ATPase and vesicle acidification do not appear to play a role in uptake of ferric citrate, but functional sulphydryl groups may be involved. CONCLUSIONS The data suggest either that ferric citrate complexes with higher molar ratios of iron to citrate relative to the incubation medium are bound preferentially to the membrane, or that once citrate has delivered its iron to the membrane, the complex dissociates and the components are internalised separately.