Vascular release of nonheme iron in perfused rabbit lungs

In this study, we hypothesized that the lung actively releases excess iron into the circulation to regulate iron homeostasis. We measured nonheme iron (NHFe) in the perfusate of control isolated perfused rabbit lungs and lungs with ischemia-reperfusion (I/R) ventilated with normoxic (21% O(2)) or hypoxic (95% N(2)) gas mixtures. Some were perfused with bicarbonate-free (HEPES) buffer or treated with the anion exchange inhibitor DIDS. The control lungs released approximately 0.25 microg/ml of NHFe or 20% of the total lung NHFe into the vascular space that was not complexed with ferritin, transferrin, or lactoferrin or bleomycin reactive. The I/R lungs released a similar amount of NHFe during ischemia and some bleomycin-detectable iron during reperfusion. NHFe release was attenuated by approximately 50% in both control and ischemic lungs by hypoxia and by >90% in control lungs and approximately 60% in ischemic lungs by DIDS and HEPES. Reperfusion injury was not affected by DIDS or HEPES but was attenuated by hypoxia. These results indicate that biologically nonreactive nonheme iron is released rapidly by the lung into the vascular space via mechanisms that are linked to bicarbonate exchange. During prolonged ischemia, redox-active iron is also released into the vascular compartment by other mechanisms and may contribute to lung injury.     

The 70 kilodalton iron regulated protein of Neisseria meningitidis is not the human transferrin receptor

Neisseria meningitidis is able to chelate iron from human transferrin (HTF), the main sequestrator of extracellular iron in vivo. Previous workers have reported that a ca. 70 kilodalton (kDa) iron regulated outer membrane protein (FeRP-70) is a highly specific receptor for HTF. We have examined the interaction between the iron regulated outer membrane proteins (OMP's) and HTF, using HTF and rabbit anti HTF, as well as gold labelled HTF (Au-HTF) to blot OMP's of various serogroups and serotypes of N. meningitidis. Also, we used monospecific rabbit anti FeRP-70 in competitive experiments to determine the role of FeRP-70 in HTF-binding. Single proteins (molecular weights range ca. 60 to ca. 90 kDa) were identified in the OMP's from each strain which reacted with HTF. HTF failed to block the reaction between FeRP-70 and the OMP's, conversely anti FeRP-70 failed to block the HTF-binding reaction. We believe that the 70 kDa iron regulated protein of N. meningitidis is not a human transferrin receptor.     

Ultrastructural visualization of sulphated complex carbohydrates in blood and epithelial cells with the high iron diamine procedure

Synopsis The high iron diamine (HID) method has been found to impart density at the ultrastructural level selectively to sites known to contain sulphated complex carbohydrates. Thus, immature primary granules in rabbit heterophils, immature précrystalloid granules in rabbit eosinophils, all granules of rabbit basophils, mouse and rat mast cells and the nucleoids of -granules of rabbit platelets were stained by HID. Granules of mast cells in rat cervical lymph node varied in the distribution pattern of the HID-reactive component. Mucous droplets within goblets of mouse colonic epithelial cells varied in HID reactivity. Sites known to contain sialomucin but no sulphates, such as mucous cells and apical plasmalemmae in mouse rectosigmoid colon, failed to stain with HID in contrast to their reactivity for dialysed iron at the ultrastructural level. The surface of mast cells and blood cells lacked affinity for HID, indicating that the dialysed iron binding at the surfaces can be attributed to neuraminic acid. HID proved more effective than dialysed iron in visualizing acid mucosubstance in precursor forms of the crystalloid granules in the eosinophil and in mast cell granules. Inclusion of 0.5% glycerol in the HID solution enhanced staining in mouse colon.     

Nature of the iron requirement for Chinese hamster V79 cells in tissue culture medium

The Chinese hamster V79 cell line can be grown in medium containing iron instead of lactalbumin hydrolysate and containing defined low molecular weight components instead of peptone. A rather large amount of inorganic iron must be supplied for optimum growth. Dose-response curves done with commercially available transferrins from various species show that this Chinese hamster cell line grows well with human and rabbit transferrins but poorly with porcine, bovine, and chicken egg white (conalbumin) transferrins. An assay of Chinese hamster serum in the presence and absence of iron shows that hamster serum is better at providing the V79 cells with iron than human or rabbit transferrin. Thus, the nature of the iron requirement of V79 cells lies in the requirement for a specific transferrin.     

Comparison of microsomal and solubilized monooxygenases from rat and rabbit by proton magnetic relaxation.

The paper presents results of a comparative study of the haem environment, by proton magnetic relaxation, in P-450 and P-448 monooxygenases from rat and rabbit, induced by phenobarbital and 3-methylcholanthrene, in both species. It was established that the method yields information on the accessibility of the haem iron for solvent molecules (protons), both in microsomes and in solubilized samples of various degrees of purification, i.e. association. The state of micelles in the solutions does not alter the haem iron accessibility. A slight difference was found for the microsomes suspended in a phosphate vs. pyrophosphate buffer, but this is without any consequence with regard to the species and form differences. The correlation time for the highly purified LM2 fraction of rabbit P-450 could not be determined more precisely than before for a sample of lower purity, because the relaxation rates are frequency independent. The correlation time for the rat P-448 monooxygenase was determined by dispersion measurements to be (4.1 +/- 0.4) x 10(-11) s. It was found that the PMRx behaviours of rabbit and rat monooxygenases are more alike in microsomes than in the partially purified solubilized form. The solubilization produces a pronounced alteration of the PMRx temperature dependence only for the rat 3-MC induced monooxygenase P-448. For the P-450 form the haem iron becomes less accessible on solubilization, both for the rabbit and the rat liver monooxygenases, whereas in case of rat liver P-448 the accessibility is considerably enhanced on solubilization. There is a substantial structural specificity of the haem environments from the two animal species, the one from rat being tighter. The reduced, NO-bound rabbit liver monooxygenase was studied also, but the results are not yet conclusive, except the fact that the unpaired spin from NO is thoroughly shielded from the solvent compared with the haem iron from the original sample. The following series of increased haem-iron accessibility emerges from the PMRx studies known so far: rat (P-448) less than rabbit (P-448) less than rat (P-450) less than rabbit (P-450) in microsomes, and rabbit (P-448, with 3-MC bound?) less than Pseudomonas putida (P-450) rat less than (P-448), less than rat (P-450) less than rabbit (P-450) from solubilized samples. For the latter, it appears that increased enzymic specificity goes along with a closing of the haem cleft.     

Non-transferrin donors of iron for heme synthesis in immature erythroid cells

The mechanism of iron uptake from several iron-containing compounds by transferrin-depleted rabbit reticulocytes and mouse spleen erythroid cells was investigated. Iron complexes of DL-penicillamine, citrate and six different aroyl hydrazones may be utilized by immature erythroid cells for hemoglobin synthesis, although less efficiently than iron from transferrin. HTF-14, a monoclonal antibody against human transferrin, reacts with rabbit transferrin and inhibits iron uptake and heme synthesis by rabbit reticulocytes. HTF-14 had no significant effect on iron uptake and heme synthesis when non-transferrin donors of iron were examined. Ammonium chloride (NH4Cl) increases intracellular pH and blocks the release or utilization of iron from the internalized transferrin. NH4Cl only slightly affected iron incorporation and heme synthesis from non-transferrin donors of iron. Hemin inhibited transferrin iron uptake and heme synthesis, but had a much lesser effect on iron incorporation and heme synthesis from non-transferrin donors of iron. These results allow us to conclude that transferrin-depleted reticulocytes take up iron from all of the examined non-transferrin iron donors without the involvement of the transferrin/transferrin receptor pathway.     

Iron transport from sepharose-bound transferrin

To ascertain whether transferrin need enter the reticulocyte to deliver its iron after the association of transferrin with the cell membrane, {¹²⁵I, ⁵⁹Fe-}labeled transferrin was covalently bound to Sepharose beads. Iron uptake from Sepharose-bound transferrin into rabbit reticulocytes was about 9% that from free transferrin while heme synthesis was more efficient at nearly 19%. Similar results were obtained with murine transferrin and murine reticulocytes.These results indicate that the entrance of transferrin inside the cell is not an obligatory step in the process of iron uptake in rabbit and murine reticulocytes.     

Differences between human and rabbit transferrins

Rabbit reticulocyte incorporation of iron from rabbit transferrin was independent of transferrin iron saturation but uptake from human transferrin was saturation dependent. Unlike human transferrin, rabbit transferrin does not surrender its iron from any unique preferred iron-binding site and can be described as functionally homogeneic.The two proteins also differ in their acid-base iron-binding properties. One human transferrin iron binding site retains an ability to bind iron at somewhat acid pH but this property is not shared by rabbit transferrin.     

Differences between human and rabbit transferrins.

Rabbit reticulocyte incorporation of iron from rabbit transferrin was independent of transferrin iron saturation but uptake from human transferrin was saturation dependent. Unlike human transferrin, rabbit transferrin does not surrender its iron from any unique preferred iron-binding site and can be described as functionally homogeneic. The two proteins also differ in their acid-base iron-binding properties. One human transferrin iron binding site retains an ability to bind iron at somewhat acid pH but this property is not shared by rabbit transferrin.     

Functional heterogeneity and pH-dependent dissociation properties of human transferrin.

Human diferric transferrin was partially labeled with 59Fe at low or neutral pH (chemically labeled) and by replacement of diferric iron previously donated to rabbit reticulocytes (biologically labeled). Reticulocyte 59Fe uptake experiments with chemically labeled preparations indicated that iron bound at near neutral pH was more readily incorporated by reticulocytes than iron bound at low pH. The pH-dependent iron dissociation studies of biologically labeled transferrin solutions indicated that Fe3+, bound at the site from which the metal was initially utilized by the cells, dissociated between pH 5.8 and 7.4. In contrast, lower pH (5.2--5.8) was required to effect dissociation of iron that has remained bound to the protein after incubation with reticulocytes. These findings suggest that each human transferrin iron-binding site has different acid-base iron-binding properties which could be related to the observed heterogenic rabbit reticulocyte iron-donating properties of human transferrin and identifies that the near neutral iron-binding site initially surrenders its iron to these cells.     

Evidence for functional differences between the two sites of rabbit transferrin: effects of serum and carbon dioxide

A recently developed technique combining urea gel electrophoresis with Western immunoblotting has been modified for assessing the relative ability of each iron binding site of rabbit transferrin in delivering iron to rabbit reticulocytes. The two sites can be made to release iron at the same or differing rates, depending on the experimental conditions. In Hanks' balanced salts solution in an atmosphere of room air or 5% CO2, the acid-labile site in the N-terminal lobe of the protein was found to be 1.4- and 2.9-times more effective than its acid-stable counterpart in providing iron to reticulocytes after 90 min incubation. Both sequential and simultaneous release of iron from the two sites was observed, but sequential release was initiated only from the N-terminal site. The same site also proved to be a better iron donor by a factor of 2 when incubations were conducted in Hanks' medium enriched with 20% serum in 5% CO2. Only in 20% serum in air were the two sites found to be equivalent iron suppliers to reticulocytes. In the cases studied, an atmosphere of 5% CO2 increased 2-fold the effectiveness of iron donation by the acid-labile site to reticulocytes, while the presence of 20% serum enhanced the iron-donating ability of the acid-stable C-terminal site. Thus, the transferrin-reticulocyte interaction is sensitive to environmental variables, and such sensitivity may help account for apparent discrepancies in previous studies of the relative iron-donating abilities of the two sites of transferrin.     

An evaluation of lysosomal enzyme leakage as a factor influencing the behaviour of transformed cells.

The effect of concanavalin A on transferrin and iron uptake by reticulocytes was determined using rabbit reticulocytes and rabbit transferrin labelled with ⁵⁹Fe and ¹²⁵I and concanavalin A (ConA) labelled with ¹³¹I. In concentrations of 50–200 μg/ml ConA markedly inhibited iron uptake but did not inhibit transferrin uptake or release from the cells. ConA was itself taken up by rabbit blood cells in a manner similar to that of transferrin except that the uptake was not specific for reticulocytes but occurred also with mature erythrocytes. The inhibition of iron uptake by concanavalin and the uptake of concanavalin by the cells were both inhibited by α-methyl-d-mannoside. It is concluded that the effects observed were due to the binding of concanavalin to glycoproteins of the cell membrane, either by a direct interaction with transferrin receptors or by the production of a non-specific change in the structure of the membrane.     

Intravesicular pH and iron uptake by immature erythroid cells

The intravesicular pH of intact rabbit reticulocytes was measured by two methods; one based on the intracellular:extracellular distribution of DMO (5, 5, dimethyl + oxazolidin-2,4-dione), methylamine, and chloroquine and the other by quantitative fluorescence microscopy of cell-bound transferrin. The latter method was also applied to nucleated erythroid cells from the fetal rat liver. A pH value of approximately 5.4 was obtained with both methods and in both types of cells. Treatment of the cells with lysosomotrophic agents, metabolic inhibitors, and ionophores elevated the intravesicular pH and inhibited iron uptake from transferrin. When varying concentrations of NH4Cl were used, a close correlation was observed between the inhibition of iron uptake and elevation of the intravesicular pH. At pH 5.4 iron release from rabbit iron-bicarbonate transferrin in vitro was much more rapid than from iron-oxalate transferrin. The bicarbonate complex donates its iron to rabbit reticulocytes approximately twice as quickly as the oxalate complex. It is concluded that the acidic conditions within the vesicles provide the mechanism for iron release from the transferrin molecule after its endocytosis and that the low vesicular pH is dependent on cellular metabolism.     

Functional heterogeneity and pH-dependent dissociation properties of human transferrin

Human diferric transferrin was partially labeled with ⁵⁹Fe at low or neutral pH (chemically labeled) and by replacement of diferric iron previously donated to rabbit reticulocytes (biologically labeled). Reticulocyte ⁵⁹ uptake experiments with chemically labeled preparations indicated that iron bound at near neutral ph was more readily incorporated by reticulocytes than iron bound at low pH. The pH-dependent iron dissociation studies of biologically labeled transferrin solutions indicated that Fe³⁺, bound at the site from which the metal was initially utilized by the cells, dissociated between pH 5.8 and 7.4. In contrast, lower pH (5.2–5.8) was required to effect dissociation of iron that had remained bound to the protein after incubation with reticulocytes. These findings suggest that each human transferrin iron-binding site has different acid-base iron-binding properties which could be related to the observed heterogenic rabbit reticulocyte iron-binding properties of human transferrin and identifies that the near neutral iron-donating site initially surrenders its iron to these cells.     

Simultaneous quantification of hepatic MRI-PDFF and R2* in a rabbit model with nonalcoholic fatty liver disease

Quantification of hepatic fat and iron content is important for early detection and monitoring of nonalcoholic fatty liver disease(NAFLD) patients. This study evaluated quantification efficiency of hepatic proton density fat fraction(PDFF) by MRI using NAFLD rabbits. R2* was also measured to investigate whether it correlates with fat levels in NAFLD. NAFLD rabbit model was successfully established by high fat and cholesterol diet. Rabbits underwent MRI examination for fat and iron analyses,compared with liver histological findings. MR examinations were performed on a 3.0 T MR system using multi-echo 3 D gradient recalled echo(GRE) sequence. MRI-PDFF showed significant differences between different steatosis grades with medians of3.72%(normal), 5.43%(mild), 9.11%(moderate) and 11.17%(severe), whereas this was not observed in R2*. Close correlation between MRI-PDFF and histological steatosis was observed(r=0.78, P=0.000). Hepatic iron deposit was not found in any rabbits. There was no correlation between R2* and either liver MRI-PDFF or histological steatosis. MR measuring MRI-PDFF and R2* simultaneously provides promising quantification of steatosis and iron. Rabbit NAFLD model confirmed accuracy of MRI-PDFF for liver fat quantification. R2* measurement and relationship between fat and iron of NAFLD liver need further experimental investigation.     

Comparative aspects of transferrin-reticulocyte interactions: membrane receptors and iron uptake

1. A comparative study was made of transferrin and iron uptake by rabbit, rat and human reticulocytes and chick embryo erythrocytes from rabbit, rat, human, chicken and porcine transferrins, human lactoferrin and chicken conalbumin. 2. Three methods were used, viz. direct and competitive uptake studies of transferrin and iron by the four species of cells, and competitive studies of transferrin binding by solubilized membrane receptors (rabbit reticulocytes only). 3. Methods were devised to analyse the data so as to obtain indices of relatedness or relative affinities of each type of heterologous transferrin in rates of iron uptake found with transferrin and cells from various species are largely due to variation in the affinity of cellular receptors for different transferrins. 5. It is concluded that the procedure used in this investigation allow the assessment of phylogenetic relationships and evolutionary trends obtained by structural studies of proteins.     

Siderophore-independent acquisition of transferrin-bound iron by Haemophilus influenzae type b

The specificity by which Haemophilus species acquired iron from transferrin (TF) was investigated. In a plate bioassay H. influenzae used iron bound to human, bovine and rabbit TFs but not mouse, rat, dog, horse, guinea-pig, pig or ovo- TFs or human and bovine lactoferrins. In contrast, H. pleuropneumoniae used iron only from pig TF whilst H. parainfluenzae was unable to utilize iron bound to any of the human or animal TFs tested. The inhibition of growth imposed on H. influenzae type b strain Eagan by the addition of the synthetic iron chelator EDDA to the culture medium was reversed by 30% iron-saturated human TF added directly to the medium but not when the TF was contained inside a dialysis bag. Dot-blotting of whole cells revealed that human TF bound to the surface of bacteria cultured in iron-restricted but not in iron-plentiful media. Incubation of whole bacterial cells in the presence of the proteolytic enzyme trypsin also abolished TF-binding activity, suggesting that the TF receptor was a protein. In competition dot blotting experiments, human and bovine but not rabbit, dog, mouse or guinea-pig TFs blocked the binding of a horseradish peroxidase--human TF conjugate. SDS-PAGE and Western blotting of outer membranes revealed the presence of a TF-binding protein of approximately 72 kDa. These results suggest that the acquisition of TF-bound iron by H. influenzae type b probably involves a direct interaction with an outer-membrane protein which shows some TF-species specificity.     

The Importance of Iron,Calcium and Free Radicals in Reperfusion Injury: An Overview of Studies in Ischaemic Rabbit Kidneys

An overview of a series of experiments attempting to link iron and calcium redistribution and release of free fatty acids with falls in pH and adenine nucleotide levels during cold storage of rabbit kidneys is presented. The data reviewed strongly suggest that these events are inextricably linked to subsequent reperfusion injury. Circumstantial evidence incriminating iron was provided by experiments showing that iron chelation decreased reperfusion injury after warm (WI) and cold ischaemia (CI) in rat skin flap and rabbit kidney models. Evidence for a role for calcium was provided when it was found that a calcium channel blocking agent added to the saline flush solution before storage inhibited lipid peroxidation, whereas chemicals which caused release or influx of calcium into the cell exacerbated oxidative damage. Additional involvement of breakdown products of adenine nucleotides was suggested by the protection from lipid peroxidation afforded by allopurinol. Involvement of calcium-activated phospholipase A, was strongly suggested by increases In free fatty acids during cold storage and both this increase and lipid peroxidation were inhibited by addition of dibucaine to the storage solution.     

Heme inhibits transferrin endocytosis in immature erythroid cells

The inhibitory effect of heme on iron uptake from transferrin by rat and rabbit reticulocytes and erythroid cells from the fetal rat liver was studied in vitro. Addition of hemin was shown to cause a decrease in the rate of transferrin endocytosis, the degree of inhibition being proportional to the reduction in iron uptake. The heme synthesis inhibitors, isoniazid and succinylacetone, stimulated the rate of transferrin endocytosis by 15-30% and caused a proportional increase in the rate of iron uptake, possibly by reducing the intracellular free heme concentration. It is concluded from these results that heme affects iron uptake by influencing the rate of transferrin endocytosis and recycling.     

Failure of a cell-free system from rabbit reticulocytes to remove iron from transferrin.

1. Cell-free solutions prepared from rabbit reticulocytes were not able to release iron from rabbit transferrin. 2. The results, which differ from those obtained with Rana catesbeiana immature erythrocytes, indicate that cellular integrity is a requirement for this process in the rabbit reticulocyte system.