Studies on the mobilization of iron from ferritin by isolated rat liver mitochondria

Rat liver mitochondria and rat liver mitoplasts mobilize iron from ferritin by a mechanism which depends on a respiratory substrate (preferentially succinate), a small molecular weight electron mediator (FMN, phenazine methosulphate or methylene blue) and (near) anaerobic conditions.The release process under optimized conditions (approx. 50 μmol/l FMN, 1 mmol/l succinate, 0.35 mmol/l Fe(III) (as ferritin iron), 37°C and pH 7.40) amounts to 0.9–1.2 nmol iron/mg protein per min.The results suggest that ferritin might function as an intermediate in the cytosolic transport of iron to the mitochondria.     

Iron content and degree of lipid peroxidation in liver mitochondria isolated from iron-loaded rats

1.The content of non-heme iron and the degree of lipid peroxidation were measured in liver mitochondria isolated from rats injected with either Jectofer (an iron-sorbitol-citric acid complex) or iron-nitrilotriacetate. 2. The sedimentation profiles of the mitochondria from controls and iron-treated rats as revealed by analytical differential centrifugation, indicated single population of mitochondria with $\text{s}{}_{\mathrm{4,B}}$ values of 13200± 560 S and 14200±590 S for controls and iron-loaded animals, respectively. In contrast, the sedimentation profiles of the acid phosphatase activity and the non-heme iron revealed marked polydispersities with at least three populations of particles for both controls and iron-loaded animals. 3. The mitochondria and iron-rich lysosomes were separated by density-gradient centrifugation in an isotonic medium of Percoll and sucrose. With this technique, the amount of non-heme iron in a mitochondrial fraction by differential centrifugation decreased from 69±28 nmol/mg protein to 5.6±1.1 nmol/mg protein and from 19.3±5.6 nmol/mg protein to 3.3±0.6 nmol/mg protein for Jectofer and iron-nitrilotriacetate injected rats, respectively. For control rats the amount of mitochondrial non-heme iron was about 2.7 nmol/mg protein both before and following density gradient centrifugation. The extra amount of non-heme iron still present in the purified mitochondrial fraction from iron-loaded rats, as compared to controls, was further characterized by the reactivity towards bathophenanthroline sulfonate. The results suggest that the extra iron was due to a small amount of either ferritin or hemosiderin still contaminaning the mitochondrial fraction. The amount of mitochondrial heme iron was the same in iron-loaded rats and controls. 4. The degree of lipid peroxidation in the mitochondria was estimated from the amount of malondialdehyde. The thiobarbituric acid method used for the quantitation of malondialdehyde was modified so that it was insensitive to variable amounts of iron present in the samples. No difference in the degree of lipid peroxidation was observed between the mitochondria from iron-loaded rats and controls. 5. In contrast to recent proposals (Hanstein, E.G. et al. (1981) Biochim. Biophys. Acta 678, 293–299), the present study showed that the amounts of non-heme iron and the degrees of lipid peroxidation are the same in mitochondria isolated from iron-loaded and control animals.     

Rapid mobilization of ferritin iron by ascorbate in the presence of oxygen

L-(—)-ascorbate mobilizes iron from horse-spleen ferritin in the presence of oxygen at pH 8.0. The reaction is strongly stimulated by Cu²⁺. Dehydroascorbate and other stable oxidation products of ascorbate are ineffective. We present evidence that monodehydroascorbate mobilizes ferritin iron by reduction.     

Roles of phosphate and an enoyl radical in ferritin iron mobilization by 5-aminolevulinic acid

5-Aminolevulinic acid (ALA), a heme precursor that accumulates in acute intermittent porphyria (AIP) and lead poisoning, undergoes enolization and subsequent iron-catalyzed oxidation at neutral pH. Iron is released from horse spleen ferritin (HoSF) by both ALA-generated O₂^•− and enoyl radical (ALA√), which amplifies the chain of ALA oxidation (autocatalysis). Iron chelators such as EDTA, ATP, but not citrate, and phosphate accelerate this process and ALA-promoted iron release from HoSF is faster in horse spleen isoferritins containing larger amounts of phosphate in the core. ALA (+0.377 V versus standard hydrogen electrode) is less effective in releasing iron from ferritin than are thioglycollic acid, 6-hydroxydopamine, and N,N,N′,N′-tetramethyl-p-phenylenediamine. During electrochemical one electron oxidation of ALA in a nitrogen atmosphere, spin trapping experiments with 3,5-dibromo-4-nitrosobenzenesulfonic acid demonstrated the formation of a spin adduct characterized by a six line signal, indicating a secondary carbon-centered radical and attributed to a resonant ALA√ radical. Iron is also released in such anaerobic electrochemical oxidations of ALA in the presence of ferritin, suggesting that, in addition to O₂^•−, ALA√ can promote iron mobilization from ferritin. Hence, ALA√ may amplify the metal-catalyzed oxidation of ALA, damaging ALA-accumulating cells and possibly contributing to the symptoms of porphyria.     

Catecholamine content of chromaffin granule ‘ghosts’ isolated from bovine adrenal glands

Studies on the mechanism of catecholamine transport into chromaffin granules is complicated by the release of endogenous catecholamines. To overcome this problem chromaffin granule ghosts have been prepared by many investigators by osmotic lysis of the granules which results in a loss of over 90% of the endogenous catecholamine. However, in the studies reported here, the resulting ghosts still contained 36 ± 3.9 nmol epinephrine/mg of protein if they were lysed by passage through a Sephadex G-50 column preequilibrated with hypoosmtic media. This residual catecholamine was foun the slowly diffuse out of the ghosts in a temperature-dependent process at a rate sufficient to interfere with kinetic analysis of catecholamine transport. Attempts to remove the endogenous catecholamine from the ghosts indicated that most of it could not be removed by further osmotic shock or freeze-thaw treatments, but that over 85% of it was released from the granules by incubating them at 30°C for 90 min or by dialysis with a 35 and 86% loss of rate of catecholamine transport into the ghosts, respectively. If the endogenous catecholamine was removed from chromaffin granule ghosts by preincubating them for 90 min at 30°C, these resulting ghosts transported catecholamine with a linear Lineweaver-Burk plot indicating a K_m of 12±2 μM. In addition, the resulting ghosts did not leak catecholamines over a 10 min period at 30°C, and the transport of catecholamines was blocked by reserpine and enhanced with increasing pH from 6.0 to 8.5.     

Pyrophosphate as a ligand for delivery of iron to isolated rat-liver mitochondria

Rat liver mitochondria accumulate iron mobilized from transferrin by pyrophosphate. The capacity of the mitochondria to accumulate iron is higher than the capacity of pyrophosphate to mobilize iron from transferrin: with ferric-iron-pyrophosphate as iron donor, iron uptake and heme synthesis are about 10-times that at corresponding concentrations of iron-transferrin plus pyrophosphate. Uptake of iron from ferric-iron-pyrophosphate depends on a functionary respiratory chain and involves reductive cleavage of the ferric-iron-pyrophosphate complex. Apotransferrin inhibits uptake of iron from ferric-iron-pyrophosphate by competing with the mitochondria for iron. The results focus on pyrophosphate as a possible candidate for intracellular iron transport.     

Iron release from ferritin by flavin nucleotides

Background

Extensive in-vitro studies have focused on elucidating the mechanism of iron uptake and mineral core formation in ferritin. However, despite a plethora of studies attempting to characterize iron release under different experimental conditions, the in-vivo mobilization of iron from ferritin remains poorly understood.Several iron-reductive mobilization pathways have been proposed including, among others, flavin mononucleotides, ascorbate, glutathione, dithionite, and polyphenols. Here, we investigate the kinetics of iron release from ferritin by reduced flavin nucleotide, FMNH2, and discuss the physiological significance of this process in-vivo.

Methods

Iron release from horse spleen ferritin and recombinant human heteropolymer ferritin was followed by the change in optical density of the Fe(II)–bipyridine complex using a Cary 50 Bio UV–Vis spectrophotometer. Oxygen consumption curves were followed on a MI 730 Clark oxygen microelectrode.

Results

The reductive mobilization of iron from ferritin by the nonenzymatic FMN/NAD(P)H system is extremely slow in the presence of oxygen and might involve superoxide radicals, but not FMNH2. Under anaerobic conditions, a very rapid phase of iron mobilization by FMNH2 was observed.

Conclusions

Under normoxic conditions, FMNH2 alone might not be a physiologically significant contributor to iron release from ferritin.

General significance

There is no consensus on which iron release pathway is predominantly responsible for iron mobilization from ferritin under cellular conditions. While reduced flavin mononucleotide (FMNH2) is one likely candidate for in-vivo ferritin iron removal, its significance is confounded by the rapid oxidation of the latter by molecular oxygen.     

Glycine transport in rat brain and liver mitochondria

Transport of glycine by rat brain and liver mitochondria has been investigated by both [¹⁴C]glycine uptake and swelling experiments. Glycine enters mitochondria passively down its concentration gradient by a respiratory-independent carrier-mediated process. This view is supported by the following observations: (a) glycine inside the mitochondria reaches the incubation medium concentration; (b) mitochondria swell in the presence of isoosmotic solutions of glycine in a concentration-dependent fashion; (c) the uptake of glycine is not influenced by respiratory inhibitors such as KCN or by uncouplers such as carbonylcyanide p-trifluoromethoxyphenylhydrazone; (d) initial rates of uptake approach saturation kinetics, the apparent K_m of the rat brain mitochondria for glycine being 1.7 mM and that of the liver mitochondria being 5.7 mM; (e) the rate of swelling is inhibited by methylmalonate, propionate and, at pH 6.5, by mersalyl, and (f) uptake is inhibited by phosphoserine, methylmalonate and propionate, but not by alanine or proline.     

Release of iron from ferritin by semiquinone, anthracycline, bipyridyl, and nitroaromatic radicals

The cytotoxicity of many xenobiotics is related to their ability to undergo redox reactions and iron dependent free radical reactions. We have measured the ability of a number of redox active compounds to release iron from the cellular iron storage protein, ferritin. Compounds were reduced to their corresponding radicals with xanthine oxidase/hypoxanthine under N₂ and the release of Fe²⁺ was monitored by complexation with ferrozine. Ferritin iron was released by a number of bipyridyl radicals including those derived from diquat and paraquat, the anthracycline radicals of adriamycin, daunorubicin and epirubicin, the semiquinones of anthraquinone-2-sulphonate, 1,5 and 2,6-dihydroxyanthraquinone, 1-hydroxyanthraquinone, purpurin, and plumbagin, and the nitroaromatic radicals of nitrofurantoin and metronidazole. In each case, iron release was more efficient than with an equivalent flux of superoxide. Introduction of air decreased the rate of iron release, presumably because the organic radicals reacted with O₂ to form superoxide. In air, iron release was inhibited by superoxide dismutase. Semiquinones of menadione, benzoquinone, duroquinone, anthraquinone 1,5 and 2,6-disulphonate, 1,4 naphthoquinone-2-sulphonate and naphthoquinone, when formed under N₂, were unable to release ferrin iron. In air, these systems gave low rates of superoxide dismutase-inhibitible iron release. Of the compounds investigated, those with a single electron reduction potential less than that of ferritin were able to release ferritin iron.     

Interplay between ferritin metabolism, reactive oxygen species and nitric oxide

 The biological relevance of each of the three inorganic species – iron, oxygen, and nitric oxide (NO) – is crucial. Moreover, their metabolic pathways cross each other and thus create a complex network of connections responsible for the regulation of many essential biological processes. The iron storage protein ferritin, one of the main regulators of iron homeostasis, influences oxygen and NO metabolism. Here, examples are given of the biological interactions of the ferritin molecule (ferritin iron and ferritin shell) with reactive oxygen species (ROS) and NO. The focus is the regulation of ferritin expression by ROS and NO. From these data, ferritin emerges as an important cytoprotective component of the cellular response to ROS and NO. Also, by its ability to alter the amount of intracellular "free" iron, ferritin may affect the metabolism of ROS and NO. It is proposed that this putative activity of ferritin may constitute a missing link in the regulatory loop between iron, ROS, and NO. Received: 2 January 1997 / Accepted: 9 June 1997     

Rapid reduction of iron in horse spleen ferritin by thioglycolic acid measured by dispersive X-ray absorption spectroscopy

Summary The release of iron from ferritin is important in the formation of iron proteins and for the management of diseases in both animals and plants associated with abnormal accumulations of ferritin iron. Much more iron can be released experimentally by reduction of the ferric hydrous oxide core than by chelation of Fe³⁺ which has led to the notion that reduction is also the major aspect of iron release in vivo. Variations in the kinetics of reduction of the mineral core of ferritin have been attributed to the redox potential of the reductant, redox properties of the iron core, the structure of the protein coat, the analytical method used to detect Fe²⁺ and reactions at the surface of the mineral. Direct measurements of the oxidation state of the iron during reduction has never been used to analyze the kinetics of reduction, although Mössbauer spectroscopy has been used to confirm the extent of reduction after electrochemical reduction using dispersive X-ray absorption spectroscopy (DXAS). We show that the near edge of X-ray absorption spectra (XANES) can be used to quantify the relative amounts of Fe²⁺ and Fe³⁺ in mixtures of the hydrated ions. Since the nearest neighbors of iron in the ferritin iron core do not change during reduction, XANES can be used to monitor directly the reduction of the ferritin iron core. Previous studies of iron core reduction which measured by Fe²⁺ · bipyridyl formation, or coulometric reduction with different mediators, suggested that rates depended mainly on the redox potential of the electron donor. When DXAS was used to measure the rate of reduction directly, the initial rate was faster than previously measured. Thus, previously measured differences in reduction rates appear to be influenced by the accessibility of Fe²⁺ to the complexing reagent or by the electrochemical mediator. In the later stages of ferritin iron core dissolution, reduction rates drop dramatically whether measured by DXAS or formation of Fe²⁺ complexes. Such results emphasize the heterogeneity of ferritin core structure.     

Reduction of exogenous flavins and mobilization of iron from ferritin by isolated mitochondria

The release mechanism for ferritin iron and the nature of the compound(s) which donate iron to the mitochondria are two important problems of intracellular iron metabolism which still await their solution. We have previously shown that isolated mitochondria reduce exogenously added flavins in a ubiquinol-flavin oxidoreductase reaction at the C-side of the inner membrane and that the resulting dihydroflavins function as reductants in mitochondrial mobilization of iron from ferritin (Ulvik, R. J., and Romslo, I. (1981). Biochim. Biophys. Acta 635, 457-469). In the present study it is shown that the rate at which iron is removed from ferritin depends on the capability of the flavins to penetrate (1) the mitochondrial outer membrane and (2) the intersubunit channels of the ferritin protein shell. Intact mitochondria reduce flavins at rates which decrease in the following order: riboflavin > FAD > FMN. The ferritin iron mobilization rates decrease in the order of riboflavin > FMN > FAD. The results are further support for the operation of a flavin-dependent mitochondrial ferrireductase, and strengthen the suggested role for ferritin as a donor of iron to the mitochondria.     

Excessive iron accumulation in the pea mutants dgl and brz: subcellular localization of iron and ferritin

The pea (Pisum sativum L.) mutants dgl and brz are defective in the regulation of iron uptake. Enhanced proton extrusion and constitutively high Fe(III) reductase activities in the roots lead to an accumulation of iron and other divalent cations in different organs of the mutants. Ultrastructural investigations of the basal leaflets of the mutants revealed in the cytoplasm, in mitochondria and especially in, or close to the endoplasmic reticulum numerous electron-dense particles which were absent in the corresponding wild type plants DGV and Sparkle. By means of electron-spectroscopic imaging and electron-energy-loss spectroscopy it could be shown that these electron-dense particles consist mainly of iron. Some of the iron deposits were immunocytochemically identified as the iron-storage protein ferritin. It is suggested that the precipitation of excessive iron in the dgl and brz mutant leaves in the form of electron-dense iron particles combined with the accumulation of ferritin is part of the plant defense mechanism against Fe-mediated oxidative stress. Received: 17 February 1998 / Accepted: 4 July 1998     

Studies on the mobilization of iron from ferritin by isolated rat liver mitochondria.

Rat liver mitochondria and rat liver mitoplasts mobilize iron from ferritin by a mechanism which depends on a respiratory substrate (preferentially succinate), a small molecular weight electron mediator (FMN, phenazine methosulphate or methylene blue) and (near) anaerobic conditions. The release process under optimized conditions (approx. 50 mumol/1 FMN, 1 mmol/l succinate, 0.35 mmol/1 Fe(III) (as ferritin iron), 37 degrees C and pH 7.40) amounts to 0.9--1.2 nmol iron/mg protein per min. The results suggest that ferritin might function as an intermediate in the cytosolic transport of iron to the mitochondria.     

Effect of phlebotomy on the ferritin iron content in the rat liver as determined morphometrically with the use of electron energy loss spectroscopy

Summary Phlebotomy of untreated and iron-loaded rats results in a significant decrease in total liver iron. In ironloaded rats a marked decrease in iron-containing particles is observed ultrastructurally in lysosomes and cytoplasm of hepatic sinusoidal cells but not in parenchymal cells. This remarkable phenomenon was further investigated in a morphometric study, based on element-specific (iron) distribution images made in situ in the parenchymal cell by means of electron energy loss spectroscopy. With the use of this technique it could be shown that in spite of phlebotomy the ferritin iron content of the iron-loaded liver parenchymal cell is not decreased.     

Oxidative phosphorylation and ATPase activities of human tumor mitochondria

Studies were carried out with intact mitochondria isolated from human astrocytoma, oat cell carcinoma and melanoma which were propagated in athymic mice. These human tumor mitochondria were capable of coupled oxidative phosphorylation. They also showed significant uncoupler-stimulated ATPase if defatted bovine serum albumin was included in the assay media. However, the uncoupler response curves were different and the magnitude of the ATPase activity was lower than could be obtained with mitochondria of a normal tissue, such as liver. Some of these characteristics were also exhibited by mitochondria from several animal hepatomas and Ehrlich ascites tumor. In the three tumors studied, mitochondria from oat cell carcinoma were more labile, whereas higher respiratory control ratios and greater stimulation of ATPase by uncouplers were obtained with melanoma mitochondria.The mitochondrial ATPase was not the major cellular ATPase in any of the three tumors. This was indicated by a low inhibition of the ATPase activity of tumor cell homogenates by oligomycin. A very large fraction of the cellular ATPase activities was recovered in the microsomal fractions.     

Ferritin-catalyzed consumption of hydrogen peroxide by amine buffers causes the variable Fe2+ to O2 stoichiometry of iron deposition in horse spleen ferritin

Ferritin catalyzes the oxidation of Fe2+ by O2 to form a reconstituted Fe3+ oxy-hydroxide mineral core, but extensive studies have shown that the Fe2+ to O2 stoichiometry changes with experimental conditions. At Fe2+ to horse spleen ferritin (HoSF) ratios greater than 200, an upper limit of Fe2+ to O2 of 4 is typically measured, indicating O2 is reduced to 2H2O. In contrast, a lower limit of Fe2+ to O2 of approximately 2 is measured at low Fe2+ to HoSF ratios, implicating H2O2 as a product of Fe2+ deposition. Stoichiometric amounts of H2O2 have not been measured, and H2O2 is proposed to react with an unknown system component. Evidence is presented that identifies this component as amine buffers, including 3-N-morpholinopropanesulfonic acid (MOPS), which is widely used in ferritin studies. In the presence of non-amine buffers, the Fe2+ to O2 stoichiometry was approximately 4.0, but at high concentrations of amine buffers (0.10 M) the Fe2+ to O2 stoichiometry is approximately 2.5 for iron loadings of eight to 30 Fe2+ per HoSF. Decreasing the concentration of amine buffer to zero resulted in an Fe2+ to O2 stoichiometry of approximately 4. Direct evidence for amine buffer modification during Fe2+ deposition was obtained by comparing authentic and modified buffers using mass spectrometry, NMR, and thin layer chromatography. Tris(hydroxymethyl)aminomethane, MOPS, and N-methylmorpholine (a MOPS analog) were all rapidly chemically modified during Fe2+ deposition to form N-oxides. Under identical conditions no modification was detected when amine buffer, H2O2, and O2 were combined with Fe2+ or ferritin separately. Thus, a short-lived ferritin intermediate is required for buffer modification by H2O2. Variation of the Fe2+ to O2 stoichiometry versus the Fe2+ to HoSF ratio and the amine buffer concentration are consistent with buffer modification.