Transferrin receptors,iron transport and ferritin metabolism in friend erythroleukemia cells

Four aspects of iron metabolism were studied in cultured Friend erythroleukemia cells before and after induction of erythroid differentiation by dimethyl sulfoxide. (1) The binding of ¹²⁵I-labeled transferrin was determined over a range of transferrin concentrations from 0.5 to 15 μM. Scatchard analysis of the binding curves demonstrated equivalent numbers of transferrin binding sites per cell: 7.78 ± 2.41 · 10⁵ in non-induced cells and 9.28 ± 1.57 · 10⁵ after 4 days of exposure to dimethyl sulfoxide. (2) The rate of iron transport was determined by measuring iron uptake from ⁵⁹Fe-labeled transferrin. Iron uptake in non-induced cells was approx. 17 000 molecules of iron/cell per min; 24 h after addition of dimethyl sulfoxide it increased to 38 000, and it rose to maximal levels of approx. 130 000 at 72 h. (3) Heme synthesis, assayed qualitatively by benzidine staining and measured quantitatively by incorporation of ⁵⁹Fe or [2-¹⁴C]glycine into cyclohexanone-extracted or crystallized heme, was not detected until 3 days after addition of dimethyl sulfoxide, when 12% of the cells were stained by benzidine and 6 pmol ⁵⁹Fe and 32 pmol [2-¹⁴C]glycine were incorporated into heme per 10⁸ cells/h. After 4 days, 60% of the cells were benzidine positive and 34 pmol ⁵⁹Fe and 90 pmol [2-¹⁴C]glycine were incorporated into heme per 10⁸ cells/h. (4) The rate of incorporation of ⁵⁹Fe into ferritin, measured by immunoprecipitation of ferritin by specific antimouse ferritin immunoglobulin G, rose from 4.4 ± 0.6 cells to 18.4 ± 1.3 pmol ⁵⁹Fe/h per 10⁸ cells 3 days after addition of dimethyl sulfoxide, and then fell to 11.6 ± 3.1 pmol 4 days after dimethyl sulfoxide when heme synthesis was maximal. These studies indicate that one or more steps in cellular iron transport distal to transferrin binding is induced early by dimethyl sulfoxide and that ferritin may play an active role in iron delivery for heme synthesis.     

Effects of deferoxamine methanesulfonate on Trichophyton mentagrophytes.

Deferoxamine methanesulfonate (Desferal), an iron chelator, inhibited germ tube formation and growth of Trichophyton mentagrophytes in a microculture assay. A 50% reduction of germ tube formation required Desferal at 5 mg/ml and a 50% reduction of growth required 1.5 mg/ml. Growth was almost completely inhibited with 50 and 100 mg/ml. Also, Desferal at 100 mg/ml inhibited further elongation when added to short hyphae (II and 21 micrometer), but showed less inhibitory effects when added to long hyphae (64 micrometer). Iron (133 microgram/ml) reversed the inhibition of growth produced by incubating spores with Desferal at 5 mg/ml, providing iron was added before 72 h incubation. Desferal at 100 mg/ml decreased viability of activated spores incubated for 3 days at 30 degrees C, but did not decrease viability of spores incubated for 3 days at 4 degrees C. The growth inhibitory effect of Desferal and transferrin were compared. Transferrin was inhibitory at low molarities (0.001 to 1.0 mM), while Desferal was inhibitory only at higher molarities (greater than 1 mM). Desferal (0.05 mM) also reversed the inhibition expected with 0.05 mM transferrin. These findings indicate that Desferal and transferrin deprive T. mentagrophytes of nutritional iron and thus inhibit growth of the fungus. Low concentrations of Desferal can also promote growth in the presence of transferrin.     

Induction of liver apolipoprotein A-IV mRNA in porphyric mice.

We have isolated cDNA clones for mRNAs that are induced by porphyria from a mouse liver library. Of the three inducible clones isolated, we have identified one as being apolipoprotein A-IV (apo A-IV) by its extensive homology with a rat apolipoprotein A-IV cDNA sequence. The level of liver apo A-IV mRNA increases rapidly in response to either of two porphyrogenic drugs. When the ferrochelatase-inhibited drug, 3,5-dicarbethoxy-1,4-dihydrocollidine (DDC) is used, a 6 and 28 fold induction of liver apo A-IV mRNA is observed in male and female mice, respectively. If the heme-destroying porphyrogenic drug, allylisopropylacetamide (AIA) is the inducing agent, liver apo A-IV mRNA levels increase 2-3 fold in both males and females. The level of apo A-IV mRNA reaches a maximum within 6-10 hr. after drug administration. Intestine apo A-IV mRNA levels do not change during either of these drug-induced porphyrias. RNA from acute-phase responsive liver or liver from mice treated with bilirubin, porphobilinogen, or protoporphyrin IX show no increase in apo A-IV mRNA. These results indicate that apo A-IV induction is tied to a disruption in porphyrin-heme biosynthesis but is not directly affected by several heme intermediates nor by the major heme degradation product, bilirubin.     

Effect of S-allylcysteine,a sulphur containing amino acid on iron metabolism in streptozotocin induced diabetic rats

It is suggested that iron may play a role in the pathogenesis of diabetes. Iron is not only chaperoned through its essential functional pathways, but it also causes damage to biological systems by catalyzing the production of reactive oxygen species. So, the parenchymal tissues of several organs are subject to cell injury and functional insufficiency due to excess deposition of iron. The present study investigated the effects of S-allylcysteine (SAC), a sulphur containing amino acid derived from garlic on the changes in iron metabolism induced by oxidative stress in tissues, as well as on serum biochemical parameters of streptozotocin (STZ)-induced diabetic rats. SAC was administered orally for 45 days to control and experimental diabetic rats. The effects of SAC on glucose, insulin, serum iron, ferritin, transferrin, serum bilirubin, heart heme oxygenase activity (HO) and δ-aminolevulinicacid dehydratase activity (δ-ALA-D) in liver and kidneys were studied. The levels of glucose, iron, ferritin, bilirubin and HO in liver were increased significantly (p < 0.05) whereas the levels of insulin, transferrin and δ-ALA-D in tissues were decreased in diabetic rats. Administration of SAC to diabetic rats showed a decrease in blood glucose, iron, ferritin, bilirubin and HO. In addition, the levels of insulin, transferrin and δ-ALA-D activity in tissues were increased in SAC treated diabetic rats. These findings suggest that S-allylcysteine could have a protective effect against alterations in oxidative stress induced iron metabolism in the diabetic state which was evidenced by the capacity of this natural antioxidant to modulate parameters of iron metabolism.     

Regulation of K562 cell transferrin receptors by exogenous iron

Single-cell analysis of K562 human erythroleukemia cells by flow cytometry was used to demonstrate the specific role of iron in regulating transferrin receptors (TfRs) and to establish that TfR expression does not necessarily correlate with growth rate. Exogenous iron concentration in culture was manipulated by supplementing the medium with sera having different iron concentrations over the range 0.6 to 5.4 micrograms/ml, by the addition of iron in the form of FeCl3, iron-saturated serum, or diferric transferrin, and by the addition of the iron chelator Desferal (desferrioxamine). TfR expression was negatively correlated with exogenous iron content: any treatment that reduced exogenous iron supply by at least 15% resulted in as much as a 1.8-fold increase in external receptors, detected as binding by both transferrin and monoclonal anti-TfR antibodies, and a 1.5-fold increase in the pool of internal receptors, as detected by anti-TfR antibody binding. None of these treatments altered growth rate, total cellular protein content, protein synthetic rate, cell cycle distribution or cell size. The rapid (12 hr) and reversible induction of internal and external receptors by Desferal was inhibited by cycloheximide and therefore may have resulted from de novo synthesis and not just mobilization of internal receptor pool to the cell surface. The correlation between growth rate and TfR expression previously observed in these and other cells must be secondary to cellular mechanisms that maintain intracellular iron pools by regulating synthesis, recycling, and cell surface expression of TfRs.     

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.     

Iron uptake and heme synthesis by isolated rat liver mitochondria. Diferric transferrin as iron donor and the effect of pyrophosphate

Isolated rat liver mitochondria accumulate iron from fully saturated transferrin at neutral pH. With 5 microM iron as diferric transferrin, accumulation at 30 degrees C amounts to approx. 40 pmol/mg protein per h. With access to a suitable porphyrin substrate, 70-80% of the amount of iron accumulated is recovered in heme. Mobilization of iron and synthesis of heme both depend on a functioning respiratory chain. Vacant iron-binding sites on mono- and apotransferrin compete with the mitochondria for iron mobilized from transferrin. Pyrophosphate at concentrations in the range 10-50 microM enhances mobilization of iron, counterbalances the inhibitory effect of mono- and apotransferrin and enhances metallochelatase activity. The results emphasize the putative suitability of pyrophosphate as an intracellular iron-transport ligand in situ.     

The role of metals in the enzymatic and nonenzymatic oxidation of epinephrine

The effects of transition metals on nonenzymatic and ceruloplasmin catalyzed epinephrine oxidation were investigated by studying rates of epinephrine oxidation in purified buffers and in the presence of metal chelating agents. We found that epinephrine does not “autoxidize” in sodium chloride solutions prepared with deionized water that was further purified by chromatography over Chelex 100 resin prior to use. Epinephrine was oxidized rapidly in sodium chloride prepared with tap water (1.20±0.12 nmoles/min) or in deionized water (0.40±0.80 nmoles/min), but this oxidation was prevented by the addition of Desferal, a potent metal chelating agent. Epinephrine oxidation was enhanced upon the addition of ceruloplasmin, and this oxidation rate could be slowed, but not eliminated, by the addition of Desferal. If epinephrine solutions were preincubated for 72 hours with Desferal prior to ceruloplasmin addition, however, no oxidation was observed. Epinephrine was shown to form colored complexes with both iron and copper at pH 7.0. The Fe(III)-epinephrine complex was much more stable than was the Cu(II)-epinephrine complex. Oxygen consumption studies of ceruloplasmin catalyzed epinephrine oxidation showed that copper was a better promoter of epinephrine oxidation than was iron, suggesting that ceruloplasmin-catalyzed epinephrine oxidation results from adventitious copper bound to the purified enzyme. In light of these results, the physiological relevance of ceruloplasmin catalyzed oxidation of biogenic amines may be minor.     

Regulation of heme synthesis in the regenerating rat liver

This investigation shows that the regulation of heme synthesis in the regenerating rat liver does not differ from the regulation in the normal liver. The heme saturation of tryptophan pyrrolase was found to be low, indicating a reduced concentration of heme in the regulatory heme pool of the regenerating rat liver. As expected, ALAS in the mitochondrial fraction was found to be elevated. It was also shown that ALAS in the regenerating rat liver can be induced by the porphyrinogenic drugs AIA and DDC and that heme reduces its activity. The decrease observed in the activity of cytosolic ALAS might be due to impaired synthesis of the enzyme but does not affect the regulation of the heme biosynthetic pathway.     

Control of heme synthesis during Friend cell differentiation: role of iron and transferrin

In many types of cells the synthesis of delta-aminolevulinic acid (ALA) limits the rate of heme formation. However, results from our laboratory with reticulocytes suggest that the rate of iron uptake from transferrin (Tf), rather than ALA synthase activity, limits the rate of heme synthesis in erythroid cells. To determine whether changes occur in iron metabolism and the control of heme synthesis during erythroid cell development Friend erythroleukemia cells induced to erythroid differentiation by dimethylsulfoxide (DMSO) were studied. While added ALA stimulated heme synthesis in uninduced Friend cells (suggesting ALA synthase is limiting) it did not do so in induced cells. Therefore the possibility was investigated that, in induced cells, iron uptake from Tf limits and controls heme synthesis. Several aspects of iron metabolism were investigated using the synthetic iron chelator salicylaldehyde isonicotinoyl hydrazone (SIH). Both induced and uninduced Friend cells take up and utilize Fe for heme synthesis directly from Fe-SIH without the involvement of transferrin and transferrin receptors and to a much greater extent than from saturating levels of Fe-Tf (20 microM). Furthermore, in induced Friend cells 100 microM Fe-SIH stimulated 2-14C-glycine incorporation into heme up to 3.6-fold as compared to the incorporation observed with saturating concentrations of Fe-Tf. In contrast, Fe-SIH, even when added in high concentrations, did not stimulate heme synthesis in uninduced Friend cells but was able to do so as early as 24 to 48 h following induction. In addition, contrary to previous results with rabbit reticulocytes, Fe-SIH also stimulated globin synthesis in induced Friend cells above the level seen with saturating concentrations of transferrin. These results indicate that some step(s) in the pathway of iron from extracellular Tf to protoporphyrin, rather than the activity of ALA synthase, limits and controls the overall rate of heme and possibly hemoglobin synthesis in differentiating Friend erythroleukemia cells.     

Transferrin binding and iron uptake in mouse hepatocytes

Methods were developed for obtaining highly viable mouse hepatocytes in single cell suspension and for maintaining the hepatocytes in adherent static culture. The characteristics of transferrin binding and iron uptake into these hepatocytes was investigated. (1) After attachment to culture dishes for 18–24 h hepatocytes displayed an accelerating rate of iron uptake with time. Immediately after isolation mouse hepatocytes in suspension exhibited a linear iron uptake rate of 1.14·10⁵molecules/cell per min in 5 μM transferrin. Iron uptake also increased with increasing transferrin concentration both in suspension and adherent culture. Pinocytosis measured in isolated hepatocytes could account only for 10–20% of the total iron uptake. Iron uptake was completely inhibited at 4°C. (2) A transferrin binding component which saturated at 0.5 μM diferric transferrin was detected. The number of specific, saturable diferric transferrin binding sites on mouse hepatocytes was 4.4·10⁴±1.9·10⁴ for cells in suspension and 6.6·10⁴±2.3·10⁴ for adherent cultured cells. The apparent association constants were 1.23·10⁷ 1·mol^?1 and 3.4·10⁶ 1·mol^?1 for suspension and cultured cells respectively. (3) Mouse hepatocytes also displayed a large component of non-saturable transferrin binding sites. This binding increased linearly with transferrin concentration and appeared to contribute to iron uptake in mouse hepatocytes. Assuming that only saturable transferrin binding sites donate iron, the rate of iron uptake is about 2.5 molecules iron/receptor per min at 5 μM transferrin in both suspension and adherent cells and increases to 4 molecules iron/receptor per min at 10 μM transferrin in adherent cultured cells. These rates are considerably greater than the 0.5 molcules/receptor per min observed at 0.5 μM transferrin, the concentration at which the specific transferrin binding sites are fully occupied. The data suggest that either the non-saturable binding component donates some iron or that this component stimulates the saturable component to increase the rate of iron uptake. (4) During incubations at 4°C the majority of the transferrin bound to both saturable and nonsaturable binding sites lost one or more iron atoms. Incubations including 2 mM α,α′-dipyridyl (an Fe¹¹ chelator) decreased the cell associated ⁵⁹Fe at both 4 and 37°C while completely inhibiting iron uptake within 2–3 min of exposure at 37°C. These observations suggest that most if not all iron is loosened from transferrin upon interaction of transferrin with the hepatocyte membrane. There is also greater sensitivity of ⁵⁹Fe uptake compared to transferrin binding to pronase digestion, suggesting that an iron acceptor moiety on the cell surface is available to proteolysis.     

Iron metabolism in K562 erythroleukemic cells

Iron delivery to K562 cells is enhanced by desferrioxamine through induction of transferrin receptors. Experiments were performed to further characterize this event with respect to iron metabolism and heme synthesis. In control cells, up to 85% of the iron taken up from iron-transferrin was incorporated into ferritin, 7% into heme, and the remainder into compartments not yet identified. In cells grown with desferrioxamine, net accumulation of intracellular desferrioxamine (14-fold) was observed and iron incorporation into ferritin and heme was inhibited by 86% and 75%, respectively. In contrast, complete inhibition of heme synthesis in cells grown with succinylacetone had no effect on transferrin binding or iron uptake. Exogenous hemin (30 microM) inhibited transferrin binding and iron uptake by 70% and heme synthesis by 90%. These effects were already evident after 2 h. Thus, although heme production could be reduced by desferrioxamine, succinylacetone, and hemin, cell iron uptake was enhanced only by the intracellular iron chelator. The effects of exogenous heme are probably unphysiologic and the greater inhibition of iron flow into heme can be explained by effects on early steps of heme synthesis. We conclude that in this cell model a chelatable intracellular iron pool rather than heme synthesis mediates regulation of iron uptake.     

Induction of aminolevulinate synthase and porphyrins in cultured liver cells maintained in chemically defined medium. Permissive effects of hormones on induction process.

Primary liver cells, isolated from 16- 17-day-old chick embryos, were incubated in a serum-free chemically defined medium (Ham's F12) supplemented with hormones for up to 6 days. The culture method also includes the complete removal of contaminating red cells before the initiation of culture. On the 2nd day in cluture, the level of amino-levulinate (ALA) synthase activity in response to allylisopropylacetamide (AIA) was increased 6-fold in cells grown in F12. Insulin, hydrocortisone, and triiodothyronine alone had no appreciable effects on ALA synthase levels. On the other hand, when added with AIA, insulin, insulin plus hydrocortisone, insulin plus hydrocortisone triiodothyronine increased ALA synthase levels 17-, 50-, 110-fold, respectively. The maximally induced levels of ALA synthase activity by AIA in the presence of insulin, hydrocortisone, and triiodothyronine were approximately 15 nmol of ALA/mg of protein/h, 37 degrees or 3 micronmol of ALA/g of tissue/h, 37 degrees, a value similar to that found in ovo or at least 5 times greater than that found in rat liver. The morphology of hepatocytes was maintained for at least 6 days in culture, although the induction of ALA synthase was reduced after the 4th day unless triiodothyronine was present. Dibutyryl adenosine 3':5'-monophosphate (10(8) M) or glucagon (5x10(8) M) had little effect on the induced as well as noninduced levels of ALA synthase or porphyrins. These data demonstrate a "permissive" effect of insulin, hydrocortisone, and triiodothyronine on the induction of ALA synthase and porphyrins by AIA in cultured chick embryo liver cells. In the absence of insulin hydrocortisone, or triiodothyronine, AIA produces only a slight increase in ALA synthase activity or porphyrins (or both); on the other hand, it produces a marked increase in the enzyme activity and porphyrins when these hormones are added to the culture medium. The term "permissive" is applied to these hormone-dependent effects. A sensitive spectrofluorometric method for heme quantitation allowed us to follow changes in the cellular heme content in hemoglobin-free cultured liver cells. Heme content in the cultured liver cells was approximately 250 pmol/mg of protein at the initiation of culture but gradually declined to 175 pmol/mg of protein at the initiation of culture but gradually declined to 175 pmol/mg of protein during 48 h of incubation. The apparent decrease in heme content may be accounted for by the concomitant increase in protein content in these cells.     

Iron accumulation and neurotoxicity in cortical cultures treated with holotransferrin

Nonheme iron accumulates in CNS tissue after ischemic and hemorrhagic insults and may contribute to cell loss. The source of this iron has not been precisely defined. After blood-brain barrier disruption, CNS cells may be exposed to plasma concentrations of transferrin-bound iron (TBI), which exceed that in the CSF by over 50-fold. In this study, the hypothesis that these concentrations of TBI produce cell iron accumulation and neurotoxicity was tested in primary cortical cultures. Treatment with 0.5-3 mg/ml holotransferrin for 24 h resulted in the loss of 20-40% of neurons, associated with increases in malondialdehyde, ferritin, heme oxygenase-1, and iron; transferrin receptor-1 expression was reduced by about 50%. Deferoxamine, 2,2′-bipyridyl, Trolox, and ascorbate prevented all injury, but apotransferrin was ineffective. Cell TBI accumulation was significantly reduced by deferoxamine, 2,2′-bipyridyl, and apotransferrin, but not by ascorbate or Trolox. After treatment with ⁵⁵Fe-transferrin, approximately 40% of cell iron was exported within 16 h. Net export was increased by deferoxamine and 2,2′-bipyridyl, but not by apotransferrin. These results suggest that downregulation of transferrin receptor-1 expression is insufficient to prevent iron-mediated death when neurons are exposed to plasma concentrations of TBI. Chelator therapy may be beneficial for acute CNS injuries associated with loss of blood-brain barrier integrity.     

Kinetics and Specificity of Feline Leukemia Virus Subgroup C Receptor (FLVCR) Export Function and Its Dependence on Hemopexin

The feline leukemia virus subgroup C receptor (FLVCR) is a heme export protein that is required for proerythroblast survival and facilitates macrophage heme iron recycling. However, its mechanism of heme export and substrate specificity are uncharacterized. Using [⁵⁵Fe]heme and the fluorescent heme analog zinc mesoporphyrin, we investigated whether export by FLVCR depends on the availability and avidity of extracellular heme-binding proteins. Export was 100-fold more efficient when the medium contained hemopexin (K_d < 1 pm) compared with albumin (K_d = 5 nm) at the same concentration and was not detectable when the medium lacked heme-binding proteins. Besides heme, FLVCR could export other cyclic planar porphyrins, such as protoporphyrin IX and coproporphyrin. However, FLVCR has a narrow substrate range because unconjugated bilirubin, the primary breakdown product of heme, was not transported. As neither protoporphyrin IX nor coproporphyrin export improved with extracellular hemopexin (versus albumin), our observations further suggest that hemopexin, an abundant protein with a serum concentration (6.7–25 μm) equivalent to that of the iron transport protein transferrin (22–31 μm), by accepting heme from FLVCR and targeting it to the liver, might regulate macrophage heme export and heme iron recycling in vivo. Final studies show that hemopexin directly interacts with FLVCR, which also helps explain why FLVCR, in contrast to some major facilitator superfamily members, does not function as a bidirectional gradient-dependent transporter. Together, these data argue that hemopexin has a role in assuring systemic iron balance during homeostasis in addition to its established role as a scavenger during internal bleeding or hemolysis.     

Effect of decreased ferrochelatase activity on iron and porphyrin content in mitochondrai of mice with porphyria induced by griseofulvin

The content of iron and protoporphyrin in liver mitochondria from mice with porphyria induced by griseofulvin was measured. The amount of porphyrin was 0.0076 ± 0.0043, 4.11 ± 0.58 and 22.2 ± 6.8 nmol/mg protein (n = 5) in mitochondria from control animals and animals treated with griseofulvin for 3 days and 4–5 weeks, respectively. The energy coupling of the mitochondia was greatly diminished after 4–5 weeks of treatment, and the ferrochelatase activity was inhibited 80–90%, compared to that of control animals. Mitochondrial preparations isolated by differential centrifugation were contaminated with iron-containing lysosomes which could be removed by Percoll density-gradient centrifugation. In purified mitochondrial preparations no change in the amount of non-heme iron was found after griseofulvin feeding, representing 3.36±0.15, 3.97±0.40 and 3.59±0.23 nmol/mg protein for control animals, 3 days- and 4–5 weeks-treated animals, respectively (n = 4). A mitochondrial iron pool previously identified in rat liver mitochondria and shown to be available for heme synthesis in vitro (Tangerås, A. (1985)) Biochim. Biophys. Acta 843 199–207) was also present in mitochondria from mice. The magnitude of this iron pool, as well as its availability for heme synthesis, was not changed after treatment of the animals with griseofulvin. The fact that porphyrin, but not iron, accumulated in the mitochondria when ferrochelatase was inhibited is discussed with regard to our understanding of the process of heme synthesis and its regulation.     

Spectroscopic evidence of interaction between 2-allyl-2-isopropylacetamide and cytochrome P-450 of rat liver microsomes

2-allyl-2-isopropylacetamide (AIA) causes marked induction of heme synthesis in rats and other species, degrades cytochrome P-450 in the presence of NADPH and causes experimental porphyria. Using difference spectroscopy we sought evidence of an interaction between AIA and P-450 in microsomes prepared from rat liver. AIA alone caused small and variable changes in the spectral properties of liver microsomes but markedly inhibited the Type I spectral change due to hexobarbitone. Phenobarbitone exhibited behaviour qualitatively similar to AIA. It is concluded that AIA binds to cytochrome P-450 without much altering its spectral properties but in such a way as to prevent the change induced by the Type I substrate hexobarbitone.     

Hemosiderin An EPR study of water-insoluble iron in human and rat liver

EPR spectra of the water-insoluble iron fraction, hemosiderin of human and rat liver are described. The homogenate of freshly prepared perfused rat liver shows a non-heme iron signal at g = 4.3 and a high-spin heme-iron signal around g = 6, whereas the washed and sonicated sample of the insoluble iron fraction shows solely a non-heme iron signal at g = 4.3. This indicates that hemosiderin from rat liver does not contain heme iron.Human-liver preparations from post mortem obtained material show in the homogenates as well as in the washed and sonicated samples an intense high-spin heme iron signal at g = 6.0 and a non-heme iron signal at g = 4.3. A comparative experiment, carried out with “aged” rat liver preparations, reveals the same spectra as with the human preparations. It is concluded that the heme present in the insoluble iron fraction is caused by degradation of hemoglobin in the obduction material, and that heme is not a constituent of the insoluble depot iron.     

Hemosiderin. an EPR study of water-insoluble iron in human and rat liver.

EPR spectra of the water-insoluble iron fraction, hemosiderin of human and rat liver are described. The homogenate of freshly prepared perfused rat liver shows a non-heme iron signal at g=4.3 and a high-spin heme-iron signal around g=6, whereas the washed and sonicated sample of the insoluble iron fraction shows solely a non-heme iron signal at g=4.3. This indicates that hemosiderin from rat liver does not contain heme iron. Human-liver preparations from post mortem obtained material show in the homogenates as well as in the washed and sonicated samples an intense high-spin heme iron signal at g=6.0 and a non-heme iron signal at g=4.3. A comparative experiment, carried out with "aged" rat liver preparations, reveals the same spectra as with the human preparations. It is concluded that that the heme present in the insoluble iron fraction is caused by degradation of hemoglobin in the obduction material, and that heme is not a constituent of the insoluble depot iron.