Heme carrier protein 1 transports heme and is involved in heme-Fe metabolism

Heme-Fe is an important source of dietary iron in humans; however, the mechanism for heme-Fe uptake by enterocytes is poorly understood. Heme carrier protein 1 (HCP1) was originally identified as mediating heme-Fe transport although it later emerged that it was a folate transporter. We asked what happened to heme-Fe and folate uptake and the relative abundance of hcp1 and ho1 mRNA in Caco-2 cells after knockdown by transfection with HCP1-directed short hairpin (sh)RNA. Control Caco-2 cells were cultured in bicameral chambers with 0-80 μM heme-Fe for selected times. Intracellular Fe and heme concentration increased in Caco-2 cells reflecting higher external heme-Fe concentrations. Maximum Fe, heme, and heme oxygenase 1 (HO1) expression and activity were observed between 12 and 24 h of incubation. Quantitative RT-PCR for hcp1 revealed that its mRNA decreased at 20 μM heme-Fe while ho1 mRNA and activity increased. When shRNA knocked down hcp1 mRNA, heme-(55)Fe uptake and [(3)H]folate transport mirrored the mRNA decrease, ho1 mRNA increased, and flvcr mRNA was unchanged. These data argue that HCP1 is involved in low-affinity heme-Fe uptake not just in folate transport.     

Biosynthesis of heme in immature erythroid cells. The regulatory step for heme formation in the human erythron

Heme formation in reticulocytes from rabbits and rodents is subject to end product negative feedback regulation: intracellular "free" heme has been shown to control acquisition of transferrin iron for heme synthesis. To identify the site of control of heme biosynthesis in the human erythron, immature erythroid cells were obtained from peripheral blood and aspirated bone marrow. After incubation with human 59Fe transferrin, 2-[14C]glycine, or 4-[14C]delta-aminolevulinate, isotopic incorporation into extracted heme was determined. Addition of cycloheximide to increase endogenous free heme, reduced incorporation of labeled glycine and iron but not delta-aminolevulinate into cell heme. Incorporation of glycine and iron was also sensitive to inhibition by exogenous hematin (Ki, 30 and 45 microM, respectively) i.e. at concentrations in the range which affect cell-free protein synthesis in reticulocyte lysates. Hematin treatment rapidly diminished incorporation of intracellular 59Fe into heme by human erythroid cells but assimilation of 4-[14C]delta-aminolevulinate into heme was insensitive to inhibition by hematin (Ki greater than 100 microM). In human reticulocytes (unlike those from rabbits), addition of ferric salicylaldehyde isonicotinoylhydrazone, to increase the pre-heme iron pool independently of the transferrin cycle, failed to promote heme synthesis or modify feedback inhibition induced by hematin. In human erythroid cells (but not rabbit reticulocytes) pre-incubation with unlabeled delta-aminolevulinate or protoporphyrin IX greatly stimulated utilization of cell 59Fe for heme synthesis and also attenuated end product inhibition. In human erythroid cells heme biosynthesis is thus primarily regulated by feedback inhibition at one or more steps which lead to delta-aminolevulinate formation. Hence in man the regulatory process affects generation of the first committed precursor of porphyrin biosynthesis by delta-aminolevulinate synthetase, whereas in the rabbit separate regulatory mechanisms exist which control the incorporation of iron into protoporphyrin IX.     

Effects of dietary factors on iron uptake from ferritin by Caco-2 cells

Biofortification of staple foods with iron (Fe) in the form of ferritin (Ft) is now possible, both by conventional plant breeding methods and transgenic approaches. Ft-Fe from plants and animals is absorbed well (25-30%) by human subjects, but little is known about dietary factors affecting its absorption. We used human intestinal Caco-2 cells and compared Fe absorption from animal Ft and FeSO4 to determine the effects of inhibitors and enhancers, such as phytic acid, ascorbic acid, tannic acid, calcium and heme. When postconfluent cells were coincubated with 59Fe-labeled (1 microM) FeSO4 and dietary factors, at different molar ratios of dietary factor to Fe (phytic acid:Fe, 10:1; ascorbic acid:Fe, 50:1; tannic acid:Fe, 50:1; calcium:Fe, 10:1 and hemin:Fe, 10:1), all inhibited uptake from FeSO4, except ascorbate, confirming earlier studies. In contrast, these dietary factors had little or no effect on Fe uptake from undigested Ft or Ft digested in vitro at pH 4, except tannins. However, results after in vitro digestion of Ft at pH 2 were similar to those obtained for FeSO4. These results suggest that Fe uptake occurs from both undigested as well as digested Ft but, possibly, via different mechanisms. The Fe-Ft stability shown here could minimize Fe-induced oxidation of Fe-supplemented food products.     

Acquisition of iron from transferrin regulates reticulocyte heme synthesis

Fe-salicylaldehyde isonicotinoylhydrazone (SIH), which can donate iron to reticulocytes without transferrin as a mediator, has been utilized to test the hypothesis that the rate of iron uptake from transferrin limits the rate of heme synthesis in erythroid cells. Reticulocytes take up 59Fe from [59Fe]SIH and incorporate it into heme to a much greater extent than from saturating concentrations of [59Fe]transferrin. Also, Fe-SIH stimulates [2-14C]glycine into heme when compared to the incorporation observed with saturating levels of Fe-transferrin. In addition, delta-aminolevulinic acid does not stimulate 59Fe incorporation into heme from either [59Fe]transferrin or [59Fe]SIH but does reverse the inhibition of 59Fe incorporation into heme caused by isoniazid, an inhibitor of delta-aminolevulinic acid synthase. Taken together, these results suggest the hypothesis that some step(s) in the pathway of iron from extracellular transferrin to intracellular protoporphyrin limits the overall rate of heme synthesis in reticulocytes.     

Caco-2 cell line: a system for studying intestinal iron transport across epithelial cell monolayers.

Iron transport across polarized intestinal epithelium was studied by using Caco-2 cells grown in bicameral chambers. When cells were grown under conditions of low, normal, or high iron concentration not only was the iron content of the cells markedly altered but the low iron cells exhibited a nearly 2-fold increase in transepithelial electrical resistance (TEER). 59Fe uptake from the apical surface into cells and transport into the basal chamber was affected both by the valency of the iron and the iron status of the cells. Uptake from 59Fe(II)-ascorbate was about 600 pmol 59Fe/h per mg protein, increased about 2-fold in low iron cells, and was about 13-200-fold greater than uptakes from 59Fe(III) chelated to nitrilotriacetic acid, BSA, or citrate. Transport into the basal chamber from 59Fe(II)-ascorbate was 3.7 +/- 1.7 pmol/h per cm2 for Fe-deficient cells vs. 0.72 +/- 0.1 pmol/h per cm2 for normal-Fe cells and from 59Fe(III)-BSA 1.1 +/- 0.2 pmol/h per cm2 vs. 0.3 +/- 0.03 pmol/h per cm2 for deficient vs. normal iron cells, respectively. The greater transport of iron both from Fe(II) and in iron deficient cells supports the use of the Caco-2 cells as a model for iron transport.     

Heme Iron Uptake by Caco-2 Cells is a Saturable,Temperature Sensitive and Modulated by Extracellular pH and Potassium

It is known that heme iron and inorganic iron are absorbed differently. Heme iron is found in the diet mainly in the form of hemoglobin and myoglobin. The mechanism of iron absorption remains uncertain. This study focused on the heme iron uptake by Caco-2 cells from a hemoglobin digest and its response to different iron concentrations. We studied the intracellular Fe concentration and the effect of time, K⁺ depletion, and cytosol acidification on apical uptake and transepithelial transport in cells incubated with different heme Fe concentrations. Cells incubated with hemoglobin-digest showed a lower intracellular Fe concentration than cells grown with inorganic Fe. However, uptake and transepithelial transport of Fe was higher in cells incubated with heme Fe. Heme Fe uptake had a low V _max and K _m as compared to inorganic Fe uptake and did not compete with non-heme Fe uptake. Heme Fe uptake was inhibited in cells exposed to K⁺ depletion or cytosol acidification. Heme oxygenase 1 expression increased and DMT1 expression decreased with higher heme Fe concentrations in the media. The uptake of heme iron is a saturable and temperature-dependent process and, therefore, could occur through a mechanism involving both a receptor and the endocytic pathway.     

Comparative study on sodium transport and Na+,K+-ATPase activity in Caco-2 and rat jejunal epithelial cells: effects of dopamine

The present study reports on the effects of dopamine on sodium transepithelial transport and Na+,K+-ATPase activity in Caco-2 cells, a human epithelial intestinal cell line which undergoes enterocyte differentiation in culture, and jejunal epithelial cells from 20 day old Wistar rats. Addition of amphotericin B to the mucosal side stimulated Isc in a concentration dependent manner (Caco-2 cells, EC50=0.9 [0.5, 1.7] microM; rat jejunum, EC50=7.4 [0.8; 70.1] microM). The presence of 1 microM dopamine did not change the effect of amphotericin B in Caco-2 cells, but produced a significant (P<0.05) decrease in the maximal effect of amphotericin B in the rat jejunum. Dopamine (1 microM), added to the serosal side, did not change the Isc profile in Caco-2 cells, but produced a significant increase in the rat jejunum. This effect was antagonized by SKF 83566 (1 microM), but not S-sulpiride (1 microM), and was mimicked by SKF 38393 (10 nM), but not by quinerolane (10 nM). Basal Na+,K+-ATPase activity (in nmol Pi mg protein(-1) min(-1)) in Caco-2 cells (49.5+/-0.2) was similar to that observed in isolated rat jejunal epithelial cells (52.3+/-3.4). Dopamine (1 microM) significantly (P<0.05) decreased Na+,K+-ATPase activity in rat jejunal epithelial cells, but failed to inhibit Na+,K+-ATPase in Caco-2 cells. This effect of dopamine was antagonized by SKF 83566 (1 microM), but not S-sulpiride (1 microM), and was mimicked by SKF 38393 (10 nM), but not by quinerolane (10 nM). The specific binding of [3H]-Sch 23390 to the rat intestinal mucosa was saturable with an apparent dissociation constant (KD) of 2.4 (0.4; 4.5) nM and maximum receptor density of 259.8+/-32.6 fmol/mg protein. No significant specific binding of [3H]-Sch 23390 was observed in membranes from Caco-2 cells. In conclusion, the results obtained show that D1-like receptor mediated effects of dopamine in the rat jejunum on sodium absorption are absent in Caco-2 cells, most probably because this cell line does not express D1-like dopamine receptors, which ultimately are responsible for the inhibitory effect of the amine upon intestinal Na+,K+-ATPase.     

Heme oxygenase 1 overexpression increases iron fluxes in caco-2 cells

Heme oxygenase-1 is a microsomal enzyme that, when induced by stress, protects the cells from oxidative injury. Heme oxygenase-1 participates in the cleavage of the heme ring producing biliverdin, CO and ferrous Fe. The released Fe becomes part of intracellular Fe pool and can be stored in ferritin or released by an iron exporter. The mechanism by which heme enters cells is not completely understood, although it had been suggested that it might be internalized by an endocytosis process. In this study, we expressed a full-length Heme oxygenase-1 cDNA in Caco-2 cells and measured intracellular iron content, heme-iron uptake and transport and immunolocalization of heme oxygenase-1 in these cells. We found that heme oxygenasc-1 expressing cells showed increased apical heme iron uptake and transepithelial transport when compared to control cells. These results suggested that heme oxygenase-1 mediates heme iron influx and efflux in intestinal cells.     

The role of transferrin in heme transport.

Porphyrin accumulation by proliferating cells, e.g., those associated with cancers or wounds, tends to correlate with increased transferrin receptor density. To determine whether transferrin might be implicated in porphyrin transport, fluorescence and absorption spectroscopy were used to study the interaction of porphyrins with transferrin. A single high-affinity binding site for heme and other porphyrins (Kd approximately 20-25 nM) was detected by fluorescence spectroscopy. Difference spectroscopy revealed three additional heme-binding sites. These sites were distinct from the iron-binding sites: 1) Apotransferrin and diferric transferrin bound porphyrins with equal affinity; 2) 59Fe was not displaced from transferrin by porphyrins. Murine erythroleukemia cells incubated with [59Fe]hemin-[125I]transferrin internalized both labels concomitantly. Accumulation of [59Fe]hemin could be blocked by a 100-fold excess of diferric transferrin but not by apotransferrin. These results indicate that cells can internalize exogenous heme, and possibly porphyrins, bound to transferrin via its receptor.     

The hemopexin receptor on the cell surface of human polymorphonuclear leukocytes

Promyelocytic leukemia HL-60 cells can be induced to differentiate to granulocytes, under the conditions of cultures in the presence of dimethyl sulfoxide (DMSO). Examination of the binding of 125I-labeled hemopexin to DMSO-induced HL-60 cells showed that the density of hemopexin receptors on the induced-cells was 1.35 times that on the uninduced cells. We proposed that a specific receptor for hemopexin was present on the plasma membranes of polymorphonuclear leukocytes (PMNs). The binding of human [125I]hemopexin to human PMNs at 4 degrees C was saturable with time and with increasing concentrations of [125I]hemopexin. Scatchard analysis of the binding revealed the presence of approximately 5.7 x 10(4) binding sites per cell with an apparent dissociation constant (Kd) of 2.3 x 10(-9) M. [125I]Hemopexin was rapidly bound then dissociated from the cells after the release of heme, when the cells were incubated with radioactive hemopexin at 37 degrees C. Incubation of the cells with the [59Fe]heme-hemopexin complex resulted in an accumulation of [59Fe]heme in the cells, with a temperature of 37 degrees C but not that of 4 degrees C. Ouabain or NaF inhibited not only the binding of [125I]hemopexin to PMNs but also the uptake of [59Fe]heme from [59Fe]heme hemopexin by the cells. Neither NH4 Cl nor chloroquine inhibited the uptake. Detergent extracts of 125I-labeled PMNs were incubated with a hemopexin-coupled Sepharose CL-6B. A polypeptide reacting with hemopexin-Sepharose was estimated to have a molecular weight of 80,000, as determined by polyacrylamide gel electrophoresis, in the presence of sodium dodecylsulfate. We propose that PMNs take up heme from hemopexin, as mediated by the 80,000 dalton receptor for hemopexin.     

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.     

Hepatic subcellular metabolism of heme from heme-hemopexin: incorporation of iron into ferritin

The subcellular distribution and metabolic fate of [⁵⁹Fe]heme-[¹²⁵I]-labeled hemopexin after receptor-mediated interaction with the liver was examined in the rat. After intravenous injection, [⁵⁹Fe]heme from the complex and ⁵⁹Fe from hepatic catabolism of this heme accumulate in the liver and undergo changes in their subcellular distribution over 2 hours. The amounts of [⁵⁹Fe]heme and particularly of ⁵⁹Fe increase in the cytosol while remaining constant or decreasing in membranous fractions. In contrast, [¹²⁵I]-labeled hemopexin associated with the liver during heme transport is always a small fraction of the dose and is not measurably catabolized under these conditions.Gel filtration of the cytosol showed that ⁵⁹Fe increased linearly with time in a high molecular weight fraction which was identified immunologically as ferritin. We conclude that heme transported by hemopexin is metabolized by the liver and the iron conserved.     

Proposing a Caco-2/HepG2 cell model for in vitro iron absorption studies

The Caco-2 cell line is well established as an in vitro model for iron absorption. However, the model does not reflect the regulation of iron absorption by hepcidin produced in the liver. We aimed to develop the Caco-2 model by introducing human liver cells (HepG2) to Caco-2 cells. The Caco-2 and HepG2 epithelia were separated by a liquid compartment, which allowed for epithelial interaction. Ferritin levels in cocultured Caco-2 controls were 21.7±10.3 ng/mg protein compared to 7.7±5.8 ng/mg protein in monocultured Caco-2 cells. The iron transport across Caco-2 layers was increased when liver cells were present (8.1%±1.5% compared to 3.5%±2.5% at 120 μM Fe). Caco-2 cells were exposed to 0, 80 and 120 μM Fe and responded with increased hepcidin production at 120 μM Fe (3.6±0.3 ng/ml compared to 2.7±0.3 ng/ml). The expression of iron exporter ferroportin in Caco-2 cells was decreased at the hepcidin concentration of 3.6 ng/ml and undetectable at external addition of hepcidin (10 ng/ml). The apical transporter DMT1 was also undetectable at 10 ng/ml but was unchanged at the lower concentrations. In addition, we observed that sourdough bread, in comparison to heat-treated bread, increased the bioavailability of iron despite similar iron content (53% increase in ferritin formation, 97% increase in hepcidin release). This effect was not observed in monocultured Caco-2 cells. The Caco-2/HepG2 model provides an alternative approach to in vitro iron absorption studies in which the hepatic regulation of iron transport must be considered.     

Heme transport exhibits polarity in Caco-2 cells: evidence for an active and membrane protein-mediated process

Heme prosthetic groups are vital for all living organisms, but they can also promote cellular injury by generating reactive oxygen species. Therefore, intestinal heme absorption and distribution should be carefully regulated. Although a human intestine brush-border heme receptor/transporter has been suggested, the mechanism by which heme crosses the apical membrane is unknown. After it enters the cell, heme is degraded by heme oxygenase-1 (HO-1), and iron is released. We hypothesized that heme transport is actively regulated in Caco-2 cells. Cells exposed to hemin from the basolateral side demonstrated a higher HO-1 induction than cells exposed to hemin from the apical surface. Hemin secretion was more rapid than absorption, and net secretion occurred against a concentration gradient. Treatment of the apical membrane with trypsin increased hemin absorption by threefold, but basolateral treatment with trypsin had no effect on hemin secretion. Neither apical nor basolateral trypsin changed the paracellular pathway. We conclude that heme is acquired and transported in both absorptive and secretory directions in polarized Caco-2 cells. Secretion is via an active metabolic/transport process. Trypsin applied to the apical surface increased hemin absorption, suggesting that protease activity can uncover a process for heme uptake that is otherwise quiescent. These processes may be involved in preventing iron overload in humans.     

Mobilization of ferritin iron in erythroblasts by chelating agents

Intracellular ferritin in newt (Triturus cristatus) erythroblasts was accessible to the chelating effects of EDTA and pyridoxal phosphate. EDTA (0.5-1 mM) promoted release of radioactive iron from ferritin of pulse-labelled erythroblasts during chase incubation, but its continuous presence was not necessary for ferritin iron mobilization. Brief exposure to EDTA was sufficient to release 60-70% of ferritin 59Fe content during ensuing chase in EDTA-free medium. EDTA also suppressed cellular iron uptake and utilization for heme synthesis, but these activities were restored upon its removal. Pyridoxal-5'-phosphate (0.5-5 mM) also stimulated loss of radioactive iron from ferritin; however, ferritin iron release by pyridoxal phosphate required its continued presence. Unlike EDTA, pyridoxal phosphate did not interfere with iron uptake or its utilization for heme synthesis. Chelator-mobilized ferritin iron accumulated initially in the hemolysate as a low-molecular-weight component and appeared to be eventually released into the medium. No radioactive ferritin was found in the medium of chelator-treated cells, indicating that secretion or loss of ferritin was not responsible for decreasing cellular ferritin 59Fe content. Moreover, there was no transfer of radioactive iron between the low-molecular-weight component released into the medium and plasma transferrin. These results indicate that chelator-released ferritin iron is not available for cellular utilization in heme synthesis and that ferritin iron released by this process is not an alternative or complementary iron source for heme synthesis. Correlation of these data with effects of succinylacetone inhibition of heme synthesis and with previous studies indicates that the main role of erythroid cell ferritin is absorption and storage of excess iron not used for heme synthesis.     

Cell surface receptor for hemopexin in human leukemia HL60 cells. Specific binding, affinity labeling, and fate of heme

The binding of 125I-labeled human hemopexin to human leukemia HL60 cell at 4 degrees C was saturable with time and with increasing concentrations of 125I-hemopexin. Scatchard analysis of the binding data revealed the presence of approximately 42,000 binding sites/cell with an apparent dissociation constant (Kd) of 1.0 X 10(-9) M. When cells were incubated with radioactive hemopexin at 37 degrees C, 125I-hemopexin was rapidly bound and then was dissociated after the release of heme. Treatment of surface-bound 125I-hemopexin with divalent lysine-directed cross-linking disuccinimidyl suberate revealed a membrane polypeptide of about 80,000 Da, to which hemopexin is cross-linked. To examine the fate of the internalized heme, lysates from the cells previously incubated with [59Fe]heme-hemopexin complex were analyzed by CM-cellulose and Sephacryl S-200 column chromatography. A considerable amount of the radioactivity was present in the fraction which co-eluted with the myeloperoxidase activity. When myeloperoxidase was isolated from the cells incubated with [59Fe]heme-hemopexin complex by immunoprecipitation with anti-myeloperoxidase antibody, radiolabeled iron associated with myeloperoxidase increased with time, and more than 30% of the radioactivity in the cells was present in the myeloperoxidase. These results indicate that the binding of hemopexin to the surface receptors triggers a release of heme and that this heme is incorporated into the intracellular myeloperoxidase.     

Caco-2 Cell Acquisition of Dietary Iron(III) Invokes a Nanoparticulate Endocytic Pathway

Dietary non-heme iron contains ferrous [Fe(II)] and ferric [Fe(III)] iron fractions and the latter should hydrolyze, forming Fe(III) oxo-hydroxide particles, on passing from the acidic stomach to less acidic duodenum. Using conditions to mimic the in vivo hydrolytic environment we confirmed the formation of nanodisperse fine ferrihydrite-like particles. Synthetic analogues of these (~ 10 nm hydrodynamic diameter) were readily adherent to the cell membrane of differentiated Caco-2 cells and internalization was visualized using transmission electron microscopy. Moreover, Caco-2 exposure to these nanoparticles led to ferritin formation (i.e., iron utilization) by the cells, which, unlike for soluble forms of iron, was reduced (p=0.02) by inhibition of clathrin-mediated endocytosis. Simulated lysosomal digestion indicated that the nanoparticles are readily dissolved under mildly acidic conditions with the lysosomal ligand, citrate. This was confirmed in cell culture as monensin inhibited Caco-2 utilization of iron from this source in a dose dependent fashion (p<0.05) whilet soluble iron was again unaffected. Our findings reveal the possibility of an endocytic pathway for acquisition of dietary Fe(III) by the small intestinal epithelium, which would complement the established DMT-1 pathway for soluble Fe(II).     

Iron utilization in rabbit reticulocytes: A study using succinylacetone as an inhibitor of heme synthesis

We have investigated the effect of succinylacetone (4,6-dioxoheptanoic acid) on hemoglobin synthesis and iron metabolism in reticulocytes. Succinylacetone, 0.1 and 1 mM, inhibited [2-¹⁴C]glycine incorporation into heme by 91.2 and 96.4%, respectively, and into globin by 85 and 90.2%, respectively. 60 μM hemin completely prevented the inhibition of globin synthesis by succinylacetone, indicating that succinylacetone inhibits specifically the synthesis of heme. Added porphobilinogen, but not δ-aminolevulinic acid, partly overcame the inhibition of ⁵⁹Fe incorporation into heme caused by succinylacetone suggesting that the drug inhibits δ-aminolevulinic acid dehydratase in reticulocytes. Succinylacetone, 10 μM, 0.1 and 1 mM, inhibited ⁵⁹Fe incorporation into heme by 50, 90 and 93%, respectively, but stimulated reticulocyte ⁵⁹Fe uptake by about 25–30%. In succinylacetone-treated cells ⁵⁹Fe accumulates in a fraction containing plasma membranes and mitochondria as well as cytosol ferritin and an unidentified low molecular weight fraction obtained by Sephacryl S-200 chromatography. Reincubation of washed succinylacetone- and ⁵⁹Fe-transferrin-pretreated reticulocytes results in the transfer of ⁵⁹Fe from the particulate fraction (plasma membrane plus mitochondria) into hemoglobin and this process is considerably stimulated by added protoporphyrin. Although the nature of the iron accumulated in the membrane-mitochondria fraction in succinylacetone-treated cells is unknown some of it is utilizable for hemoglobin synthesis, while cytosolic ferritin iron would appear to be mostly unavailable for incorporation into heme.     

Ferritin is not a required intermediate for iron utilization in heme synthesis

Pulse-chase analysis of newt (Triturus cristatus) erythroblasts has shown that ferritin is not a primary source of iron for heme synthesis. During chase incubation with and without non-radioactive plasma iron in the medium, no transfer of 59Fe from ferritin to hemoglobin was detected although the integrity of heme synthesis was maintained. In puromycin-inhibited cells where iron uptake was drastically curtailed, heme synthesis continued to occur, though at reduced levels; incorporation of 59Fe from the plasma appeared initially in heme and hemoglobin without any prior labelling of ferritin. These results indicate that ferritin is neither an obligatory iron intermediate in heme synthesis nor a cytosolic transport molecule involved in mobilization of iron from the transferrin-receptor complex. The most likely role for erythroid ferritin is storage of excess iron.     

Immunochemical analysis of respiratory-chain components of micrococcus luteus (lysodeikticus).

Membrane-bound antigens of the respiratory chain of Micrococcus luteus were analyzed by crossed immunoelectrophoresis after growth of the organism in the presence of 59Fe, the flavin adenine dinucleotide-flavin mononucleotide precursor D-[2-14C]riboflavin, or the heme precursor 5-amino-[4-(14)C]levulinic acid. Using zymograms and procedures of selective extraction in conjunction with autoradiography, it was possible to resolve and partially characterize a number of antigens. Succinate dehydrogenase (EC 1.3.99.1) was shown to possess covalently bound flavin and nonheme iron and was possibly present as a complex with cytochrome. Three other dehydrogenases, namely, NADH dehydrogenase, NAD(P)H dehydrogenase (EC 1.6.99.3), and malate dehydrogenase (EC 1.1.1.37), contained flavin in noncovalent linkage, the NAD(P)H dehydrogenase also possessing nonheme iron. Four other discrete antigens (or antigen complexes) containing both iron and heme centers also resolved, as were two minor immunogens possessing iron as the sole detectable prosthetic group.