Regulation of intracellular iron distribution in K562 human erythroleukemia cells

TNF-alpha gene polymorphism and its relation to vitamin D, calcium, alkaline phosphatase and ferritin status in Iraqi beta thalassemia patients

Introduction and Aim: Due to a lack of effective medications, beta-thalassemia is a serious issue in Iraq. Thus, the current investigation aimed to explore the relationship between TNF-alpha gene polymorphism G/A (rs 1800629), Vitamin D (Vit D), Calcium (Ca), alkaline phosphatase (ALP), and ferritin status in Iraqi beta thalassemia major and intermediate patients.   Materials and Methods: Blood samples were collected from 46 patients suffering from thalassemia major (TM) plus 48 patients suffering from thalassemia intermediate (TI) and 48 of apparently healthy volunteers as control group aged 18-60 years, from Ibn Al-Baladi Hospital, Baghdad.   Results: Studies for the distribution of TNF- alpha G/A (rs 1800629) genotype showed that among TM patients and TI patients, the prevalence of the mutant AA genotype (rs 1800629) was higher in TM patients, while in the control group, it was lower.  Similarly, for the wild genotype (GG), the prevalence was highest in control group followed by T1 and TM patients. The frequency of A allele was high in TM patients, while the G allele frequency was more in the control group. Results also showed that the TNF- alpha genotype variations influenced Vitamin D, Calcium, ALP, and ferritin levels in TM and TI patients, wherein the patients with TNF-alpha mutant genotype (AA) were associated with highest levels of ferritin and ALP among all genotypes groups, while the patients of with TNF-alpha wild genotype (GG) were associated with high levels of Vitamin D and Calcium among all genotypes groups.   Conclusion: Patients with at least one copy of (A) allele had a higher risk of TM and TI and there was an association between the heterogeneous (GA) and mutant (AA) genotypes, also presence of (A) allele with status differences of Vit D, Ca, ALP, and ferritin in Iraqi beta thalassemia major and intermediate patients.

Detection and functional analysis of an SNP in the promoter of the human ferritin H gene that modulates the gene expression

The H ferritin promoter spans approximately 150 bp, upstream of the transcription start and is composed by two cis-elements in position -132 (A box) and -62 (B-box), respectively. The A box is recognized by the transcription factor Sp1, and the B-box by a protein complex called Bbf, which includes the CAAT binding factor NF-Y. In this study we performed a functional analysis of an H ferritin promoter allele carrying a G to T substitution adjacent to the Bbf binding site, in position -69. In vitro studies with reporter constructs revealed a significantly reduced transcriptional activity of this allele compared to that of the w.t. promoter that was mirrored by a decrease in Bbf binding. In vivo, this variant genotype is accompanied by a reduced amount of the H mRNA in peripheral blood lymphocytes.

Contrasting effects of excess ferritin expression on the iron-mediated oxidative stress induced by tert-butyl hydroperoxide or ultraviolet-A in human fibroblasts and keratinocytes

Iron and/or ferritin accumulation are known to occur under pathological conditions in many inflammatory skin diseases or in human skin chronically exposed to UV light. Under such conditions, ferritin is believed to play an effective protective role in accommodating and 'deactivating' excess 'free' iron produced by the inflammatory process or the UV illumination. The present study compares the relationship between ferritin over-expression and effects of an oxidative stress induced chemically by tert-butyl hydroperoxide or photochemically by UV-A radiation. As shown by immunoassay, cultured MRC 5 and HS 68 fibroblasts treated for at least one day with transferrin or overnight with non-toxic concentrations of the ferric nitrilotriacetate complex express up to 10 times more ferritin than untreated cells, whereas a five-fold increase is obtained with NCTC 2544 keratinocytes. In all cases a parallel increase in soluble cellular iron is measured by inductive plasma emission spectroscopy. The superoxide dismutase and catalase activities and total glutathione levels are not modified by the iron treatment, whereas a transient increase in the Se-dependent glutathione peroxidase activity of keratinocytes is observed after a short incubation with the iron complex. In keratinocytes and fibroblasts, ferritin over-expression after iron treatment markedly inhibits lipid peroxidation but, paradoxically, not the mortality induced by tert-butyl hydroperoxide. In contrast, this excess ferritin does not protect cells from both the peroxidation and mortality induced by moderate doses (30 J/cm2) of UV-A radiation. As a consequence, protection against oxidative damage by excess ferritin synthesis clearly depends on the nature of the oxidative stress on cell targets and it seems to be of lesser importance in the case of photochemically induced oxidation.

Translational control of specific genes during differentiation of HL-60 cells

Eukaryotic gene expression can be regulated through selective translation of specific mRNA species. Nevertheless, the limited number of known examples hampers the identification of common mechanisms that regulate translation of specific groups of genes in mammalian cells. We developed a method to identify translationally regulated genes. This method was used to examine the regulation of protein synthesis in HL-60 cells undergoing monocytic differentiation. A partial screening of cellular mRNAs identified five mRNAs whose translation was specifically inhibited and five others that were activated as was indicated by their mobilization onto polysomes. The specifically inhibited mRNAs encoded ribosomal proteins, identified as members of the 5'-terminal oligopyrimidine tract mRNA family. Most of the activated transcripts represented uncharacterized genes. The most actively mobilized transcript (termed TA-40) was an untranslated 1.3-kilobase polyadenylated RNA with unusual structural features, including two Alu-like elements. Following differentiation, a significant change in the cytoplasmic distribution of Alu-containing mRNAs was observed, namely, the enhancement of Alu-containing mRNAs in the polysomes. Our findings support the notion that protein synthesis is regulated during differentiation of HL-60 cells by both global and gene-specific mechanisms and that Alu-like sequences within cytoplasmic mRNAs are involved in such specific regulation.

Association of redox-active iron bound to high molecular weight structures in nuclei with inhibition of cell growth by H2O2

Perturbations to Fe species contributing to generation of DNA single-strand breaks (SSBs) and inhibition of growth by H2O2 were studied in HL-60 cells made Fe-deficient by 24 h pretreatment with 144 microM bathophenanthroline disulfonic acid and 400 microM ascorbic acid (Free Radic. Biol. Med. 20: 399; 1996). The diffusion distance for SSB generation (d) in Fe-deficient cells, measured via inhibition with the *OH scavenger Me2SO using alkaline elution, was 6.5 nm. This is similar to the d for Fe-normal cells reported previously. After 1 and 3 h in fresh RPMI 1640 medium containing 10% serum, SSB generation increased from 29 to 56 and 93% of control Fe-normal cells, respectively. The d of the major contributor to SSB generation at these two treatment times was 1.9 nm. This d resembled the d for Fe-ATP as determined in isolated Ehrlich cell nuclei. The association of ATP with Fe2+ was further supported by decreased SSB generation in cells in which ATP synthesis was inhibited. In contrast to SSB generation, H2O2-induced inhibition of growth of Fe-deficient cells treated immediately after placing in fresh medium was not appreciably different from Fe-normal cells. However, after 3 h, an approximately 70% greater concentration of H2O2 than for control, Fe-normal cells was required to inhibit growth. This increase in H2O2 concentration was associated with decreased generation of SSBs by H2O2 in isolated HL-60 cell nuclei. Thus, Fe bound to nuclear structures is more closely associated with inhibition of cell growth than apparent Fe-ATP species. In parallel experiments, changes in total cellular Fe assayed by ashing and complexing with ferrozine were consistent with a non-transferrin mode of acquisition. These short-term changes appear due to processes accompanying reestablishment of the Fe content and distribution normally observed during long-term growth.

Expression and localization of ferritin mRNA in ameloblasts of rat incisor

At the maturation stage, the ameloblasts of the rat incisor incorporate iron, supplied through the bloodstream, and deposit it into the surface layer of the enamel. In this unique iron transport system, ferritin functions as a transient iron reservoir in the cells. Here the expression of ferritin mRNA and its localization in the rat enamel organ was examined. Among various tissues, the enamel organ showed the highest expression for both ferritin H- and L-chain mRNA, as quantified by reverse transcription-polymerase chain reaction. In situ hybridization using digoxigenin-labelled cRNA probes for each chain demonstrated that both ferritin H- and L-chain mRNA were abundantly expressed in presecretory and secretory ameloblasts. The intensity of the positive hybridization signal gradually decreased toward the incisal direction. Differing from the mRNA localization, ferritin protein was immunologically undetectable in presecretory or secretory ameloblasts but was found in ameloblasts at the maturation stage, into which iron is known to be incorporated from the bloodstream. Thus, the expression of ferritin mRNA precedes the protein expression in the developmental stages of rat incisor ameloblasts, and the translation of ferritin and its half-life are probably controlled by the iron entry, as has been reported for other cell types.

Elevated ferritin production, iron containment, and oxidant resistance in hemin-treated leukemia cells

Hemin (ferriprotoporphyrin IX), the oxidized prosthetic group of hemoglobin, is a source of potentially cytotoxic iron, but in chronic low doses can induce cytoprotection against iron-stimulated oxidative stress. The latter property of hemin has been examined, using murine L1210 cells and three different oxidant generating systems: (i) glucose/glucose oxidase, (ii) near-ultraviolet irradiation, and (iii) dye-mediated photodynamic action. Cells treated with the lipophilic iron donor ferric-8-hydroxyquinoline, Fe(HQ)2 (1 microM, 30 min) were found to be more sensitive to oxidative killing than nontreated controls. However, cells challenged after long-term (20-24 h) exposure to hemin (10 microM) were substantially more resistant than controls and were sensitized far less by Fe(HQ)2. Immunoblot analyses of 24-h hemin-treated cells indicated that the ferritin heavy (H) subunit was elevated 12- to 15-fold, whereas the light (L) subunit was essentially unchanged. Experiments carried out with 55Fe(HQ)2 showed that iron uptake capacity of cells was greatly enhanced after hemin treatment. More specifically, hemin-stimulated cells were found to contain approximately 9 times more immunoprecipitable ferritin iron after incubation with saturating levels (4-5 microM) of 55Fe(HQ)2 and approximately 3 times more iron per ferritin molecule compared with nonstimulated controls. The nonferritin iron content of the latter was estimated to be approximately 40 times greater than that of the former following low-level (0.5 microM) 55Fe(HQ)2 treatment. These results are consistent with the idea that induced ferritin, enriched in H-chain, sequesters redox active iron rapidly and copiously, thereby enhancing cellular resistance to oxidants.

Transport of iron and other transition metals into cells as revealed by a fluorescent probe

Transport of nontransferrin-bound iron into cells is thought to be mediated by a facilitated mechanism involving either the trivalent form Fe(III) or the divalent form Fe(II) following reduction of Fe(III) at the cell surface. We have made use of the probe calcein, whose fluorescence is rapidly and stoichiometrically quenched by divalent metals such as Fe(II), Cu(II), Co(II), and Ni(II) and is minimally affected by variations in ionic strength, Ca(II) and Mg(II). Addition of Fe(II) salts to calcein-loaded human erythroleukemia K-562 cells elicited a slow quenching response that was markedly accelerated by the ionophore A-23187 and was reversed by membrane-permeant but not by impermeant chelators. These observations were confirmed by fluorescence imaging of cells. Other divalent metals such as Co(II), Ni(II), and Mn(II) permeated into cells at roughly similar rates, and their uptake, like that of Fe(II), was blocked by trifluoperazine, bepridil, and impermeant sulfhydryl-reactive organomercurials, indicating the operation of a common transport mechanism. This method could provide a versatile tool for studying the transport of iron and other transition metals into cells.

Ascorbic acid enhances iron-induced ferritin translation in human leukemia and hepatoma cells

Ascorbate is an important cofactor in many cellular metabolic reactions and is intimately linked to iron homeostasis. Continuously cultured cells are ascorbate deficient due to the lability of the vitamin in solution and to the fact that daily supplementation of media with ascorbate is unusual. We found that ascorbate repletion alone did not alter ferritin synthesis. However, ascorbate-replete human hepatoma cells, Hep3B and HepG2, as well as K562 human leukemia cells achieved a substantially higher cellular ferritin content in response to a challenge with iron than did their ascorbate-deficient counterparts grown under standard culture conditions. Most of the elevation in ferritin content was due to an increase in de novo ferritin synthesis of greater than 50-fold, as shown by in vivo labeling with [35S]methionine and immunoprecipitation. RNA-blot analysis showed only minor changes in steady state levels of ferritin mRNA, suggesting that ascorbate enhances iron-induced ferritin synthesis primarily by post-transcriptional events. Transient gene expression experiments using chloramphenicol acetyltransferase reporter gene constructs showed that the ascorbate effect on ferritin translation is not mediated through the stem-loop near the translational start site that transduces ferritin synthesis in response to cytokines. The data suggest that ascorbate possibly modifies the action of the iron-responsive element on ferritin translation, although more precise structure-function studies are needed to clarify this issue. These data demonstrate a novel role of ascorbate as a signaling molecule in post-transcriptional gene regulation. The mechanism by which ascorbate modulates cellular iron metabolism is complex and requires additional detailed investigation.

Regulation of ferritin and transferrin receptor expression by iron in human hepatocyte cultures

HepG2 cell cultures and human hepatocyte primary cultures were used to develop appropriate hepatocytic in vitro models of iron load in order to further understand the pathophysiological mechanisms occurring in the liver of patients with hemochromatosis. The first step of this study was to obtain an efficient iron supply in conditions of minimal toxicity. It was demonstrated that iron complexed to citrate entered efficiently into HepG2 cells and human hepatocytes. This iron load was obtained with minimal toxicity in both culture models as evaluated by the intracellular LDH activity and the total protein content. The second step was to study the effect of iron on ferritin and transferrin receptor expression. In HepG2 cell cultures, intracellular and extracellular ferritin concentrations were strikingly increased by iron in dose- and time-dependent manners. However, the relative amounts of H and L ferritin mRNAs were not significantly affected by iron, suggesting that ferritin regulation occurred at a translational level. On the other hand, in human hepatocyte cultures, the increase of intracellular and extracellular ferritin concentrations was accompanied by an increase in the amounts of H and L ferritin mRNAs. In this model, iron-induced ferritin biosynthesis seemed to be more complex than in HepG2 cells and to be governed by transcriptional and/or post-transcriptional regulatory mechanisms. However, an additional translational level of regulation could not be excluded. In contrast, transferrin receptor expression was decreased by iron in HepG2 cells as well as in human hepatocyte cultures. This decrease was associated with a decrease in the mRNA steady-state level. In both culture models, transferrin receptor regulation seemed to occur at a transcriptional or post-transcriptional level. These results demonstrate that normal human hepatocytes in primary culture respond to iron in a manner close to that observed in vivo and thereby provide a promising experimental model for further understanding pathophysiological mechanisms involved in human hemochromatotic liver.

Transferrin and iron distribution in subcellular fractions of K562 cells in the early stages of transferrin endocytosis

Iron distribution in subcellular fractions was investigated at different times after a single cohort of 59Fe-125 I-labeled transferrin (Tf) endocytosis in K562 cells. Cell homogenates prepared by hypotonic lysis and deoxyribonuclease (DNAase) treatment were fractionated on Percoll density gradients. Iron-containing components in the postmitochondrial supernatant were further fractionated according to their molecular weight using gel chromatography and membrane filtration. In the initial phases of endocytosis, both iron and Tf were found in the light vesicular fraction. After 3 min the labels diverged, with iron appearing in the postmitochondrial supernatant and Tf in the heavy fraction containing mitochondria, lysosomes and nuclei. Iron released from Tf-containing vesicles appeared both in low- and high-molecular-weight fractions in the postmitochondrial supernatant. After 5 min of endocytosis 59Fe activity in the low-molecular-weight fraction remained constant and 59Fe accumulated in a high-molecular-weight fraction susceptible to desferrioxamine chelation. After 10 min, 59Fe radioactivity in this fraction decreased and a majority of cytosolic 59Fe was found in ferritin. These results do not support the concept of the cytosolic low-molecular-weight iron pool as a kinetic intermediate between transferrin and ferritin iron in K562 cells.

Coordination of cellular iron metabolism by post-transcriptional gene regulation

Maintenance of cellular iron homeostasis demands the coordination of iron uptake, intracellular storage, and utilization. Recent investigations suggest that a single genetic regulatory system orchestrates the expression of proteins with central importance for all three aspects of cellular iron metabolism at the level of mRNA stability and translation. Two components of this regulatory system have been defined: a cis-acting mRNA sequence/structure motif called "iron-responsive element" (IRE) and a specific trans-acting cytoplasmic binding protein, here referred to as "IRE-binding protein" (IRE-BP). As an early event in the regulatory cascade, cellular iron deprivation induces the IRE-binding activity of IRE-BP, whereas binding activity is reduced in iron-replete cells. IRE-BP is highly homologous to the iron-sulphur (Fe-S) protein aconitase which strongly suggests that IRE-BP is an Fe-S protein itself. Control over IRE-BP activity by the cellular iron status is exerted post-translationally and likely involves changes between (4Fe-4S) and (3Fe-4S) states of the postulated IRE-BP Fe-S cluster. In addition, post-translational regulation of IRE-BP activity via heme has been proposed. Subsequent to its activation, IRE-BP binds with high affinity to single IREs contained in the 5' untranslated regions (UTRs) of ferritin and erythroid 5-aminolevulinic acid synthase (eALAS) mRNAs. The binding represses translation of these proteins involved in iron storage and utilization, respectively. In contrast, iron uptake is largely regulated via multiple IREs in the 3' UTR of transferrin receptor (TfR) mRNA. TfR-IREs are required for the iron-sensitive control of TfR mRNA stability. IRE-BP binding stabilizes TfR gene transcripts against as yet undefined ribonucleases. As a result of these regulatory interactions, iron starvation induces the expression of TfR, thereby increasing iron uptake, and represses the synthesis of proteins involved in iron storage and utilization. As cellular iron levels rise, the homeostatic balance is maintained by lowering iron uptake and increasing iron storage in ferritin.

Uptake and intracellular handling of iron from transferrin and iron chelates by mitogen stimulated mouse lymphocytes

The ability of lymphocytes to utilise iron from different sources has been investigated. Iron uptake from transferrin by proliferating lymphocytes gradually increased as saturation of the protein with iron was increased up to 100%, but rose sharply when addition of further iron resulted in the presence of non-transferrin bound iron. Increasing the saturation of transferrin with iron caused an increased rate of proliferation up to about 100% saturation but when the level of iron present exceeded the binding capacity of the protein, proliferation decreased and at high levels of iron it was reduced below that seen in the absence of transferrin. Comparison of the degree of iron uptake from transferrin and from iron chelators showed that the hydrophilic chelator ferric nitrilotriacetate (FeNTA) donated larger amounts of iron to cells than did transferrin or the lipophilic chelator ferric-pyridoxal isonicotinoyl hydrazone (FePIH), but did not promote proliferation, and when present in high amounts caused inhibition. In contrast, FePIH supported proliferation as efficiently as transferrin. In cells cultured with FeNTA, iron was found predominantly in an insoluble form while in the cells cultured with Fe-transferrin or FePIH the largest proportion of iron was found in the non-ferritin high molecular weight fraction, which probably represents iron in enzymes and other metabolically-important proteins. In no case did iron associated with ferritin exceed 15% of the total uptake, and the cells showed no marked increase in synthesis of ferritin in response to any of the forms of iron. These results indicate that different forms of iron are handled in different ways by lymphocytes, and that iron delivered from hydrophilic chelates may be toxic and not readily available for metabolic use. Lymphocytes appear to be poorly equipped to sequester excess iron in ferritin, and this may account for abnormalities in the immune system reported in patients with iron overload.

Mechanisms and regulation of intestinal uptake and transfer of iron

Despite much research over the past fifty years, the precise details of intestinal iron absorption remain unclear. The lack of understanding extends both to the specific biochemical mechanisms of transport as well as the means by which these are regulated. Iron in several dietary forms must be digested and processed in the intestinal lumen, taken up across the mucosal brush border membrane, transported through the intestinal absorptive cell, accomplish a second transmembrane passage across the basolateral membrane and, finally, be transported to sites of iron metabolism and storage within the body. Recent findings in several of these areas are reviewed. Evidence is presented to support the involvement, or non-involvement, of several intestinal iron-binding components in iron transport. In the future, the application of molecular biology to the investigation of intestinal iron metabolism will undoubtedly increase understanding of absorption mechanisms and their regulation.

Transport of transferrin-bound iron into rat Sertoli cells and spermatids

Transferrin (Tf), a major secretory protein of Sertoli cells, may transport iron to spermatogenic cells. This was assessed by measuring the uptake of Fe from 59Fe-125I-labelled rat Tf by Sertoli cells and round spermatids in vitro. Uptake of Fe from labelled Tf by Sertoli cells after a 72-h pre-incubation period was linear for 20 h (approximately 18 pmol/10(6) cells/20 h), whereas the uptake of Fe from labelled Tf by round spermatids after a 16-h pre-incubation period reached a plateau by 2 h (approximately 5 pmol/10(6) cells/2 h). The corresponding net uptake of Tf by both cell types was less than 0.1 pmol. High speed supernatants prepared from Sertoli cells and spermatids labelled with 59Fe-125I-Tf were fractionated by gel permeation chromatography. Separate peaks of protein-bound 59Fe and 125I-Tf were observed. Protein bound 59Fe could be precipitated with an antiserum to rat ferritin. It is concluded that iron from exogenous Tf is transported into Sertoli cells and round spermatids in vitro, and is complexed to intracellular ferritin. However, the present results do not exclude the possibility that Sertoli cell Tf may serve purposes other than iron transport.