UNIPROT:P02794 - FACTA Search

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Query: UNIPROT:P02794 (ferritin)
17,525 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A food frequency questionnaire (FFQ) was developed and tested for assessing iron nutrition in infants through comparison with a three-day food record (3d-FR) and measures of iron status. Parents of 148 infants aged eight to 26 months completed a 3d-FR and an FFQ. Blood was collected for measures of hemoglobin (Hgb), ferritin, and transferrin receptor (sTfR). Iron deficiency anemia and iron depletion (ferritin < or =12 microg/L) were found in 9% and 26% of infants, respectively. The intakes of energy, total iron, heme and non-heme iron, vitamin C, and dietary fibre determined by the FFQ were associated with the intakes of the same nutrient determined by the 3d-FR (p<0.05). The intakes of energy, total iron, non-heme and heme iron, vitamin C, and fibre were significantly higher when estimated by the FFQ than by the 3d-FR. Total and heme iron intakes determined by the FFQ were significantly associated with serum ferritin, sTfR, and the sTfR:ferritin ratio (p<0.05). However, iron intakes explained <10% of the variability in iron status. Despite relative validity of the FFQ for evaluating differences in energy, iron, vitamin C, and fibre intake compared with a 3d-FR, FFQs need further development before they can be used to advance assessment of iron intake and status in infants.
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PMID:Food frequency questionnaire for assessing infant iron nutrition. 1615 11

Iron, the major trace element in the body, is an essential component of many proteins and enzymes. As low-molecular-weight iron is potentially toxic to cells, higher organisms express a number of proteins for the transport and storage of iron. We review our current understanding of the intestinal absorption of iron in the light of recently identified membrane proteins, namely the ferrric reductase, Dcytb, the two iron(II) transport proteins, DMT1 and ferroportin/Ireg1, and hephaestin, the membrane-bound homologue of the ferroxidase ceruloplasmin. Two types of mammalian transferrin receptor, TfR1 and TfR2, are now known to exist. The structure of TfR1 and its role in the process of receptor-mediated cellular uptake of iron are presented together with structural information on the iron storage protein ferritin. Mechanisms for the regulation of levels of TfR1 and ferritin, as well as other proteins involved in iron homeostasis, are discussed. Our current knowledge and understanding of the structure of members of the transferrin family of iron-binding proteins and the nature of the iron-binding centres in transferrins is presented, together with information on the processes of iron-uptake and iron-release by transferrin and a summary of the elements that have been found to bind to transferrins.
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PMID:Structure/function overview of proteins involved in iron storage and transport. 1630 65

Although it is almost certain that alpha(+)-thalassemia protects against malaria, the mechanisms for that are still unknown. It has been suggested that an increased number of young circulating red blood cells in alpha(+)-thalassemic children, as a result of some degree of ineffective erythropoiesis, could be related to the high frequencies of the alpha(+)-thalassemic allele in malaria endemic areas. Reticulocyte evaluation in this condition, however, has been poorly performed so far. Our objective was to determine the reticulocyte number and maturation degree, in addition to the soluble transferrin receptor and serum erythropoietin levels, in alpha(+)-thalassemia heterozygotes, comparing them with normal alpha-genotype controls. One hundred twenty-one alpha(+)-thalassemia carriers (-alpha(3.7)/alphaalpha) and 249 controls (alphaalpha/alphaalpha), all of them with normal serum ferritin levels, were subclassified according to age (1-5, 6-10, 11-15, 16-20, and over 20 years old). Reticulocyte analyzes were carried out by flow cytometry and sTfR and s-Epo levels determined by immunonephelometry and chemiluminescence, respectively. The comparisons did not show any significant difference between thalassemics and controls regarding the reticulocyte parameters [percentages and absolute values, P = 0.2643 and 0.5421; high, medium, and low maturation degree, P = 0.2579, 0.2196, and 0.4192; RET maturity index (RMI), P = 0.2471, respectively], as well as the s-Epo levels (P = 0.5711). The sTfR concentrations were higher in the thalassemic group (P = 0.0001), but statistical significance was due only to the 1-5 and over 20 subgroups (P = 0.0082 and 0.0436, respectively). The results found here are compatible with a compensated erythropoiesis and do not confirm the hypothesis mentioned above.
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PMID:Reticulocyte evaluation in alpha(+)-thalassemia. 1636 54

Gallium (Ga) shows significant antitumor activity by markedly interfering with iron (Fe) metabolism, and (67)Ga is used as a radio-imaging agent for cancer detection. Therefore, the mechanisms involved in (67)Ga uptake, metabolism, and resistance are critical to understand. The development of tumor lines that are gallium-resistant suggests (67)Ga uptake may be different in these cells, providing an opportunity for understanding intracellular (67)Ga and (59)Fe transport and gallium resistance. In this study, gallium-resistant cells were used to assess (67)Ga and (59)Fe uptake using native polyacrylamide gel electrophoresis autoradiography. In contrast to the common view that (67)Ga and (59)Fe use the same uptake pathways, we show that the trafficking of these two metal ions is different in cells either resistant (R) or sensitive (S) to gallium. Indeed, in contrast to (59)Fe, little (67)Ga is incorporated into ferritin, with most present as a labile (67)Ga pool. We also report unique changes in (67)Ga and (59)Fe trafficking between R and S cells. In particular, in R cells, there was a distinct transferrin-transferrin receptor 1-hemochromatosis protein (HFE) complex (band B) not observed in S cells. Furthermore, because HFE regulates iron and gallium uptake, the two Tf-TfR1-HFE complexes in R cells may be involved in reduced (67)Ga and (59)Fe uptake compared with S cells. In S cells, a novel iron-binding intermediate (band D) was identified that was not present in R cells and may be a "sensitivity factor" to gallium. In contrast to the general view that (67)Ga and (59)Fe use the same or similar uptake pathways, we show that their distribution and trafficking is markedly different in R and S cells.
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PMID:Resistance to the antineoplastic agent gallium nitrate results in marked alterations in intracellular iron and gallium trafficking: identification of novel intermediates. 1637 28

Terminal erythropoiesis is accompanied by extreme demand for iron to ensure proper hemoglobinization. Thus, erythroblasts must modify the "standard" post-transcriptional feedback regulation, balancing expression of ferritin (Fer; iron storage) versus transferrin receptor (TfR1; iron uptake) via specific mRNA binding of iron regulatory proteins (IRPs). Although erythroid differentiation involves high levels of incoming iron, TfR1 mRNA stability must be sustained and Fer mRNA translation must not be activated because iron storage would counteract hemoglobinization. Furthermore, translation of the erythroid-specific form of aminolevulinic acid synthase (ALAS-E) mRNA, catalyzing the first step of heme biosynthesis and regulated similarly as Fer mRNA by IRPs, must be ensured. We addressed these questions using mass cultures of primary murine erythroid progenitors from fetal liver, either undergoing sustained proliferation or highly synchronous differentiation. We indeed observed strong inhibition of Fer mRNA translation and efficient ALAS-E mRNA translation in differentiating erythroblasts. Moreover, in contrast to self-renewing cells, TfR1 stability and IRP mRNA binding were no longer modulated by iron supply. These and additional data stemming from inhibition of heme synthesis with succinylacetone or from iron overload suggest that highly efficient utilization of iron in mitochondrial heme synthesis during normal erythropoiesis alters the regulation of iron metabolism via the IRE/IRP system.
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PMID:Remodeling the regulation of iron metabolism during erythroid differentiation to ensure efficient heme biosynthesis. 1642 95

Indicators of maternal iron (Fe) status were studied in relation to placental Fe (Pl-Fe) status. Placental (Pl) and maternal (M) venous blood samples were obtained from primiparous women (n = 38), with normal delivery at Paroissien Hospital, Argentina. Maternal hemoglobin (M Hb), soluble transferrin receptor (M sTfR) (ELISA) and serum ferritin (M S-Ft) were studied in relation to Pl-Fe, ferritin (Pl-Ft) and transferrin receptor (Pl-TfR). Pl-TfR was measured by dot blot assay, Pl-Ft and M S-Ft by immunoassay (IRMA) and Pl-Fe by atomic absorption spectrometry. Fe status indicators were, respectively, (mean +/- SD): M Hb 113 +/- 16 g/L; M S-Ft 36 +/- 42 microg/L; M sTfR 6.3 +/- 3.1 mg/L; Pl-Fe 170 +/- 56 microg/g placenta; Pl-Ft 33 +/- 18 microg/g placenta; Pl-TfR 18 +/- 18 (range 0-58) microg/g placenta. Pl-Fe, Pl-Ft and Pl-TfR did not correlate to M Hb, M S-Ft and M sTfR. Women with Pl- Fe, Pl-Ft and Pl-TfR above or below the corresponding median values did not show any statistical significant difference in M Hb, M sTfR or M S-Ft values. Pl-Ft concentration was lower in women with Hb < 110 g/L than in women with normal values: 26 +/- 13 vs. 38 +/- 20 microg/g, respectively (p = 0.021). When Pl-TfR, Pl-Ft and Pl-Fe were compared in women with M S-Ft above or below the cut-off point of 10 or 20 microg/L, no significant difference was found for Pl-TfR neither for Pl-Ft nor Pl-Fe. These results suggest that maternal indicators of Fe status, particularly M sTfR and M S-Ft, do not reflect Fe status of the placenta at delivery.
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PMID:Do indicators of maternal iron status reflect placental iron status at delivery? 1644 72

Ferumoxides-protamine sulfate (FE-Pro) complexes are used for intracellular magnetic labeling of cells to non-invasively monitor cell trafficking by in vivo MRI. FE-Pro labeling is non-toxic to cells; however, the effects of FE-Pro labeling on cellular expression of transferrin receptor (TfR-1) and ferritin, proteins involved in iron transport and storage, has not been reported. FE-Pro-labeled human mesenchymal stem cells (MSCs), HeLa cells and primary macrophages were cultured from 1 week to 2 months and evaluated for TfR-1 and ferritin gene expression by RT-PCR and protein levels were determined using Western blots. MTT (proliferation assay) and reactive oxygen species (ROS) analysis were performed. FE-Pro labeling of HeLa and MSCs resulted in a transient decrease in TfR-1 mRNA and protein levels. In contrast, Fe-Pro labeling of primary macrophages resulted in an increase in TfR-1 mRNA but not in TfR-1 protein levels. Ferritin mRNA and protein levels increased transiently in labeled HeLa and macrophages but were sustained in MSCs. No changes in MTT and ROS analysis were noted. In conclusion, FE-Pro labeling elicited physiological changes of iron metabolism or storage, validating the safety of this procedure for cellular tracking by MRI.
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PMID:Expression of transferrin receptor and ferritin following ferumoxides-protamine sulfate labeling of cells: implications for cellular magnetic resonance imaging. 1667 57

The iron regulatory proteins (IRP1 and IRP2) are two cytoplasmic RNA-binding proteins that control iron metabolism in mammalian cells. Both IRPs bind to specific sequences, called iron-responsive elements (IREs), located in the 3' or 5' untranslated regions (UTR) of several mRNAs, in particular the mRNA encoding ferritin subunits and transferrin receptor. At low intracellular iron concentration, IRPs bind to the IRE of ferritin mRNA at its 5'-UTR and block translation, whereas they stabilize transferrin receptor mRNA through direct interactions with several IRE motifs in the 3'-UTR. The converse regulation of ferritin and TfR synthesis, resulting from lack of binding of IRPs to IRE, occurs in cells with high iron level. In both, iron deficiency and excess IRP-mediated regulation rapidly restore the physiological cytosolic iron level. The role of IRPs in maintaining the intracelluar iron balance has been well characterized in numerous types of mammalian cells in culture. However, the importance of IRPs in the regulation of systemic iron metabolism in mammals, in particular in signaling between cells which play major roles in body iron metabolism, such as duodenal enterocytes, reticuloendothelial macrophages, hepatocytes, and bone marrow precursors of red blood cells, is only beginning to be investigated. This review presents the basic features of iron metabolism in IRP1 and IRP2 knockout mice and focuses on how recent studies on these animal models have advanced our understanding of the role of IRPs in iron mammalian physiology.
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PMID:[The role of iron regulatory proteins (IRPs) in the regulation of systemic iron homeostasis: lessons from studies on IRP1 and IRP2 knock out mice]. 1681 31

Smoking is associated with oxidative stress and increased risks of many chronic diseases that both shorten life and impair its quality. Low concentrations of several micronutrients, especially the antioxidants vitamin C and beta-carotene, are also associated with smoking, and there has been much interest in determining whether deficiencies in micronutrients are involved etiologically in smoking-related diseases. The objective of this review was to bring together reports on dietary intakes, biochemical indicators of micronutrient status, and results of some intervention studies on micronutrients where authors had compared outcomes in smokers and non-smokers. The micronutrients discussed are vitamins A, E, and C; the carotenoids; some of the B-vitamin group; and the minerals selenium, zinc, copper, and iron. The data were then examined to determine whether effects on the biochemical markers of micronutrient status were due to differences in dietary intakes between smokers and non-smokers or to the consequences of inflammatory changes caused by the oxidative stress of smoking. It was concluded that although smoking is associated with reduced dietary intake of vitamin C and carotenoid-containing foods, inflammatory changes increase turnover of these micronutrients so that blood concentrations are still lower in smokers than non-smokers even when there is control for dietary differences. In the case of vitamin E, there is some evidence for increased turnover of this nutrient in smokers, but this has little to no influence on blood concentrations, and there are no differences in dietary intake of vitamin E between smokers and non-smokers. Serum concentrations of vitamin A, folate, and vitamin B12 and B6 markers do not appear to be influenced by smoking, although there is some influence of dietary intake on concentrations of these nutrients in the body. In the case of the minerals examined, the main effects on biochemical markers of mineral status were attributed to inflammation and were therefore greater in heavy or long-term smokers. Serum concentrations of selenium and erythrocyte GPx activity were lower in smokers. Erythrocyte CuZn-SOD activity and serum ceruloplasmin concentrations were elevated, while serum zinc concentrations were depressed only in heavy smokers. Lastly, smoking appears to affect iron homeostasis mainly by changing hemoglobin concentrations, which were in general increased. Serum iron, TfR, and ferritin were mostly unaffected by smoking, except in pregnancy where there is evidence of increased erythropoiesis causing lower saturation of plasma transferrin and some evidence of lowering of iron stores.
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PMID:Monitoring micronutrients in cigarette smokers. 1704 81

Erythrocytosis is an adaptive response to improve oxygen transport in cyanotic congenital heart disease (CCHD). However, at highly increased hematocrit levels patients may experience hyperviscosity symptoms. Iron deficiency in CCHD patients is often overlooked due to elevated hemoglobin concentrations. A 29-year-old male with CCHD was readmitted to our outpatient clinic. Red blood cells (11.65*10(12)/L), hemoglobin (25.7 g/dL), and hematocrit (80%) were extremely elevated. Measurements of iron supply showed a constellation typical for iron deficiency with low ferritin (13.2 microg/L), and high sTfR (20 mg/L). We present a case of extremely high red blood cell counts with concomitant iron deficiency. For appropriate management and to avoid misinterpretation of the iron status, ferritin and sTfR should always accomplish laboratory examination of CCHD patients.
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PMID:Iron deficiency in a patient with extreme erythrocytosis due to cyanotic congenital heart disease. 1709 63

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