UMLS:C0240066 - FACTA Search

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Query: UMLS:C0240066 (iron deficiency)
7,156 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Iron deficiency and marginal vitamin A (VA) deficiency frequently coexist and affect billions of people, mostly children and women, worldwide. The effects of these micronutrient deficiencies alone and in combination on hematologic, biochemical and molecular indices of iron and VA status were investigated in a 2 x 2 randomized blocked study conducted in growing male Sprague-Dawley rats. From 3-8 wk of age, rats were fed one of four purified diets that were either adequate or restricted in iron (Fe) and adequate or marginal in VA: (+)Fe(+)VA, 20.3 and 0.367 micro g/g, respectively, denoted control diet; (-)Fe(+)VA, 3.34 and 0.405 micro g/g; (+)FeVA(m), 22.2 and 0.051 micro g/g; or (-)FeVA(m), 3.03 and 0.055 micro g/g. Weight-matched rats fed adequate micronutrients were included to control for possible confounding effects of Fe deficiency on growth and feed efficiency. Iron restriction reduced (P < 0.05) weight gain, feed efficiency, blood hemoglobin and hematocrit. Plasma and liver iron and plasma transferrin saturation were reduced by approximately 50%, whereas liver transferrin mRNA and protein and transferrin receptor mRNA were elevated, as was liver ferritin light-chain protein and light-chain mRNA. Liver heavy-chain ferritin mRNA, hemopexin, ceruloplasmin and cellular retinol-binding protein mRNA were not affected by iron or VA restriction. Although marginal VA deficiency did not exacerbate indices of poor iron status during iron deficiency, iron deficiency was associated with lower plasma retinol and elevated liver VA concentrations. These results are consistent with an impaired mobilization of liver retinol during iron deficiency as well as multiple alterations in iron metabolism.
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PMID:Iron deficiency and marginal vitamin A deficiency affect growth, hematological indices and the regulation of iron metabolism genes in rats. 1246 96

Whole body homeostasis can be viewed as the balance between absorption and excretion, which can be regulated independently. Present evidence suggests that for iron, intestinal absorption is the main site for homeostatic regulation, while for copper it is biliary excretion. There are connections between iron and copper in intestinal absorption and transport. The blue copper plasma protein, ceruloplasmin, and its intracellular homologue, hephaestin, play a role in cellular iron release. The studies reviewed here compare effects of Fe(II) and Cu(II) on their uptake and overall transport by monolayers of polarized Caco2 cells, which model intestinal mucosa. In the physiological range of concentrations, depletion of cellular iron or copper (by half) increased uptake of both metal ions. Depletion of iron or copper also enhanced overall transport of iron from the apical to the basal chamber. Copper depletion enhanced overall copper transport, but iron depletion did not. Pretreatment with excess copper also stimulated copper absorption. Plasma ceruloplasmin (added to the basal chamber) failed to enhance basolateral iron release, and Zn(II) failed to compete with Cu(II) for uptake. Neither copper nor iron deficiency altered expression of IREG1 or DMT1 (-IRE form) at the mRNA level. Thus, in the low-normal range of iron and copper availability, intestinal absorption of both metals appears to be positively related to the need for these elements by the whole organism. The two metal ions also influenced each other's transport; but with copper excess, other mechanisms come into play.
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PMID:Iron and copper homeostasis and intestinal absorption using the Caco2 cell model. 1257 74

Fre1p is a metalloreductase in the yeast plasma membrane that is essential to uptake of environmental Cu2+ and Fe3+. Fet3p is a multicopper oxidase in this membrane essential for high affinity iron uptake. In the uptake of Fe3+, Fre1p produces Fe2+ that is a substrate for Fet3p; the Fe3+ produced by Fet3p is a ligand for the iron permease, Ftr1p. Deletion of FET3 leads to iron deficiency; this deletion also causes a copper sensitivity not seen in wild type. Deletion of FTR1 leads to copper sensitivity also. Production in the ftr1delta strain of an iron-uptake negative Ftr1p mutant, Ftr1p(RAGLA), suppressed this copper sensitivity. This Ftr1p mutant supported the plasma membrane targeting of active Fet3p that is blocked in the parental ftr1delta strain. A ferroxidase-negative Fet3p did not suppress the copper sensitivity in a fet3delta strain, although it supported the plasma membrane localization of the Fet3p.Ftr1p complex. Thus, loss of membrane-associated Fet3p oxidase activity correlated with copper sensitivity. Furthermore, in vitro Cu1+ was shown to be an excellent substrate for Fet3p. Last, the copper sensitivity of the fet3delta strain was suppressed by co-deletion of FRE1, suggesting that the cytotoxic species was Cu1+. In contrast, deletion of CTR1 or of FET4 did not suppress the copper sensitivity in the fet3delta strain; these genes encode the two major copper transporters in laboratory yeast strains. This result indicated that the apparent cuprous ion toxicity was not due to excess intracellular copper. These biochemical and physiologic results indicate that at least with respect to cuprous and ferrous ions, Fet3p can be considered a metallo-oxidase and appears to play an essential role in both iron and copper homeostasis in yeast. Its functional homologs, e.g. ceruloplasmin and hephaestin, could play a similar role in mammals.
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PMID:Fre1p Cu2+ reduction and Fet3p Cu1+ oxidation modulate copper toxicity in Saccharomyces cerevisiae. 1295 29

Iron is essential for oxidation-reduction catalysis and bioenergetics; however, unless appropriately shielded, this metal plays a crucial role in the formation of toxic oxygen radicals that can attack all biological molecules. Organisms are equipped with specific proteins designed for iron acquisition, export and transport, and storage, as well as with sophisticated mechanisms that maintain the intracellular labile iron pool at an appropriate level. Despite these homeostatic mechanisms, organisms often face the threat of either iron deficiency or iron overload. This review describes several hereditary iron-overloading conditions that are confined to the brain. Recently, a mutation in the L-subunit of ferritin has been described that causes the formation of aberrant L-ferritin with an altered C-terminus. Individuals with this mutation in one allele of L-ferritin have abnormal aggregates of ferritin and iron in the brain, primarily in the globus pallidus. Patients with this dominantly inherited late-onset disease present with symptoms of extrapyramidal dysfunction. Mice with a targeted disruption of a gene for iron regulatory protein 2 (IRP2), a translational repressor of ferritin, misregulate iron metabolism in the intestinal mucosa and the central nervous system. Significant amounts of ferritin and iron accumulate in white matter tracts and nuclei, and adult IRP2-deficient mice develop a movement disorder consisting of ataxia, bradykinesia, and tremor. Mutations in the frataxin gene are responsible for Friedreich's ataxia, the most common of the inherited ataxias. Frataxin appears to regulate mitochondrial iron-sulfur cluster formation, and the neurologic and cardiac manifestations of Friedreich's ataxia are due to iron-mediated mitochondrial toxicity. Patients with Hallervorden-Spatz syndrome, an autosomal recessive, progressive neurodegenerative disorder, have mutations in a novel pantothenate kinase gene (PANK2). The cardinal feature of this extrapyramidal disease is pathologic iron accumulation in the globus pallidus. The defect in PANK2 is predicted to cause the accumulation of cysteine, which binds iron and causes oxidative stress in the iron-rich globus pallidus. Finally, aceruloplasminemia is an autosomal recessive disorder of iron metabolism caused by loss-of-function mutations in ceruloplasmin gene that leads to misregulation of both systemic and central nervous system iron trafficking. Affected individuals suffer from extrapyramidal signs, cerebellar ataxia, progressive neurodegeneration of retina, and diabetes mellitus. Excessive iron depositions are found in the brain, liver, pancreas, and other parenchymal cells, but plasma iron concentrations are decreased. These conditions are not common, but awareness about them is important for differential diagnosis of various neurodegenerative disorders.
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PMID:Hereditary causes of disturbed iron homeostasis in the central nervous system. 1510 72

Iron deficiency during pregnancy causes problems both for the mother and fetus. Iron deficiency is known to have secondary effects on copper metabolism. In this study, we use a rat model to examine the effect of iron deficiency on copper levels in maternal and fetal tissue. We assess whether the effects of iron deficiency on copper metabolism are due to alterations in mRNA levels of proteins of copper transport. Rowett Hooded Lister rats were fed diets with four different iron contents before and during pregnancy. Maternal and fetal samples were collected on day 21 of gestation. Copper and iron levels of liver and placenta were analyzed, mRNA levels of genes involved in copper transport were studied, and copper oxidase activity measured. Reduced dietary iron was found to increase maternal liver copper, inversely correlating with iron levels. Correspondingly, copper and ceruloplasmin increased in maternal serum. The placenta showed the greatest increase in copper levels. As the iron content of the maternal diet decreased so did the iron and copper levels in the fetal liver. In all tissues examined, mRNA expression for CTR1, ATOX1, ATP7A, and ATP7B was unchanged by iron deficiency. However, copper oxidase activity in maternal serum and placenta was increased. Our study in a rat model demonstrates that iron deficiency during pregnancy has a differential effect on copper metabolism in the mother and fetus. It is clear from this study that the changes in copper levels that accompany iron deficiency are not mediated by changes in transcription of the genes involved in copper transport.
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PMID:Iron deficiency in the pregnant rat has differential effects on maternal and fetal copper levels. 1515 43

Iron is one of the most important essential metal ions of which significance is well known for ages. This element is a key moiety of several enzymes in iron containing heme or nonheme form and transfer and storage protein, hemoglobin and myoglobin. Several membrane carriers of iron have already been identified. The redox state of iron is determined by xanthine oxidase, cytochromes and Hp or ceruloplasmin and ferroxidase activity of apo-ferritin, respectively. Some vitamins (C, B2-, B3-, B6-, B12) play also a role in the metabolism of iron. The iron content of cells of the organs is well regulated by the iron homeostasis. Iron has a significant role in the immune system by producing oxygen containing free radicals. Anaemia induced by iron deficiency may cause a challenge concerns for pregnant women, babies and adolescent, primarily.
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PMID:[Physiologic and pathologic role of iron in the human body. Iron deficiency anemia in newborn babies]. 1550 4

Iron and copper are essential nutrients, excesses or deficiencies of which cause impaired cellular functions and eventually cell death. The metabolic fates of copper and iron are intimately related. Systemic copper deficiency generates cellular iron deficiency, which in humans results in diminished work capacity, reduced intellectual capacity, diminished growth, alterations in bone mineralization, and diminished immune response. Copper is required for the function of over 30 proteins, including superoxide dismutase, ceruloplasmin, lysyl oxidase, cytochrome c oxidase, tyrosinase and dopamine-beta-hydroxylase. Iron is similarly required in numerous essential proteins, such as the heme-containing proteins, electron transport chain and microsomal electron transport proteins, and iron-sulfur proteins and enzymes such as ribonucleotide reductase, prolyl hydroxylase phenylalanine hydroxylase, tyrosine hydroxylase and aconitase. The essentiality of iron and copper resides in their capacity to participate in one-electron exchange reactions. However, the same property that makes them essential also generates free radicals that can be seriously deleterious to cells. Thus, these seemingly paradoxical properties of iron and copper demand a concerted regulation of cellular copper and iron levels. Here we review the most salient characteristics of their homeostasis.
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PMID:Iron and copper metabolism. 1611 86

Calprotectin, also known as the S100A8/A9 or MRP8/14 complex, is a major calcium-binding protein in the cytosol of neutrophils, monocytes, and keratinocytes. It differs from other S100 proteins in its zinc-binding capacity. The authors describe a 4-year-old girl with severe anemia, neutropenia, inflammation, and severe growth failure. Bone marrow examination showed moderate dyserythropoiesis. No hemolysis, iron deficiency, hemoglobinopathies, immunologic diseases, or autoantibodies were detected. Serum levels of copper and ceruloplasmin were within the normal range, although the serum zinc concentration was markedly increased (310 microg/dL). Urinary zinc excretion and erythrocyte zinc concentrations were within the normal range. Family studies showed normal zinc and copper plasma levels. The patient's plasma calprotectin concentration showed a 6,000-fold increase (2,900 mg/L) compared with normal values. The calprotectin concentration is known to be elevated in many inflammatory conditions but is generally below 10 mg/L and thus far below the levels reported in this patient. The authors describe this case as an inborn error of zinc metabolism caused by dysregulation of calprotectin metabolism, which mainly presented with the features of microcytic anemia and inflammation.
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PMID:Severe anemia and neutropenia associated with hyperzincemia and hypercalprotectinemia. 1618 40

Copper and iron metabolism intersect in mammals. Copper deficiency simultaneously leads to decreased iron levels in some tissues and iron deficiency anemia, whereas it results in iron overload in other tissues such as the intestine and liver. The copper requirement of the multicopper ferroxidases hephaestin and ceruloplasmin likely explains this link between copper and iron homeostasis in mammals. We investigated the effect of in vivo and in vitro copper deficiency on hephaestin (Heph) expression and activity. C57BL/6J mice were separated into 2 groups on the day of parturition. One group was fed a copper-deficient diet and another was fed a control diet for 6 wk. Copper-deficient mice had significantly lower hephaestin and ceruloplasmin (approximately 50% of controls) ferroxidase activity. Liver hepcidin expression was significantly downregulated by copper deficiency (approximately 60% of controls), and enterocyte mRNA and protein levels of ferroportin1 were increased to 2.5 and 10 times, respectively, relative to controls, by copper deficiency, indicating a systemic iron deficiency in the copper-deficient mice. Interestingly, hephaestin protein levels were significantly decreased to approximately 40% of control, suggesting that decreased enterocyte copper content leads to decreased hephaestin synthesis and/or stability. We also examined the effect of copper deficiency on hephaestin in vitro in the HT29 cell line and found dramatically decreased hephaestin synthesis and activity. Both in vivo and in vitro studies indicate that copper is required for the proper processing and/or stability of hephaestin.
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PMID:Decreased hephaestin activity in the intestine of copper-deficient mice causes systemic iron deficiency. 1661 10

Brain iron uptake is regulated by the expression of transferrin receptor 1 in endothelial cells of the blood-brain barrier. Transferrin-bound iron in the systemic circulation is endocytosed by brain endothelial cells, and elemental iron is released to brain interstitial fluid, likely by the iron exporter, ferroportin. Transferrin synthesized by oligodendrocytes in the brain binds much of the iron that traverses the blood-brain barrier after oxidation of the iron, most likely by a glycophosphosinositide-linked ceruloplasmin found in astrocytic foot processes that ensheathe brain endothelial cells. Neurons acquire iron from diferric transferrin, but it is less clear how glial cells acquire iron. In aging mammals, iron accumulates in the basal ganglia, and iron accumulation is believed to contribute to neurodegenerative diseases, including Parkinson and Alzheimer disease. Here we consider the possibility that iron accumulations, which are often thought to facilitate free radical generation and oxidative damage, may contain insoluble iron that is unavailable for cellular use, and the pathology associated with iron accumulations may result from functional iron deficiency in some diseases.
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PMID:Brain iron metabolism. 1710 52

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