Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0002871 (anemia)
52,094 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We report the case of an African American woman with sickle cell anemia and iron overload incompletely explained by erythrocyte transfusion who is heterozygous for a promoter mutation in the X-linked erythroid-specific 5-aminolevulinate synthase gene (ALAS2): a C to G transversion at nucleotide -206 from the transcription start site, as defined by primer extension (-258 from the start ATG). This mutation has previously been associated with sideroblastic anemia and iron overload in members of a Welsh kinship. No coding region mutation of HFE, FPN1, TFR2, HAMP, or HJV genes was detected. The mother of the proband has mild, chronic anemia and is also heterozygous for the same proximal promoter region mutation of ALAS2. However, she has no evidence of iron overload. We conclude that an ALAS2 promoter region mutation could partly account for iron overload in the present proband, and that this or other ALAS2 mutations could explain the occurrence of iron overload in other whites or blacks with or without anemia. The occurrence of anemia and iron overload may be discordant in women heterozygous for ALAS2 mutations.
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PMID:Iron overload in an African American woman with SS hemoglobinopathy and a promoter mutation in the X-linked erythroid-specific 5-aminolevulinate synthase (ALAS2) gene. 1588 6

We report the case of a man with severe X-linked sideroblastic anemia, severe iron overload, and hepatic cirrhosis who died of hepatocellular carcinoma. Evaluation of family members using DNA sequencing revealed that he was hemizygous for the novel ALAS2 mutation R452H (exon 9; nt 1407 G --> A). The proband's brother, an ALAS2 R452H hemizygote, had mild anemia and mild iron overload. Four female relatives were ALAS2 R452H heterozygotes, but they had mild or no anemia and no iron overload. Sequencing of TFR2, HFE, FPN1 (SLC40A1), HAMP, HJV, and the erythrocyte pyruvate kinase genes of family members was also performed. We thus detected the novel TFR2 missense mutation I449V (exon 10; nt 1345 A --> G) in the proband's wife and daughter, neither of whom had anemia or iron overload. Possible explanations for the disparate red blood cell and iron phenotypes of the proband and his family members are discussed.
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PMID:Disparate phenotypic expression of ALAS2 R452H (nt 1407 G --> A) in two brothers, one with severe sideroblastic anemia and iron overload, hepatic cirrhosis, and hepatocellular carcinoma. 1654 Mar 54

Hepcidin evolves as a potent hepatocyte-derived regulator of the body's iron distribution piloting the flow of iron via, and directly binding, to the cellular iron exporter ferroportin. The hepcidin-ferroportin axis dominates the iron egress from all cellular compartments that are critical to iron homeostasis, namely placental syncytiotrophoblasts, duodenal enterocytes, hepatocytes and macrophages of the reticuloendothelial system. The gene that encodes hepcidin expression (HAMP) is subject to regulation by proinflammatory cytokines, such as IL-6 and IL-1; excessive hepcidin production explains the relative deficiency of iron during inflammatory states, eventually resulting in the anaemia of inflammation. The haemochromatosis genes HFE, TfR2 and HJV potentially facilitate the transcription of HAMP. Disruption of each of the four genes leads to a diminished hepatic release of hepcidin consistent with both a dominant role of hepcidin in hereditary haemochromatosis and an upstream regulatory role of HFE, TfR2 and HJV on HAMP expression. The engineered generation of hepcidin agonists, mimetics or antagonists could largely broaden current therapeutic strategies to redirect the flow of iron.
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PMID:New insights into the regulation of iron homeostasis. 1663 33

We evaluated and treated four white adults (one man, three women) who had iron overload associated with daily ingestion of iron supplements for 7, 15, 35, and 61 years, respectively. We performed HFE mutation analysis to detect C282Y, H63D, and S65C in each patient; in two patients, HFE exons were sequenced. In two patients, direct sequencing was performed to detect coding region mutations of TFR2, HAMP, FPN1, HJV, and ALAS2. Patients 1-4 ingested 153, 547, 1,341, and 4,898 g of inorganic iron as supplements. Patient 1 had hemochromatosis, HFE C282Y homozygosity, and beta-thalassemia minor. Patient 2 had spherocytosis and no HFE coding region mutations. Patient 3 had no anemia, a normal HFE genotype, and no coding region mutations in HAMP, FPN1, HJV, or ALAS2; she was heterozygous for the TFR2 coding region mutation V583I (nt 1,747 G-->A, exon 15). Patient 4 had no anemia and no coding region mutations in HFE, TFR2, HAMP, FPN1, HJV, or ALAS2. Iron removed by phlebotomy was 32.4, 10.4, 15.2, and 4.0 g, respectively. There was a positive correlation of log(10) serum ferritin and the quantity of iron removed by phlebotomy (P = 0.0371). Estimated absorption of iron from supplements in patients 1-4 was 20.9%, 1.9%, 1.1%, and 0.08%. We conclude that the clinical phenotypes and hemochromatosis genotypes of adults who develop iron overload after ingesting iron supplements over long periods are heterogeneous. Therapeutic phlebotomy is feasible and effective, and would prevent complications of iron overload.
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PMID:Iron overload and prolonged ingestion of iron supplements: clinical features and mutation analysis of hemochromatosis-associated genes in four cases. 1683 33

The anemia of inflammation is an acquired disorder affecting patients with a variety of medical conditions, and it is characterized by changes in iron homeostasis and erythropoiesis. Mounting evidence suggests that hepcidin antimicrobial peptide plays a primary role in the pathogenesis of the anemia of inflammation. To evaluate which features of this anemia can be attributed to hepcidin, we have generated mice carrying a tetracycline-regulated hepcidin transgene. Expression of the hepcidin transgene resulted in down-regulation of endogenous hepcidin mRNA. The transgenic mice developed a mild-to-moderate anemia associated with iron deficiency and iron-restricted erythropoiesis. Similar to the anemia of inflammation, iron accumulated in tissue macrophages, whereas a relative paucity of iron was found in the liver. Circulating erythrocytes in transgenic animals had normal survival rates, but transgenic animals had an impaired response to erythropoietin. Thus, hepcidin transgenic mice recapitulate each of the key features of anemia of inflammation in human patients and serve as a useful model of this prevalent disorder.
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PMID:Hepcidin antimicrobial peptide transgenic mice exhibit features of the anemia of inflammation. 1721 83

Since the discovery of HFE gene in 1996, considerable progress has been made concerning the iron-metabolism and its major abnormalities. Five types of hereditary hemochromatosis are actually known: type 1 (HFE gene), type 2A (HJV gene), type 2B (HAMP gene), type 3 (TfR2 gene), type 4 (SLC40A1 gene). The HFE C282Y +/+ mutation is responsible for the most frequent type of hemochromatosis in France. Various secondary causes can lead to iron-overload: associated genetic diseases, exogenous iron intake, thalassaemia and refractory anaemia, hepatic siderosis, alcoholic hepatitis, cutaneous porphyria and cirrhosis. The deleterious consequences of iron-overload are due to the interactions of the environmental factors. The role of HFE heterozygote mutations is still discussed. In clinical practice, the interpretation of a serum ferritin increase is a frequent problem that needs a careful evaluation based on the tranferrin saturation measurement. Significant increase of both these factors is in favour of an HFE C282Y +/+ hemochromatosis, after exclusion of a hepatocellular insufficiency or a refractory anaemia. Nevertheless, high ferritin is not always a marker of iron-overload. Thus, there are many disorders increasing the serum ferritin levels without iron overload : cytolysis (hepatic...), inflammatory or infectious syndromes, high alcohol intake, neoplasia... Looking for HFE mutations help to separate type 1 hemochromatosis from other conditions mainly hepatic siderosis (metabolic disorders). The identification of rare types of hemochromatosis (types 2-4) is only required in particular cases. The evaluation of the iron overload is now based on hepatic MRI determination rather than liver biopsy. Repeated phlebotomies remain the essential way to decrease the iron overload in HFE hemochromatosis and to prevent the occurrence of severe and irreversible complications (cirrhosis, arthropathies, cardiac failure, and diabetes). Because of the link established between the amount of iron-overload and the occurrence of complications and the mortality over-risk in HFE C282Y +/+ hemochromatosis, venesections must be started when serum ferritin is higher than 300 microg/l in man and 200 microg/l in woman, whatever the clinical manifestations are and obviously before the symptomatic phase of the disease.
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PMID:[Hereditary and acquired iron overload]. 1737 75

Hereditary iron overload is mainly due to mutations of the HFE gene, implicated in most cases of hereditary hemochromatosis. Non-HFE-related hereditary iron overload is rare. It includes hereditary hemochromatosis related to mutations of other genes, ferroportin disease (also known as hemochromatosis type 4), and entities associated with specific clinical manifestations. Four genes have been implicated in hereditary hemochromatosis: HFE and TFR2 (which codes for the second transferrin receptor), both involved in adult forms of hereditary hemochromatosis, and HAMP and HJV, which code for hepcidin and hemojuvelin, respectively, and are responsible for juvenile hemochromatosis. All types of hereditary hemochromatosis share common clinical and biological characteristics, including an autosomal recessive inheritance pattern, elevation of transferrin saturation as the initial manifestation, hepatic parenchymal iron overload, and sensitivity to therapeutic phlebotomy. They are due to hyperabsorption of dietary iron and are linked to a deficit of hepcidin, the principal iron regulator in the body. Ferroportin disease is a special dominantly inherited clinical form of iron overload due to mutations of the SLC40A1 gene. Its expression differs significantly from that of hereditary hemochromatosis, and its mechanism is related to impairment of iron release from reticuloendothelial cells. Other causes of non-HFE-related hereditary iron overload are usually associated with recognizable clinical manifestations, such as anemia or neurological disorders.
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PMID:[Non-HFE-related hereditary iron overload]. 1754 May 36

Hepcidin is an iron-regulatory protein that is upregulated in response to increased iron or inflammatory stimuli. Hepcidin reduces serum iron and induces iron sequestration in the reticuloendothelial macrophages - the hallmark of anaemia of inflammation. Iron deprivation is used as a defense mechanism against infection, and it also has a beneficial effect on the control of cancer. The tumour-suppressor p53 transcriptionally regulates genes involved in growth arrest, apoptosis and DNA repair, and perturbation of p53 pathways is a hallmark of the majority of human cancers. This study inspected a role of p53 in the transcriptional regulation of hepcidin. Based on preliminary bioinformatics analysis, we identified a putative p53 response-element (p53RE) contained in the hepcidin gene (HAMP) promoter. Chromatin immunoprecipitation (ChIP), reporter assays and a temperature sensitive p53 cell-line system were used to demonstrate p53 binding and activation of the hepcidin promoter. p53 bound to hepcidin p53RE in vivo, andthis p53RE could confer p53-dependent transcriptional activation. Activation of p53 increased hepcidin expression, while silencing of p53 resulted in decreased hepcidin expression in human hepatoma cells. Taken together, these results define HAMP as a novel transcriptional target of p53. We hypothesise that hepcidin upregulation by p53 is part of a defence mechanism against cancer, through iron deprivation. Hepcidin induction by p53 might be involved in the pathogenesis of anaemia accompanying cancer.
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PMID:Hepcidin, a key regulator of iron metabolism, is transcriptionally activated by p53. 1759 32

The review summarizes the results of the state-of-the-art studies of hemochromatosis (HC): iron-regulatory genes (HFE, HJV, HAMP, TFR2, SLC40A1) have been discovered; the HC types caused by mutations in these genes (types 1, 2, 3, and 4 in the OMIM register) have been identified; the inflammation anemia (IA) mediator - the polypeptide hepatic hormone hepcidin that is an important constituent of the natural immunity system - has been found. This gives an idea of hypersiderosis and dissiderosis as types of iron microelementosis. Types 1, 2, and 3 HC in which iron absorption and its total reserves are increased in the body serve as examples of hypersiderosis. Dissiderosis is characterized by the redistribution of iron between the functional and spare funds inherent in type 4 HC and IA. By taking into account their findings, the authors briefly discuss the leading clinical and morphological manifestations of HC and IA, difficulties in differential diagnosis, and treatment ways and prospects.
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PMID:[Hypersiderosis and dissiderosis in the context of data on hemochromatosis microelementosis]. 1872 23

Heme oxygenase-1 (HO-1) contribution to iron homeostasis has been postulated, because it facilitates iron recycling by liberating iron mostly from heme catabolism. This enzyme also appears to be responsible for the resolution of inflammatory conditions. In a patient with HO-1 deficiency, inflammation and dysregulation of body iron homeostasis, including anemia and liver and kidney hemosiderosis, are evidenced. Here we postulated that HO-1 is critical in the regulation of ferroportin, the major cellular iron exporter, and hepcidin, the key regulator of iron homeostasis central in the pathogenesis of anemia of inflammation. Our current experiments in human THP-1 monocytic cells indicate a HO-1-induced iron-mediated surface-ferroportin expression, consistent with the role of HO-1 in iron recycling. Surprisingly, we observed low hepcidin levels in the HO-1-deficient patient, despite the presence of inflammation and hemosiderosis, both inducers of hepcidin. Instead, we observed highly increased soluble transferrin receptor levels. This suggests that the decreased hepcidin levels in HO-1 deficiency reflect the increased need for iron in the bone marrow due to the anaemia. Using human hepatoma cells, we demonstrate that HO-activity did not have a direct modulating effect on expression of HAMP, the gene that encodes for hepcidin. Therefore, we argue that the decreased iron recycling may, in part, have contributed to the low hepcidin levels. These findings indicate that dysregulation of iron homeostasis in HO-1 deficiency is the result of both defective iron recycling and erythroid activity-associated inhibition of hepcidin expression. This study therefore shows a crucial role for HO-1 in maintaining body iron balance.
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PMID:Hepcidin suppression and defective iron recycling account for dysregulation of iron homeostasis in heme oxygenase-1 deficiency. 1877 56


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