Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UMLS:C0240066 (iron deficiency)
 7,156 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mechanism that leads to iron overload in hereditary hemochromatosis is not yet fully understood and genes other than HFE may be involved. Nramp2 is an intestinal iron transporter, upregulated by dietary iron deficiency, which also colocalizes with transferrin in recycling endosomes. The purpose of the present study was to analyze the coding region of the Nramp2 gene in 14 hemochromatosis probands which did not carry any HFE mutations on both chromosomes. We confirmed the existence of a polymorphism (1254 T --> C), which presumably is not associated with hereditary hemochromatosis, but we did not find any mutation. On the other hand, we identified 17 splice variants of the Nramp2 mRNA. Eight corresponded to activation of cryptic splicing sequences between exons 3 and 4. They were observed in a majority of hemochromatosis probands and control subjects. This indicates the existence of an important splicing instability in this region. At this stage, the biological significance of these variants is unclear. Our study did not find evidence for the involvement of the Nramp2 gene in hereditary hemochromatosis. The remaining question is whether hemochromatosis probands in our study have iron overload because of environmental factors or due to mutation in gene(s) other than HFE and Nramp2.
 ...
PMID:Nramp2 analysis in hemochromatosis probands. 1104 33

We describe a case of homozygosity due to the substitution of aspartic acid with histidine at position 63 of the protein encoded by the gene (known as HFE) associated with hereditary hemochromatosis. Liver biopsy did not disclose stainable iron accumulation; serum ferritin was elevated (639 ng/mL), while the transferrin saturation index was within the normal range (38.1%). As the patient was affected by chronic hepatitis C virus, the high serum ferritin could be attributed to this disease, a frequent occurrence. We also describe a case of heterozygosity for both the substitution of tyrosine with cysteine at position 282 and the substitution of histidine to aspartic acid at position 63 (so-called "compound heterozygosity"). The patient had the typical biochemical abnormalities of iron overload: transferrin saturation index of 53.1% and elevated serum ferritin (658 ng/mL). The removal of > 5 g of iron by phlebotomies did not precipitate iron deficiency. Although the patient refused to undergo liver biopsy, clinical evidence alone enabled a diagnosis of hemochromatosis. These two cases concord with the present scientific orientation, i.e.: 1) homozygosity for the major mutation is associated with the phenotypical (clinical) picture of hemochromatosis, but compound heterozygosity also determines significant iron metabolism abnormalities; 2) homozygosity for the minor mutation does not appear to determine important phenotypical abnormalities.
 ...
PMID:[Significance of "minor" genetic mutations in hereditary hemochromatosis: 2 case reports]. 1105 64

Restless legs syndrome (RLS) occurs in some persons with iron deficiency, and some persons with RLS benefit from oral iron therapy. Approximately one in 200 persons of northern European ancestry have hemochromatosis attributable to inheritance of two common mutations of the hemochromatosis-associated HFE gene on chromosome 6. We evaluated and treated a 46-year-old man with RLS who was diagnosed as having hemochromatosis after he developed new symptoms associated with taking iron therapy for RLS. He had transferrin saturation 88%, serum ferritin 658 ng/ml, and C282Y homozygosity. Therapeutic phlebotomy of one unit of blood (450-500 ml) weekly (total 24 units) relieved his non-RLS symptoms, caused RLS symptoms to occur more frequently, and was associated with transient fatigue and mild dependent edema. His sister, who also has RLS, was subsequently diagnosed as having hemochromatosis. We conclude that serum transferrin saturation and ferritin levels should be measured before initiation of iron therapy of RLS. Patients with a history of iron deficiency or low serum iron parameters should undergo evaluation for iron deficiency; patients who have histories suggestive of hemochromatosis or iron overload or elevated pre-treatment transferrin saturation or serum ferritin levels should undergo evaluation to determine the cause of these abnormalities before they are treated with iron. In all persons with RLS treated with oral iron, serum iron parameters should be re-measured once or twice yearly during therapy.
 ...
PMID:Hemochromatosis and iron therapy of Restless Legs Syndrome. 1131 89

Hereditary hemochromatosis (HH) is a common genetic disorder. Although it is inherited in an autosomal recessive manner, heterozygous individuals are believed to be protected against iron deficiency. Screening to estimate the prevalence of HH was frequently performed among blood donors, not considering that carriers of the HH gene mutations may be present in higher proportion in this population. To examine the allele frequencies of the HH gene (HFE) point mutations, C282Y and H63D genotyping was carried out in 996 consecutive, first-time, and regular Hungarian blood donors by PCR-RFLP techniques. Iron parameters of the first-time donors and the identified C282Y heterozygotes and age, gender, and number of previous blood donation-matched wild-type donors were also determined. We were not able to demonstrate a significant increase in the frequency of C282Y and H63D alleles among regular blood donors, compared to first-time blood donors. However, there was a trend of higher C282Y allele frequency among women with higher number of previous blood donations (2.2 +/- 1.5% in female blood donors with 0-8 previous blood donations compared to 4.8 +/- 2.3% in women with more than 8 previous blood donations, P = 0.06). No detectable phenotypic differences were observed in serum iron, ferritin, and transferrin saturation values between C282Y wild-type and heterozygous groups. However, the single identified C282Y homozygous male (age 21) showed definite signs of iron overload. Our observations suggest that the protective effect of C282Y heterozygosity against iron deficiency may be less significant than other environmental (e.g., iron-rich diet) or genetic factors.
 ...
PMID:Genotype screening for hereditary hemochromatosis among voluntary blood donors in Hungary. 1135 95

The content of body iron is regulated primarily by absorption since humans have no physiological mechanism by which excess iron is excreted. This regulation, however, is not absolute. Many factors such as the content of diets, iron doses, life styles, etc. influence iron absorption. In the past, nutrition programs for iron fortification and the ingestion of iron preparations have been widely practiced because of the seriousness of worldwide iron deficiency. Also, we now know that a significant number of asymptomatic people carry the hemochromatosis gene, HFE, indicating that these people have the potential to accumulate excess body iron in their lifetime. Excess body iron can be highly toxic. This toxicity involves many organs leading to a variety of serious diseases such as liver disease, heart disease, diabetes mellitus, hormonal abnormalities, dysfunctional immune system, etc. The tissue damage associated with iron overload is believed to result primarily from free radical reactions mediated by iron. Iron is an effective catalyst in free radical reactions. The diseases associated with iron overload can be managed effectively or prevented. Therefore, early diagnosis of iron overload and appropriate therapy are critical. By providing the necessary laboratory data, clinical chemistry laboratories can play the pivotal role in the management of these health problems.
 ...
PMID:Chronic iron overload and toxicity: clinical chemistry perspective. 1151 32

This review examines the clinical consequences for the practicing hematologist of remarkable new insights into the pathophysiology of disorders of iron and heme metabolism. The familiar proteins of iron transport and storage-transferrin, transferrin receptor, and ferritin-have recently been joined by a host of newly identified proteins that play critical roles in the molecular management of iron homeostasis. These include the iron-regulatory proteins (IRP-1 and -2), HFE (the product of the HFE gene that is mutated in most patients with hereditary hemochromatosis), the divalent metal transporter (DMT1), transferrin receptor 2, ceruloplasmin, hephaestin, the "Stimulator of Fe Transport" (SFT), frataxin, ferroportin 1 and others. The growing appreciation of the roles of these newly identified proteins has fundamental implications for the clinical understanding and laboratory evaluation of iron metabolism and its alterations with iron deficiency, iron overload, infection, and inflammation. In Section I, Dr. Brittenham summarizes current concepts of body and cellular iron supply and storage and reviews new means of evaluating the full range of body iron stores including genetic testing for mutations in the HFE gene, measurement of serum ferritin iron, transferrin receptor, reticulocyte hemoglobin content and measurement of tissue iron by computed tomography, magnetic resonance imaging and magnetic susceptometry using superconducting quantum interference device (SQUID) instrumentation. In Section II, Dr. Weiss discusses the improved understanding of the molecular mechanisms underlying alterations in iron metabolism due to chronic inflammatory disorders. The anemia of chronic disorders remains the most common form of anemia found in hospitalized patients. The network of interactions that link iron metabolism with cellular immune effector functions involving pro- and anti-inflammatory cytokines, acute phase proteins and oxidative stress is described, with an emphasis on the implications for clinical practice. In Section III, Dr. Brissot and colleagues discuss how the diagnosis and management of hereditary hemochromatosis has changed following the identification of the gene, HFE, that is mutated in most patients with hereditary hemochromatosis, and the subsequent development of a genotypic test. The current understanding of the molecular effects of HFE mutations, the usefulness of genotypic and phenotypic approaches to screening and diagnosis and recommendations for management are summarized.
 ...
PMID:Clinical Consequences of New Insights in the Pathophysiology of Disorders of Iron and Heme Metabolism. 1170 34

Iron is a vitally important element in mammalian metabolism because of its unsurpassed versatility as a biologic catalyst. However, when not appropriately shielded or when present in excess, iron plays a key role in the formation of extremely toxic oxygen radicals, which ultimately cause peroxidative damage to vital cell structures. Organisms are equipped with specific proteins designed for iron acquisition, export, transport, and storage as well as with sophisticated mechanisms that maintain the intracellular labile iron pool at an appropriate level. These systems normally tightly control iron homeostasis but their failure can lead to iron deficiency or iron overload and their clinical consequences. This review describes several rare iron loading conditions caused by genetic defects in some of the proteins involved in iron metabolism. A dramatic decrease in the synthesis of the plasma iron transport protein, transferrin, leads to a massive accumulation of iron in nonhematopoietic tissues but virtually no iron is available for erythropoiesis. Humans and mice with hypotransferrinemia have a remarkably similar phenotype. Homozygous defects in a recently identified gene encoding transferrin receptor 2 lead to iron overload (hemochromatosis type 3) with symptoms similar to those seen in patients with HFE-associated hereditary hemochromatosis (hemochromatosis type 1). Transferrin receptor 2 is primarily expressed in the liver but it is unclear how mutant forms cause iron overload. Mutations in the gene encoding the iron exporter, ferroportin 1, cause iron overload characterized by iron accumulation in macrophages yet normal plasma iron levels. Plasma iron, together with dominant inheritance, discriminates iron overload due to ferroportin mutations (hemochromatosis type 4) from hemochromatosis type 1. Heme oxygenase 1 is essential for the catabolism of heme and in the recycling of hemoglobin iron in macrophages. Homozygous heme oxygenase 1 deletion in mice leads to a paradoxical accumulation of nonheme iron in macrophages, hepatocytes, and many other cells and is associated with low plasma iron levels, anemia, endothelial cell damage, and decreased resistance to oxidative stress. A similar phenotype occurred in a child with severe heme oxygenase 1 deficiency. 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 ataxia, the most common of the inherited ataxias. Frataxin appears to regulate mitochondrial iron (or iron-sulfur cluster) export and the neurologic and cardiac manifestations of Friedreich ataxia are due to iron-mediated mitochondrial toxicity. Finally, 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.
 ...
PMID:Rare causes of hereditary iron overload. 1238

The modern British diet contains less red meat and is lower in iron than that consumed 30 years ago. This is in spite of the fact that fortification of foods, particularly breakfast cereals, with iron has become more widespread. Although there is no clear relationship between dietary iron intake and iron status, isotope studies have identified multiple dietary factors that influence iron absorption, such as ascorbic acid, animal tissue, phytates and polyphenols. There is no evidence to suggest that current dietary changes will have a major impact on iron status in the general population; however, effects on the incidence of iron overload in individuals with HFE mutations and iron deficiency in children and premenopausal women remain to be determined.
 ...
PMID:Clinical implications of changes in the modern diet: iron intake, absorption and status. 1240 5

Haemochromatosis may be inherited or acquired. The commonest inherited form is HFE-related genetic haemochromatosis (GH). This is associated with homozygosity for the C282Y mutation in the HFE gene. Individuals with GH present in several ways depending upon the severity of iron overload. However, only a small proportion of genetically susceptible individuals develop disease. Diagnosis of GH is based on measurement of transferrin saturation, serum ferritin levels and mutation analysis of HFE. Liver biopsy is not necessary for diagnosis. It is used to establish the severity of liver disease in selected patients. Other complications of iron overload are identified by specific tests. Initial management of GH is by weekly venesection until borderline iron deficiency is achieved. The serum ferritin is then maintained at 50 microg/l by 3-6 monthly venesection. Specific organ damage is managed appropriately. Early diagnosis and treatment before irreversible damage has occurred gives a normal life expectancy. Non-HFE related inherited iron overload may be due to mutations in other iron related genes. Management is along the same lines as for GH, although if venesection is not tolerated, other approaches may be necessary.
 ...
PMID:Diagnosis and management of genetic haemochromatosis. 1240 8

Iron deficiency is the most common disorder of iron metabolism worldwide, but there is concern that iron accumulation resulting from enhanced iron absorption may also be a cause of morbidity. In patients with genetic haemochromatosis the clinical manifestations of iron overload are well-known. In northern Europe 90% of such patients are homozygous for the C282Y mutation of the HFE gene and this genotype is found in 1 in 200 of the population. Heterozygosity for C282Y occurs in 15% of the population and 25% carry another mutation, H63D. Population studies have revealed (i) the serum transferrin saturation is strongly influenced by HFE genotype, being lowest in subjects lacking mutations and highest in those homozygous for C282Y; (ii) most subjects homozygous for C282Y accumulate iron but do not present with the clinical manifestations of iron overload. Testing for HFE mutations in clinics for diabetes, liver disease and cardiovascular disease has shown that homozygosity for C282Y is not commonly found. Heterozygosity for either C282Y or H63D does not appear to be a risk factor for these common conditions.
 ...
PMID:HFE Mutations as risk factors in disease. 1240 9


<< Previous 1 2 3 4 5 6 7 8 Next >>