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Target Concepts:
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Query: UMLS:C0086543 (
cataract
)
29,165
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The classification of hereditary abnormalities of iron metabolism was recently expanded and diversified. Genetic hemochromatosis now corresponds to six diseases, namely classical hemochromatosis HFE 1; juvenile hemochromatosis HFE 2 due to mutations in an unidentified gene on chromosome 1; hemochromatosis HFE 3 due to mutations in the transferrin receptor 2 (TfR2); hemochromatosis HFE 4 caused by a mutation in the H subunit of ferritin; and hemochromatosis HFE 6 whose gene is hepcidine (
HAMP
). Systemic iron overload is also associated with aceruloplasminemia, atransferrinemia and the "Gracile" syndrome caused by mutations in BCS1L. The genes responsible for neonatal and African forms of iron overload are unknown. Other genetic diseases are due to localized iron overload: Friedreich's ataxia results from the expansion of triple nucleotide repeats within the frataxin (FRDA) gene; two forms of X-linked sideroblastic anemia are due to mutations within the delta aminolevulinate synthetase (ALAS 2) or ABC-7 genes; Hallervorden-Spatz syndrome is caused by a pantothenate kinase 2 gene (PANK-2) defect; neuroferritinopathies; and hyperferritinemia--
cataract
syndrome due to a mutation within the L-ferritin gene. In addition to this wide range of genetic abnormalities, two other features characterize these iron disorders: 1) most are transmitted by an autosomal recessive mechanism, but some, including hemochromatosis type 4, have dominant transmission; and 2) most correspond to cytosolic iron accumulation while some, like Friedreich's ataxia, are disorders of mitochondrial metabolism.
...
PMID:[Genetics of hereditary iron overload]. 1550 16
The number of new genes implicated in iron metabolism has dramatically increased during the last few years. Alterations of these genes may cause hyperferritinemia associated or not with iron overload. Correct assignment of the specific disorder of iron metabolism requires the identification of the causative gene mutation. Here, we propose a rational strategy that allows targeting the gene(s) to be screened for a diagnostic purpose. This strategy relies on the age of onset of the disease, the type of clinical symptoms, the biochemical profile (elevated or normal serum transferrin saturation (TfSat)), the presence or not of visceral iron excess, and the mode of inheritance (autosomal recessive or dominant). Then, two main entities can be differentiated: genetic (adult or juvenile) hemochromatosis characterized by elevated TfSat, and hereditary hyperferritinemias where TfSat is normal (or only slightly modified). Adult genetic hemochromatosis (GH) is related mainly to mutations of the HFE gene, and exceptionally to mutations of the TFR2 gene. Juvenile GH is a rare condition related principally to mutations of the HJV gene coding for hemojuvelin, and rarely to mutations of the
HAMP
gene coding for hepcidin. Hereditary hyperferritinemias are linked to mutations of three genes: the L-ferritin gene responsible for the hereditary hyperferritinemia
cataract
syndrome (without iron overload), the ferroportin gene leading to a dominant form of iron overload, and the ceruloplasmin (CP) gene corresponding to an iron overload syndrome with neurological symptoms. The proposed strategic approach may change with the identification of other genes involved in iron metabolism.
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PMID:The evaluation of hyperferritinemia: an updated strategy based on advances in detecting genetic abnormalities. 1584 97
