UMLS:C0086543 - FACTA Search

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Query: UMLS:C0086543 (cataract)
29,165 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In higher eukaryotes, the expression of about 1 gene in 10 is strongly regulated at the level of messenger RNA (mRNA) translation into protein. Negative regulatory effects are often mediated by the 5'-untranslated region (5'-UTR) and rely on the fact that the 40S ribosomal subunit first binds to the cap structure at the 5'-end of mRNA and then scans for the first AUG codon. Self-complementary sequences can form stable stem-loop structures that interfere with the assembly of the preinitiation complex and/or ribosomal scanning. These stem loops can be further stabilized by the interaction with RNA-binding proteins, as in the case of ferritin. The presence of AUG codons located upstream of the physiological start site can inhibit translation by causing premature initiation and thereby preventing the ribosome from reaching the physiological start codon, as in the case of thrombopoietin (TPO). Recently, mutations that cause disease through increased or decreased efficiency of mRNA translation have been discovered, defining translational pathophysiology as a novel mechanism of human disease. Hereditary hyperferritinemia/cataract syndrome arises from various point mutations or deletions within a protein-binding sequence in the 5'-UTR of the L-ferritin mRNA. Each unique mutation confers a characteristic degree of hyperferritinemia and severity of cataract in affected individuals. Hereditary thrombocythemia (sometimes called familial essential thrombocythemia or familial thrombocytosis) can be caused by mutations in upstream AUG codons in the 5'-UTR of the TPO mRNA that normally function as translational repressors. Their inactivation leads to excessive production of TPO and elevated platelet counts. Finally, predisposition to melanoma may originate from mutations that create translational repressors in the 5'-UTR of the cyclin-dependent kinase inhibitor-2A gene.
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PMID:Translational pathophysiology: a novel molecular mechanism of human disease. 1082 6

The case of a male infant who was found to have hyperferritinemia was made at the age of 3 months is described. The patient and several members of his family from three generations were diagnosed with hereditary hyperferritinemia-cataract syndrome with a new point mutation in the iron-responsive element of the L-ferritin gene. Differential diagnosis of hyperferritinemia is discussed with emphasis on the need for the knowledge of this entity to avoid unnecessary investigations.
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PMID:[Isolated hyperferritinemia in a healthy male infant: hereditary hyperferritinemia-cataract syndrome]. 1246 62

Previous studies have shown that lenticular levels of Fe and Cu are elevated in age-related cataract. However, it is not known if these metals are present in a state that is permissive for redox reactions that may lead to the formation of free radicals. In addition, there is little data available concerning the concentration and lenticular distribution of ferritin, the major intracellular Fe-sequestering protein, in the lens. The aim of the present work was therefore to determine the distribution of ferritin and the redox-availability of Fe and Cu in healthy and cataractous lenses. Lens ferritin distribution was assessed by ELISA and immunohistochemistry. A modified ELISA detected ferritin in an 'insoluble' lens protein fraction. Ferritin levels were not significantly different in the cortex vs nucleus of healthy lenses. In contrast, ferritin levels in the cataractous lens nuclei appeared to be 70% lower compared to the cortex. This was at least partially due to the presence of ferritin within an insoluble protein fraction of the homogenized lenses. In normal lenses, ferritin staining was most intense in the epithelium, with diffuse staining observed throughout the cortex and nucleus. The redox-availability of lenticular metals was determined using: (1) autometallography; (2) Ferene-S as a chromogenic Fe chelator; and (3) NO release from nitrosocysteine to probe for redox-active Cu. The autometallography studies showed that the cataractous lenses stained more heavily for redox-active metals in both the nucleus and cortex when compared to age-matched control lenses. Chelatable Fe was detected in homogenized control lenses after incubation with Ferene-S, with almost three-fold higher levels detected in the cataractous lenses on average. The Cu-catalysed liberation of NO from added nitrosocysteine was not demonstrated in any lens sample. When exogenous Cu (50 n M) was added to the lenses, it was rapidly chelated. The cataractous samples were approximately twice as effective at redox-inactivation of added Cu. These studies provide evidence that a chelatable pool of potentially redox-active Fe is present at increased concentrations in human cataractous lenses. In contrast, it seems that lenticular Cu may not be readily available for participation in redox reactions.
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PMID:Distribution of ferritin and redox-active transition metals in normal and cataractous human lenses. 1109 12

Hereditary hyperferritinaemia cataract syndrome (HHCS) is characterized by hyperferritinaemia without iron overload. It is essential to differentiate true iron accumulation from HHCS as these patients rapidly develop iron-deficient anaemia when subjected to phlebotomies. The diagnosis of HHCS relies on the identification of point mutations or deletions present in the iron-responsive element of the first exon of the L-ferritin gene. However, many samples referred for diagnosis of putative HHCS are normal. To avoid unnecessary DNA sequencing, we have developed a diagnosis strategy based on the screening of the target DNA region by denaturing gradient gel electrophoresis. This method enabled the accurate identification of 11 different previously known mutations. This strategy will be of interest for family studies or for the screening of large series of patients.
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PMID:Denaturing gradient gel electrophoresis screening for mutations in the hereditary hyperferritinaemia cataract syndrome. 1116 83

Hereditary hyperferritinemia-cataract syndrome is a genetic condition characterized by constitutively increased serum ferritin values in the absence of iron overload and by bilateral cataract. It has been demonstrated that mutations in the stem loop structure of the iron regulatory element (IRE) located in the 5'-untranslated region of the ferritin L-subunit gene (19q13.1) are responsible for the anomalous expression of this protein. Although not clearly explained, cataract formation seems secondary to the increased levels of ferritin in the lens. We analyzed a large Basque family in order to identify possible germline alterations of the iron regulatory element of the ferritin-L gene in affected individuals and first-degree relatives. All members of the family presented hyperferritinemia and cataract except a young child who had hyperferritinemia but did not present cataract. Sequence analysis permitted the identification of an A40-->G mutation in all members, including this child. This could demonstrate that cataract formation is a consequence of ferritin accumulation in the lens.
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PMID:Molecular analysis of hereditary hyperferritinemia-cataract syndrome in a large Basque family. 1130 47

Ferritin, the iron-storing molecule, is made by the assembly of various proportions of 2 different H and L subunits into a 24-mer protein shell. These heteropolymers have distinct physicochemical properties, owing to the ferroxidase activity of the H subunit, which is necessary for iron uptake by the ferritin molecule, and the ability of the L subunit to facilitate iron core formation inside the protein shell. It has previously been shown that H ferritin is indispensable for normal development, since inactivation of the H ferritin gene by homologous recombination in mice is lethal at an early stage during embryonic development. Here the phenotypic analysis of the mice heterozygous for the H ferritin gene (Fth(+/-) mice) is reported, and differences in gene regulation between the 2 subunits are shown. The heterozygous Fth(+/-) mice were healthy and fertile and did not present any apparent abnormalities. Although they had iron-overloaded spleens at the adult stage, this is identical to what is observed in normal Fth(+/+) mice. However, these heterozygous mice had slightly elevated tissue L ferritin content and 7- to 10-fold more L ferritin in the serum than normal mice, but their serum iron remained unchanged. H ferritin synthesis from the remaining allele was not up-regulated. This probably results from subtle changes in the intracellular labile iron pool, which would stimulate L ferritin but not H ferritin synthesis. These results raise the possibility that reduced H ferritin expression might be responsible for unexplained human cases of hyperferritinemia in the absence of iron overload where the hereditary hyperferritinemia-cataract syndrome has been excluded. (Blood. 2001;98:525-532)
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PMID:H ferritin knockout mice: a model of hyperferritinemia in the absence of iron overload. 1146 45

Hereditary hyperferritinaemia-cataract syndrome (HHCS) is an autosomal dominant disease caused by mutations in the iron responsive element (IRE) of the l-ferritin gene. Despite the elucidation of the genetic basis, the overall clinical spectrum of HHCS has been less well studied as, to date, only individual case reports have been described. Therefore, we studied a total of 62 patients in 14 unrelated families, with nine different mutations. No relevant symptoms other than visual impairment were found to be associated with the syndrome. A marked phenotypic variability was observed, particularly with regard to ocular involvement (i.e. age range at which cataract was diagnosed in 16 subjects with the C39T: 6-40 years). Similarly, serum ferritin levels varied substantially also within subjects sharing the same mutation (i.e. range for the A40G: 700-2412 microg/l). We followed an HHCS newborn in whom well-defined lens opacities were not detectable either at birth or at 1 year. The lens ferritin content was analysed in two subjects who underwent cataract surgery at different ages, with different cataract morphology. Values were similar and about 1500-fold higher than in controls. These observations suggest that: (i) in HHCS the cataract is not necessarily congenital; (ii) in addition to the IRE genotype, other genetic or environmental factors may modulate the phenotype, especially the severity of the cataract.
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PMID:Clinical, biochemical and molecular findings in a series of families with hereditary hyperferritinaemia-cataract syndrome. 1170 32

In the last few years, mutations that cause disease through increased efficiency of mRNA translation have been discovered. Hereditary hyperferritinaemia-cataract syndrome (HHCS) arises from various point mutations or deletions within the iron-responsive element (IRE) in the 5'-UTR of the L-ferritin mRNA. Each unique mutation confers a characteristic degree of hyperferritinaemia and severity of cataract in affected individuals. We report a novel six-nucleotide deletion identified in an Italian family presenting with elevated serum ferritin and early onset bilateral cataract. This deletion involves a sequence with a TCT repetition and may have occurred through a mechanism of slippage mispairing. Because of the above repetition, the observed mutation can be interpreted as deletion 22-27, 23-28, 24-29 or 25-30. Structural modelling predicted an IRE stem modification that is expected to markedly reduce the binding to iron-regulatory proteins. A double-gradient denaturing gradient gel electrophoresis (DG-DGGE) method easily detected the above deletion.
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PMID:A novel deletion of the L-ferritin iron-responsive element responsible for severe hereditary hyperferritinaemia-cataract syndrome. 1184 30

Hereditary hyperferritinaemia-cataract syndrome (HHCS) (OMIM #600886) is a rare autosomal dominant condition identified by high serum ferritin levels with normal iron saturation and distinctive bilateral cataract. It may be misdiagnosed as haemochromatosis and such patients become anaemic as a result of inappropriate venesection. The elevated serum ferritin is due to a mutation in the iron-responsive element (IRE) of the l-ferritin gene, resulting in excessive l-ferritin production. We report the identification of three Australian pedigrees; one with a previously described mutation at position 40, a pedigree with a novel mutation at position 39 and an individual with a de novo mutation at position 32 of the l-ferritin IRE.
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PMID:Mutation spectrum in Australian pedigrees with hereditary hyperferritinaemia-cataract syndrome reveals novel and de novo mutations. 1219 4

In mammalian cells, cellular iron homeostasis is maintained by the co-ordinated regulation of transferrin receptor and ferritin synthesis that occurs at the translational level. This regulation is mediated by iron-responsive elements (IREs) that are found within the untranslated regions (UTRs) of mRNA and by cytoplasmic mRNA-binding proteins, known as iron regulatory proteins (IRPs). When cellular iron is scarce, IRPs are available for binding the 5' IRE of ferritin mRNA, initiation of translation is prevented and ferritin synthesis is inhibited. By contrast, the presence of abundant intracellular iron prevents binding of the IRPs to the 5' IRE and allows efficient mRNA translation to proceed. Hereditary hyperferritinaemia/cataract syndrome (HHCS) arises as a result of various point mutations or deletions within a protein binding sequence in the 5'-UTR of the L-ferritin mRNA, which results in increased efficiency of L-ferritin translation. Each unique mutation confers a characteristic degree of hyperferritinaemia and severity of cataract in affected individuals. This exemplifies a new paradigm in which mutations in mRNA cis-acting elements may be responsible for phenotypic variability in disease states.
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PMID:Hereditary hyperferritinaemia/ cataract syndrome. 1240 13

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