UNIPROT:P06889 - FACTA Search

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Query: UNIPROT:P06889 (Mol)
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1. Iron, acid phosphatase and N-acetyl-beta-glucosaminidase were assayed in liver biopsies from control subjects and patients with primary and secondary haemochromatosis. 2. The activities of the lysosomal enzymes were significantly higher in liver biopsies from patients with iron overload than in those from other patient groups. 3. Lysosomes from the livers of patients with iron overload were strikingly more fragile than those of control subjects as demonstrated by assays of latent and sedimentable N-acetyl-beta-glucosaminidase. 4. Lysosomal integrity was essentially normal in biopsies from patients with a wide variety of chronic liver diseases. 5. It is suggested that iron accumulation damages lysosomal membrane, releasing acid hydrolases into the cytoplasm and thus initiating cell damage.
Clin Sci Mol Med 1976 Jan
PMID:Acid hydrolase activities and lysosomal integrity in liver biopsies from patients with iron overload. 124 5

Rats fed a carbonyl iron-supplemented diet for 4-15 months were studied for iron content and morphologic changes in the liver, spleen, intestinal mucosa, pancreas and heart. All organs had an increased iron content measured by atomic absorption, with the highest concentrations in the liver and spleen. The periportal distribution of stored iron in the liver was similar to that in human hemochromatosis. In animals treated beyond 6 months Kupffer cells and sinusoidal lining cells also showed cytosiderosis. Electron microscopy provided information on ferritin and hemosiderin content and distribution within parenchymal and sinusoidal cells of the liver but no excessive fibrosis was found. Except for the spleen, the other organs showed less iron deposition. Iron-filled lysosomes (siderosomes) were found in macrophages in the intestinal lamina propria and pancreas, as well as in enterocytes, pancreatic acinar cells and heart muscle cells. Heavily iron-laden siderosomes had increased membrane instability which was demonstrated both morphologically and by measurements of latent lysosomal enzyme activities. Even though cirrhosis was not found, the distribution pattern of accumulated storage iron and lysosomal lability indicated that the carbonyl iron-fed rat is a suitable experimental model for human hemochromatosis.
Virchows Arch B Cell Pathol Incl Mol Pathol 1987
PMID:Ultrastructural observations in the carbonyl iron-fed rat, an animal model for hemochromatosis. 289 Feb 33

The expression of transferrin receptors (TfR's) has been investigated in eight liver biopsy specimens (four from patients without demonstrable iron and four from patients with iron storage due to primary hemochromatosis (HC)) using immunoelectron microscopy to demonstrate TfR's by the simultaneous application of two specific monoclonal antibodies (OKT9 and B3/25) to tissue chopper sections. In the four specimens without iron overload, hepatocytes, but not sinusoidal lining cells, stained positively and immunoreactivity was mainly localized in the cytoplasm. Positively stained cisternae of the endoplasmic reticulum indicated synthesis of the TfR. The presence of TfR's on segments and coated invaginations of the sinusoidal membrane and in small, but otherwise unidentified vesicles in the cytoplasm is compatible with endo-/exocytotic transport and recycling of TfR's as demonstrated by biochemical studies. Occasional positively stained material in canalicular lumina together with positively stained canalicular microvilli and pericanalicular vesicles suggest that transcellular transport may be an additional pathway for TfR's. In three biopsies showing severe iron overload due to HC, TfR immunoreactivity was completely absent. The remaining specimen showing HC, exhibited relatively mild iron overload and showed only a few positively stained hepatocytes. This supports the previously reported disappearance of hepatic TfR expression in HC when iron overload is severe.
Virchows Arch B Cell Pathol Incl Mol Pathol 1988
PMID:Immunoelectron microscopic localization of hepatic transferrin receptors in human liver with and without iron overload. 289 29

The gene for hereditary haemochromatosis (HC) is linked to HLA-A and D6S105 on chromosome 6p. Both markers have also been reported to display linkage disequilibrium with the disease. However, their physical localization relative to one another has not been established. We demonstrate by fluorescent in situ hybridisation that D6S105 lies at least 1-2 Mb telomeric of HLA-A. The haemochromatosis critical region extending from proximal of HLA-A to distal of D6S105 is therefore large. To improve the genetic resolution in this region more highly polymorphic markers are required. We have therefore isolated three novel CA dinucleotide repeats close to D6S105. A linkage disequilibrium study, with two of these microsatellites, in HC patients and controls lends support to the conclusion that D6S105 is a close marker to the haemochromatosis gene.
Hum Mol Genet 1994 Nov
PMID:Isolation of CA dinucleotide repeats close to D6S105; linkage disequilibrium with haemochromatosis. 787 24

A yeast artificial chromosome (YAC B30) with a 320 kb insert of genomic DNA which includes the HLA-A gene was used to screen a cDNA library of human duodenal mucosa. Seven cDNA clones were isolated which correspond to seven new non-HLA class I structural genes. These new genes are located within a region that may well contain the gene responsible for hemochromatosis and have therefore been named HCG I-VII (Hemochromatosis Candidate Gene). HCG I, III, V and VI are probably single copy genes, situated at 180, 155, 140 and 230 kb centromeric to HLA-A, respectively. HCG II, IV and VII present several copies: one copy of HCG II, one of HCG IV and one of HCG VII are centromeric to HLA-A (at 30, 70 and 100 kb respectively). Another copy of HCG IV is 20 kb telomeric to HLA-A. Each of the genes localized on the YAC B30 is associated with an CpG/HTF island.
Hum Mol Genet 1993 Jan
PMID:Localization of seven new genes around the HLA-A locus. 849 Jun 24

Hereditary Hemochromatosis (HFE) is one of the most common inherited disorders with an estimated frequency of homozygous patients of 0.002-0.0045. The disease is characterized by increased intestinal iron absorption and progressive iron overload. Affected subjects show clinical symptoms of parenchymal organ damage after the third-fourth decade of life and have a 200 fold increased risk of developing hepatocellular carcinoma. Early diagnosis and treatment prevent complications and may normalize life expectancy of patients. The biochemical and genetic defects leading to progressive iron accumulation are still unknown, but the HFE gene is tightly linked to HLA complex on the short arm of chromosome 6. Utilizing HLA serotypes and the study of several polymorphic markers of 6p21, a linkage analysis of the disease locus was performed in a series of Italian hemochromatosis families. The data obtained by linkage analysis and the study of a family with a double recombinant allowed us to better define the HFE gene location with respect to HLA-class I A and F loci.
Hum Mol Genet 1993 May
PMID:Linkage analysis of 6p21 polymorphic markers and the hereditary hemochromatosis: localization of the gene centromeric to HLA-F. 851 96

The haemochromatosis gene (HFE) is linked to both HLA-A and D6S105 on the short arm of chromosome 6 but these markers are separated by approximately 2 Mb of DNA. Most chromosomes carrying HFE have a common haplotype which extends from HLA-A to D6S105 and includes HLA-F. To localise the gene more precisely we have examined 10 microsatellite markers extending over a genetic distance of approximately 5 cM from D6S265 (within 100 kb of HLA-A on the centromeric side) to D6S299 (telomeric). The order of markers is D6S265, HLA-F, D6S258, D6S306, CS3, D6S105, D6S464, CS5, D6S461 and D6S299. We confirm that haemochromatosis appears to originate from a founder mutation which has multiplied in the population through successive generations. This mutation is associated with the haplotype D6S306-5, CS3-3, D6S105-8, D6S464-9 and CS5-4 which is found on approximately 70% of HFE chromosomes. We have applied a new and powerful, likelihood analysis for linkage disequilibrium. The maximum value of lambda (proportion of total possible association between a marker and disease) is 0.74 for marker CS5 (allele 4). A multipoint analysis also gives a maximum likelihood near marker CS5. We conclude that the HFE gene is likely to be located telomeric of D6S105 and close to CS5.
Hum Mol Genet 1995 Oct
PMID:New polymorphic microsatellite markers place the haemochromatosis gene telomeric to D6S105. 859 9

Selective hybridization of small intestine and liver cDNA libraries was carried out using yeast artificial chromosomes (YACs) surrounding D6S105, the microsatellite that appears to be close to the gene for hereditary hemochromatosis (HFE). Of 14 candidate probes hybridizing with these YACs, only one, designated. LD5-1, detected abnormalities in southern blots of patients with hemochromatosis. Two different abnormalities. were detected in 3 of 55 patients with hemochromatosis with the LD5-1 probe, and one of these was detected in one of 44 normal subjects. The gene that hybridizes with this probe is located about 300-400 kb centromeric of D6S105. It is transcribed into mRNA that is about 8.5 kb in length in many tissues, including peripheral blood leukocytes. The available sequence indicates tha it codes for a zinc finger protein. We propose that there is a reasonable probability that LD5-1 hybridizes with the gene for hereditary hemochromatosis.
Blood Cells Mol Dis 1995
PMID:A strategy for cloning the hereditary hemochromatosis gene. 867 73

The genetic basis of idiopathic hemochromatosis, a common disorder of iron metabolism, has remained an enigma for over two decades. In an attempt to refine the chromosomal localization of this gene, we have conducted a linkage disequilibrium mapping study utilizing a large group of unrelated American patients. The 12 microsatellites used as genetic markers in this analysis include a series of recently described polymorphic dinucleotide (D6S1558, D6S1545 and D6S1554) and tetranucleotide (D6S1016 and D6S1281) repeats which map between D6S105 and D6S299. Haplotype reconstructions indicate that a core genotype, composed of D6S464 allele 3/D6S1260 allele 4/D6S1558 allele 5, exists on a majority of disease chromosomes. Stringent statistical measures of marker-disease disequilibrium suggest that only associations with D6S1260 are significant and furthermore, aid in the assignment of refined centromeric and telomeric limits for the likely location of the hemochromatosis gene. In summary, the genetic data presented in this report predict that the hemochromatosis locus resides between D6S464 and D6S1558, most likely very close to marker D6S1260. Because a single yeast artificial chromosome clone contains all three of the above loci, a thorough search for coding sequences in this region is likely to identify the gene mutated in this common disorder.
Blood Cells Mol Dis 1996
PMID:Localization of the hemochromatosis disease gene: linkage disequilibrium analysis using an American patient collection. 880 84

The DNA of 147 patients of European origin clinically diagnosed with idiopathic hemochromatosis and 193 controls was examined for mutations of the HLA-H gene at nt 845 and nt 187. One hundred twenty-one (82.3%) of the hemochromatosis patients were homozygous and 10 (6.8%) heterozygous for the 845A (C282Y) mutation. All of the homozygous patients were also homozygous for nt 187C, and all 845A heterozygotes had at least one copy of 187C. Thus, the nt 845 and nt 187 mutations were in complete linkage disequilibrium; nt 187 was a C on all chromosomes with the 845A mutation. Eight of the 10 heterozygotes for 845A were heterozygous for 187G(H63D). The excess of heterozygotes at both nt 187 and nt 845 suggested either the presence of as yet undiscovered mutations existing in trans with 845A and in linkage disequilibrium with 187G, or that the 187G itself is a deleterious mutation, which in concert with the 845A can give rise to hemochromatosis. None of the 193 normal controls were homozygous for 845A and 29/193 (15%) were heterozygous for 845A. Although 47/193 (24.3%) of normal controls were heterozygous for the 187G mutation only two of these carried the 845A mutation. If the 187G mutation complemented the 845A mutation with high penetrance in causing hemochromatosis, then the population frequency of the two genes would require that a high proportion of patients with hemochromatosis be heterozygous for 845A and 187G. Instead, the frequency of homozygotes for the 845A mutation was much higher than that of the 845A/187G genotype. Based on our data, the penetrance of the 845A/187G genotype is only 1.5% and based on the data of Feder et al. only 0.5%. In contrast, the penetrance of the homozygous 845A/845A genotype seems to be very high. Thus, screening for this genotype should be very useful.
Blood Cells Mol Dis 1996
PMID:Mutation analysis in hereditary hemochromatosis. 893 58

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