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Query: UNIPROT:P02794 (
ferritin
)
17,525
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Although the iron-loading disease,
hereditary hemochromatosis
, has a strong causal association with hepatocellular carcinoma (HCC), the carcinogenic potential of dietary iron overload in Black Africans is not known. We investigated this potential by evaluating iron status, alcohol consumption, markers for hepatitis B (HBV) and C virus (HCV) infections, and exposure to dietary aflatoxin B1 in 24 rural patients with this tumor, 48 race-, sex-, and age-matched hospital-based controls, and 75 related or unrelated close family members of the cancer patients. Iron overload was defined as a raised serum
ferritin
concentration in combination with a transferrin saturation > or = 60%, and was confirmed histologically when possible. Among 24 patients and 48 hospital controls, the risk of developing HCC in the iron-loaded subjects was 10.6 (95% confidence limits of 1.5 and 76.8) relative to individuals with normal iron status, after adjusting for alcohol consumption, chronic HBV and HBC infections, and exposure to aflatoxin B1. The risk of HCC in subjects with HBV infection was 33.2 (7.2, 153.4) (odds ratio [95% confidence limits]), HCV infection 6.4 (0.3, 133.5), and alcohol consumption 2.0 (0.5, 8.2). Aflatoxin B1 exposure did not appear to increase the risk of HCC. The population attributable risk of iron overload in the development of HCC was estimated to be 29%. Among 20 cancer patients and 75 family members, the risk of developing HCC with iron overload was 4.1 (0.5, 32.2). We conclude that dietary iron overload may contribute to the development of HCC in Black Africans.
...
PMID:Dietary iron overload as a risk factor for hepatocellular carcinoma in Black Africans. 962 Mar 27
Hepatic iron has been associated with more aggressive liver disease in chronic viral hepatitis. We evaluated whether the recently described C282Y mutation of the hemochromatosis gene, designated HFE (responsible for at least 83% of
hereditary hemochromatosis
), was associated with more advanced liver disease in chronic hepatitis C. One hundred thirty-seven patients with biopsy-proven chronic hepatitis C were studied and liver biopsies scored for necroinflammation (grade 0-18) and fibrosis (stage 0-6). Genomic DNA was amplified by polymerase chain reaction and the C282Y mutation identified by restriction with RsaI and electrophoretic separation of restriction fragments. Ten (7.3%) patients had the C282Y mutation. No C282Y homozygous patients were identified. Age, sex distribution, and estimated weekly alcohol consumption were not significantly different between those with and without the mutation. Serum
ferritin
was higher in the heterozygotes (mean, 339 microg/L) compared with homozygous wild types (153 microg/L; P = .0005). In the majority of patients, liver iron was graded 0 out of 4, but hepatocyte iron staining was more commonly present in heterozygotes compared with homozygous normals (30% compared with 4% [P = .02]). Liver disease was more advanced in those with the mutant allele (mean fibrosis stage: 3.6, compared with wild type: 1.5 [P = .01]). Cirrhosis was found more often in those with the mutation (40%) compared with those without (8.7%) (P = .01; odds ratio: 7.6 [1.9-31.2]). There was no significant difference in inflammation scores between heterozygotes and wild type (mean, 5.4 compared with 4.1). Hepatitis C virus (HCV)-RNA titers were measured by branched DNA assay (HCV RNA 2.0-Chiron), and there was no difference between heterozygous and homozygous normal patients. Thus, despite relatively minor increases in iron stores, individuals who are heterozygous for hemochromatosis appear to develop more fibrosis in chronic hepatitis C. Venesection may be useful therapy in this subgroup.
...
PMID:Heterozygosity for hereditary hemochromatosis is associated with more fibrosis in chronic hepatitis C. 1033 38
The mechanism by which a novel major histocompatibility complex class I protein, HFE, regulates iron uptake into the body is not known. HFE is the product of the gene that is mutated in >80% of
hereditary hemochromatosis
patients. It was recently found to coprecipitate with the transferrin receptor (Feder, J. N., Penny, D. M., Irrinki, A., Lee, V. K., Lebron, J. A., Watson, N., Tsuchihashi, Z., Sigal, E., Bjorkman, P. J., and Schatzman, R. C. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 1472-1477; Parkkila, S., Waheed, A., Britton, R. S., Bacon, B. R., Zhou, X. Y., Tomatsu, S., Fleming, R.E. , and Sly, W. S. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 13198-13202) and to decrease the affinity of transferrin for the transferrin receptor (Feder et al.). In this study, HeLa cells were transfected with HFE under the control of the tetracycline-repressible promoter. We demonstrate that HFE and the transferrin receptor are capable of associating with each other within 30 min of their synthesis with pulse-chase experiments. HFE and the transferrin receptor co-immunoprecipitate throughout the biosynthetic pathway. Excess HFE is rapidly degraded, whereas the HFE-transferrin receptor complex is stable. Immunofluorescence experiments indicate that they also endocytose into transferrin-positive compartments. Combined, these results suggest a role for the transferrin receptor in HFE trafficking. Cells expressing HFE have modestly increased levels of transferrin receptor and drastically reduced levels of
ferritin
. These results implicate HFE further in the modulation of iron levels in the cell.
...
PMID:Co-trafficking of HFE, a nonclassical major histocompatibility complex class I protein, with the transferrin receptor implies a role in intracellular iron regulation. 970 50
This study investigated the release of erythrocyte-derived iron from purified human monocytes obtained from healthy volunteers and
hereditary hemochromatosis
(HH) patients. After erythrophagocytosis of 59Fe-labeled erythrocytes, a complete transfer of iron from hemoglobin (Hb) to
ferritin
was observed within 24 hours in both control and HH monocytes. The iron was released from the monocytes in the form of
ferritin
, Hb, and as nonprotein bound low molecular weight iron (LMW-Fe). During the initial rapid phase (<1.5 hours), iron release mostly consisted of Hb and LMW-Fe, while in the later phase (>1.5 hours), it was composed of
ferritin
and LMW-Fe. The kinetics of iron release were identical for HH monocytes. A high percentage of the total amount of iron was released as Hb both by viable normal and HH monocytes, suggesting that iron release as Hb is a physiologic process, which may occur whenever the erythrocyte-processing capacity of macrophages is exceeded. Most remarkably, HH monocytes released twice as much iron in a LMW form as control cells. Iron released in the form of LMW-Fe readily binds to plasma transferrin and may contribute to the high transferrin saturation and the occurrence of circulating nontransferrin-bound iron observed in HH patients.
...
PMID:Iron release from human monocytes after erythrophagocytosis in vitro: an investigation in normal subjects and hereditary hemochromatosis patients. 974 92
Genetic (hereditary) hemochromatosis is probably the most common autosomal recessive disorder found in white Americans, of whom about 5/1,000 (0.5 percent) are homozygous for the associated gene. The hemochromatosis gene is probably located close to the HLA-A locus on the short arm of chromosome 6. Homozygous individuals may develop severe and potentially lethal hemochromatosis, especially after age 39. Hereditary hemochromatosis involves an increased rate of iron absorption from the gut with subsequent progressive storage of iron in soft organs of the body. Excess iron storage eventually produces pituitary, pancreatic, cardiac, and liver dysfunction and death may result from cardiac arrhythmias, congestive heart failure, and/or hepatic failure or cancer. Early diagnosis can prevent these excess iron-induced problems. Iron overload owing to HLA-linked
hereditary hemochromatosis
can be distinguished from other causes of hemochromatosis by liver biopsies and interpretations. Patients at risk for genetic hemochromatosis should be screened, identified, and treated as early as age 20 to prevent or minimize the deadly complications of hemochromatosis. Population screening should include measurements of serum iron concentration, total iron binding capacity (TIBC), percent saturation of transferrin, and serum
ferritin
concentrations. Family members of
hereditary hemochromatosis
patients are at increased risk and should be tested. Screening, identification and early treatment (phlebotomies, sometimes in combination with the use of Desferal or other iron-chelating agents) may help prevent or reduce iron-related organ damage and premature deaths. Early diagnosis and treatment will reduce the population of aging individuals with severe, complicated hemochromatosis and dramatically reduce medical costs (billions of U.S. dollars per annum) associated with the management of this disease.
...
PMID:Hereditary hemochromatosis. 978 32
HFE is the protein product of the gene mutated in the autosomal recessive disease
hereditary hemochromatosis
(Feder, J. N., Gnirke, A., Thomas, W., Tsuchihashi, Z., Ruddy, D. A., Basava, A., Dormishian, F., Domingo, R. J., Ellis, M. C., Fullan, A., Hinton, L. M., Jones, N. L., Kimmel, B. E., Kronmal, G. S., Lauer, P., Lee, V. K., Loeb, D. B., Mapa, F. A., McClelland, E., Meyer, N. C., Mintier, G. A., Moeller, N., Moore, T., Morikang, E., Prasss, C. E., Quintana, L., Starnes, S. M., Schatzman, R. C., Brunke, K. J., Drayna, D. T., Risch, N. J., Bacon, B. R., and Wolff, R. R. (1996) Nat. Genet. 13, 399-408). At the cell surface, HFE complexes with transferrin receptor (TfR), increasing the dissociation constant of transferrin (Tf) for its receptor 10-fold (Gross, C. N., Irrinki, A., Feder, J. N., and Enns, C. A. (1998) J. Biol. Chem. 273, 22068-22074; Feder, J. N., Penny, D. M., Irrinki, A., Lee, V. K., Lebron, J. A., Watson, N. , Tsuchihashi, Z., Sigal, E., Bjorkman, P. J., and Schatzman, R. C. (1998) Proc. Natl. Acad. Sci. U S A 95, 1472-1477). HFE does not remain at the cell surface, but traffics with TfR to Tf-positive internal compartments (Gross et al., 1998). Using a HeLa cell line in which the expression of HFE is controlled by tetracycline, we show that the expression of HFE reduces 55Fe uptake from Tf by 33% but does not affect the endocytic or exocytic rates of TfR cycling. Therefore, HFE appears to reduce cellular acquisition of iron from Tf within endocytic compartments. HFE specifically reduces iron uptake from Tf, as non-Tf-mediated iron uptake from Fe-nitrilotriacetic acid is not altered. These results explain the decreased
ferritin
levels seen in our HeLa cell system and demonstrate the specific control of HFE over the Tf-mediated pathway of iron uptake. These results also have implications for the understanding of cellular iron homeostasis in organs such as the liver, pancreas, heart, and spleen that are iron loaded in hereditary hemochromatotic individuals lacking functional HFE.
...
PMID:The hereditary hemochromatosis protein, HFE, specifically regulates transferrin-mediated iron uptake in HeLa cells. 1008 50
Reference values for two
ferritin
assays (Tina-quanta Ferritin, Enzymun, both Roche Diagnostics, Mannheim, Germany) were established (136 males and 139 females). To rule out inflammation as well as iron deficiency in the reference population, subjects with the C-reactive protein concentration < 5 mg/l, and zinc protoporphyrin < 40 micromol/mol heme and the soluble transferrin receptor < 3 mg/l were selected. Taking into account latent iron deficiency as well as
hereditary hemochromatosis
the 5-95 percentile range was as follows: male, 27-365 microg/l; female, 13-148 microg/l for Tina-quanta and 12-151 microg/l for Enzymun. The Tina-quanta Ferritin assay showed a very good correlation (r > or = 0.990) to Enzymun
ferritin
, Ferritin Abbott (Abbott Diagnostics, Delkenheim, Germany), N Latex Ferritin (Dade Behring, Marburg, Germany) and the Ferritin Chiron (Chiron Diagnostics, Fernwald, Germany). However, the slopes of the standard principal component method analysis were calculated to be between 1.03 (Enzymun) and 1.41 (N Latex Ferritin). For four assays the median recovery of the 3rd International Recombinant Ferritin Standard (NIBSC 94/572) measured by serial dilution was 89-109%. The N Latex Ferritin assay recovered half of the target values. Because of the good correlation with other assays, a matrix effect is likely. The question arises whether the manufacturers' agreement on the recombinant
ferritin
standard would harmonize
ferritin
measurement.
...
PMID:Reference values for a homogeneous Ferritin assay and traceability to the 3rd International Recombinant Standard for Ferritin (NIBSC code 94/572). 1053 31
Hereditary hemochromatosis (HH) is an autosomal recessive disorder of iron metabolism, resulting in an increased iron deposition and multiorgan failure. Recently a candidate gene of HH, termed HFE, has been identified on chromosome 6, coding for a protein homologous to major histocompatibility complex (MHC) class I molecules. Two mutations of the hemochromatosis gene leading to an exchange of cysteine to tyrosine at aminoacid 282 and histidine to asparagine at aminoacid 63, are retained responsible for the development of
hereditary hemochromatosis
. The Cys282Tyr-mutation disrupts a disulfid bond and thus abrogates binding of the mutant HFE-protein to beta 2-microglobulin and its presentation on the cell surface. The His63Asp-mutation seems to play a role in pH-regulated dissociation of the transferrin receptor/transferrin complex in the lysosome. Mutations of the HFE-protein alter the affinity of the transferrin receptor for its ligand transferrin and may thus cause an intracellular accumulation of iron. Knowledge of the responsible gene allows a molecular diagnosis of HH. The new genetic marker can be used for screening and confirmation of HH reducing the need for confirmatory liver biopsies. Compared to standard screening parameters like
ferritin
and transferrin saturation genetic testing will allow the diagnosis of HH in an early, asymptomatic state before iron accumulation has occurred. As a normal life expectancy of patients with HH can be achieved if iron reduction is initiated early, genetic testing may thus be of great benefit for patients with HH.
...
PMID:[Hereditary hemochromatosis--new developments after discovery of the HFE gene]. 1066 43
In 1996 two mutations in Hfe, the gene affected in
hereditary hemochromatosis
, were identified as C282Y (c.845G. A) and H63D (c.187C. G). Immunohistochemical studies have localized the protein product of Hfe to the deep crypts of the duodenum, the maximum site of iron absorption. To date, there are no published data on the cellular location and regulation of Hfe in patients with hemochromatosis who are homozygous for C282Y. The aim of this study was to identify the cellular localization of Hfe in genotyped individuals and to study possible regulation of this protein by the mutations described in the Hfe gene locus and iron deficiency. Duodenal biopsy specimens and serum for iron,
ferritin
, and transferrin saturation were taken from controls (n = 10) and patients with
hereditary hemochromatosis
(n = 10) and iron deficiency anemia (n = 10). All participants were genotyped for C282Y and H63D mutations. Expression of Hfe in the duodenum was demonstrated by immunohistochemistry. Hfe was expressed in the deep crypts of the duodenum in all three groups in a perinuclear fashion. Hfe staining was weaker in the hemochromatosis and iron deficiency patients (mean transferrin saturation 69.6%, SD 23% and 15%, SD 11%, respectively) when compared to controls (mean transferrin saturation 33.1%, SD 15%). There was no difference in the intensity of Hfe staining within the hemochromatosis group who were iron overloaded when compared to their iron-depleted counterparts. In summary, Hfe is expressed strongly in the deep crypts of the small intestine of normal subjects. Homozygosity for C282Y and conditions of iron deficiency result in a downregulation of Hfe. Furthermore, Hfe is not regulated by therapeutic iron depletion in patients with hemochromatosis who are homozygous for the C282Y mutation.
...
PMID:Immunohistochemistry of the Hfe protein in patients with hereditary hemochromatosis, iron deficiency anemia, and normal controls. 1077 70
We compared 48-hour urinary iron excretion after a twice-daily subcutaneous bolus injection of deferoxamine and after 12 hours of subcutaneous continuous infusion of the drug in 27 patients with iron overload (mean age, 55.7 years). In most patients, the iron overload was due to multiple transfusions administered during chemotherapy or as part of supportive care for a hematologic or oncologic disorder. One patient had sickle cell anemia and 1 had
hereditary hemochromatosis
and spherocytosis. Similar urinary iron excretion was observed with the 2 methods of administration; mean +/- SD values were 6935.3 +/- 3832.3 microg/48 hours with subcutaneous bolus injection and 6630.4 +/- 3606.9 microg/48 hours with subcutaneous continuous infusion (P =.3). Twenty-six patients (96.3%) chose to continue therapy with bolus injection. The long-term efficacy of bolus injection was evaluated by measuring the serum
ferritin
concentration at regular intervals for a follow-up time of 20.1 +/- 4.5 months. Ferritin concentration decreased to below 1000 microg/L in 73% of the patients and to below 500 microg/L in 42% and became normal in 26%. Best results were obtained in patients who were no longer receiving blood transfusions when chelation therapy was initiated. Three of 26 patients (11.5%) had mild, transient side effects after bolus injection. Larger prospective, randomized studies must be conducted before deferoxamine bolus injection can be routinely recommended for patients with iron overload. (Blood. 2000;95:2776-2779)
...
PMID:Safety and efficacy of subcutaneous bolus injection of deferoxamine in adult patients with iron overload. 1077 20
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