Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P02794 (ferritin)
17,525 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The frequency and significance of gastric parietal cell autoimmunity was assessed in 771 patients with insulin-dependent diabetes (IDD) of onset before 30 yr of age. Gastric parietal autoantibodies (PCA) were found 4 times more frequently in the patients with IDD (9%) than among 600 matched nondiabetic controls (2%). Caucasian female patients with IDD had PCA twice as frequently as male patients. Thyroid microsomal autoantibodies were more frequent in patients with IDD and PCA, than in those with IDD alone (Caucasian 46% versus 18%, black 25% versus 2.5%). A history of pernicious anemia and/or PCA was found in 25 or 40 families of IDD probands with PCA. Achlorhydria was demonstrated in 6 of 11 patients (54%) with PCA but in none of seven IDD patients without PCA. The six patients with achlorhydria had significantly lower uptakes of oral radiolabeled cobalamin, lower serum cobalamin levels, lower intrinsic factor-R protein ratios in their gastric aspirates, and lower plasma ferritin levels than patients with IDD but without PCA. None of the study group had IF antibodies in their serum or gastric juice. Overt pernicious anemia and neuropathy were found in one patient with PCA. Young patients with IDD at risk for atrophic gastritis and cobalamin deficiency can initially be identified by screening for PCA. Many of these young patients with PCA already have achlorhydria and evidence of decreased absorption of cobalamin. These patients can then be followed with cobalamin levels and/or with complete blood counts to identify those requiring therapy.
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PMID:Predictive value of gastric parietal cell autoantibodies as a marker for gastric and hematologic abnormalities associated with insulin-dependent diabetes. 717 96

Induction of cytochrome P-450s by 3-methylcholanthrene (MC) and phenobarbital (PB) and distribution of P-450s in the rat liver nuclear envelope were investigated by biochemical analyses and ferritin immunoelectron microscopy using specific antibodies against the major molecular species of MC- and PB-induced cytochrome P-450. It was found, in agreement with Kasper (J. Biol. Chem., 1971, 246: 577-581), that the total amount of cytochrome P-450s determined by biochemical analysis was markedly increased by MC, but not by PB, treatment. Immunoelectron microscopic analysis, however, showed marked and slight increases in ferritin labeling by MC and PB treatment, respectively. The latter finding was interpreted as resulting from the induction of a particular molecular species of PB-induced cytochrome P-450s. Ferritin immunoelectron microscopic analysis of intact isolated nuclei, naked nuclei from which the outer membrane of the nuclear envelope was partially detached (mechanically), and isolated nuclear envelopes have shown that the ferritin particles are found exclusively on the cytoplasmic face of the outer nuclear envelopes. Neither the nucleoplasmic face of the inner membrane of the nuclear envelope nor the cisternal face of both membranes of the nuclear envelope showed any labeling with ferritin. This indicates that cytochrome P-450 is located only on the outer membrane of the nuclear envelope and does not diffuse laterally into the domain of the inner membrane of the nuclear envelope across the nuclear pores. Our results suggest that a marked heterogeneity exists in the enzyme distribution between the outer and inner membrane of the nuclear envelope and that microsomal marker enzymes such as cytochrome P-450 exist exclusively in the outer membrane. In addition, it appears that cytochrome P-450 is probably not a transmembrane protein but an intrinsic protein located on the cytoplasmic face of the outer membrane of the nuclear envelope.
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PMID:Distribution and induction of cytochrome P-450 in rat liver nuclear envelope. 729 16

In vivo experiments with 48V and 59Fe radiotracers were performed to study the association of V with Fe proteins. Each male rat was injected ip with 10 micrograms 48VO2+ and then with 1 microgram 59Fe3+ to label Fe-containing proteins. The radioactivities incorporated were measured in plasma transferrin, red blood cell hemoglobin, liver ferritin, partially purified heart myoglobin, and liver mitochondrial and microsomal cytochromes b and c and ferriporphyrin. Liver ferritin can bind V in vivo similarly to plasma transferrin, as shown by gel filtration and immunoprecipitation. Negligible amounts of 48 V were incorporated into hemoglobin, partially purified myoglobin, and cytochromes b and c. These findings suggest that the nonenzymatic Fe-containing proteins may be involved in the V metabolism.
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PMID:Relations between iron and vanadium metabolism: in vivo incorporation of vanadium into iron proteins of the rat. 734 66

The in vitro incorporation of cytochrome b5 into purified plasma membranes was investigated by biochemical and immunological methods. Plasma membrane preparations incorporated three times less cytochrome b5 than did microsomal preparations; 60% of this cytochrome b5 could not be reduced by the NADH-cytochrome b5 reductase and considered as being bound to the plasma membrane. The morphological observations made after the immunochemical labeling of cytochrome b5 clearly showed a good but asymmetrical distribution of the ferritin labeling: only the inner face of the plasma membrane incorporated cytochrome b5. These results are discussed with respect to theories which concern the subcellular membrane relationships in the cell.
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PMID:The binding of cytochrome b5 to plasma membranes of rat liver: its implication for membrane specificity and biogenesis. 737 3

Two-dimensional polyacrylamide gel electrophoresis has been used to search for disease-related protein variation in South Hampshire sheep with ovine ceroid-lipofuscinosis. Several hundred proteins in homogenates and subcellular fractions from livers have been examined, using isoelectric focusing as the first dimension separation, and SDS PAGE in the second dimension. Under these circumstances it was not possible to detect subunit c of the Fo region of ATP synthase, as this protein did not enter the isoelectric focusing gels. However, our studies emphasize the selective nature of misprocessing of subunit c, as we have not been able to detect any other consistent variation between affected and control animals for over 200 mitochondrial fraction proteins. Comparison of the presence or absence, and abundance, of proteins from isolated storage bodies with their counterparts in subcellular fractions from normal liver indicated that storage bodies contained a small subset of mitochondrial proteins, in addition to subunit c, with possible minor contributions from lysosomal, microsomal, and soluble proteins. Analysis of extramitochondrial proteins showed greater than 10-20-fold accumulation of ferritin light chains in microsomes, and partial loss of a putatively lysosomal protein, in ovine ceroid-lipofuscinosis. In addition, senescence marker protein was more abundant in the cytosolic fraction of controls, compared with affected individuals. We are currently investigating the basis and significance of these differences.
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PMID:Variant proteins in ovine ceroid-lipofuscinosis. 766 45

The heme oxygenase isozymes, HO-1 and HO-2, oxidatively cleave the heme molecule to produce antioxidants, the bile pigments, the gaseous cellular messenger, CO, and iron, a regulator of transferrin, ferritin, and nitric oxide synthase gene expression. HO-1 (hsp32) is a stress-inducible enzyme, whereas HO-2 is constitutively expressed at high levels in the testes and brain. In the present study, using immunohistochemical and in situ hybridization techniques, we report for the first time the cellular distribution of HO-1 and HO-2 in the testes of normal and heat-shocked rats and define a cell-specific expression of the isozymes and a stage-specific expression of HO-2 in the organ. In normal tissue, HO-1 was present at low levels in the Sertoli cells and could not be detected in germ or Leydig cells. HO-2, on the other hand, was most prominently expressed in residual bodies and was not detected in spermatogonia. Modest levels of HO-2 were observed in spermatocytes, spermatids, and select Leydig cells. In contrast, prominent expression of HO-2 messenger RNAs (mRNAs) was detected by in situ hybridization in spermatogonia, as well as spermatocytes, spermatids, and residual bodies of the seminiferous epithelium. The expression pattern of HO-2 protein and transcript in testes of heat-stressed (42 C; 20 min) rats did not differ from that in the control animals, whereas the expression pattern of HO-1 differed from that in the controls, in which distinct populations of Leydig and Sertoli cells displayed intense immunoreactivity. Thermal stress also resulted in an increase (2.8-fold) in the testicular HO-1 mRNA level within 1 h after treatment, followed by a significant increase (32%) in total microsomal heme oxygenase activity 6 h after treatment. Notably, this increase followed a significant depression (36%) in enzyme activity, which was detected 1 h after hyperthermia. The disparity between HO-2 mRNA and protein distribution clearly indicates cell-specific differences in the translational efficiency of HO-2 transcripts. It appears that HO-2 mRNA translation is linked to the maturation and expression of a factor(s) that regulates this process. This, in turn, appears to coincide with sperm development. HO-1 activity, on the other hand, which has a transcriptional component to its regulation, may have a role in maintenance of the conditions required for spermatogenesis.
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PMID:Distribution of constitutive (HO-2) and heat-inducible (HO-1) heme oxygenase isozymes in rat testes: HO-2 displays stage-specific expression in germ cells. 772 Jun 78

To study the iron, transferrin, and ferritin distribution at subcellular levels in response to acute dietary iron deficiency, we tested the hypothesis that early post-weaning iron deficiency can change iron and iron regulatory protein concentrations in rat brain. Male Sprague-Dawley rats were fed diets containing either 2 or 35 micrograms iron/g for 2, 3 or 4 wk starting at 21 d of age. Brain iron, transferrin and ferritin concentrations in cytosolic and microsomal fractions of either whole brain or pons and cerebellum were then determined. After 14 d of dietary iron restriction, brain iron concentrations were 50% lower in the microsomal fraction and 30% lower in cytosol compared with controls. Brain cytosolic transferrin concentration almost doubled in the same animals. Brain ferritin concentration in fractions from rats fed the iron-deficient diet for 14 d was lower than in controls, but then remained fairly constant. Absolute brain weight and total brain protein contents were unaffected by iron restriction. This study extends previous research by demonstrating that the brain responds to changes in body iron status with a change in transferrin concentration. If the dietary restriction is quite severe, this adaptation is insufficient. This study also notes that brain ferritin decreases with decreasing body iron status, though it was less responsive than nonheme iron in liver. The concept that iron enters the brain through a highly regulated endocytotic process at the blood brain barrier, that undoubtedly involves the regulation of transferrin receptors in capillary endothelial cell, is supported by our observation of elevated transferrin concentrations in brain of iron-deficient rats.
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PMID:Brain iron, transferrin and ferritin concentrations are altered in developing iron-deficient rats. 778 7

There are several inherited and acquired disorders that can result in chronic iron overload in humans, and the major clinical consequences are hepatic fibrosis, cirrhosis, hepatocellular cancer, cardiac disease, and diabetes. It is clear that lipid peroxidation occurs in experimental iron overload if sufficiently high levels of iron within hepatocytes are achieved. Lipid peroxidation is associated with hepatic mitochondrial and microsomal dysfunction in experimental iron overload, and lipid peroxidation may underlie the increased lysosomal fragility that has been detected in liver samples from both iron-loaded human subjects and experimental animals. Reduced cellular ATP levels, impaired cellular calcium homeostasis, and damage to DNA may all contribute to hepatocellular injury in iron overload. Long-term dietary iron overload in rats can lead to increased collagen gene expression and hepatic fibrosis, perhaps due to activation of hepatic lipocytes. The mechanisms whereby lipocytes are activated in iron overload remain to be elucidated; possible mediators include aldehydic products of iron-induced lipid peroxidation produced in hepatocytes, tissue ferritin, and/or cytokines released by activated Kupffer cells.
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PMID:Pathophysiology of iron toxicity. 788 29

Glucose-6-phosphatase (G6Pase) is a microsomal enzyme which is very sensitive to inactivation by lipid peroxidation. Experiments were carried out to evaluate whether ferritin, which is the major storage form of iron within cells, could catalyze inactivation of G6Pase and to determine the mechanism responsible for this effect of ferritin. Incubation of microsomes with NADPH in the absence of ferritin led to decreased activity of G6Pase. Ferritin stimulated this inactivation of G6Pase in a time- and concentration-dependent manner. Ferritin did not stimulate G6Pase inactivation when NADH replaced NADPH as the microsomal reductant. Superoxide dismutase but not catalase or DMSO prevented the ferritin-stimulated inactivation of G6Pase suggesting a role for superoxide, but not H2O2 or hydroxyl radical, in the overall mechanism. Trolox, at concentrations which prevent lipid peroxidation, also prevented the ferritin-catalyzed inactivation of G6Pase. Inhibition of G6Pase by ferritin was further enhanced in the presence of ATP but was inhibited in the presence of EDTA or desferrioxamine; ferric-ATP stimulates, whereas ferric-EDTA inhibits microsomal lipid peroxidation. The redox cycling agent paraquat increased the ability of ferritin to inactivate G6Pase by a reaction prevented by superoxide dismutase, trolox, EDTA, and desferrioxamine, but not by catalase or DMSO. Ferritin stimulated microsomal light emission, a reaction reflecting lipid peroxidation, with time and concentration dependence, and sensitivity to scavengers (trolox, superoxide dismutase), iron chelators and paraquat, identical to the inactivation of G6Pase. These results indicate that one possible toxicological consequence of ferritin-catalyzed lipid peroxidation is inhibition of microsomal enzymes such as G6Pase.
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PMID:Ferritin-dependent inactivation of microsomal glucose-6-phosphatase. 818 31

Heme oxygenase-1 mRNA levels increase following exposure of many mammalian cell lines to oxidative stress such as ultraviolet A (UVA) irradiation. Here we demonstrate a 4-fold increase in microsomal heme oxygenase activity and a 40% decrease in microsomal heme content 14 h after treatment of human skin fibroblasts (FEK4) with 250 kJ m-2 of UVA radiation. Paralleling this was a 2-fold increase in ferritin levels that was sustained for at least 46 h after UVA irradiation. Treatment of fibroblasts with the iron chelating agent desferrioxamine, after the UVA-dependent induction of heme oxygenase, prevented the increase in ferritin levels. Treatment of fibroblasts with Sn-protoporphyrin IX (an inhibitor of heme oxygenase) also prevented the effect of UVA radiation on ferritin levels. Thus we conclude that the effect of UVA radiation on ferritin levels is via the heme oxygenase-dependent release of iron from endogenous heme sources. We propose that the increase in ferritin that follows UVA irradiation would decrease intracellular free iron such that iron-catalyzed free radical reactions would be restricted during periods of subsequent oxidative stress.
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PMID:Oxidative stress resulting from ultraviolet A irradiation of human skin fibroblasts leads to a heme oxygenase-dependent increase in ferritin. 832 45


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