Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P02794 (ferritin)
 17,525 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have compared the magnetic properties of various types of materials known to affect MR images. The materials compared were: (i) MR contrast agents based on chelates of paramagnetic metals (Gd-DTPA, Dy-DTPA); (ii) biological forms of iron (horse spleen ferritin and deoxyhemoglobin); and (iii) a superparamagnetic iron oxide (AMI-25). The properties compared were the magnetic susceptibility and the magnetization. The magnetization and susceptibility of superparamagnetic AMI-25 are far larger than that of ferritin or low molecular weight, paramagnetic chelates. Superparamagnetic iron oxide colloids, like AMI-25, are a uniquely powerful class of magnetic materials.
 ...
PMID:The magnetic properties of some materials affecting MR images. 181 47

The affinity-purified by chromatography on immobilized antigen rabbit IgG was modified with mixed carboxycarbonic anhydride of DTPA which markedly alters the interaction of charged residues in the protein molecule. To study the correlation between the antigen binding activity and the conformational mobility of IgG, the reactivity of modified IgG towards conformational probes targeted at variable and constant IgG domains, was investigated. The antibody against CH2 domains of IgG, staphylococcal protein A and protein antigen ferritin were used as conformational probes. It was found that modification of IgG amino groups entails the global increase in conformational mobility involving the Fab fragments, CH2 and, probably, the CH3 domains of the Fc portion of IgG. Taking advantage of Fab fragments modification it was shown that two processes contribute to the global increase in the conformational mobility of IgG. These processes are: i) stimulation of segmental flexibility and, ii) increase in the mobility within the Fv domains of the Fab fragments.
 ...
PMID:[Study of rabbit IgG, modified with carboxycarbonic anhydride of diethylenetriaminopentacetic acid]. 193 39

When 111In-labeled murine monoclonal antibodies are used in radio-scintigraphic diagnostic procedures, a large fraction of the injected radionuclide is sequestered by the liver. Neither the cells responsible for the uptake nor the mechanism of uptake are known. Little is known about either the site within the liver of antibody metabolism or the form of the products of metabolism. In these studies, the uptake and metabolism of a monoclonal antibody, B6.2 radiolabeled with 111In or 125I [either intact B6.2 or F(ab')2] were determined in rats. One h after injection of either 125I- or 111In-diethylenetriaminepentaacetic acid (111In-DTPA)-labeled B6.2, the predominant liver cell in which the radionuclide was found was the parenchymal cell. At this time, the absolute uptake of 125I in the liver was 0.23 +/- 0.06% (SD) of the injected dose compared to 0.61 +/- 0.06% when the radionuclide was 111In. Removal of the Fc portion of the antibody reduced the absolute liver uptake of 125I to 0.10 +/- 0.01 and the absolute uptake of 111In to 0.16 +/- 0.06. Both radionuclides were still associated predominantly with the parenchymal cell. Using size exclusion high performance liquid chromatography analysis of liver supernatants the metabolism of radiolabeled B6.2 was followed for 24 h. Of the radioactivity recovered, 47.9% of the 125I was precipitable by centrifugation (and presumed bound to cell membranes) while 15.4% was attached to B6.2 found in the cytosol. In contrast, when 111In-DTPA-B6.2 was administered, 16.0% of 111In recovered from the liver was precipitable by centrifugation, and 6.5% was attached to B6.2 found in the cytosol. Sixty % of the 111In was recovered as a low molecular weight (less than 1000) component in the cytosol. This metabolite was not immunoreactive, nor did it comigrate with ferritin, and was resolved into four components by ion exchange high performance liquid chromatography. Of these, only a minor component cochromatographed with an 111In-DTPA standard. These data suggest that the large accretion of radionuclide by the liver is due to uptake of monoclonal antibodies by an Fc receptor-mediated mechanism and the subsequent accumulation of low molecular weight metabolites, presumably 111In-DTPA, attached to one or more amino acids. The reasons for the entrapment of metabolites in the liver are under investigation.
 ...
PMID:Uptake and metabolism of 111In-labeled monoclonal antibody B6.2 by the rat liver. 229 33

Trophoblast cells isolated from term human placenta and maintained as an adherent culture express surface receptors for transferrin as indicated by quantitative binding studies using 125I-labelled transferrin. The Kd was 5.3 x 10(-9) M. About 36 per cent of the total cell receptor population was found at the cell surface, the remainder being intracellular. Both 125I-labelled and 59Fe-labelled transferrin were internalized by receptor-mediated endocytosis with similar rates. Pulse-chase experiments showed that 125I-labelled transferrin was recycled and released back to the medium, whereas 59Fe accumulated intracellularly and was released slowly. Polyacrylamide gel electrophoresis followed by autoradiography revealed that 59Fe was accumulated by cells largely in the form of ferritin. A small intracellular pool of low molecular weight 59Fe was also detected. In the presence of monensin, the transfer of 59Fe to ferritin was greatly reduced. The nature and amount of 59Fe released from cells could be modulated by the incubation conditions. In the absence of chelating agents and iron salts, released 59Fe was found to be associated with a low molecular weight fraction as well as with transferrin and ferritin. The low molecular weight 59Fe readily formed a complex with added chelators such as apotransferrin, DTPA or desferrioxamine. The release of 59Fe could be increased by repeatedly changing the medium during the course of the incubation. 59Fe release from trophoblast cells exceeded the release of lactate dehydrogenase and also exceeded the release of 59Fe from 3T3 fibroblasts, suggesting a cell-specific process.
 ...
PMID:Uptake and processing of 125I-labelled transferrin and 59Fe-labelled transferrin by isolated human trophoblast cells. 232 36

Since 1/T2 of protons of tissue water is generally much greater than 1/T1 at typical imaging fields, small single-ion contrast agents--such as Gd(DTPA), which make comparable incremental contributions and therefore smaller fractional contributions to 1/T2 compared to 1/T1--are not as desirable for contrast-enhancement as agents that could enhance 1/T2 preferentially. In principle, such specialized agents will only be effective at higher fields because the field dependence (dispersion) of 1/T1 is such that it approaches zero at high fields whereas 1/T2 approaches a constant value. The residual 1/T2 is called the "secular" contribution and arises from fluctuations in time--as sensed by the protons of diffusing solvent or tissue water molecules--of the component of the magnetic field parallel to the static applied field. For solutions or suspensions of sufficiently large paramagnetic or ferromagnetic particles (greater than or equal to 250 A diameter), the paramagnetic contributions to the relaxation rates satisfy 1/T2 much greater than 1/T1 at typical imaging fields. We examine the theory of secular relaxation in some detail, particularly as it applies to systems relevant to magnetic resonance imaging, and then analyze the data for solutions, suspensions, or tissue containing ferritin, erythrocytes, agar-bound magnetite particles, and liver with low-density composite polymer-coated magnetite. In most cases we can explain the relaxation data, often quantitatively, in terms of the theory of relaxation of protons (water molecules) diffusing in the outer sphere environments of magnetized particles. The dipolar field produced by these particles has a strong spatial dependence, and its apparent fluctuations in time as seen by the diffusing protons produce spin transitions that contribute to both 1/T1 and /T2 comparably at low fields; for the larger particles, because of dispersion, the secular term dominates at fields of interest. On the basis of the agreement of theory with data for solutions of small paramagnetic complexes, large magnetite particles, and liver containing low-density polymer-coated magnetite agglomerates, it is argued that the theory is sufficiently reliable so that, e.g., for ferritin--for which 1/T2 is unexpectedly large--the source of its large relaxivity must reside in nonideal chemistry of the ferritin core. For blood, it appears that diffusion through intracellular gradients determines 1/T2.
 ...
PMID:Transverse relaxation of solvent protons induced by magnetized spheres: application to ferritin, erythrocytes, and magnetite. 282 67

At typical imaging fields, the transverse relaxation rates 1/T2 of the protons of soft tissue are much greater than their longitudinal rates 1/T1. Because of this, clinical magnetic resonance images are generally collected using relatively short values of TR, an approach that both increases comfort for the patient and reduces medical costs. As a result, image contrast is dominated by the 1/T2 values of the tissue protons. Currently, small single-ion paramagnetic complexes--Gd-DTPA is the prime example--are being used to enhance contrast in clinical magnetic resonance imaging (MRI). However, such agents contribute comparably to 1/T1 and 1/T2 so that their utility is greatest when introduced into body fluids, for which 1/T1 and 1/T2 are also comparable; they are much less useful for enhancing contrast of soft tissue. For this, one must look elsewhere, to rather large aggregates of paramagnetic ions, which may either be paramagnetic or ferromagnetic. Iron in its many chemical and biochemical forms, both exogenous and endogenous, is important in this respect. Its presence in ferritin and hemosiderin--in excess in some diseases--is one example; deoxyhemoglobin in cells and methemoglobin in blood pools from trauma are others in which endogenous iron in several oxidation states is important. Magnetic particulates of various iron oxides are now being used as exogenous agents for enhancing 1/T2 preferentially at imaging fields. Predicting contrast enhancement under such circumstances can become rather complex, not because the theory is difficult, but because the underlying concepts are subtle.(ABSTRACT TRUNCATED AT 250 WORDS)
 ...
PMID:Transverse relaxation (1/T2) of solvent protons induced by magnetized spheres and its relevance to contrast enhancement in MRI. 319 49

Iron overload is relatively common and is now detected more frequently because of inclusion of serum iron measurement in automated clinical chemistry panels. Secondary hemosiderosis and hemochromatosis result from increased iron absorption associated with increased erythropoiesis compensating for hemolysis, increased dietary iron, inappropriate prolonged oral iron therapy or chronic multiple transfusions. Primary hemochromatosis is a genetic metabolic disorder associated with the HLA locus on chromosome 6 resulting in increased iron absorption, though erythropoiesis and dietary iron are normal, and abnormal diversion of iron from reticuloendothelial (RE) to parenchymal cells. A genetic increase of intracellular iron carrier is a proposed basic mechanism. Only in the cirrhotic stage of primary hemochromatosis do RE iron and serum ferritin increase. Since both serum iron and serum ferritin may remain normal in the precirrhotic stage and may be falsely positive in the absence of iron overload, direct measurement of body iron stores is often useful. Measurement of tissue iron in liver biopsy specimens is widely used. However, quantitation of total mobilizable body iron by measurement of a 6-hour urine collection after intravenous injection of 59Fe-DTPA is noninvasive, sensitive, relatively accurate, and together with other laboratory and clinical data provides a practical means of establishing the correct diagnosis and therapy early enough to minimize organ damage.
 ...
PMID:Iron overload syndromes. 395 74

Delivery of iron to K562 cells by diferric transferrin involves a cycle of binding to surface receptors, internalization into an acidic compartment, transfer of iron to ferritin, and release of apotransferrin from the cell. To evaluate potential feedback effects of iron on this system, we exposed cells to iron chelators and monitored the activity of the transferrin receptor. In the present study, we found that chelation of extracellular iron by the hydrophilic chelators desferrioxamine B, diethylenetriaminepentaacetic acid, or apolactoferrin enhanced the release from the cells of previously internalized 125I-transferrin. Presaturation of these compounds with iron blocked this effect. These chelators did not affect the uptake of iron from transferrin. In contrast, the hydrophobic chelator 2,2-bipyridine, which partitions into cell membranes, completely blocked iron uptake by chelating the iron during its transfer across the membrane. The 2,2-bipyridine did not, however, enhance the release of 125I-transferrin from the cells, indicating that extracellular iron chelation is the key to this effect. Desferrioxamine, unlike the other hydrophilic chelators, can enter the cell and chelate an intracellular pool of iron. This produced a parallel increase in surface and intracellular transferrin receptors, reaching 2-fold at 24 h and 3-fold at 48 h. This increase in receptor number required ongoing protein synthesis and could be blocked by cycloheximide. Diethylenetriaminepentaacetic acid or desferrioxamine presaturated with iron did not induce new transferrin receptors. The new receptors were functionally active and produced an increase in 59Fe uptake from 59Fe-transferrin. We conclude that the transferrin receptor in the K562 cell is regulated in part by chelatable iron: chelation of extracellular iron enhances the release of apotransferrin from the cell, while chelation of an intracellular iron pool results in the biosynthesis of new receptors.
 ...
PMID:Effect of iron chelators on the transferrin receptor in K562 cells. 609 56

During acute viral hepatitis, disturbances in iron metabolism occur. To obtain more insight into this, DFO and DTPA induced urinary iron excretion was studied during acute viral hepatitis. It was found that liver cell damage enhances iron excretion, in proportion to the extent of liver cell disintegration: a highly significant correlation was shown between the DFO as well as DTPA induced urinary iron excretion, and the SGPT. Also, a correlation existed between sideruria and the serum iron level, as well as with the serum bilirubin concentration, provided the test was performed within 10 days after the onset of the jaundice. It is suggested that during liver cell damage, iron, which is liberated during ferritin catabolism, forming a transit pool within the hepatocyte and/or at the cell membrane, is the immediate source of iron donation to DFO and/or DTPA. The practical importance for interpretation of iron mobilisation tests is pointed out.
 ...
PMID:Iron mobilisation with chelating agents during acute viral hepatitis. 717 6

Iron mobilized from ferritin has been shown to catalyze production of potent reactive oxygen intermediates. Experiments were carried out to evaluate the ability of ferritin to catalyze nuclear generation of hydroxyl radical in the presence of either NADPH or NADH. In the absence of redox cycling agents, ferritin did not catalyze nuclear oxidation of hydroxyl radical scavenging agents (2-keto-4-thiomethylbutyric acid, dimethylsulfoxide, ethanol) even if EDTA was added to chelate any released iron. The addition of menadione or paraquat resulted in a ferritin-dependent oxidation of chemical scavengers; menadione promoted the catalysis by ferritin with either NADPH or NADH, whereas paraquat was much more reactive with NADPH as the nuclear reductant. The presence of an externally added iron chelator was required for elevated rates of scavenger oxidation, with EDTA and DTPA being more reactive than ATP or citrate and desferrioxamine being inhibitory. The ferritin-catalyzed hydroxyl radical scavenger oxidation was sensitive to superoxide dismutase, catalase, and competitive scavengers. In the absence or presence of ferritin, rates of NADPH- or NADH-dependent H2O2 production were low; menadione increased H2O2 production with both NADPH and NADH, whereas paraquat was mostly effective with NADPH. Depending on the nature of the added chelating agent (e.g., EDTA, ATP) and the reductant, rates of nuclear production of .OH in the presence of redox cycling agent plus ferritin were 10 to 70% as high as rates found with redox cycling agent plus ferric-chelate (e.g., ferric-EDTA, ferric-ATP). Since reactive oxygen intermediates such as the hydroxyl radical can alter the structural integrity of the nucleus and interact with DNA, the ability of ferritin to promote nuclear generation of hydroxyl radical may play a role in the toxicity associated with iron as well as redox cycling agents.
 ...
PMID:Ferritin stimulation of hydroxyl radical production by rat liver nuclei. 831 76


1 2 Next >>