Ferritin structure and biosynthesis

Atrial structure and function in middle-aged, physically-active males and females: A cardiac magnetic resonance study

Recent studies have reported on an association between endurance sport, atrial enlargement and the development of lone atrial fibrillation in younger, male cohorts. The atrial morphology and function of middle‐aged, physically‐active males and females have not been well studied. We hypothesized that middle‐aged males would demonstrate larger left atrium (LA) and right atrium (RA) volumes compared to females, but atrial function would not differ. LA and RA volume and function were evaluated at rest in healthy adults, using a standardized 3.0Tesla cardiac magnetic resonance protocol. Physical activity, medical history, and maximal oxygen consumption (V˙O2peak) were also assessed. Physically‐active, middle‐aged men (n = 60; 54 ± 5 years old) and women (n = 30; 54 ± 5 years old) completed this study. Males had a higher body mass index, systolic blood pressure, and V˙O2peak than females (p < .05 for all), despite similar reported physical activity levels. Absolute and BSA and height‐indexed LA and RA maximum volumes were higher in males relative to females, despite no differences in ejection fractions (p < .05 for all). In multivariable regression, male sex p < .001) and V˙O2peak (p = .004) were predictors of LA volume (model R² = 0.252), whereas V˙O2peak (p < .001), male sex (p = .03), and RV EF (p < .05) were predictors of RA volume (model R² = 0.377). While middle‐aged males exhibited larger atrial volumes relative to females, larger, prospective studies are needed to explore the magnitude of physiologic atrial remodeling and functional adaptations in relation to phenotypic factors.

Degradation of psoralen photo-oxidation products induced by ferrous ions

Psoralen was irradiated at 366 nm in aerated aqueous or ethanol solutions. Fe2+ ions reduced photo-oxidized psoralen (POP) with the formation of free radicals and electronically excited states. Free radicals were detected by the electron spin resonance (ESR) method using the spin trap C-phenyl-N-tert-butyl-nitrone (PBN), and electronically excited states were registered by chemiluminescence (ChL) accompanying the destruction of POP by Fe2+ ions. PBN could not scavenge directly free radicals generated by the reduction of POP with Fe2+ and required the presence of ethanol during the reaction. Analysis of ESR spectra indicated that PBN trapped hydroxyethyl free radicals which were produced as a byproduct in the reaction of POP and Fe2+. The dependence of the yield of PBN adducts on the fluence of psoralen irradiation and the concentration of Fe2+ ions was measured. Although both ESR and ChL estimated the POP products destructible by Fe2+ (POPFe), they gave information about different POPFe products. A kinetic analysis showed that ChL-estimated POPFe products were produced with the participation of two molecules of psoralen (one in the electronically excited state and one in the ground state), whereas ESR-estimated POPFe products were produced with the participation of one molecule of psoralen in the excited state. ESR-estimated products were stable in both water and ethanol solutions and could be stored for 20 h without significant decay; pre-incubation of POP solutions with catalase or glutathione-peroxidase decreased the yield of PBN adducts by 50%. ChL-estimated products were essentially less stable, about 30% being spontaneously destroyed during storage in ethanol solution at room temperature; pre-incubation of these products with catalase decreased the ChL by 90%. The possible biological role of POPFe products is discussed.

Ferrous ion release from ferritin by ultraviolet-A radiations

Ferritin is the principal protein of iron storage (in the Fe(III) state). The UV-A irradiation of 0.25 microM ferritin solutions (from horse spleen) loaded with 530 microM Fe(III) induces Fe2+ release in the medium. The initial quantum yield is wavelength dependent (phi(365 nm) approximately 2 x 10(-3) but pH and oxygen independent. The Fe2+ release reaches a plateau which strongly depends on pH and oxygen. The amino acid composition of the apoprotein is not altered by the UV irradiation. Addition of formate ions enhances the Fe2+ production, suggesting that the ferritin photoreduction involves an electron transfer from an OH- ligand. The possible importance of this phenomenon in skin photobiology is discussed.

Characterization of ferritin from human placenta. Implications for analysis of tissue specificity and microheterogeneity of ferritins

Mammalian ferritins can be resolved into multiple components by isoelectric focusing, and each tissue contains a characteristic subset of isoferritins. Ferritin isolated from human liver was compared to acidic ferritin isolated from mid-gestational human placenta to define a structural basis for ferritin heterogeneity. Placenta ferritin contained several major bands with isoelectric points in the range of pI = 4.7-5.0 which were more acidic than the predominant isoferritins of human liver. Ferritin from each tissue was resistant to denaturation by 10 M urea and appeared to be identical by electron microscopy. Circular dichroism measurements revealed that placenta ferritin had substantially less ordered secondary structure than liver ferritin. Both types of ferritin contained only two subunits when analyzed by electrophoresis in sodium dodecyl sulfate gels, but isoelectric focusing of dissociated subunits in urea revealed 6-7 different components. In this system, placenta ferritin was enriched in the more acidic subunits and it completely lacked the most basic subunits noted in liver ferritin; placental ferritin had no unique components. Differences in isoelectric points among assembled ferritins from these two tissues appear to result from different proportions of these acidic and basic subunits.

Renal tubular ferritin-uptake, a consequence of the increased glomerular permeability, during the benign and malignant course of renal hypertension in rats

Tubular uptake of ferritin given intravenously was studied in the right and left kidneys of 74 Goldblatt-hypertensive rats. Previous observations pointed out the pathologically enhanced permeability of glomerular barrier as the cause of the phenomenon. It was assumed, that the extent of tubular areas taking up ferritin, refers to the number of damaged glomeruli. The process was characterized semiquantitatively by planimetric measurements and determination of the non-hemin iron concentration in the renal cortical tissue. A more frequent and extensive tubular ferritin-uptake (and glomerular damage) was bilaterally recorded in the kidneys of malignant hypertensive rats in comparison to the benign ones. The development of the phenomenon in the clamped kidneys, being defended from high blood pressure, suggests a humoral factor behind the enhanced glomerular permeability. Saline intake has a beneficial effect on the glomerular damage similar to the hypertensive angiopathy.

Correlations between subunit distribution, microheterogeneity, and iron content of human liver ferritin

Subunit heterogeneity of human liver ferritin was investigated by two-dimensional electrophoretic methods. The protein which ordinarily remains assembled in 10 M urea solution was dissociated into subunits in acid-urea or sodium dodecyl sulfate solutions. In agreement with earlier studies, the subunits migrated as two bands in sodium dodecyl sulfate or acid-urea gel electrophoresis systems or in two-dimensional combinations of these systems. Isoelectric focusing methods, however, resolved four major subunit bands and three to five minor bands. Each of these components migrated as either a 22 000 or a 19 000 molecular weight component in sodium dodecyl sulfate gel electrophoresis in the second dimension. The multiple subunit model, which is contrary to currently accepted representations of ferritin structure, is compatible with certain inherent properties of the protein. Thus, ferritin was fractionated on the basis of iron content to show that the relative amounts of individual subunit types were directly dependent upon the iron composition of the protein. Iron-loaded molecules were deficient in the most basic subunit types, and apoferritin was enriched in these components. Aspects of microheterogeneity of assembled ferritin molecules were correlated to subunit heterogeneity, and discrete differences in subunit populations among purified isoferritin components were demonstrated.