A Simple and Rapid Method for the Determination of "free" Iron in Biological Fluids

We present a convenient method for determining "free" or non-protein-bound iron in biological fluids. The new method is based on the bathophenantroline method for determination of total serum iron, and comprises binding of iron by a chromogenic chelator (bathophenantroline-disulphonate, BPS), which is specific for ferrous iron. The ferrous complex of BPS absorbs strongly at 535 nm, and the detection limit is less than 1 &#119 M in a sample size of 50 &#119 l. The chelator does not liberate iron from either haemoglobin or transferrin. Interference from copper or zinc in concentrations up to 50 &#119 M does not significantly disturb measurements. The main problem when measuring in blood plasma, the high and fluctuating background in the region around 535 nm, has been overcome through filtering techniques. Data from measurements of ferrous iron in microdialysate, cerebrospinal fluid, and blood plasma in different animal models and clinical conditions are presented as illustrative examples of the usefulness of the method. The method allows the determination of ferric, as well as ferrous, iron in the same sample.     

A simple and rapid method for the determination of "free" iron in biological fluids

We present a convenient method for determining "free" or non-protein-bound iron in biological fluids. The new method is based on the bathophenantroline method for determination of total serum iron, and comprises binding of iron by a chromogenic chelator (bathophenantroline-disulphonate, BPS), which is specific for ferrous iron. The ferrous complex of BPS absorbs strongly at 535 nm, and the detection limit is less than 1 μM in a sample size of 50 μl. The chelator does not liberate iron from either haemoglobin or transferrin. Interference from copper or zinc in concentrations up to 50 μM does not significantly disturb measurements. The main problem when measuring in blood plasma, the high and fluctuating background in the region around 535 nm, has been overcome through filtering techniques. Data from measurements of ferrous iron in microdialysate, cerebrospinal fluid, and blood plasma in different animal models and clinical conditions are presented as illustrative examples of the usefulness of the method. The method allows the determination of ferric, as well as ferrous, iron in the same sample.     

Microanalysis of non-heme iron in animal tissues

The method recommended by the Iron Panel of the International Committee for the Standardization in Haematology for measurement of serum iron was adapted for measurement of non-heme iron in animal tissues. The method developed was designed specifically to facilitate measurement of non-heme iron using as little as 10 mg of tissue, in a final reaction volume of 60 microl. In this assay, tissue homogenates are treated with hydrochloric acid and trichloroacetic acid and heated at 95 degrees C. Non-heme iron is released and protein is precipitated. Following centrifugation, iron in the supernatant is reacted with ferrozine in the presence of the reducing agent thioglycolic acid, and the complex is quantified by spectrophotometry. The method was validated by analysis of two Standard Reference Materials (bovine liver), comparing results of this assay against certified values and concentrations determined by flame atomic absorption spectrometry following acid digestion. Results using this method for analysis of non-heme iron in guinea pig tissues (liver, kidney and heart) compared favorably with those obtained using micro-scale adaptations of three published reference methods. The new method was more sensitive, required less time, and was less cumbersome than the three published methods to which it was compared.     

Aerobic ferrisiderophore reductase assay and activity stain for native polyacrylamide gels

The reduction of ferric iron from microbial iron-binding compounds (siderophores) releases the iron from the siderophore so that it may be utilized by the microorganism. A method to detect aerobic ferrisiderophore reductase activity using ferrozine as a ferrous iron trap is shown to be applicable to cytoplasmic fractions from Rhodopseudomonas sphaeroides and four other different species of bacteria. The ferrisiderophore reductase uses reduced nicotinamide cofactors as reducing agents, and activity is stimulated by flavins. This assay has been adapted as a staining method to locate ferrisiderophore reductase activity in native polyacrylamide gels.     

On the non-ferritin depot iron fraction in the rat liver

Liver depot iron can be divided into two fractions: ferritin iron and non-ferritin depot iron. Three methods intended to measure the non-ferritin depot iron in the rat liver were compared using livers of normal rats and livers of rats loaded with iron by transfusion of erythrocytes. Liver depot iron varied between 75 and 850 μg Fe/g liver. Non-ferritin depot iron, measured as the iron fraction sedimentable at 10 000 × g, was in the range 4–22 μg Fe/g liver. This fraction did contain ferritin. When measured as the difference between total liver depot iron and heat-stable iron (ferritin iron), the range was 10–270 μg Fe/g liver but this fraction also includes some ferritin iron.The values derived with both methods were linearly proportional to the total liver depot iron values.Non-ferritin depot iron, when measured as the difference between total liver depot iron and total ferritin iron, ranged from 0 to 190 μg Fe/g liver. In this last method no ferritin iron is included. This method provides the best estimate of the non-ferritin depot iron fraction. The concentrations obtained with this method were not always linearly proportional to the total liver depot iron concentration. Intravenous injection of rat liver ferritin resulted in a rapid accumulation of ferritin iron in the liver, together with an increase of the non-ferritin depot iron fraction from 18 μg Fe/g liver to 55 μg Ge/g liver. This confirms a relationship between ferritin catabolism and the non-ferritin depot iron fraction.     

The Histochemical Detection of iron in Tissues

The fixation and staining of iron in tissues is discussed. Procedures for demonstrating iron in hemoglobin and nuclei are also briefly considered.

Lillie's formalin buffered at neutrality gave the optimal fixation for iron. The Prussian blue method was preferred to the Turnbull blue. Lison's procedure of the former, slightly modified, gave the most satisfactory results. When a procedure is required that employs non-iron-containing reagents, Macallum's or Mallory's hema-toxylin and Quincke's ammonium sulfide method are useful. The former, though not entirely specific, is preferable under controlled conditions when the quantities of iron are small. Hemoglobin iron in paraffin sections can be demonstrated by the usual procedures for iron after previous exposure of the section to peroxide, as recommended by Brown. The property of nuclei to adsorb iron from inorganic sources and from hemoglobin can readily be shown; caution is required in interpreting the iron detected in nuclei after Macallum's sulfuric acid hydrolysis.     

Numerical methods for estimating iron requirements from population data

The estimation of iron requirements is crucial for nutrition and food policy. The traditional methods for estimating iron requirements are balance methods based on iron intakes and excretions and factorial methods based on estimated iron absorption rates and estimated iron losses from body compartments. As an alternative, numerical methods for estimating iron requirements from population data of iron status were developed. The iron status data reported by Satoh (1991) were used in the sixth edition of Recommended Dietary Allowances for Japanese. The menstrual iron losses in Japanese premenopausal women were estimated from the literature to calculate total iron losses as the sum of basal iron losses and menstrual iron losses. The use of this alternative method is illustrated by analyzing the same population data comprising the prevalence of iron deficiency and the distribution of iron intake. The estimated average requirements were affected by the form of distribution function, the relative standard deviation of requirements, and the correlation coefficient between iron intakes and requirements. We conclude that numerical methods can be very useful for estimating iron requirements and to elucidate dietary recommendations of iron. These methods may contribute to determining requirements of other nutrients as well as iron.     

Determination of nonheme iron using inductively coupled plasma-atomic emission spectrometry

A technique for the rapid and accurate estimation of nonheme iron using inductively coupled plasma-atomic emission spectrometry is described. Yttrium was used as an internal standard. An external calibration method was used. The standards were prepared in a matrix composed of 2.5N HCl in 10% (w/v) trichloroacetic acid. The supernatant and coagulum fractions of liver nonheme iron were separated by the method of Drysdale and Ramsay with minor modification. The data determined by this procedure was compared and found to be agreement with data determined by the method of Hallgren. To evaluate the iron status of rats, hemoglobin and liver nonheme iron were determined. Hemoglobin and all of the nonheme iron fractions of the rats fed an iron-deficient diet were significantly lower than those of the rats fed an iron-sufficient diet. The blood content in the liver was estimated to be 80 microL/g from the blood iron concentration, and the difference between total and nonheme iron concentration in liver.     

Does the calcein-AM method assay the total cellular 'labile iron pool' or only a fraction of it?

The calcein-AM (calcein-acetoxymethyl ester) method is a widely used technique that is supposed to assay the intracellular 'labile iron pool' (LIP). When cells in culture are exposed to this ester, it passes the plasma membrane and reacts with cytosolic unspecific esterases. One of the reaction products, calcein, is a fluorochrome and a hydrophilic alcohol to which membranes are non-permeable and which, consequently, is retained within the cytosol of cells. Calcein fluorescence is quenched following chelation of low-mass labile iron, and the degree of quenching gives an estimate of the amounts of chelatable iron. However, a requirement for the assay to be able to demonstrate cellular LIP in total is that such iron be localized in the cytosol and not in a membrane-limited compartment. For some time it has been known that a major part of cellular, redox-active, labile, low-mass iron is temporarily localized in the lysosomal compartment as a result of the autophagic degradation of ferruginous materials, such as mitochondrial complexes and ferritin. Even if some calcein-AM may escape cytosolic esterases and enter lysosomes to be cleaved by lysosomal acidic esterases, the resulting calcein does not significantly chelate iron at 相似文献   

Cellular iron uptake from transferrin: is endocytosis the only mechanism?

Receptor mediated endocytosis has been proposed as the method of cellular iron uptake from transferrin (TF). However, the experimental evidence for endocytosis in every situation is found wanting. This is particularly true for the hepatocyte where an alternative mechanism of iron release at the cell surface can account for all iron uptake. It may be, that under appropriate physiological conditions (e.g. degree of iron saturation of TF) cells may take up iron by either an endocytotic or nonendocytotic mechanism.     

A modified ferrozine method for the measurement of enzyme-bound iron

A general procedure for the determination of the iron content of enzymes by digestion with methanesulfonic acid to release protein-bound iron has been developed. This procedure replaces the tedious and potentially hazardous method of wet ashing with concentrated nitric-sulfuric-perchloric acids. The method has been used to determine the stoichiometry of iron for nanomole quantities of heme-iron proteins, iron-sulfur proteins, complex iron-sulfur proteins, as well as in phenylalanine hydroxylase, an enzyme with iron in an undetermined coordination.     

Free iron in bacteria

Free iron content has been estimated in autotrophic and heterotrophic bacteria. It constituted 40-50 micrograms/g dry weight as compared to 15 micrograms/g dry weight in animal cells. A method for estimation of free iron has been proposed. It is based on formation of paramagnetic dinitrosyl iron complexes by free iron and protein thiol groups or low molecular weight thiol ligands. The reasons for high iron content in bacteria have been discussed.     

The iron-binding properties of hen ovotransferrin.

1. The distribution of iron between the two iron-binding sites in partially saturated ovotransferrin was studied by labelling with 55Fe and 59Fe and by gel electrophoresis in a urea-containing buffer. 2. When iron is added in the form of chelate complexes at alkaline pH, binding occurs preferentially at the N-terminal binding site. In acid, binding occurs preferentially at the C-terminal site. 3. When simple iron donors (ferric and ferrous salts) are used the metal is distributed at random between the binding sites, as judged by the gel-electrophoresis method. The double-isotope method shows a preference of ferrous salts for the N-terminal site. 4. Quantitative treatment of the results of double-isotope labelling suggests that in the binding of iron to ovotransferrin at alkaline pH co-operative interactions between the sites occur. These interactions are apparently absent in the displacement of copper and in the binding of iron at acid pH.     

Determination of the chelatable iron pool of single intact cells by laser scanning microscopy

We have previously established a method of detecting intracellular chelatable iron in viable cells based on digital fluorescence microscopy. To quantify cellular chelatable iron, it was crucial to determine the intracellular indicator concentration. In the present study, we therefore adapted the method to confocal laser scanning microscopy, which should allow the determination of the indicator concentration on the single-cell level. The fluorescent heavy-metal indicator phen green SK (PG SK), the fluorescence of which is quenched by iron, was loaded into cultured rat hepatocytes. The hepatocellular fluorescence increased when cellular chelatable iron available to PG SK was removed from the probe by an excess of the membrane-permeable transition metal chelator 2,2'-dipyridyl (2, 2'-DPD, 5 mM). We optimized the scanning parameters for quantitatively recording changes in fluorescence and determined individual intracellular PG SK concentrations from the unquenched cellular fluorescence (after 2,2'-DPD) compared with PG SK standards in a "cytosolic" medium. An ex situ calibration method based on laser scanning microscopy was set up to determine the concentration of cellular chelatable iron from the increase of PG SK fluorescence after addition of 2,2'-DPD (5 mM). As the stoichiometry of the PG SK:Fe(2+) complex was 3:1 as long as PG SK was not limiting, cellular chelatable iron was calculated directly from absolute changes in cellular fluorescence. Using this method, we found 2.5 +/- 2.2 microM chelatable iron in hepatocytes. This method makes it possible to determine the pool of chelatable iron in single vital cells independently of cellular differences (e.g., dye loading, cell volume) in heterogeneous cell populations.     

Polynuclear iron compounds in human transferrin preparations

During commonly used saturation procedures of transferrin with iron compounds, both as ferri and ferrous, polynuclear iron compounds are easily formed, even when nitrilotriacetate (NTA) is used as a strong iron ligand. The presence of these nonspecific bound irons is demonstrated with Mossbauer spectroscopy and with electronic optical spectroscopy. But no evidence, however, has been found of two different iron binding sites. Because dialysis is not able to remove all polynuclear iron, an easy method with gel filtration has been developed that does remove the polynuclear iron. Some notes are made about the often used method, in transferrin biochemistry, of saturation determination, i.e. the quotient of the absorbances of 470 and 280 nm.     

Role of iron in the interaction of red blood cells with methylglyoxal. Modification of L-arginine by methylglyoxal is catalyzed by iron redox cycling.

Diabetes mellitus is characterized by increased methylglyoxal (MG) production. The aim of the present study was to investigate the role of iron in the cellular and molecular effects of MG. A red blood cell (RBC) model and L-arginine were used to study the effects of MG in the absence and presence of iron. Intracellular free radical formation and calcium concentration were measured using dichlorofluorescein and Fura-2-AM, respectively. Effects of MG were compared to the effect of ferrous iron. Reaction of L-arginine with MG was investigated by electron spin resonance (ESR) spectroscopy and by a spectrophotometric method. MG caused an iron dependent oxidative stress in RBCs and an elevation of the intracellular calcium concentration due to formation of reactive oxygen species. Results of co-incubation of MG with ferrous iron in the RBC model suggested an interaction of MG and iron; one interaction was a reduction of ferric iron by MG. A role of iron in the MG-L-arginine reaction was also verified by ESR spectroscopy and by spectrophotometry. Ferric iron increased free radical formation as detected by ESR in the MG-L-arginine reaction; however, ferrous iron decreased it. The reaction of MG with L-arginine yielded a brown product as detected spectrophotometrically and this reaction was catalyzed at a lower rate with ferric iron but at a higher rate with ferrous iron. These data suggest that MG causes oxidative stress in cells, which is due at least in part to ferric iron reduction by MG and to the modification of amino acids e.g. L-arginine by MG, which is catalyzed by iron redox cycling.     

Determination of desferrioxamine-available iron in biological tissues by high-pressure liquid chromatography

Intracellular iron loosely bound to proteins such as ferritin or in the form of low molecular weight chelates is available to catalyze adverse reactions such as the formation of reactive free radicals. A method to measure this small but important iron pool by utilizing the highly specific iron-chelator desferrioxamine is described. Following incubation of tissue fractions with desferrioxamine, the parent compound and its iron-bound form, ferrioxamine, are extracted using solid-phase cartridges and quantitated by reversed-phase HPLC using uv detection. Calculation of the ferrioxamine:desferrioxamine ratio and comparison with a standard curve constructed using a series of known iron concentrations allow the determination of micromolar amounts of desferrioxamine-available iron in biological samples.     

Preparation of enterochelin from Escherichia coli.

A convenient method has been developed for the preparation of enterochelin, the natural iron carrier produced by Escherichia coli. The method employs a mutant strain which is unable to transport the ferric-enterochelin complex into the cell and which excretes large quantities of enterochelin into the culture medium. The addition of excess iron to the medium allows the enterochelin to accumulate as the ferric-enterochelin complex which is purified by ion-exchange chromatography and then dissociated and the free enterochelin further purified by differential extraction and crystallization. The enterochelin is isolated in good yield and appears to be of high purity as judged by a number of criteria.     

The effect of estrogens on serum ferritin levels in duck

Serum and tissue ferritin content is measured in duck by a RIA method before and after treatment with estrogens, as well as serum ferritin in laying and non-laying hen. Both serum ferritin and tissue ferritin decrease after treatment with estrogens, while serum iron increases. A relationship between serum ferritin and iron stores in duck is shown.     

Mitochondrial iron not bound in heme and iron-sulfur centers and its availability for heme synthesis in vitro

Rat liver mitochondrial fractions have previously been shown to contain a pool of iron which was bound neither in cytochromes nor in iron-sulfur centers (Tangerås, A., Flatmark, T., Bäckström, D. and Ehrenberg, A. (1980) Biochim. Biophys. Acta 589, 162–175), and in the present study the availability of this iron pool for heme synthesis has been studied in isolated mitochondria. A minor fraction of this iron is here shown to originate from iron-rich lysosomes present as a contaminant in mitochondrial fractions isolated by differential centrifugation, and a method for the selective quantitation of this iron pool was developed. The availability of the mitochondrial iron pool for heme synthesis by mitochondria in vitro was studied using a recently developed HPLC method for the assay of ferrochelatase activity. When deuteroporphyrin was used as the substrate, 1.04±0.13 nmol/mg protein of deuteroheme was formed after 6 h incubation at 37°C when a plateau was approached, and the initial rate of heme synthesis was 0.3 nmol/h per mg protein. Heme formation from the physiological substrate protoporphyrin was also seen. The heme synthesis increased with the amount of mitochondria used and was blocked by both Fe(II) and Fe(III) chelators. The heme synthesis was independent of mitochondrial oxidizable substrates and no difference was observed between pH 7.4 and 6.5. FMN slightly stimulated the formation of heme from endogenous iron, probably by mobilization of a small amount of contaminating lysosomal iron present in the preparations. The possibility that the mitochondrial iron pool functions as the proximate iron donor for heme synthesis by ferrochelatase in vivo is discussed.