Bathophenanthroline Sulfonate Research Articles

Quantitative Analysis of Iron Bound to Humic Substances in Surface Water

Water-soluble iron species in surface water are predominantly composites of Fe(III) and natural organic matter (Fe(III)NOM), such as fulvic acid and humic acid (HA). Fe(III)NOM can promote the growth of microorganisms and plants; therefore, it has significant impact on aquaculture and agriculture businesses. In this paper, a simple method of concurrent pretreatment and colorimetry by using deferoxamine (DFO), L-ascorbic acid, and dye nanoparticle-coated test strip (DNTS) for Fe(II) has been proposed for the on-site and direct detection of Fe(III)NOM in surface water. DFO, well-known as a siderophore, shows sufficient intake ability of Fe(III) (Fe(III)DFO K: 1031) from Fe(III)NOM, but unfortunately it interfered with the color detection of Fe(II) with DNTS loading bathophenanthroline sulfonate. However, the addition of a large excess of L-ascorbic acid and the following pH decrease certainly solved the problem by decomposition of the Fe(III)DFO complex and the following reduction, thereby causing a color change corresponding to the Fe concentration. A quantitative analysis of Fe(III)HA in the range from 15 ppb to 1 ppm has been demonstrated to be surely successful by a comparison with two calibration curves of Fe(II) and Fe(III)- humic acid.

A nonheme high-spin ferrous pool in mitochondria isolated from fermenting Saccharomyces cerevisiae.

Mössbauer spectroscopy was used to detect pools of Fe in mitochondria from fermenting yeast cells, including those consisting of nonheme high-spin (HS) Fe(II) species, Fe(III) nanoparticles, and mononuclear HS Fe(III) species. At issue was whether these species were located within mitochondria or on their exterior. None could be removed by washing mitochondria extensively with ethylene glycol tetraacetic acid or bathophenanthroline sulfonate (BPS), Fe(II) chelators that do not appear to penetrate mitochondrial membranes. However, when mitochondrial samples were sonicated, BPS coordinated the Fe(II) species, forming a low-spin Fe(II) complex. This treatment also diminished the levels of both Fe(III) species, suggesting that all of these Fe species are encapsulated by mitochondrial membranes and are protected from chelation until membranes are disrupted. 1,10-Phenanthroline is chemically similar to BPS but is membrane soluble; it coordinated nonheme HS Fe(II) in unsonicated mitochondria. Further, the HS Fe(III) species and nanoparticles were not reduced by dithionite until the detergent deoxycholate was added to disrupt membranes. There was no correlation between the percentage of nonheme HS Fe(II) species in mitochondrial samples and the level of contaminating proteins. These results collectively indicate that the observed Fe species are contained within mitochondria. Mossbauer spectra of whole cells were dominated by HS Fe(III) features; the remainder displayed spectral features typical of isolated mitochondria, suggesting that the Fe in fermenting yeast cells can be coarsely divided into two categories: mitochondrial Fe and (mostly) HS Fe(III) ions in one or more non-mitochondrial locations.

Cisplatin upregulates Saccharomyces cerevisiae genes involved in iron homeostasis through activation of the iron insufficiency‐responsive transcription factor Aft1

The response of Saccharomyces cerevisiae to cisplatin was investigated by examining variations in gene expression using cDNA microarrays and confirming the results by reverse transcription polymerase chain reaction (RT-PCR). The mRNA levels of 14 proteins involved in iron homeostasis were shown to be increased by cisplatin. Interestingly, the expression of all 14 genes is known to be regulated by Aft1, a transcription factor activated in response to iron insufficiency. The promoter of one of these genes, FET3, has been relatively well studied, so we performed a reporter assay using the FET3 promoter and showed that an Aft1 binding site in the promoter region is indispensable for induction of transcription by cisplatin. The active domain of Aft1 necessary for activation of the FET3 promoter by cisplatin is identical to the one required for activation by bathophenanthroline sulfonate, an inhibitor of cellular iron uptake. Furthermore, we found that cisplatin inhibits the uptake of (55)Fe(II) into yeast cells. These findings suggest that cisplatin activates Aft1 through the inhibition of iron uptake into the cells, after which the expression of Aft1 target genes involved in iron uptake might be induced.

Zip14 (Slc39a14) mediates non-transferrin-bound iron uptake into cells

Zip14 is a member of the SLC39A zinc transporter family, which is involved in zinc uptake by cells. Up-regulation of Zip14 by IL-6 appears to contribute to the hepatic zinc accumulation and hypozincemia of inflammation. At least three members of the SLC39A family transport other trace elements, such as iron and manganese, in addition to zinc. We analyzed the capability of Zip14 to mediate non-transferrin-bound iron (NTBI) uptake by overexpressing mouse Zip14 in HEK 293H cells and Sf9 insect cells. Zip14 was found to localize to the plasma membrane, and its overexpression increased the uptake of both (65)Zn and (59)Fe. Addition of bathophenanthroline sulfonate, a cell-impermeant ferrous iron chelator, inhibited Zip14-mediated iron uptake from ferric citrate, suggesting that iron is taken up by HEK cells as Fe(2+). Iron uptake by HEK and Sf9 cells expressing Zip14 was inhibited by zinc. Suppression of endogenous Zip14 expression by using Zip14 siRNA reduced the uptake of both iron and zinc by AML12 mouse hepatocytes. Zip14 siRNA treatment also decreased metallothionein mRNA levels, suggesting that compensatory mechanisms were not sufficient to restore intracellular zinc. Collectively, these results indicate that Zip14 can mediate the uptake of zinc and NTBI into cells and that it may play a role in zinc and iron metabolism in hepatocytes, where this transporter is abundantly expressed. Because NTBI is commonly found in plasma of patients with hemochromatosis and transfusional iron overload, Zip14-mediated NTBI uptake may contribute to the hepatic iron loading that characterizes these diseases.

Role of Glutaredoxin-3 and Glutaredoxin-4 in the Iron Regulation of the Aft1 Transcriptional Activator in Saccharomyces cerevisiae

The transcription factors Aft1 and Aft2 from Saccharomyces cerevisiae regulate the expression of genes involved in iron homeostasis. These factors induce the expression of iron regulon genes in iron-deficient yeast but are inactivated in iron-replete cells. Iron inhibition of Aft1/Aft2 was previously shown to be dependent on mitochondrial components required for cytosolic iron sulfur protein biogenesis. We presently show that the nuclear monothiol glutaredoxins Grx3 and Grx4 are critical for iron inhibition of Aft1 in yeast cells. Cells lacking both glutaredoxins show constitutive expression of iron regulon genes. Overexpression of Grx4 attenuates wild type Aft1 activity. The thioredoxin-like domain in Grx3 and Grx4 is dispensable in mediating iron inhibition of Aft1 activity, whereas the conserved cysteine that is part of the conserved CGFS motif in monothiol glutaredoxins is essential for this function. Grx3 and Grx4 interact with Aft1 as shown by two-hybrid interactions and co-immunoprecipitation assays. The interaction between glutaredoxins and Aft1 is not modulated by the iron status of cells but is dependent on the conserved glutaredoxin domain Cys residue. Thus, Grx3 and Grx4 are novel components required for Aft1 iron regulation that most likely occurs in the nucleus.

Comparison of Bathophenanthroline Sulfonate and Ferene as Chromogens in Colorimetric Measurement of Low Hepatic Iron Concentration

Sensitive and accurate measurement of hepatic iron concentration (HIC) is required to investigate liver fibrogenesis (1) and its influence on the outcome of interferon therapy for chronic viral hepatitis C (2)(3). Hepatic iron content can be measured by a quantitative chemical method and/or evaluated by semiquantitative histologic scoring. Quantitative chemical methods assess all liver iron forms, whereas histologic scoring evaluates only the hemosiderin form. A colorimetric method using bathophenanthroline sulfonate as chromogen was recommended in 1978 by the International Committee for Standardization in Hematology (ICSH) for determination of serum iron (4)(5). It was adapted by Barry and Sherlock (6) to the determination of HIC, and we recently evaluated it for measurement of low HIC (7). In 1990, the ICSH replaced bathophenanthroline sulfonate with ferene, a more sensitive chromogen, in the determination of serum iron (8). The aim of the present study was to evaluate the replacement of bathophenanthroline sulfonate with ferene to improve the sensitivity of the colorimetric determination of low HIC. We used samples of a frozen Wistar rat liver for quality control and determination of reliability criteria of both assays. We compared the results obtained with the two chromogens on 66 liver biopsies from patients with chronic liver diseases hospitalized in the Department of Hepatogastroenterology of the Pitie-Salpetriere Hospital. The clinical diagnoses of these patients are summarized in Table 1⇓ . We determined the CV for HIC measurements on two separate samples from the same liver specimen for each chromogen on 38 human liver biopsies. Histologic iron scoring was according to the method of Deugnier et al. (9); among the 66 biopsies, 20 had no stainable iron (score of 0), and the 46 others exhibited iron overload (score ≥6). Biopsies were fixed in 40 g/L formaldehyde and embedded in paraffin as part of …

Inhibition of 2,3-dimethyl-1,4-naphthohydroquinone auto-oxidation by copper and by superoxide dismutase

2,3-Dimethyl-1,4-naphthohydroquinone undergoes auto-oxidation to the corresponding quinone at pH 7.4, with stoichiometric consumption of oxygen and formation of hydrogen peroxide. In an unpurified buffer, the rate of oxidation was low, but it increased nearly 9-fold when trace metals were removed from the buffer by treatment with Chelex resin. A similar increase in rate was achieved by addition of DTPA or bathophenanthroline sulfonate to unpurified buffer, whereas EDTA and desferal were less effective. Addition of copper to purified buffer led to inhibition of oxidation, with a 50% decrease in rate being observed at a metal concentration of 7.1 nM, and it is likely that the low auto-oxidation rate recorded in unpurified buffer was due to copper contamination of the latter. The auto-oxidation of 2,3-dimethyl-1,4-naphthohydroquinone was exceptionally sensitive to inhibition by superoxide dismutase, with a concentration of only 4.5 ng/ml being sufficient for a 50% decrease in rate, and the inhibitory effect of copper may be due to the ability of this metal to catalyse the dismutation of superoxide. Previous studies have shown that the rates of auto-oxidation of 1,4-naphthohydroquinone and 2-methyl-1,4-naphthohydroquinone are influenced by copper contamination of buffer and the present study shows that this is also true for a di-substituted naphthohydroquinone. For accurate assessment of rates of naphthohydroquinone auto-oxidation, it is important that purified buffers or appropriate chelating agents are employed.

Inhibition of retinal growth cone activity by specific metalloproteinase inhibitors in vitro.

The developing neural retina expresses a set of extracellular proteases including plasminogen activator and gelatinases. Since neurites of retina cells cultured on fluorescent gelatin digest the substrate in their paths, we have suggested that the proteases are used by the tips of growing fibers to allow them to migrate within the mass of the tissue in vivo. In order to obtain further information about relationships between extracellular proteases and fiber growth, we have examined the effects of the specific inhibitors HS-LFA (HS-Leu-Phenylala-Ala, enantiomeric forms 1 and 2), bathophenanthroline sulfonate (BPS), phenylmethyl sulfonyl fluoride (PMSF), and relevant controls on the activity of retinal growth cones in vitro, monitored by time lapse video microscopy. Of the inhibitors tested, only the two enantiomeric forms of HS-LFA caused a reproducible cessation of both spike extension and filopodial processes at the growth cone ruffling, while control media had no effect. In some cases, the growth cone swelled and exhibited small protrusions. The behavior of growth cones was in sharp distinction to that of the cytoplasm of neural cells, and membrane ruffling of flat cells, which continued in activity throughout. Growth cone activity returned after several hours in the presence of the agent. BPS was toxic at concentrations above 2.5 mM. Below that, it had no effect. L-cysteine, PMSF, and control media had no effect. The relevance of these results to the possible role of proteases in fiber outgrowth from retinal cells is discussed.

Lipid peroxidation of rat erythrocyte membrane induced by adriamycin-Fe3+.

Adriamycin-Fe3+ caused lipid peroxidation of erythrocyte membrane in relation to its concentration. Adriamycin-Fe3+ had a high affinity for membrane and the adriamycin-Fe(3+)-binding membranes membranes was also found to cause lipid peroxidation. Under aerobic conditions, adriamycin-Fe3+ caused a reduction of cytochrome c and ferrous iron formed spontaneously. Superoxide dismutase (EC 1.15.1.1) (SOD) strongly inhibited the reduction of cytochrome c; however, the enzyme promoted formation of ferrous iron independent of enzymatic action. These results suggest that cytochrome c was reduced by superoxide radical (O2-) or an adriamycin-iron-O2 complex such as adriamycin-Fe(3+)-O2-, but not by adriamycin-Fe2+. The ferrous iron chelator bathophenanthroline sulfonate (BPS) completely inhibited oxygen consumption caused by adriamycin-Fe3+, indicating that ferrous iron is absolutely required for the lipid peroxidation. SOD and hydroxyl radical scavengers did not inhibit the lipid peroxidation, indicating that O2- and hydroxyl radical were not involved in membrane peroxidation. The peroxidation reaction was dramatically inhibited by Tris buffer (2-amino-2-hydroxymethyl-1,3-propanediol). However, hydroxyl radical generation and lipid peroxidation in Tris buffer were not related obviously, indicating that Tris did not act as a hydroxyl radical scavenger. The initial rate of TBARS (thiobarbituric acid reactive substances) formation induced by a mixture of adriamycin-Fe3+ and adriamycin-Fe2+ was much faster than that induced by adriamycin-Fe2+ or adriamycin-Fe3+ alone. These results made it became possible to speculate that the lipid peroxidation might be initiated by an adriamycin-Fe(3+)-oxygen-adriamycin-Fe2+ complex.

Inhibition of superoxide and ferritin-dependent lipid peroxidation by ceruloplasmin

Ceruloplasmin (CP) was found to inhibit xanthine oxidase and ferritin-dependent peroxidation of phospholipid liposomes, as evidenced by decreased malondialdehyde formation. Ceruloplasmin was also shown to inhibit superoxide-mediated mobilization of iron from ferritin, in a concentration-dependent manner, as measured spectrophotometrically using the iron(II) chelator bathophenanthroline sulfonate. Ceruloplasmin failed to function as a peroxyl radical-scavenging antioxidant as evidenced by its inability to inhibit free radical-initiated peroxidation of linoleic acid, suggesting that CP inhibited lipid peroxidation by affecting the availability of ferritin-derived iron. In addition, CP scavenged xanthine oxidase-derived superoxide as measured spectrophotometrically via its effect on cytochrome c reduction. However, the extent of the superoxide scavenging of CP did not quantitatively account for its effects on iron release, suggesting that CP inhibits superoxide-dependent mobilization of ferritin iron independently of its ability to scavenge superoxide. The effects of CP and apoferritin on iron-catalyzed lipid peroxidation in systems containing exogenously added ferrous iron was also investigated. In the absence of apoferritin, CP exhibited a concentration-dependent prooxidant effect. However, CP-dependent, iron-catalyzed lipid peroxidation was inhibited by the addition of apoferritin. Apoferritin did not function as a peroxyl radical-scavenging antioxidant but was shown to incorporate iron in the presence of CP. These data suggest that CP inhibits superoxide and ferritin-dependent lipid peroxidation largely via its ability to reincorporate reductively mobilized iron back into ferritin.

The effect of various chelating agents on the mobilization of iron from reticulocytes in the presence and absence of pyridoxal isonicotinoyl hydrazone

The chelating agent pyridoxal isonicotinoyl hydrazone (PIH) has recently been shown to mobilize 59Fe from reticulocytes loaded with non-heme 59Fe. In this study, various chelating agents were tested for their ability to effect the mobilization of iron from reticulocytes by PIH. They fall into several groups. The largest group includes chelators such as citrate, ethylenediaminetetracetic acid and desferrioxamine, which fail to affect PIH-induced iron mobilization and do not mobilize iron per se. Either these chelators do not enter reticulocytes or they do not take up iron from PIH-Fe complexes. The second group includes chelators such as 2,2′-bipyridine, 1,10-phenanthroline, bathophenanthroline sulfonate and N, N′-ethylenebis( o-hydroxyphenylglycine) which inhibit PIH-induced iron mobilization from reticulocytes and, when added together with PIH, induce radioiron accumulation in an alcohol-soluble fraction of reticulocytes. It appears that these chelators enter the cell and compete with PIH for 59Fe(II), but having bound iron are unable to cross the cell membrane. Spectral analysis suggests that Fe(II) chelators such as 2,2′-bipyridine and 1,10-phenanthroline remove iron from Fe(II)PIH but are not able to do so from Fe(III)PIH. Then there are compounds such as 2,3-dihydroxybenzoic acid and catechol which potentiate PIH-induced iron mobilization although they are unable to mobilize iron from reticulocytes by themselves. Lastly, there is a group of miscellaneous compounds which include chelators that either potentiate the iron-mobilizing effect of PIH as well as mobilizing iron from reticulocytes by themselves (tropolone), or that reduce PIH-induced iron mobilization while themselves having an iron-mobilizing effect ( N, N′-bis(2,3-dihydroxybenzoyl)-1,6-diaminohexane). In further experiments, heme was found to stimulate globin synthesis in reticulocytes, the heme synthesis of which was inhibited by PIH, suggesting that PIH is probably not toxic to the cells.

A transmembranous NADH-dehydrogenase in human erythrocyte membranes.

Evidence is presented for a transmembranous NADH-dehydrogenase in human erythrocyte plasma membrane. We suggest that this enzyme is responsible for the ferricyanide reduction by intact cells. This NADH-dehydrogenase is distinctly different from the NADH-cytochrome b5 reductase on the cytoplasmic side of the membrane. Pretreatment of erythrocytes with the nonpenetrating inhibitor diazobenzene sulfonate (DABS) results in a 35% loss of NADH-ferricyanide reductase activity in the isolated plasma membrane. Since NADH and ferricyanide are both impermeable, the transmembrane enzyme can only be assayed in open membrane sheets with both surfaces exposed, and not in closed vesicles. The transmembrane dehydrogenase has affinity constants of 90 microM for NADH and 125 microM for ferricyanide. It is inhibited by p-chloromercuribenzoate, bathophenanthroline sulfonate, and chlorpromazine.

Iron content and degree of lipid peroxidation in liver mitochondria isolated from iron-loaded rats

1.The content of non-heme iron and the degree of lipid peroxidation were measured in liver mitochondria isolated from rats injected with either Jectofer (an iron-sorbitol-citric acid complex) or iron-nitrilotriacetate. 2. The sedimentation profiles of the mitochondria from controls and iron-treated rats as revealed by analytical differential centrifugation, indicated single population of mitochondria with s 4,B values of 13200± 560 S and 14200±590 S for controls and iron-loaded animals, respectively. In contrast, the sedimentation profiles of the acid phosphatase activity and the non-heme iron revealed marked polydispersities with at least three populations of particles for both controls and iron-loaded animals. 3. The mitochondria and iron-rich lysosomes were separated by density-gradient centrifugation in an isotonic medium of Percoll and sucrose. With this technique, the amount of non-heme iron in a mitochondrial fraction by differential centrifugation decreased from 69±28 nmol/mg protein to 5.6±1.1 nmol/mg protein and from 19.3±5.6 nmol/mg protein to 3.3±0.6 nmol/mg protein for Jectofer and iron-nitrilotriacetate injected rats, respectively. For control rats the amount of mitochondrial non-heme iron was about 2.7 nmol/mg protein both before and following density gradient centrifugation. The extra amount of non-heme iron still present in the purified mitochondrial fraction from iron-loaded rats, as compared to controls, was further characterized by the reactivity towards bathophenanthroline sulfonate. The results suggest that the extra iron was due to a small amount of either ferritin or hemosiderin still contaminaning the mitochondrial fraction. The amount of mitochondrial heme iron was the same in iron-loaded rats and controls. 4. The degree of lipid peroxidation in the mitochondria was estimated from the amount of malondialdehyde. The thiobarbituric acid method used for the quantitation of malondialdehyde was modified so that it was insensitive to variable amounts of iron present in the samples. No difference in the degree of lipid peroxidation was observed between the mitochondria from iron-loaded rats and controls. 5. In contrast to recent proposals (Hanstein, E.G. et al. (1981) Biochim. Biophys. Acta 678, 293–299), the present study showed that the amounts of non-heme iron and the degrees of lipid peroxidation are the same in mitochondria isolated from iron-loaded and control animals.

Studies on ribonucleoside-diphosphate reductase in permeable animal cells: II. Catalytic and regulatory properties of the enzyme in mouse L cells

Ribonucleoside-diphosphate reductase (EC 1.17.4.1) was studied in mouse L cells selectively permeabilized to small molecules by treatment with dextran sulfate ( R. Kucera and H. Paulus, 1982, Arch. Biochem. Biophys. 214, 102–113). The reduction of CDP was almost completely dependent on added ATP or adenyl-5′-yl imidodiphosphate, and that of GDP on dTTP. The pattern of inhibition by deoxyribonucleoside triphosphates was similar to that observed by others in cell-free preparations except for a somewhat higher sensitivity to inhibition. The substrate saturation curves for CDP and GDP were hyperbolic with apparent K m values of 0.05 and 0.24 m m, respectively. The maximum velocities for CDP and GDP reduction were close to the in vivo rate of DNA synthesis. Ribonucleotide reductase activity was not affected by the addition of ferric salts but was inhibited by the chelators bathophenanthroline sulfonate and thenoyltrifluoroacetone and also by hydroxyurea. EDTA caused a reversible stimulation of GDP reduction and an irreversible inhibition of CDP reduction; the latter could be partially reactivated by the addition of magnesium salts. Ribonucleotide reductase activity was inhibited by arsenite but only slightly stimulated by NADPH or dithiols; however, if the cells were first treated with 2,6-dichlorophenolindophenol, an almost complete dependence on NADPH was observed which could also be met by dithiothreitol or dihydrolipoic acid but not by reduced glutathione. This suggests that ribonucleotide reductase in dextran sulfate-treated L cells is relatively tightly coupled to an endogenous hydrogen donor system.

A kinetic method for determining iron reducing activity released from plant roots

Abstract This paper describes the development and validation of a new method for determining the iron reducing activity of nutrient solutions supporting plant growth. The method depends on the rate at which an aliquot of nutrient solution reduces the iron of Fe3+‐nitrilotriacetate (NTA). The reduced iron is bound by bath‐ophenanthroline sulfonate (BPS) and the rate of Fe2+‐BPS formation is measured at 535 nm. Fe3+‐NTA was chosen as the test iron reagent, since it is susceptible to reduction, yet, nonpolymeric and stable in solution. Reducing agents showed a wide spectrum of activity in this test. The rate at which they reduce Fe3+‐NTA is not a function of their standard oxidation reduction potential alone. Use of the method is illustrated in a study of the release of iron reducing activity by the roots of a tomato plant. The test proved to be simple, fast, and precise. The advantages and limitations of the method are discussed.

Evidence for a plasma membrane redox system on intact ascites tumor cells with different metastatic capacity

A NADH-ferricyanide reductase of the external surface of intact mouse ascites tumor cells grown in culture was shown. The oxidation/reduction reaction was due to enzymatic rather than inorganic iron catalysis as demonstrated by the kinetics and specificity of the reaction. Activities of three markers for cytoplasmic contents were lacking with the intact tumor cells. The dehydrogenase activity was inhibited by p-chloromercuribenzoate, bathophenanthroline sulfonate, and the anticancer drug adriamycin. Sodium azide and potassium cyanide inhibited partially. The response to inhibitors resembled that of isolated plasma membranes rather than that of mitochondria. Concurrent with these findings, neither superoxide dismutase nor rotenone affected the redox activity. The findings provide evidence for the operation of a plasma membrane redox system at the surface of intact, living cells.

Naphthalene metabolism by pseudomonads: purification and properties of 1,2-dihydroxynaphthalene oxygenase.

1,2-Dihydroxynaphthalene oxygenase was purified from Pseudomonas putida NCIB 9816 grown on naphthalene as the sole source of carbon and energy. The enzyme had a subunit molecular weight of 19,000 and in a medium containing phosphate buffer, 1 mM mercaptoethanol, and 10% (vol/vol) ethanol had a native molecular weight greater than 275,000. The enzyme required Fe2+ for activity. It was inactivated slowly on standing, and inactivation was accelerated by dilution with aerated buffers and by H2O2. Bathophenanthroline sulfonate, o-phenanthroline, 8-hydroxyquinoline, and 2,2'-dipyridyl also inhibited the enzyme. The inactive enzyme was reactivated by anaerobic incubation with ferrous sulfate and ferrous ammonium sulfate. Thiol reagents and acetone, ethanol, or glycerol decreased the rate of loss of activity. The enzyme was most active with 1,2-dihydroxynaphthalene, for which the Km was 2.8 X 10(-4) M. 3-Methyl- and 4-methylcatechols were oxidized at 3 and 1.5%, respectively, of the rate of 1,2-dihydroxynaphthalene, and the Km for 3-methylcatechol was 1.5 X 10(-4) M. Purified 1,2-dihydroxynaphthalene oxygenase catalyzed the oxidation of 1,2-dihydroxynaphthalene, leading to the appearance of 2-hydroxychromene-2-carboxylic acid, but 3-methylcatechol was oxidized by this enzyme to 2-hydroxy-6-oxoheptadienoic acid. Thus, a product structurally analogous to 2-hydroxychromene-2-carboxylic acid was not observed when 3-methylcatechol was oxidized. This may indicate that 2-hydroxychromene-2-carboxylic acid results from cyclization of a ring fission product before release from the enzyme.

Mitochondrial iron not bound in heme and iron-sulfur centers. Estimation, compartmentation and redox state

A method is described for the assay of total mitochondrial non-heme iron and a fraction which does not belong to the iron-sulfur proteins (FeS centers) of the outer and inner membrane. The assay of the latter fraction, which is termed ‘non-heme non-FeS iron’, is based on the formation of a chelate of Fe(II) with bathophenanthroline sulfonate in osmotically swollen mitochondria under conditions where the FeS centers are quite stable as determined by EPR spectroscopy at 20.4 K, 93 K and 123 K.The ‘non-heme non-FeS iron’, which in normal rat liver mitochondria amounts to approx. one third of the total mitochondrial iron (i.e. 1.7 ± 0.3 nmol · mg−1 protein), does not represent a homogeneous pool of iron. Based on studies of its reaction with bathophenanthroline sulfonate and the dependency of this reaction on reducing agents in mitochondria and mitoplasts, evidence is presented that this non-heme iron is present in two major pools in which the inner membrane constitutes the barrier. A minor fraction (i.e. 0.4 ± 0.2 nmol · mg− protein) is localized to the ‘outer’ compartment and a major fraction (i.e. 1.1 ± 0.1 nmol · mg−1 protein) is localized to the ‘inner’ compartment and is equally distributed between the inner membrane and the matrix.The experiments described in this study also indicate that approximately half of the ‘non-heme non-FeS iron’ of the ‘inner’ pool is in the ferrous form in mitochondria as isolated, and this was not increased when oxidizable substrates were added to the mitochondria. Although the biological significance of this iron pool is not yet clear, it is likely that it represents a transit iron pool being the proximate iron donor for heme synthesis catalyzed by the enzyme ferrochelatase.

Mobilization of iron from specifically labeled reticulocyte ghosts

Specifically labeled 59Fe ghosts have been prepared by incubation of whole reticulocytes with 59Fe 3+-transferrin-CO 3 2− followed by washing and ghost isolation. The binding of 59Fe by the membrane fraction is quite stable over a wide range of conditions, but iron mobilization occurs on incubation with chelating agents or cell lysate. The time course of 59Fe mobilization by unlabeled reticulocyte lysate exhibits five apparently zero-order phases. The rate of iron mobilization is linearly dependent on the concentration of 59Fe ghosts present in the incubation mixture. In contrast, the relative concentration of lysate appears to exhibit a saturation dependence with regard to membrane iron mobilization. Bathophenanthroline sulfonate follows a multiphasic time course of iron mobilization similar to that found with the lysate. Lysate from mature erythrocytes was found to mobilize iron with kinetics that are identical to reticulocyte lysate. The number and duration of the phases is independent of the mobilizing agent. The role of the membrane fraction in regulating the rate of iron release to cytosol was also investigated by the repetitive incubation of 59Fe ghosts with fresh lysate. The rate of 59Fe mobilization depended on the condition of the ghost with regard to prior 59Fe depletion. This publication emphasizes the active role of the membrane fraction in determining the rate at which iron will become available to the cytosol and the possibility that cytosol factors modulate the action of membrane bound components.

Polyacrylamide gel staining with Fe 2+-bathophenanthroline sulfonate

The utilization of Fe 2+-bathophenanthroline sulfonate for the detection and quantitation of protein bands in cylindrical polyacrylamide gels is described. Two procedures are outlined. The first procedure is used in standard disc electrophoresis and involves fixing the protein with trichloroacetic acid, staining with Fe 2+-bathophenanthroline sulfonate, and destaining with an ethanol:acetic acid solution. The second protocol reported is utilized with sodium dodecyl sulfate-containing gels. After electrophoresis, the gels are incubated with a methanol: acetic acid solution to remove the sodium dodecyl sulfate. The gels are then stained with Fe 2+-bathophenanthroline sulfonate and destained with a methanol: acetic acid solution. Excellent background clarity is observed with both methods. Densitometric areas of the stained protein bands are linear to 60 μg of bovine serum albumin, and the limit of detection of this protein is 1 μg. Because of its rapidity of staining and destaining, good sensitivity, and reproducibility of stain intensity, Fe 2+-bathophenanthroline sulfonate is an excellent protein stain.