Effects of specific reagents and urea on the reactivity of non-heme iron and thiol groups of pea and corn ferredoxins]

The reactivities of the SH-groups of pea and corn ferredoxins were found to be different. One or two SH-groups in the molecule of pea ferredoxin and one SH-group in the molecule of corn ferredoxin are readily available for the thyol group specific reagents. Four SH-groups of both ferredoxins are completely masked, i. e. available for the thyol reagents only after protein denaturation in the presence of urea. The rates of SH-group interaction with the sulfhydryl reagents in corn ferredoxin are lower than those in pea ferredoxin. The non-haem iron of pea ferredoxin interacts with the complex formers far more rapidly as compared to corn ferredoxin. The ferredoxins tested differ in the amount of iron atoms. The latter require the presence of oxygen for their complete interaction with the complex formers.     

Separation of Fe from transferrin in endocytosis: Role of the acidic endosome

NH₄Cl and monensin, two agents which neutralize intracellular acidic compartments, block the segregation of iron from transferrin after endocytosis, while neither of these reagents affects internalization of diferric transferrin into the cell. In conclusion the molecular separation of iron from transferrin inside the cell requires a non-lysosomal acidic compartment     

Fenton反应及其可能的活性产物

活性氧对许多生物分子,如脂质、蛋白质和DNA等均可引起损伤,它与许多疾病过程相联系.由超氧阴离子自由基和过氧化氢所引起的许多损伤被认为与它们转变为反应活性更强的组分有关,这些组分包括羟自由基及可能的高价铁组分.实验材料及理论结果表明,当铁盐与过氧化氢混合时,除羟自由基产生以外,高价铁组分也被认为同时产生.Fenton试剂的活性中间体是一亲核加合物,其反应活性及其产物不同于游离态羟自由基的反应活性及产物.Fenton试剂的产物分布依赖于不同的过渡金属离子、不同的配位体、不同的反应底物以及不同的溶剂基体效应.     

Significant interaction between low-spin iron(III) site and pyrroloquinoline quinone in active center of nitrile hydratase

Nitrile hydratase, a unique non-heme iron enzyme, contains low-spin Fe(III) site and pyrroloquinoline quinone in the active center. The enzymatic activity of nitrile hydratase is strongly inhibited by typical carbonyl reagents such as phenylhydrazine and semicarbazide. Of special interest is the fact that these carbonyl reagents induced significant alteration of the ESR features of the native iron(III) enzyme at pH 7.2. In addition, the isobutyronitrile(inhibitor)-bound enzyme was also remarkably affected by phenylhydrazine and then the transformed ESR characteristics were different from those of phenylhydrazine-treated enzyme. The present results reveal the first evidence for an important interaction between the low-spin Fe(III) site and pyrroloquinoline quinone which is essential for the activity of nitrile hydratase.     

Ferritin iron uptake and release. Structure–function relationships

Iron uptake and release by ferritin molecules of different iron contents show similar profiles. These are discussed in relation to the structure of the ferritin molecule. Two models of iron uptake and release are considered. One involves iron oxidation–reduction sites on the protein. The other allows direct interaction of reagents with the iron-core crystallites. It is concluded that the second model accounts better for the experimental results presented now and in previous publications.     

Myeloperoxidase of the leukocyte of normal blood. Nature of the prosthetic group of myeloperoxidase

The absorption spectra of alkaline pyridine hemochrome of myeloperoxidase in its native, acid, and modified forms were similar to those of heme a, and the molar extinction coefficient of myeloperoxidase heme was very similar to that of heme a, assuming that myeloperoxidase contains only one heme. The anaerobic titration of myeloperoxidase with dithionite showed that one electron was consumed per molecule of the enzyme for its conversion to its reduced form. The EPR spectrum of myeloperoxidase indicated that the enzyme contains both high-spin heme and non-heme iron. Carbonyl reagents, such as borohydride, hydrazine, and benzhydrazide, reacted with myeloperoxidase, causing blue shifts in its absorption spectrum. The heme was labeled with a tritium of boro[3H]hydride, suggesting that the reagents reacted with a formyl group on the porphyrin ring of the myeloperoxidase heme. When hydrazine was added to cyanide complex I of myeloperoxidase the complex was converted to the hydrazine-enzyme compound. Myeloperoxidase reacted with bisulfite to form a compound with an absorption spectrum similar to that of cyanide complex I. Borohydride-treated myeloperoxidase formed only one cyanide complex, while the native enzyme formed two different cyanide complexes, I (Kd = 0.3 muM) and II (approximate Kd = 0.1 mM). The EPR spectrum indicated that cyanide complex I of myeloperoxidase still contained high-spin heme. The results suggested that cyanide complex I and the bisulfite compound of myeloperoxidase were adducts between the nucleophilic reagents and the formyl group of myeloperoxidase heme. Based on these results, we concluded that one of the two iron atoms in a myeloperoxidase molecule exists in a formyl-heme moiety similar to heme a and the other exists as a non-heme iron.     

Study of a Fenton type reaction: effect of captopril and chelating reagents.

The purpose of this study was to determine if captopril, an angiotensin-converting enzyme inhibitor, could interact with iron ions and so modify a Fenton type reaction. Results indicate that different degrees of thiobarbituric acid-reactive substance from deoxyribose are obtained in an ascorbate-driven Fenton system depending on the order of addition of captopril and iron to the incubation medium. Similar results were obtained with the chelating reagents ethylenediaminetetraacetic acid and diethylenetriaminepentaacetic acid, indicating that the buffer solution plays a relevant role when a particular iron complex is formed with a chelating agent. These metal complexes produce oxidizing species in a Fenton type system whose nature is discussed.     

Differential sensitivities of the subunits of mammalian ribonucleotide reductase to proteases, sulfhydryl reagents, and heat

Ribonucleotide reductase catalyzes the rate-limiting step in the formation of 2'-deoxyribonucleoside 5'-triphosphates. It consists of two nonidentical protein subunits, the nonheme iron subunit, and the effector-binding subunit. It has previously been shown that these two components making up the active enzyme species are not coordinately synthesized or degraded. It was found that the effector-binding subunit was more sensitive to proteolysis by chymotrypsin, to heating at 55 degrees C, and to the sulfhydryl reagents, pCMB and NEM. The nonheme iron subunit was more sensitive to trypsin treatment. ATP and dATP protected the effector-binding subunit from proteolytic inactivation. Neither ATP nor CDP protected the effector-binding subunit from inactivation by the sulfhydryl reagents. These data indicate that the protein properties of the two subunits of mammalian ribonucleotide reductase are significantly different.     

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.     

Transferrin endocytosis and iron uptake in developing myogenic cells in culture: effects of microtubular and metabolic inhibitors, sulphydryl reagents and lysosomotrophic agents

The experiments described in this study were designed to investigate receptor-mediated endocytosis of transferrin and its role in iron uptake by cultured chick presumptive myoblasts (dividing and non-dividing) and myotubes. The effects of a variety of inhibitors on the internalization of transferrin and iron were investigated and three main effects were found: (i) sulphydryl reagents and microtubular inhibitors reduced the rate of transferrin and iron internalization to similar degrees, (ii) metabolic inhibitors reduced the rate of iron uptake more than that of transferrin endocytosis, and (iii) lysosomotrophic agents almost completely abolished iron accumulation by the cells without any effect on the rate of transferrin internalization. The results suggest that metabolic energy is required not only for the endocytosis of transferrin but also for subsequent steps in the iron uptake process, and that iron release from transferrin occurs in acidified endosomes. Overall, these experiments show that all or virtually all of the iron taken up by developing muscle cells from transferrin occurs as a consequence of receptor-mediated endocytosis of the protein.     

Characterization of horse spleen apoferritin reactive lysines by MALDI-TOF mass spectrometry combined with enzymatic digestion

Ferritins are a class of iron storage protein spheres found mainly in the liver and spleen, which have attracted many research interests due to their unique structural features and biological properties. Recently, ferritin and apoferritin (ferritin devoid of the iron core), have been employed as chemically addressable nanoscale building blocks for functional materials development. However, the reactive residues of apoferritin or ferritin have never been specified and it is still unclear about the chemoselectivity of apoferritin towards different kinds of bioconjugation reagents. In this work, matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry combined with enzymatic digestion analysis was used to identify the reactive lysine residues of horse spleen apoferritin when conjugated with N-hydroxysuccinimide reagents. The result demonstrated that among all the lysine residues, K97, K83, K104, K67 and K143 are the reactive ones that can be addressed.     

Reconstitution of the diiron sites in hemerythrin and myohemerythrin

The first reconstitutions of functional diiron sites in the nonheme O2-carrying proteins hemerythrin (Hr) and myohemerythrin (myoHr) have been achieved. Both proteins are reconstituted under anaerobic conditions, and the procedure consists of (i) denaturation of the native met form with 6 M guanidinium chloride in the presence of sodium dithionite and 2,2'-dipyridyl, (ii) separation of the apoprotein from the other reagents and products, (iii) addition of an iron(II) stock solution to the apoprotein in the presence of 2-mercaptoethanol, and (iv) several cycles of slow dilution and reconcentration by ultrafiltration to remove excess reagents. Iron analyses indicate that the apoproteins have been essentially completely freed of iron and that reconstituted Hr contains its full complement of iron, i.e., approximately 2 Fe/subunit. Ferrous rather than ferric iron appears to be necessary for recovery of the native structures for both myoHr and Hr. In the case of Hr, reconstitution was successful only when iron(II) was added to apoHr prior to removal of denaturant. ApoHr is essentially insoluble at pH 7 in the absence of denaturants but remains soluble when denaturant is removed in the presence of ferrous iron, which leads to recovery of the octameric structure containing all of its diiron sites. Iron(II) apparently stabilizes the native or a nearly native structure during reconstitution. OxymyoHr and oxyHr are the major initial products of reconstitution. The yield of oxymyoHr from apomyoHr was approximately 87%. In contrast to reconstituted oxymyoHr, where essentially all of the iron appears to be functional, approximately 30% of the diiron sites in the reconstituted oxyHr are unable to bind O2 at ambient p(O2).(ABSTRACT TRUNCATED AT 250 WORDS)     

Ascorbate Oxidation: UV Absorbance of Ascorbate and ESR Spectroscopy of the Ascorbyl Radical as Assays for Iron

Catalytic transition metals are an absolute requirement for the aerobic oxidation of ascorbate monoanion. Thus, for example. the concentration of iron can be determined by the metal-dependent rate of ascorbate oxidation in near-neutral solutions. The lower limit of detection of iron, as Fe(III)EDTA. by monitoring the decrease in absorbance at 265 nm of ascorbate is about 200 nM. However, by measuring the concentration of the ascorbyl radical by ESR spectroscopy the lower limit is about 10nM.

Using these assays, I have shown that the typical microliter laboratory syringe can introduce significant iron into solutions. Thus. for studies involving iron, these two tests can be used to determine the amount of contaminating iron in reagents as well as iron from other sources such as laboratory equipment.     

Short communication: Adverse effect of surface-active reagents on the bioleaching of pyrite and chalcopyrite by Thiobacillus ferrooxidans

Oxidation of Fe(II) iron and bioleaching of pyrite and chalcopyrite by Thiobacillus ferrooxidans was adversely affected by isopropylxanthate, a flotation agent, and by LIX 984, a solvent-extraction agent, each at 1 g/l. The reagents/l were adsorbed on the bacterial surface, decreasing the bacteria's development and preventing biooxidation. Both reagents inhibited the bioleaching of pyrite and LIX 984 also inhibited the bioleaching of chalcopyrite.     

Ascorbate Oxidation: UV Absorbance of Ascorbate and ESR Spectroscopy of the Ascorbyl Radical as Assays for Iron

Catalytic transition metals are an absolute requirement for the aerobic oxidation of ascorbate monoanion. Thus, for example. the concentration of iron can be determined by the metal-dependent rate of ascorbate oxidation in near-neutral solutions. The lower limit of detection of iron, as Fe(III)EDTA. by monitoring the decrease in absorbance at 265 nm of ascorbate is about 200 nM. However, by measuring the concentration of the ascorbyl radical by ESR spectroscopy the lower limit is about 10nM.

Using these assays, I have shown that the typical microliter laboratory syringe can introduce significant iron into solutions. Thus. for studies involving iron, these two tests can be used to determine the amount of contaminating iron in reagents as well as iron from other sources such as laboratory equipment.     

A possible iron delivery function of the dinuclear iron center of HcgD in [Fe]-hydrogenase cofactor biosynthesis

HcgD, a homolog of the ubiquitous Nif3-like protein family, is found in a gene cluster involved in the biosynthesis of the iron-guanylylpyridinol (FeGP) cofactor of [Fe]-hydrogenase. The presented crystal structure and biochemical analyses indicated that HcgD has a dinuclear iron-center, which provides a pronounced binding site for anionic ligands. HcgD contains a stronger and a weaker bound iron; the latter being removable by chelating reagents preferentially in the oxidized state. Therefore, we propose HcgD as an iron chaperone in FeGP cofactor biosynthesis, which might also stimulate investigations on the functionally unknown but physiologically important eukaryotic Nif3-like protein family members.     

Mixed ligand complexes of iron with cyanide and phenanthroline as new probes of metalloprotein electron transfer reactivity. Analysis of reactions involving rusticyanin from Thiobacillus ferrooxidans

A family of 12 different mixed ligand complexes of iron with cyanide and substituted 1,10-phenanthroline was prepared. The electron transfer properties of each reagent were systematically manipulated by varying the substituent(s) on the aromatic ring system and the stoichiometry of the two types of ligands in the complex. Values for the standard reduction potentials of each member of this family of electron transfer reagents were determined and spanned from 500 to 900 mV. The one-electron transfer reactions between each of these substitution-inert reagents and the high potential blue copper protein, rusticyanin, from Thiobacillus ferrooxidans were studied by stopped flow spectrophotometry under acidic conditions. For comparison with the protein results, the kinetics of electron transfer between each of these reagents and sulfatoiron were also investigated. The Marcus theory of electron transfer was successfully applied to this set of kinetic data to demonstrate that 10 of the 12 reagents had equal kinetic access to the redox center of the rusticyanin and utilized the same reaction pathway for electron transfer. The utility of these synthetic electron transfer reagents in characterizing the electron transfer properties of very high potential, redox-active metalloproteins is illustrated.     

A specific stain for the detection of nonheme iron proteins in polyacrylamide gels.

Nonheme iron proteins can be visualized as blue bands in native polyacrylamide gels using a staining method that is both simple and rapid. The reaction of potassium ferricyanide with protein-bound iron atoms to form royal blue complexes occurs almost instantaneously and is sensitive enough to detect 1 microgram of analytical-grade ferritin and 2 micrograms of purified ferredoxin from cyanobacteria. No special treatment of reagents or apparatus was necessary. On comparison, this stain was found to be more specific than the Ferene S stain, not detecting bovine serum albumin even when present as a hundredfold excess over ferritin. The method was found to be effective for isoelectric focusing gels as well.     

Radial (tetracyclopentadienyl)cyclobutadiene pentametals

Radial (tetracyclopentadienyl)cyclobutadiene pentametals have been synthesized by the Pd-catalyzed coupling of cyclopentadienyltin or of (CpM)zinc reagents with (tetraiodocyclobutadiene)iron(tricabonyl). X-ray structural and NMR data reveal that, while these arrays are crowded, the substituents enjoy considerable rotational freedom.The method constitutes a significant complement to currently existing strategies for the construction of persubstituted cyclobutadiene complexes.