STIMULATORY AND INHIBITORY EFFECTS OF IRON ON PHOTODYNAMIC INACTIVATION OF LEUKEMIA CELLS

The influence of exogenous iron on merocyanine 540 (MC540))sensitized photoinactivation of leukemia cells has been investigated. Irradiation of murine L1210 or human HL-60 cells (-lOh/mL in 1 % serumiRPM1 medium) with broadband visible light in the presence of MC540 (2 pIM) resulted in a progressive loss of clonally assessed cell viability. When added to cells 30 min before irradiation, the low polarity chelate, ferric 8-hydroxyquinoline [Fe(HQ), 0.5 *MI stimulated dye-sensitized pho- tokilling, whereas high polarity chelates such as ferric 8-hydroxyquinoline-5-sulfonate [Fe(HQS)2, 0.5 p M] or ferric ethylenediaminetetraacetate (Fe.EDTA, 0.5 FM) had no effect. A striking reversal of Fe(HQ),-enhanced photokilling was observed upon increasing the preirradiation incubation time with Fe(HQ)2 such that a marked resistance (relative to non-iron-treated controls) was evident after 24 h. Cells exposed for 24 h to Fe(HQS), or Fe.EDTA showed similar or even greater resistance to photo-killing. Like phototoxicity, H,O,-induced cytotoxicity was enhanced after a 30 min exposure of cells to Fe(HQ)2 but strongly repressed after 24 h. Immunoblot (western) analysis, using a polyclonal antibody to ferritin, revealed that cells exposed to Fe(HQ): for 24 h contained at least 12 times as much ferritin heavy chain as non-Fe(HQ)?-treated controls. Preincubating cells with emetine, an inhibitor of protein synthesis, prevented both ferritin induction and the development of hyperresistance. These findings, along with the observation that exogenous apoferritin protected LI 2 10 cells against photokilling, suggest a possible role for ferritin in iron-stimulated photoresistance. It is conceivable that in photodynamic treatment of tumors, certain cells might resist inactivation via this mechanism, a possibility that has not been recognized heretofore.     

Protoporphyrin IX-sensitized photoinactivation of 5-aminolevulinate-treated leukemia cells: effects of exogenous iron

Photodynamic therapy with 5-aminolevulinic acid (ALA) is based on metabolism of ALA to a photosensitizing agent, protoporphyrin IX (PpIX), in tumor cells. Photosensitivity of target cells may be influenced by mitochondrial iron levels because ferrochelatase-catalyzed insertion of Fe2+ into PpIX converts it to heme, a nonsensitizer. To investigate this prospect, we exposed L1210 cells (approximately 10(6)/mL in 1% serum-containing medium) to a lipophilic iron chelate, ferric-8-hydroxyquinoline (Fe[HQ]2, 0.5 microM), prior to treating with ALA (0.2 mM, 4 h) and irradiating with broadband visible light. When Fe(HQ)2 was added to cells immediately or 1 h before ALA, the initial rate of photokilling, as measured by thiazolyl blue (mitochondrial dehydrogenase) assay, was markedly less than that of non-iron controls. The HPLC analysis of cell extracts indicated that ALA-induced PpIX was at least 50% lower after this Fe(HQ)2 treatment, presumably explaining the drop in photolethality. By contrast, cells treated with ALA and light 20 h after being exposed to Fe(HQ)2 contained the same amount of PpIX as non-iron controls and were photoinactivated at nearly the same rate. The 20 h delayed cells contained approximately 12 times more immunodetectable ferritin heavy subunit than controls or 1 h counterparts, which could account for the disappearance of iron's antisensitization effects in the former. Consistent with this idea, the short-term effects of Fe(HQ)2 on ALA-induced sensitization were found to be blunted significantly in ferritin-enriched cells. The Fe(HQ)2 produced strikingly different results when cells were sensitized with exogenous PpIX, stimulating photokilling after short-term contact but inhibiting it after long-term contact while having no significant effect on the level of cell-associated PpIX in either case. Thus, iron can have diverse effects on PpIX-mediated photokilling, depending on contact time with cells and whether the porphyrin is metabolically derived or applied as such.     

Mechanochemical reactions of fluorides with hemin

Hemin has two potential sites to react with fluorides, the peripheral acid groups and the central Fe^III cation. The mechanochemical reactions of hemin with fluorides (LiF, NaF, KF, CsF, NH₄F and AgF) were monitored using X-ray diffraction (XRD), and IR and Mössbauer spectroscopies. LiF and NaF were found inert when milled with hemin, however KF, CsF, NH₄F and AgF react at both hemin sites. At the iron site Cl⁻ is replaced by F⁻ with formation of KCl, CsCl, NH₄Cl, and AgCl, as detected by XRD, while with the peripheral acid groups, fluorides collect the acidic protons to form KHF₂, CsHF₂, NH₄HF and AgHF₂. The reactions of hemin with the reactive fluorides take place first at the iron site and then at the propionic acid groups.     

Iron release from ferritin induced by light and ionizing radiation

The reductive release of iron from ferritin by UV light or ionizing radiation has been investigated in separate experiments. When ferritin is exposed to light, the mineral core is the main photoreceptor for the Fe(III) reduction. In radiolytic studies, we determined that, in the absence of oxygen, the hydrated electron (e_aq⁻) is the reducing agent triggering redox reactions associated with iron mobilization from ferritin. In an aerobic system, the superoxide radical anion (O₂^•−) is also involved in the iron release process. We found that, in photochemical and radiolytical studies, Fe(II) mobilization from ferritin required an iron chelator. Without a chelator, ferritin is an electron-storage molecule for a long period, on the order of at least several hours. The reductant or chelator entry into the ferritin core is not necessary for iron release. The ferrozine is a convenient chelating agent to monitor Fe(II) mobilization, due to a high extinction coefficient of \textFe ( \textferrozine )₃^{4 -} {\text{Fe}}\,\left( {\text{ferrozine}} \right)_{3}^{4 - } and a high rate constant of complexation process (2.65 × 10⁴ dm³ mol⁻¹ s⁻¹).     

Determination of Hemin using a Parallel Catalytic Reduction Wave of its Protoporphyrin IX Ring

Abstract

Hemin, iron (III) protoporphyrin IX chloride, in NH₃‐NH₄Cl buffer solution of pH 9.5 produces an insensitive reduction wave at about ?0.70 V (vs. saturated calomel reference electrode, SCE) by using single sweep polarography. Adding oxidant K₂S₂O₈ to the solution, hemin reduction wave is catalyzed, yielding a parallel catalytic wave. The catalytic current is 20 times of hemin original reduction current. The derivative peak height is linearly proportional to the hemin concentration in the range of 7.5×10^?8 to 4.5×10^?6 mol/l, the detection limit is 5.0×10^?8 mol/l. Serum albumin, common amino acids, and metal ions have no interference with the hemin determination. The proposed method has been applied to the determination of hemin content in oral liquid samples with satisfactory results. The parallel catalytic wave is attributed to the catalytic reduction of porphyrin ring of hemin at the dropping mercury electrode. The new method could be useful in biochemical, clinical, and pharmaceutical analysis.     

SIMILARITIES IN THE INDUCTION OF SYNTHESIS OF A CELL-SURFACE POLYPEPTIDE IN Arthrobacter sp. BY NEAR-UV IRRADIATION and PHOTODYNAMIC CONDITIONS

Irradiation of aerobic suspensions of Arthrobacter sp. with near-UV light (310-400 nm) induced synthesis of a 21 000 dalton, cell-surface polypeptide. Synthesis of this polypeptide also was induced by visible light in the presence of photodynamic dyes, as shown previously (Hoober, 1978). Induction of the polypeptide in near-UV light and with visible light plus dyes was inhibited by histidine. Hemin inhibited induction in near-UV light and in visible light with methylene blue, neutral red and acrifiavin, which are cationic dyes, but failed to inhibit induction in visible light with rose bengal, an anionic dye. These results suggested that inhibition by hemin required electrostatically favored interaction between the anionic porphyrin and the sensitizer, and that the near-UV light effect was mediated by a cationic or neutral endogenous sensitizer. The similarities in the responses of the cells to near-UV irradiation and visible light plus dyes suggested that the mechanism of induction under the two conditions was the same.     

Photokilling Squamous Carcinoma Cells SCCVII with Ultrafine Particles of Selected Metal Oxides

The ability of ultrafine particles of TiO₂, WO₃ and iron-doped TiO₂ to kill cancer cells in the presence of UV irradiation was investigated. The best photokilling effect on carcinoma cells SCVII cultured in vitro showed iron-doped TiO₂ ultrafine particles synthesized by the sol-gel procedure with starting chemicals Ti(IV)-isopropoxide and anhydrous Fe(II)-acetate. It was found that a small particle size and high dispersity influenced citotoxicity and photocatalytic efficiency. The remarkable photokiling effect of highly iron-doped TiO₂ ultrafine particles (the molar ratio Fe/Ti = 0.136) in the presence of UV irradiation was observed. The influence of ultrafine metal oxide particles on the inhibition of cancer cell proliferation was measured using a ³H-thymidine incorporation test. The possible mechanism involved in the photokilling of carcinoma cells with ultrafine particles of selected metal oxides was discussed.     

Biosynthesis, isolation and characterization of 57Fe-enriched Phaseolus vulgaris ferritin after heterologous expression in Escherichia coli

Ferritin is the major iron storage protein in the biosphere. Iron stores of an organism are commonly assessed by measuring the concentration of the protein shell of the molecule in fluids and tissues. The amount of ferritin-bound iron, the more desirable information, still remains inaccessible owing to the lack of suitable techniques. Iron saturation of ferritin is highly variable, with a maximum capacity of 4,500 iron atoms per molecule. This study describes the direct isotopic labeling of a complex metalloprotein in vivo by biosynthesis, in order to measure ferritin-bound iron by isotope dilution mass spectrometry. [⁵⁷Fe]ferritin was produced by cloning and overexpressing the Phaseolus vulgaris ferritin gene pfe in Escherichia coli in the presence of ⁵⁷FeCl₂. Recombinant ferritin was purified in a fully assembled form and contained approximately 1,000 iron atoms per molecule at an isotopic enrichment of more than 95% ⁵⁷Fe. We did not find any evidence of species conversion of the isotopic label for at least 5 months of storage at −20 °C. Transfer efficiency of enriched iron into [⁵⁷Fe]ferritin of 20% was sufficient to be economically feasible. Negligible amounts of non-ferritin-bound iron in the purified [⁵⁷Fe]ferritin solution allows for use of this spike for quantification of ferritin-bound iron by isotope dilution mass spectrometry.     

Hemin-adsorbed carbon felt for sensitive and rapid flow-amperometric detection of dissolved oxygen

Hemin was physically adsorbed onto porous carbon felt (CF), a microelectrode ensemble of micro-carbon fiber (ca. 7 μm in diameter) and possessing a three-dimensional random structure. The hemin-CF exhibited a well-defined redox wave that is due to Fe(III)/Fe(II) redox process in hemin, with a formal potential of ?0.32 V (vs. Ag/AgCl) in deoxygenated buffer solution of pH 7.0. The surface coverage of the electroactive hemin molecules on the surface of the CF was calculated to be 5.0?×?10^?11 mol cm^?2, and the apparent heterogeneous electron transfer rate constant is 3.35 s^?1. The hemin-CF electrode displays excellent electrocatalytic activity for the reduction of dissolved oxygen (DO), and the magnitude of the cathodic current increases with increasing concentrations of DO in the sample solution. The electrode was used as a flow-through detector for sensitive and rapid consecutive determination of DO. Deoxygenated pH 7.0 solutions were analyzed at a flow rate of 8.0 mL min^?1 at an applied potential of ?0.2 V, and highly reproducible cathodic peak current responses to DO were observed in the 0.72 to 13.3 mg L^?1 concentration range. The maximum throughput is 170 samples h^?1. The hemin-CF-based amperometric flow-sensor was applied to determine the concentration of DO in environmental water samples.

Hemin as a General Static Dark Quencher for Constructing Heme Oxygenase-1 Fluorescent Probes

The development of small-molecule probes suitable for live-cell applications remains challenging yet highly desirable. We report the first fluorescent probe, RBH, for imaging the heme oxygenase-1 (HO-1) activity in live cells after discovering hemin as a universal dark quencher. Hemin works via a static quenching mechanism and shows high quenching efficiency (>97 %) with fluorophores across a broad spectrum (λ_ex=400–700 nm). The favorable properties of RBH (e.g. long excitation/emission wavelengths, fast response rate and high magnitude of signal increase) enable its use for determining HO-1 activity in complex biological samples. As HO-1 is involved in regulating antioxidant defence, iron homeostasis and gasotransmitter carbon monoxide production, we expect RBH to be a powerful tool for dissecting its functions. Also, the discovery of hemin as a general static dark quencher provides a straightforward strategy for constructing novel fluorescent probes for diverse biological species.     

Kinetics of oxidation of hydrogen peroxide at hemin-modified electrodes in nonaqueous solvents

Hemin adsorbed on graphite electrodes and used to catalyse the reduction of hydrogen peroxide in an aqueous buffer and in a range of nonaqueous solvents has been described. The immobilised hemin is stable in the solvents examined. The rate limiting step involves the reaction between hemin and hydrogen peroxide. Kinetic analysis of the response in nonaqueous solvents showed that I_max / K_m^app increased linearly with the solvent hydrophobicity (log P) in all solvents, a trend that is explained by preferable partitioning of hydrogen peroxide into the polar hemin layer.     

Direct electrochemical reduction of hemin in imidazolium-based ionic liquids

The direct electrochemical reduction of hemin, protoporphyrin(IX) iron(III) chloride, ligated with strong or weak heterocyclic bases, was investigated in the ionic liquids (IL), 1-butyl-3-methylimidazolium hexafluorophosphate ([bmim][PF₆]) and 1-octyl-3-methylimidazolium hexafluorophosphate ([omim][PF₆]), using cyclic voltammetry and chronocoulometry. Hemin complexed with N-methylimidazole (NMI) or with pyridine had E_1/2 values slightly (4–59 mV) more positive in IL (without electrolyte) than in methanol (1.0 M electrolyte) using a gold electrode. NMI-ligated hemin had a lower E_1/2 than pyridine-ligated hemin in either IL, consistent with the stronger electron donor characteristic of NMI. [Bmim][PF₆] solutions consistently yielded E_1/2 values 30 mV more negative than [omim][PF₆] solutions. The diffusion coefficients D_o of hemin in the IL ranged between 1.50 and 2.80×10⁻⁷ cm² s⁻¹, while the heterogeneous electron-transfer rate constants k_s ranged between 3.7 and 14.3×10⁻³ cm s⁻¹. Cyclic voltammetry of hemin adsorbed to a gold surface through 4,4′-bispyridyl disulfide (AT4) linkages showed a large positive shift in the oxidation wave, indicating that adsorption stabilizes the reduced hemin state. The surface concentration Γ_o of the adsorbed hemin was determined to be 1.21×10⁻¹⁰ mol cm⁻², indicating the presence of one or more complete monolayers of hemin. These findings suggest that while hemin is electrochemically active in IL, its behavior is modified by the ligand field strength and surface adsorption phenomena.     

Artesunate interaction with hemin

Artesunate is an important new antimalarial drug. The interaction of artesunate with hemin was investigated by electrochemical methods and UV spectroelectrochemistry (UV-SEC). Artesunate underwent an entirely irreversible reduction at ca. −1.27 V (vs. Ag/AgCl) on the glassy carbon electrode. Hemin can catalyze the decomposition of artesunate. In the presence of concentration of hemin as low as 2×10⁻⁸ M, the cathodic overpotential of artesunate was reduced ca. 680 mV (E_pc=−0.59 V vs. Ag/AgCl). UV-SEC experiments further confirm this process. UV spectra show that the decomposed products of artesunate have absorption behavior similar to artesunate. These results indicated that artesunate might undergo the identical antimalarial mechanism as its parent compound Qinghaosu, and hemin plays a catalyst role in the process of action of Qinghaosu-type antimalarial drugs.     

Nanophase iron phosphate, iron arsenate, iron vanadate, and iron molybdate minerals synthesized within the protein cage of ferritin

Nanoparticles of iron phosphate, iron arsenate, iron molybdate, and iron vanadate were synthesized within the 8 nm interior of ferritin. The synthesis involved reacting Fe(II) with ferritin in a buffered solution at pH 7.4 in the presence of phosphate, arsenate, vanadate, or molybdate. O2 was used as the oxidant to deposit the Fe(III) mineral inside ferritin. The rate of iron incorporation into ferritin was stimulated when oxo-anions were present. The simultaneous deposition of both iron and the oxo-anion was confirmed by elemental analysis and energy-dispersive X-ray analysis. The ferritin samples containing iron and one of the oxo-anions possessed different UV/vis spectra depending on the anion used during mineral formation. TEM analysis showed mineral cores with approximately 8 nm mineral particles consistent with the formation of mineral phases inside ferritin.     

DNA sensing on glassy carbon electrodes by using hemin as the electrochemical hybridization label

The electrochemical behavior of hemin, an iron complex of porphyrin, on binding to DNA at a glassy carbon electrode (GCE) and in solution, is described. Hemin, which interacts with covalently immobilized calf thymus DNA, was detected by use of a bare GCE, a double-stranded DNA-modified GCE (dsDNA-modified GCE), and a single-stranded DNA-modified GCE (ssDNA-modified GCE), in combination with differential pulse voltammetry (DPV). The structural conformation of DNA was determined from changes in the voltammetric signals acquired on reduction of hemin. As a result of its large steric structure and anionic substitution on its porphyrin plane, hemin intercalates between the base pairs of dsDNA. A scan-rate study for hemin and the dsDNA-hemin complex were also performed to determine the electrochemical behavior of the complex. The partition coefficient was obtained from the peak currents measured when different concentrations of hemin were in the presence of dsDNA. By observing the oxidation signals of guanine, damage to DNA after reaction with hemin at the GCE surface was also detected. The electrochemical detection of hybridization between the covalently immobilized probe and its target sequence was detected by use of hemin. These results demonstrate the use of DNA biosensors in conjunction with hemin for electrochemical detection of hybridization and damage to DNA.     

Determination of iron and titanium in kaolins by the method of non-dispersive X-ray fluorescence

The possibility of application of the radioactive source excited X-ray fluorescence analysis for titanium and iron determination in kaolins to the routine test of the refinement process has been studied. The iron content can be determined with a simple counting system using a single-channel pulse height analyser, argon filled proportional counter and¹⁰⁹Cd source of 3 mCi for the excitation of K Fe rays. The samples were analysed both as pellets and powders. The iron content ranged from 0.2–2.5% and titanium from 0.1–0.64%. For simultaneous determination of titanium and iron a Si(Li) spectrometer has been used. The²³⁸Pu source has been used for K Fe and K Ti excitation. It is the most convenient source for simultaneous determination of titanium and iron.⁵⁵Fe is the most efficient source for the determination of titanium alone. The best values of precision and determination limit have been achieved for iron with²³⁸Pu and for titanium with⁵⁵Fe.     

Extraction and preconcentration of hemin from human blood serum and breast cancer supernatant

A green, facile, fast, and sensitive liquid‐phase microextraction method is presented for the extraction and preconcentration of hemin in the presence of free iron ions prior to flame atomic absorption spectroscopic determination. In this technique, an anion‐functionalized task‐specific ionic liquid is used as the extracting solvent. The interface between the extracting solvent and the bulk aqueous phase containing hemin is enormously enlarged by dispersing the ionic liquid to the aqueous phase with the help of ultrasound radiation. Hemin is selectively extracted into the ionic liquid after interaction with the functional group of the ionic liquid. Then, the concentration of the extracted hemin is determined through the absorbance of the iron ions contained in the hemin structure using flame atomic absorption spectroscopy. Different experimental parameters affecting the extraction efficiency have been optimized. Under the optimized conditions, the proposed method has a hemin concentration linear range of 0.020–0.80 mg/L with a detection limit of 0.0080 mg/L. This method has been successfully applied to the extraction and determination of hemin in human serum and supernatant samples.     

Electrochemical determination of dioxygen and hydrogen peroxide using Fe3O4@SiO2@hemin microparticles

Iron oxide microparticles were coated with 3-aminopropyltriethoxysilane and then coated with hemin via an amidation reaction. The resulting composite particles were characterized by transmission electron microscopy. FTIR spectroscopy revealed two bands (at 1,701 and 1,634 cm^?1), which were assigned to the carboxy group and the amide linkage, respectively, resulting from the linkage between hemin and the amino-modified Fe₃O₄ particles. In addition, strong Fe-O vibrations can be observed at 563 cm^?1. An electrode was modified with these microparticles and then showed a well-defined redox behavior of the immobilized hemin, with a fast heterogeneous electron transfer process (14.5 s^?1). The electrode is capable of sensing both O₂ and H₂O₂ and displays a wide linear range, high sensitivity, and fast response. The composites reported here also may serve as a support for the immobilization of proteins, which paves the way to potential applications in novel biosensors and bioelectronic devices.

The effect of UVB irradiation on ferritin subunit synthesis,ferritin assembly and Fe metabolism in cultured canine lens epithelial cells

Ferritin is a multimeric protein consisting of heavy and light chains assembled in different tissue-specific ratios, which can protect cells from oxidative stress by storing reactive iron (Fe). Because the lens is constantly exposed to UV irradiation, we studied its effects on ferritin synthesis and Fe metabolism in cultured lens epithelial cells with and without ascorbic acid (Asc). UVB caused a large increase in accumulation of newly synthesized ferritin chains; this increase was additive to that induced by Asc. In contrast to the Asc-induced increase in Fe storage, Fe storage in ferritin was unaltered by UVB. Although UVB increased accumulation of newly synthesized ferritin chains, total ferritin levels were unaltered. In contrast, Asc, which induced a quantitatively similar increase in accumulation of newly synthesized ferritin chains, doubled the total amount of ferritin. Because UVB did not change Fe storage in ferritin or the size of the labile Fe pool, it was hypothesized and then determined that these newly synthesized chains did not assemble into functional holoferritin. Numerous studies detail the effects of various treatments on de novo ferritin synthesis; however, this study provides a cautionary note regarding the conclusions of such studies in the absence of data indicating assembly of functional ferritin molecules.