Assembly system of direct modified superparamagnetic iron oxide nanoparticles for target-specific MRI contrast agents

We report the direct modification of SPIOs with a biomolecule and the target-specific assembly system of these modified SPIOs for using MRI contrast agents. The transverse relaxation rate of the aqueous solutions containing the modified SPIOs was altered by the dispersion state.     

Nitric oxide mediates iron release from ferritin

Nitric oxide (NO) synthesis by cytotoxic activated macrophages has been postulated to result in a progressive loss of iron from tumor target cells as well as inhibition of mitochondrial respiration and DNA synthesis. In the present study, the addition of an NO-generating agent, sodium nitroprusside, to the iron storage protein ferritin resulted in the release of iron from ferritin and the released iron-catalyzed lipid peroxidation. Hemoglobin, which binds NO, and superoxide anion, which reacts with NO, inhibited nitroprusside-dependent iron release from ferritin, thereby providing evidence that NO can mobilize iron from ferritin. These results suggest that NO generation in vivo could lead to the mobilization of iron from ferritin disrupting intracellular iron homeostasis and increasing the level of reactive oxygen species.     

Mono- and binuclear non-heme iron chemistry from a theoretical perspective

In this minireview, we provide an account of the current state-of-the-art developments in the area of mono- and binuclear non-heme enzymes (NHFe and NHFe₂) and the smaller NHFe₍₂₎ synthetic models, mostly from a theoretical and computational perspective. The sheer complexity, and at the same time the beauty, of the NHFe₍₂₎ world represents a challenge for experimental as well as theoretical methods. We emphasize that the concerted progress on both theoretical and experimental side is a conditio sine qua non for future understanding, exploration and utilization of the NHFe₍₂₎ systems. After briefly discussing the current challenges and advances in the computational methodology, we review the recent spectroscopic and computational studies of NHFe₍₂₎ enzymatic and inorganic systems and highlight the correlations between various experimental data (spectroscopic, kinetic, thermodynamic, electrochemical) and computations. Throughout, we attempt to keep in mind the most fascinating and attractive phenomenon in the NHFe₍₂₎ chemistry, which is the fact that despite the strong oxidative power of many reactive intermediates, the NHFe₍₂₎ enzymes perform catalysis with high selectivity. We conclude with our personal viewpoint and hope that further developments in quantum chemistry and especially in the field of multireference wave function methods are needed to have a solid theoretical basis for the NHFe₍₂₎ studies, mostly by providing benchmarking and calibration of the computationally efficient and easy-to-use DFT methods.     

The chemistry of DNA damage from nitric oxide and peroxynitrite

Nitric oxide is a key participant in many physiological pathways; however, its reactivity gives it the potential to cause considerable damage to cells and tissues in its vicinity. Nitric oxide can react with DNA via multiple pathways. Once produced, subsequent conversion of nitric oxide to nitrous anhydride and/or peroxynitrite can lead to the nitrosative deamination of DNA bases such as guanine and cytosine. Complex oxidation chemistry can also occur causing DNA base and sugar oxidative modifications. This review describes the different mechanisms by which nitric oxide can damage DNA. First, the physiological significance of nitric oxide is discussed. Details of nitric oxide and peroxynitrite chemistry are then given. The final two sections outline the mechanisms underlying DNA damage induced by nitric oxide and peroxynitrite.     

Reactivity of ruthenium carbonyls on metal oxide surfaces: effects of the surface acid-base chemistry

The reactivity of tetraruthenium carbonyl clusters supported on metal oxides (SiO₂, TiO₂, γ-Al₂O₃, and MgO) under various atmospheres has been investigated by infrared and ultraviolet-visible spectroscopies and electron microscopy. [H₄Ru₄(CO)₁₂] physisorbed on SiO₂ easily decomposes and aggregates to form metal particles. The tetraruthenium clusters supported on TiO₂ are oxidized by surface hydroxyl groups, giving mononuclear complexes; virtually the same chemistry occurs, but less readily, on γ-Al₂O₃. The tetramthenium clusters supported on MgO, in contrast, are highly resistant to oxidation. The strong basicity of this support leads to an increased stability of small polynuclear complexes, hindering the formation of oxidized complexes and aggregated metallic structures. The unique character of the basic support appears to be related to the tendency of the support to form and stabilize cluster anions.     

Nitric oxide does not promote iron release from ferritin

It has been previously reported that iron release from ferritin could be promoted by nitric oxide (NO) generated from sodium nitroprusside. It was thus proposed that some of the toxic effects of NO could be related to its ability to increase intracellular free iron concentrations and generate an oxidative stress. On the contrary, the iron exchange experiments reported here show that NO from S-nitrosothiols is unable to promote iron release from ferritin. The discrepancy may be explained by the disregarded ability of ferrozine, the ferrous trap used in the previous report, to mobilize iron both from ferritin and from sodium nitroprusside spontaneously.     

Assembly of monomeric acetylcholinesterase into tetrameric and asymmetric forms

A pulse-chase experiment was performed in embryonic rat myotube cultures to examine possible precursor-product relationships among the various molecular forms of acetylcholinesterase (AChE). AChE was labeled with paraoxon, a compound which diethylphosphorylates AChE at its active site. Diethylphosphorylated (labeled) AChE is inactive but can be reactivated by treatment with 1-methyl-2-hydroxyiminomethyl-pyridinium. Thus labeled enzyme could be followed as AChE that regained activity following treatment with 1-methyl-2-hydroxyiminomethylpyridium. To selectively label monomeric AChE (the hypothesized precursor form), cultures were treated with methanesulfonylfluoride which irreversibly inactivated more than 97% of total cellular AChE. Methylsulfonylfluoride was then washed from the cultures, and they were labeled with paraoxon during a 40-55-min recovery period. AChE appearing in the cultures during this recovery period is newly synthesized and consists almost entirely (92%) of the monomeric form. Immediately and 120-130 min after labeling, cultures were subjected to a sequential extraction procedure to separate globular from asymmetric forms. Individual forms were then separated by velocity sedimentation on sucrose gradients. In our first series of experiments, we observed a 55% decrease in labeled monomers during the chase, a 36% increase in labeled tetramers, and a 36% increase in labeled asymmetric forms. In a second series of experiments focused on individual asymmetric forms, we observed a 55% decrease in labeled monomers, a 58% increase in labeled tetramers, an overall increase of 81% in labeled asymmetric forms, and a 380% increase in labeled A12 AChE. These data provide the first uniequivocal proof that complex forms of AChE are assembled from active monomeric precursors.     

Specific bonds between an iron oxide surface and outer membrane cytochromes MtrC and OmcA from Shewanella oneidensis MR-1

Shewanella oneidensis MR-1 is purported to express outer membrane cytochromes (e.g., MtrC and OmcA) that transfer electrons directly to Fe(III) in a mineral during anaerobic respiration. A prerequisite for this type of reaction would be the formation of a stable bond between a cytochrome and an iron oxide surface. Atomic force microscopy (AFM) was used to detect whether a specific bond forms between a hematite (Fe(2)O(3)) thin film, created with oxygen plasma-assisted molecular beam epitaxy, and recombinant MtrC or OmcA molecules coupled to gold substrates. Force spectra displayed a unique force signature indicative of a specific bond between each cytochrome and the hematite surface. The strength of the OmcA-hematite bond was approximately twice that of the MtrC-hematite bond, but direct binding to hematite was twice as favorable for MtrC. Reversible folding/unfolding reactions were observed for mechanically denatured MtrC molecules bound to hematite. The force measurements for the hematite-cytochrome pairs were compared to spectra collected for an iron oxide and S. oneidensis under anaerobic conditions. There is a strong correlation between the whole-cell and pure-protein force spectra, suggesting that the unique binding attributes of each cytochrome complement one another and allow both MtrC and OmcA to play a prominent role in the transfer of electrons to Fe(III) in minerals. Finally, by comparing the magnitudes of binding force for the whole-cell versus pure-protein data, we were able to estimate that a single bacterium of S. oneidensis (2 by 0.5 microm) expresses approximately 10(4) cytochromes on its outer surface.     

Lymph node localisation of biodegradable nanospheres surface modified with poloxamer and poloxamine block co-polymers

Studies were performed to develop a sub-100 nm biodegradable colloidal system for the efficient delivery of drugs and diagnostic agents to the lymphatic system. Nanospheres of poly(lactide-co-glycolide) were prepared by interfacial polymer deposition. The nanospheres were coated with block co-polymers in order to modify their surface characteristics. Radiolabelling of the nanospheres for in vivo tracing was achieved by the incorporation of the lipophilic complex ¹¹¹In-oxine during nanosphere preparation. In vitro stability of the radiolabelled nanospheres was determined in rat serum at 37°C. The lymphatic distribution of the nanospheres was determined after subcutaneous administration to the rat. Lymphatic uptake of all coated systems was enhanced compared to the uncoated nanospheres, and a maximal uptake of 17% of the administered dose in the regional lymph nodes was achieved. These observations suggest that the nanospheres are suitable for diagnostic and therapeutic applications in clinical and experimental medicine.     

Nitric oxide and iron: effect of iron overload on nitric oxide production in endotoxemia

The amount of iron within the cell is carefully regulated in order to provide an adequate level of micronutrient while preventing its accumulation and toxicity. Iron excess is believed to generate oxidative stress, understood as an increase in the steady-state concentration of oxygen radical intermediates. Nitric oxide (NO) is an inorganic free-radical gaseous molecule which has been shown over the last decade to play an unprecedented variety of roles in biological systems. The effect of nitrogen reactive species may explain the iron sequestration pattern that characterizes macrophages under inflammatory conditions. From a patho-physiological viewpoint, further studies are required to assess the usefulness of this mechanism to minimize formation and release of free radicals in diseased tissues. However, contrary to the deleterious effects of the reactive nitrogen oxide species formed from either NO/O(2) and NO/O(2)(-), it has been pointed out that NO shows antioxidant properties. A number of studies have described the complex relationships between iron and NO, but controversy remains as to the influence and significance of iron on inflammatory NO production. To explore the initial steps of the effects triggered by LPS administration in the presence of excess iron, male Wistar rats were treated with: lipopolysaccharide from Escherichia coli (serotype 0127:B8) (LPS); iron-dextran; or iron-dextran plus LPS and liver samples were taken after 6 h. EPR spectra of NO-Hb in the venous blood were determined at 77 K. Iron-dextran administered to rats intraperitoneally resulted predominantly in iron uptake by the liver Kupffer cells and led to an increased NO level in blood in the presence of LPS. Further studies will be required to assess the complex role of the Kupffer cells on iNOS induction and NO production.     

Nitroxidative chemistry interferes with fluorescent probe chemistry: Implications for nitric oxide detection using 2,3-diaminonaphthalene

Simultaneous production of nitric oxide (NO) and superoxide generates peroxynitrite and causes nitroxidative stress. The fluorometric method for NO detection is based on the formation of a fluorescent product from the reaction of a nonfluorescent probe molecule with NO-derived nitrosating species. Here, we present an example of how nitroxidative chemistry could interact with fluorescent probe chemistry. 2,3-Naphthotriazole (NAT) is the NO-derived fluorescent product of 2,3-diaminonaphthalene (DAN), a commonly used NO-detecting molecule. We show that NO/superoxide cogeneration, and particularly peroxynitrite, mediates the chemical decomposition of NAT. Moreover, the extent of NAT decomposition depends on the relative fluxes of NO and superoxide; the maximum effect being reached at almost equivalent generation rates for both radicals. The rate constant for the reaction of NAT with peroxynitrite was determined to be 2.2 × 10³ M⁻¹ s⁻¹. Further, various peroxynitrite scavengers were shown to effectively inhibit NO/superoxide- and peroxynitrite-mediated decomposition of NAT. Taken together, the present study suggests that the interference of a fluorometric NO assay can be originated from the interaction between the final fluorescent product and the formed reactive nitrogen and oxygen species.     

A model of Martian surface chemistry

Summary Alkaline earth and alkali metal superoxides and peroxides,-Fe₂O₃ and carbon suboxide polymer are proposed to be constituents of the Martian surface material. These reactive substances explain the water modified reactions and thermal behaviors of the Martian samples demonstrated by all of the Viking Biology Experiments. It is also proposed that the syntheses of these substances result mainly from electrical discharges between wind-mobilized particles at Martian pressures; plasmas are initiated and maintained by these discharges. Active species in the plasma either combine to form or react with inorganic surfaces to create the reactive constitutents.     

Release of iron ions from transferrin under the effect of nitric oxide

The dynamics of EPR signals from the iron-transporting blood protein Fe(3+)-transferrine after the administration of sodium nitrite and metronidazole to animals was studied. It was shown that exogenin nitric oxide produced by nitrocompounds resulted in the release of iron from Fe(3+)-transferrine.     

Solution chemistry and Mössbauer study of iron(II) and iron(III) complexes from gallocyanine

The iron solution chemistry of the FeCl₃-gallocyanine system has been investigated by pH titration, UV visible spectroscopy and Mössbauer spectroscopy. Iron reduction was found in the pH range 2–5 and photo-reduction of the iron(III) present was also noted. Due to the instability of the species present in solution, the use of gallocyanine as a spectrophotometric indicator in iron systems is not encouraged. The iron-gallocyanine system was proposed as a potential model of the photosensitive anti-cancer drug, Bleomycin.     

Electric-field controlled liposome formation with embedded superparamagnetic iron oxide nanoparticles

Liposomes are one of the most promising biomaterial carriers to deliver DNA,(1) proteins, drugs and medicine in human bodies. However, artificially formed liposomes have to satisfy some crucial functions such as: (i) to efficiently carry drugs to targeted systems, (ii) to be biologically stable until they are removed from human body, (iii) to be biodegradable, and (iv) to be sufficiently small in size for effective drug delivery. Here, we report an efficient and novel method to simultaneously manufacture and incorporate super-paramagnetic iron-oxide nanoparticles (efficient target finder in the presence of external magnetic field) into the liposome's interior and its bilayer. In this technique, we use electric field to control the formation of liposomes and the incorporation of iron oxide nanoparticles. Our preparation procedure does not require any chemical or ultrasound treatments. Apart from that, we also provide further experimental investigations on the role of electric fields on the formation of liposomes using XPS(2) and the magnetic-optical microscope.     

Reaction of neuronal nitric oxide synthase with the nitric oxide spin-trapping agent, iron complexed with N-dithiocarboxysarcosine.

A water-soluble iron complex with N-dithiocarboxysarcosine (Fe-DTCS) has been developed as an ESR spin-trapping agent for NO and successfully applied to ESR imaging of endogenous NO production in mice. We attempted to measure NO produced by purified neuronal NO synthase (nNOS) by this method, but could not detect NO. We speculated that Fe-DTCS inhibits NOS activity. In fact, it markedly inhibited NOS activity with an IC50 value of 9.7 +/- 0.7 microM in the citrulline-formation assay. DTCS alone did not inhibit the activity. An iron complex with N-methyl-D-glucamine dithiocarbamate, a similar spin-trapping agent for NO, also inhibited the activity, with an IC50 value of 25.1 +/- 2.9 microM. Fe-DTCS suppressed cytochrome c and ferricyanide reductase activities of nNOS, and markedly increased nNOS-mediated NADPH oxidation. Concomitantly, it accelerated oxygen consumption caused by activated nNOS. These results suggest that the ESR spin-trapping agent Fe-DTCS inhibits NO synthesis by interfering with the physiological electron flow from NADPH to nNOS heme iron.