Nitric oxide interaction with lactoferrin and its production by macrophage cells studied by EPR and spin trapping

Biochemical and Functional Analysis of Cyanobacterium Geitlerinema sp. LPS on Human Monocytes

Cyanobacterial blooms are an increasing source of environmental toxins that affect both human and animals. After ingestion of cyanobacteria, such as Geitlerinema sp., toxins and lipopolysaccharide (LPS) from this organism induce fever, gastrointestinal illness, and even death. However, little is known regarding the effects of cyanobacterial LPS on human monocytes after exposure to LPS upon ingestion. Based on our previous data using Geitlerinema sp. LPS (which was previously named Oscillatoria sp., a genus belonging to the same order as Geitlerinema), we hypothesized that Geitlerinema sp. LPS would activate human monocytes to proliferate, phagocytose particles, and produce cytokines that are critical for promoting proinflammatory responses in the gut. Our data demonstrate that Geitlerinema sp. LPS induced monocyte proliferation and TNF-α, IL-1, and IL-6 production at high concentrations. In contrast, Geitlerinema sp. LPS is equally capable of inducing monocyte-mediated phagocytosis of FITC-latex beads when compared with Escherichia coli LPS, which was used as a positive control for our experiments. In order to understand the mechanism responsible for the difference in efficacy between Geitlerinema sp. LPS and E. coli LPS, we performed biochemical analysis and identified that Geitlerinema sp. LPS was composed of significantly different sugars and fatty acid side chains in comparison to E. coli LPS. The lipid A portion of Geitlerinema sp. LPS contained longer fatty acid side chains, such as C15:0, C16:0, and C18:0, instead of C12:0 found in E. coli LPS which may explain the decreased efficacy and toxicity of Geitlerinema sp. LPS in comparison to E. coli LPS.

Effects of nitrogen monoxide and carbon monoxide on molecular and cellular iron metabolism: mirror-image effector molecules that target iron

Many effector functions of nitrogen monoxide (NO) and carbon monoxide (CO) are mediated through their high-affinity for iron (Fe). In this review, the roles of NO and CO are examined in terms of their effects on the molecular and cellular mechanisms involved in Fe metabolism. Both NO and CO avidly form complexes with a plethora of Fe-containing molecules. The generation of NO and CO is mediated by the nitric oxide synthase and haem oxygenase (HO) families of enzymes respectively. The effects of NO on Fe metabolism have been well characterized, whereas knowledge of the effects of CO remains within its infancy. In terms of the role of NO in Fe metabolism, one of the best characterized interactions includes its effect on the iron regulatory proteins. These molecules are mRNA-binding proteins that control the expression of the transferrin receptor 1 and ferritin, molecules that are involved in Fe uptake and storage respectively. Apart from this, activated macrophages impart their cytotoxic activity by generating NO, which results in marked Fe mobilization from tumour-cell targets. This deprives the cell of the Fe that is required for DNA synthesis and energy production. Considering that HO degrades haem, resulting in the release of CO, Fe(II) and biliverdin, it is suggested that a CO-Fe complex will form. This may account for the rapid Fe mobilization observed from macrophages after haemoglobin catabolism. Intriguingly, overexpression of HO results in cellular Fe mobilization, suggesting that CO has a similar effect to NO on Fe trafficking. Preliminary evidence suggests that, like NO, CO plays important roles in Fe metabolism.

Differential pattern in circulating nitrogen derivatives, lactoferrin, and anti-lactoferrin antibodies in HIV type 1 and HIV type 2 infections

HIV-1 infection is associated with a dramatic reduction in antioxidative molecules both at the cellular level and in the circulation. This is particularly so for lactoferrin, an iron-binding protein involved in natural defenses (antimicrobial and antiviral activities, etc.) and found in whole secretions, including milk and mucus. In addition to its ability to chelate iron ions, lactoferrin inhibits hydroxy radical formation and interacts with nitric oxide (NO). Levels of plasma lactoferrin decreased in HIV-1-infected patients in correlation with progression of the disease, and highly specific anti-lactoferrin autoantibodies increased. This profile was specific to HIV-1 infection; it was not found in HIV-2-infected patients. In parallel with the drop in lactoferrin, a marked increase in circulating nitrogen derivatives was observed in HIV-1-infected patients, whereas low levels were found in normal donors and in HIV-2-infected patients. These data suggested hyperstimulation of the NO pathway throughout HIV-1 but not HIV-2 infection. This overproduction of NO could play an important role in the development of AIDS symptoms and signs.

Examination of the mechanism of action of nitrogen monoxide on iron uptake from transferrin

Nitrogen monoxide (NO) exerts many of its functions by binding to iron (Fe) in the active sites of a number of key proteins. Previously we have shown that NO produced by NO-generating agents decreased cellular Fe uptake from transferrin (Tf). However, the mechanism of this effect was not elucidated. In this study we examined the possible mechanisms whereby NO could interfere with Fe uptake. Our experiments demonstrate that NO produced by the NO generator S-nitroso-N-acetylpenicillamine was slightly more effective than the Fe chelator deferoxamine at reducing iron 59 uptake from 59Fe-labeled Tf by LMTK- fibroblasts. Other NO generators including S-nitrosoglutathione (GSNO) and spermine-NONOate also decreased 59Fe uptake from 59Fe-labeled Tf. In contrast, precursors of these compounds that do not release NO had no effect. When the RAW264.7 macrophage cell line was activated to produce NO by incubation with lipopolysaccharide or lipopolysaccharide and interferon-gamma, a decrease in 59Fe uptake from 59Fe-labeled Tf was also observed. Experiments with electron paramagnetic resonance spectroscopy and ultraviolet-Vis spectrophotometry demonstrated that NO did not prevent Fe uptake by binding to the Fe-ligating sites of Tf, suggesting that it acted more distally. Because the uptake of Fe is an energy-dependent process, and since NO inhibits mitochondrial respiration, cellular adenosine triphosphate (ATP) was estimated after incubation with GSNO. In the presence of D-glucose (D-G), GSNO reduced ATP levels by 35% as compared with the control, while in the absence of D-G, GSNO reduced ATP by 72%. When the same experiments were performed with D-fructose (D-F), which cannot be efficiently metabolized by fibroblasts, no "rescue" effect was observed on ATP levels. The addition of D-G to GSNO prevented the decrease in 59Fe uptake from 59Fe-labeled Tf while D-F did not, in good correlation with their effects on ATP levels. These results suggest that D-G acts as a salvage metabolite to prevent the NO-mediated decrease in ATP levels and Fe uptake from Tf. Although NO could reduce Fe uptake by a number of mechanisms, the decrease in ATP levels appears, at least in part, to play a role. The results are discussed in the context of the effect of NO on cellular Fe metabolism.

The molecular mechanisms of the metabolism and transport of iron in normal and neoplastic cells

Iron uptake by mammalian cells is mediated by the binding of serum Tf to the TfR. Transferrin is then internalized within an endocytotic vesicle by receptor-mediated endocytosis and the Fe released from the protein by a decrease in endosomal pH. Apart from this process, several cell types also have other efficient mechanisms of Fe uptake from Tf that includes a process consistent with non-specific adsorptive pinocytosis and a mechanism that is stimulated by small-Mr Fe complexes. This latter mechanism appears to be initiated by hydroxyl radicals generated by the Fe complexes, and may play a role in Fe overload disease where a significant amount of serum non-Tf-bound Fe exists. Apart from Tf-bound Fe uptake, mammalian cells also possess a number of mechanisms that can transport Fe from small-Mr Fe complexes into the cell. In fact, recent studies have demonstrated that the membrane-bound Tf homologue, MTf, can bind and internalize Fe from 59Fe-citrate. However, the significance of this Fe uptake process and its pathophysiological relevance remain uncertain. Iron derived from Tf or small-Mr complexes is probably transported into mammalian cells in the Fe(II) state. Once Fe passes through the membrane, it then becomes part of the poorly characterized intracellular labile Fe pool. Iron in the labile Fe pool that is not used for immediate requirements is stored within the Fe-storage protein, ferritin. Cellular Fe uptake and storage are coordinately regulated through a feedback control mechanism mediated at the post-transcriptional level by cytoplasmic factors known as IRP1 and IRP2. These proteins bind to stem-loop structures known as IREs on the 3 UTR of the TfR mRNA and 5 UTR of ferritin and erythroid delta-aminolevulinic acid synthase mRNAs. Interestingly, recent work has suggested that the short-lived messenger molecule, NO (or its by-product, peroxynitrite), can affect cellular Fe metabolism via its interaction with IRP1. Moreover, NO can decrease Fe uptake from Tf by a mechanism separate to its effects on IRP1, and NO may also be responsible for activated macrophage-mediated Fe release from target cells. On the other hand, the expression of inducible NOS which produces NO, can be stimulated by Fe chelators and decreased by the addition of Fe salts, suggesting that Fe is involved in the control of NOS expression.

Association between serum levels of reactive nitrogen intermediates and coma in children with cerebral malaria in Papua New Guinea

Serum levels of reactive nitrogen intermediates (RNI; nitrate plus nitrite) were measured in 92 patients with cerebral malaria in the Madang Province of Papua New Guinea. RNI levels were compared to disease severity and clinical outcome, and correlated with both the depth of coma on admission and its duration. Median levels were higher among children with deeper coma than among those with lighter coma (35.6 microM vs. 16.7 microM; P = 0.008) and also among children with longer duration of coma (72 h; 59.3 microM vs. 19.3 microM; P = 0.004). RNI levels also correlated with clinical outcome, fatal cases having significantly higher RNI levels than survivors (41.2 microM vs. 18.5 microM; P = 0.014). Thus, high RNI levels are associated with indices of disease severity and may predict outcome in children with cerebral malaria. These data are consistent with the hypothesis that nitric oxide is involved in the pathogenesis of coma in human cerebral malaria.

Measurement of methemoglobin formation from oxyhemoglobin. A real-time, continuous assay of nitric oxide release by human polymorphonuclear leukocytes

We have evaluated the spectrophotometric measurement (at 401 vs. 411 nm) of nitric oxide (NO)-dependent methemoglobin formation from oxyhemoglobin in order to assess NO release from human polymorphonuclear neutrophil leukocytes (PMN). S-nitroso-D,L-acetyl-penicillamine (SNAP, 25-200 microM), a donor of NO, induced a dose-dependent methemoglobin formation. Furthermore, when PMN were activated with N-formyl-methionylleucyl-phenylalanine or phorbol myristate acetate in the presence of superoxide dismutase (SOD) and catalase, methemoglobin formation ensued. The amount of methemoglobin formed was dependent on the amounts of oxyhemoglobin and stimulus used, and the number of PMN in the assay. The NO synthase (NOS) inhibitors NG-monomethyl-L-arginine or nitro-L-arginine methyl ester did not affect methemoglobin generation from oxyhemoglobin induced by SNAP but inhibited that mediated by activated PMN with IC50 values of 250 microM and 340 microM, respectively. The substrate for NO formation from NOS, L-arginine in concentrations up to 1 mM did not significantly influence the methemoglobin formation either induced by SNAP or activated PMN. Exclusion of SOD did not affect SNAP-dependent oxidation of oxyhemoglobin. Exclusion of SOD from the cell-containing system attenuated methemoglobin formation, and if catalase was also excluded the response was further reduced. Finally, PMN from a patient with X-linked chronic granulomatous disease, unable to produce superoxide anions, showed a similar production of methemoglobin from HbO2 as did healthy PMN, activated with the respective agonists. We conclude that spectrophotometric measurement of methemoglobin formation from oxyhemoglobin in the presence of SOD and catalase is a suitable method for the measurement of NO release from PMN, with the benefits of a real-time, continuous assay.

Nitrogen monoxide decreases iron uptake from transferrin but does not mobilise iron from prelabelled neoplastic cells

The effect of congeners of nitrogen monoxide (NO) on iron (Fe) uptake from 59Fe-125I-transferrin (Tf) and release of 59Fe from prelabelled cells have been investigated in SK-MEL-28 human melanoma cells, human K562 cells and mouse MDW-4 cells. These studies have been initiated as it has been suggested that the tumoricidal effects of NO may be mediated by its acting to release Fe from cells (Hibbs et al., 1984 Biochem. Biophys. Res. Commun. 123, 716-723; Hibbs et al., 1988 Biochem. Biophys. Res. Commun. 157, 87-94). The nitrosonium ion (NO+) generator, sodium nitroprusside (SNP), decreased 59Fe uptake by melanoma cells to 57% of the control without decreasing 125I-Tf uptake after a 4-h incubation with 59Fe-125-Tf (1.25 microM). Longer incubations up to 24 h decreased 59Fe uptake and also 125I-Tf uptake. Two breakdown products of SNP, ferricyanide and cyanide, had no effect on 59Fe uptake. In addition, photolysis of the SNP solution prevented the inhibition of 59Fe uptake, suggesting that NO was the active agent. Two nitric oxide (NO.) producing agents, 3-morpholinosydnonimine (SIN), and S-nitroso-N-acetylpenicillamine (SNAP), also decreased 59Fe uptake from 59Fe-125I-Tf. Superoxide dismutase increased the efficacy of SIN, and the NO-scavenger, oxyhaemoglobin, prevented the inhibition of 59Fe uptake mediated by SNAP, again suggesting that NO was the active agent. Furthermore, dialysis studies demonstrated that none of the NO-generating agents could remove 59Fe from 59Fe-125I-Tf, suggesting that the decrease in cellular Fe uptake observed was not due to NO releasing Fe from the Fe-binding sites of Tf. Despite the ability of NO-producing agents at inhibiting 59Fe uptake by cells, they could not remove significant amounts of 59Fe from melanoma cells prelabelled with either 59Fe-citrate or 59Fe-125I-Tf. Similar data were obtained using K562 and MDW-4 cells. Interestingly, the NO+ generating agent, SNP, had no effect on [3H]thymidine uptake. However, when SNP was converted to an NO. generator by the addition of 1 mM ascorbate, its effect was similar to the NO. generator, SNAP, markedly reducing [3H]thymidine incorporation to 33% of the control value. The addition of unlabelled diferric Tf (0.625 microM) to SNAP ameliorated its inhibitory effect on cellular [3H]thymidine uptake, suggesting that the interaction of NO. with Fe was of importance in the inhibition observed. The results are discussed in the context of the cytostatic potential of NO via its binding to Fe.