Stimulation of IRE-BP activity of IRF by tetrahydrobiopterin and cytokine dependent induction of nitric oxide synthase

Nitric oxide inhibits the replication cycle of porcine parvovirus in vitro

This study investigated the inhibitory effect and mechanism of nitric oxide (NO) on porcine parvovirus (PPV) replication in PK-15 cells. The results showed that two NO-generating compounds, S-nitroso-l-acetylpenicillamine (SNAP) and l-arginine (LA), at a noncytotoxic concentration could reduce PPV replication in a dose-dependent manner and that this anti-PPV effect could be reversed by the NO synthase (NOS) inhibitor N-nitro-l-arginine methyl ester (l-NAME). By assaying the steps of the PPV life cycle, we also show that NO inhibits viral DNA and protein synthesis. This experiment provides a frame of reference for the study of the anti-viral mechanism of NO.

Cytokine mRNA expression and iron status in children living in a malaria endemic area

Iron deficiency has been reported to affect both malaria pathogenesis and cell-mediated immune responses; however, it is unclear whether the protection afforded by iron deficiency is mediated through direct effects on the parasite, through immune effector functions or through both. We have determined cytokine mRNA expression levels in 59 children living in a malaria endemic area on the coast of Kenya who we selected on the basis of their biochemical iron status. Real-time quantitative reverse transcriptase polymerase chain reaction analysis of cytokine mRNA levels of peripheral blood mononuclear cells (PBMC) obtained from these children showed an association between interleukin-4 (IL-4) mRNA levels and all the biochemical indices of iron that we measured. Furthermore, IL-10 mRNA was higher in parasite blood smear-positive children than in blood smear-negative children irrespective of their iron status. This study suggests that IL-4 expression by PBMC may be affected by iron status.

Effects of hepatocellular iron imbalance on nitric oxide and reactive oxygen intermediates production in a model of sepsis

BACKGROUND/AIMS

In mammals iron homeostasis is most important, as imbalance of iron such as iron overload may lead to severe diseases. Recently, it has been shown that the iron regulatory protein-1 is partially controlled by nitric oxide and reactive oxygen intermediates, molecules frequently seen in inflammatory events. The aim of the present study was to investigate the effects of impaired iron homeostasis on the interaction of nitric oxide, and reactive oxygen intermediate formation in hepatocytes in a model of acute inflammation.

METHODS

Hepatocytes isolated from Corynebacterium parvum (C parvum)-injected rats were used to examine the formation of nitrogen and oxygen intermediates by iron deprivation and iron overload in the presence of lipopolysaccharide. In addition, we investigated the RNA binding and aconitase activity of iron regulatory protein-1.

RESULTS

In the present study we show that iron overload in lipopolysaccharide-treated C. parvum-primed hepatocytes downregulated the RNA binding of iron regulatory protein-1 and aconitase activity. Subsequently, we observed a reduced formation of nitrite/nitrate and S-nitrosothiols but an increased production of reactive oxygen species, and hepatocellular damage. Moreover, the addition of iron to cell cultures caused a further increase in cellular damage, a drop in the cellular glutathione pool, and an increase in peroxynitrite and hydroxyl-like radicals. In contrast, addition of deferoxamine (an iron chelator) to lipopolysaccharide-treated C. parvum-primed hepatocytes protected cells by stabilizing the GSH content, maintaining the nitric oxide formation, and by reducing Fenton oxidants.

CONCLUSIONS

Our results show that the antioxidative effects of iron chelators prevent the formation of toxic Fenton oxidants in severe inflammatory events, which should be considered in the treatment of disorders characterized by an iron imbalance.

Ironing-out mechanisms of neuronal injury under hypoxic-ischemic conditions and potential role of iron chelators as neuroprotective agents

Iron is the most abundant transition metal in the brain, where it functions as an important cofactor in a host of vital metabolic processes and plays an absolutely essential role in cell viability. Free iron is also very toxic when present in high concentrations, thus placing this essential metal at the core of neurotoxic injury in a number of neurological disorders. The pivotal role of iron in cellular homeostasis, including its latent toxicity, necessitates a tight regulation of iron metabolism. Oxygen and iron appear to play an important role in iron homeostasis. They appear to exert their homeostatic role by modulating the proteins involved in a complex interplay between iron sensing, transport, and storage. These key regulatory proteins include ferritin (intracellular storage), transferrin (extracellular transport), transferrin receptor, and iron regulatory protein (sensor of intracellular iron concentration). The interplay of iron and oxygen is most intriguing in the setting of stroke, where hypoxia and free iron appear to interact in causing the subsequent neuronal death.

Nitric oxide inhibition of coxsackievirus replication in vitro

Nitric oxide is a radical molecule with antibacterial, -parasitic, and -viral properties. We investigated the mechanism of NO inhibition of Coxsackievirus B3 (CVB3) replication in vitro by determining the effect of NO upon a single replicative cycle of CVB3 grown in HeLa cells. Transfection of inducible NO synthase cDNA into HeLa cells reduces the number of viral particles produced during a single cycle of growth. Similarly, a noncytotoxic concentration of the NO donor S-nitroso-amino-penicillamine reduces the number of viral particles in a dose-dependent manner. To explore the mechanisms by which NO exerts its antiviral effect, we assayed the attachment, replication, and translation steps of the CVB3 life cycle. NO does not affect the attachment of CVB3 to HeLa cells. However, NO inhibits CVB3 RNA synthesis, as shown by a [3H]uridine incorporation assay, reverse transcription-PCR, and Northern analysis. In addition, NO inhibits CVB3 protein synthesis, as shown by [35S]methionine protein labeling and Western blot analysis of infected cells. Thus, NO inhibits CVB3 replication in part by inhibiting viral RNA synthesis by an unknown mechanism.