Production of nitric oxide (NO) by macrophages is important for the killing of intracellular infectious agents. Interferon (IFN)-gamma and lipopolysaccharide stimulate NO production by transcriptionally up-regulating the inducible NO synthase (iNOS). Macrophages from mice with a targeted disruption of the IFN regulatory factor-1 (IRF-1) gene (IRF-1-/- mice) produced little or no NO and synthesized barely detectable iNOS messenger RNA in response to stimulation. Two adjacent IRF-1 response elements were identified in the iNOS promoter. Infection with Mycobacterium bovis (BCG) was more severe in IRF-1-/- mice than in wild-type mice. Thus, IRF-1 is essential for iNOS activation in murine macrophages.
SummaryExposure of BALB/c mice to mosquitoes infected with irradiated Plasmodium berghei confers protective immunity against subsequent sporozoite challenge. Immunized mice challenged with viable sporozoites develop parasitemia when treated orally with substrate inhibitors of nitric oxide synthase (NOS). This suggests that the production of nitric oxide (NO) prevents the development of exoerythrocytic stages of malaria in liver. Liver tissue from immunized mice expressed maximal levels of mKNA for inducible NOS (iNOS) between 12 and 24 h after challenge with sporozoites. Intraperitoneal injection of neutralizing monoclonal antibody against interferon 3/(IFN-3') or in vivo depletion of CD8 + T cells, but not CD4 + T cells, at the time of challenge blocked expression of iNOS mlLNA and ablated protection in immunized mice. These results show that both CD8 § T cells and IFN-~/are important components in the regulation of iNOS in liver which contributes to the protective response of mice immunized with irradiated malaria sporozoites. IFN-3,, likely provided by malaria-specific CD8 + T cells, induces liver cells, hepatocytes and/or Kupffer cells, to produce NO for the destruction of infected hepatocytes or the parasite within these cells. W ithin minutes after an infected Anopheles mosquito bites the vertebrate host, malaria sporozoites migrate to the liver and invade hepatocytes. There, the parasite matures, and after several days the infected hepatocytes lyse, releasing thousands of merozoites. Once in circulation, the parasite infects erythrocytes causing parasitemia. Prior exposure to irradiated sporozoites confers protective immunity (1, 2). This immunity is directed against liver stage malaria, and does not protect against the blood stage malaria.CD8 + T cells and IFN-3' are required for protective immunity to sporozoite challenge. In vivo depletion of CD8 § T cells or neutralization of IFN-3~ blocks induction of effector activity at the hepatic stage, resulting in parasitaemia (3-5). In vitro studies show that IFN-qr kills parasites by stimulating malaria-infected hepatocytes to produce nitric oxide (NO), and the addition of monomethyl-r-arginine (NGMMLA), a substrate inhibitor of nitric oxide synthase (NOS), to primary cultures of mouse hepatocytes reversed the antiparasitic effects of IFN-'y (6, 7). Human hepatocytes also respond to IFN-3' for NO production (8). As to whether human hepatocytes exhibit antimalaria activity when stimulated to produce NO, remains to be examined.At present, the antimalaria effector mechanism triggered by sporozoites in immunized animals is not fully understood. Presumably malaria-specific CD8 + T cells act directly against infected hepatocytes by recognizing malaria antigen on the cell surface (i.e., induction of CTLs) or malaria-specific lymphocytes release cytokines, such as IFN-3,, upon parasite stimulation, which induces an antimalarial response (3)(4)(5)(9)(10)(11)(12). The relationship between CD8 + T cells, IFN-% and NO-mediated protection in sporozoite-immunized mice was ...
To discover how nitric oxide (NO) synthesis is controlled in different tissues as cells within these tissues combat intracellular pathogens, we examined three distinctively different experimental murine models designed for studying parasite-host interactions: macrophage killing of Leishmania major; nonspecific protection against tularemia (Francisella tularensis) by Mycobacterium bovis (BCG); and specific vaccine-induced protection against hepatic malaria with Plasmodium berghei. Each model parasite and host system provides information on the source and role of NO during infection and the factors that induce or inhibit its production. The in vitro assay for macrophage antimicrobial activity against L. major identified cytokines involved in regulating NO-mediated killing of this intracellular protozoan. L. major induced the production of two competing cytokines in infected macrophages: (1) the parasite activated the gene for tumor necrosis factor (TNF), and production of TNF protein was enhanced by the presence of interferon-gamma (IFN-gamma). TNF then acted as a autocrine signal to amplify IFN-gamma-induced production of NO; and (2) the parasite upregulated production of transforming growth factor-beta (TGF-beta), which blocked IFN-gamma-induced production of NO. Whether parasite-induced TNF (parasite destruction) or TGF-beta (parasite survival) prevailed depended upon the presence and quantity of IFN-gamma at the time of infection. The relationship between NO production in vivo and host resistance to infection was demonstrated with M. bovis (BCG).(ABSTRACT TRUNCATED AT 250 WORDS)
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