Regulation of peripheral lymph node genesis by the tumor necrosis factor family member TRANCE.

Proper lymph node (LN) development requires tumor necrosis factor-related activation-induced cytokine (TRANCE) expression. Here we demonstrate that the defective LN development in TRANCE(-/)- mice correlates with a significant reduction in lymphotoxin (LT)alphabeta(+)alpha(4)beta(7)(+)CD45(+)CD4(+)CD3(-) cells and their failure to form clusters in rudimentary mesenteric LNs. Transgenic TRANCE overexpression in TRANCE(-/)- mice results in selective restoration of this cell population into clusters, and results in full LN development. Transgenic TRANCE-mediated restoration of LN development requires LTalphabeta expression on CD45(+) CD4(+)CD3(-) cells, as LNs could not be induced in LTalpha(-/)- mice. LTalpha(-/)- mice also showed defects in the fate of CD45(+)CD4(+)CD3(-) cells similar to TRANCE(-/)- mice. Thus, we propose that both TRANCE and LTalphabeta regulate the colonization and cluster formation by CD45(+) CD4(+)CD3(-) cells in developing LNs, the degree of which appears to correlate with the state of LN organogenesis.

Lethality of endotoxin in mice genetically deficient in the respiratory burst oxidase, inducible nitric oxide synthase, or both.

Two classes of oxidants are thought to play a critical role in tissue damage in septic shock: reactive oxygen intermediates (ROI) and reactive nitrogen intermediates (RNI). Particular importance has been ascribed to peroxynitrite, a product arising from the reaction of nitric oxide with superoxide. A major source of ROI is the respiratory burst oxidase of neutrophils, eosinophils, monocytes, and macrophages. A major source of RNI is inducible nitric oxide synthase (iNOS), an enzyme expressed in leukocytes, hepatocytes, vascular smooth muscle cells, endothelium, and cardiac myocytes during inflammation. In previous studies using various mouse models of endotoxic shock, genetic deficiency of iNOS as a sole intervention did not consistently alter survival. Here, using Salmonella typhimurium endotoxic bacterial lipopolysaccharide (LPS) as a sole challenge, genetic deficiency of iNOS was associated with no protection or a reduction in survival, depending on the dose of LPS. Further, no protection from lethality was observed when LPS was injected into mice genetically deficient in the 91 kDa subunit of the respiratory burst oxidase (gp91phox) nor in mice genetically deficient in both gp91phox and iNOS (gp91phox-/-/NOS2-/- mice). For the latter experiments, mice were challenged either with S. typhimurium LPS alone or with inactivated bacille Calmette-Guerin (BCG) followed by Escherichia coli LPS. Deficiency of gp91phox impaired the inflammatory response to inactivated Propionobacterium acnes, rendering survival studies following priming with P. acnes difficult to interpret. Thus, in two models of endotoxic shock, major reductions in the ability to form nitric oxide or superoxide, alone or in combination, failed to improve survival.

Phenotype of mice and macrophages deficient in both phagocyte oxidase and inducible nitric oxide synthase.

The two genetically established antimicrobial mechanisms of macrophages are production of reactive oxygen intermediates by phagocyte oxidase (phox) and reactive nitrogen intermediates by inducible nitric oxide synthase (NOS2). Mice doubly deficient in both enzymes (gp91(phox-/-)/NOS2(-/-)) formed massive abscesses containing commensal organisms, mostly enteric bacteria, even when reared under specific pathogen-free conditions with antibiotics. Neither parental strain showed such infections. Thus, phox and NOS2 appear to compensate for each other's deficiency in providing resistance to indigenous bacteria, and no other pathway does so fully. Macrophages from gp91(phox-/-)/NOS2(-/-) mice could not kill virulent Listeria. Their killing of S. typhimurium, E. coli, and attenuated Listeria was markedly diminished but demonstrable, establishing the existence of a mechanism of macrophage antibacterial activity independent of phox and NOS2.

Rapid interferon gamma-dependent clearance of influenza A virus and protection from consolidating pneumonitis in nitric oxide synthase 2-deficient mice.

Viral infection often activates the interferon (IFN)-gamma-inducible gene, nitric oxide synthase 2 (NOS2). Expression of NOS2 can limit viral growth but may also suppress the immune system and damage tissue. This study assessed each of these effects in genetically deficient NOS2(-/-) mice after infection with influenza A, a virus against which IFN-gamma has no known activity. At inocula sufficient to cause consolidating pneumonitis and death in wild-type control mice, NOS2(-/-) hosts survived with little histopathologic evidence of pneumonitis. Moreover, they cleared influenza A virus from their lungs by an IFN-gamma-dependent mechanism that was not evident in wild-type mice. Even when the IFN-gamma-mediated antiviral activity was blocked in NOS2(-/-) mice with anti-IFN-gamma mAb, such mice failed to succumb to disease. Further evidence that this protection was independent of viral load was provided by treating NOS2(+/+) mice with the NOS inhibitor, Nomega-methyl-L-arginine (L-NMA). L-NMA prevented mortality without affecting viral growth. Thus, host NOS2 seems to contribute more significantly to the development of influenza pneumonitis in mice than the cytopathic effects of viral replication. Although NOS2 mediates some antiviral effects of IFN-gamma, during influenza infection it can suppress another IFN-gamma-dependent antiviral mechanism. This mechanism was observed only in the complete absence of NOS2 activity and appeared sufficient to control influenza A virus growth in the absence of changes in cytotoxic T lymphocyte activity.

Identification of nitric oxide synthase 2 as an innate resistance locus against ectromelia virus infection.

To assess whether nitric oxide synthase 2 (NOS2) fulfills the criteria of an innate resistance locus against an acute viral infection, we inoculated genetically deficient NOS2-/- mice with virulent ectromelia virus (EV), the causative agent of mousepox. NOS2-/- mice proved highly susceptible to EV yet showed no diminution in other well-characterized anti-EV immune responses, i.e. , gamma interferon secretion and NK cell and EV-specific cytotoxic T lymphocyte activities. Thus, the NOS2 locus can be considered a critical monogenic determinant of EV resistance that contributes to host survival.

Inducible nitric oxide synthase-deficient mice have enhanced leukocyte-endothelium interactions in endotoxemia.

Nitric oxide (NO) from constitutive NO synthase (NOS) has been postulated to be a homeostatic regulator of leukocyte-endothelial cell interactions. By contrast, the inducible NO synthase (iNOS) isoform has been invoked as a potential pathogenic enzyme in numerous inflammatory diseases. The objective of this study was to determine whether the iNOS isoform is also capable of functioning as a regulator of leukocyte recruitment. Mice received endotoxin (LPS, 30 microg/kg, i.v.); 2-4 h later, intravital microscopy was used to examine leukocyte rolling and adhesion in postcapillary venules of the cremaster muscle and the sinusoids and postsinusoidal venules of the hepatic microcirculation. Leukocyte recruitment into the lung was also examined. RT-PCR confirmed that this treatment induced iNOS mRNA expression in wild-type mice as early as 2 h after LPS treatment. Between 2 and 4 h after LPS administration, the number of rolling and adherent leukocytes in cremasteric postcapillary venules and of adherent cells in liver postsinusoidal venules of iNOS-deficient mice were significantly higher than in wild-type mice. Leukocyte accumulation in the lung (measured by myeloperoxidase assay) was also significantly elevated in iNOS-deficient animals. These effects could not be attributed to differences in systemic blood pressure, shear rates, circulating leukocyte numbers, or baseline levels of rolling and adhesion because these parameters were not different between the two groups. To establish whether the differences in leukocyte recruitment were related to the leukocytes per se, perfusion of iNOS+/+ or iNOS-/- septic blood over purified E-selectin (using parallel plate flow chambers) revealed much larger recruitment of iNOS-/- leukocytes. These results suggest that iNOS induced in response to LPS releases NO that is capable of reducing leukocyte accumulation by affecting leukocytes directly and raises the possibility that induction of iNOS is a homeostatic regulator for leukocyte recruitment.

Identification of nitric oxide synthase as a protective locus against tuberculosis.

Mutagenesis of the host immune system has helped identify response pathways necessary to combat tuberculosis. Several such pathways may function as activators of a common protective gene: inducible nitric oxide synthase (NOS2). Here we provide direct evidence for this gene controlling primary Mycobacterium tuberculosis infection using mice homozygous for a disrupted NOS2 allele. NOS2(-/-) mice proved highly susceptible, resembling wild-type littermates immunosuppressed by high-dose glucocorticoids, and allowed Mycobacterium tuberculosis to replicate faster in the lungs than reported for other gene-deficient hosts. Susceptibility appeared to be independent of the only known naturally inherited antimicrobial locus, NRAMP1. Progression of chronic tuberculosis in wild-type mice was accelerated by specifically inhibiting NOS2 via administration of N6-(1-iminoethyl)-L-lysine. Together these findings identify NOS2 as a critical host gene for tuberculostasis.

Altered responses to bacterial infection and endotoxic shock in mice lacking inducible nitric oxide synthase.

Mice deficient in inducible nitric oxide synthase (iNOS) were generated to test the idea that iNOS defends the host against infectious agents and tumor cells at the risk of contributing to tissue damage and shock. iNOS-/-mice failed to restrain the replication of Listeria monocytogenes in vivo or lymphoma cells in vitro. Bacterial endotoxic lipopolysaccharide (LPS) caused shock and death in anesthetized wild-type mice, but in iNOS-/-mice, the fall in central arterial blood pressure was markedly attenuated and early death averted. However, unanesthetized iNOS-/-mice suffered as much LPS-induced liver damage as wild type, and when primed with Propionobacterium acnes and challenged with LPS, they succumbed at the same rate as wild type. Thus, there exist both iNOS-dependent and iNOS-independent routes to LPS-induced hypotension and death.

Inhibition of viral replication by interferon-gamma-induced nitric oxide synthase.

Interferons (IFNs) induce antiviral activity in many cell types. The ability of IFN-gamma to inhibit replication of ectromelia, vaccinia, and herpes simplex-1 viruses in mouse macrophages correlated with the cells' production of nitric oxide (NO). Viral replication was restored in IFN-gamma-treated macrophages exposed to inhibitors of NO synthase. Conversely, epithelial cells with no detectable NO synthesis restricted viral replication when transfected with a complementary DNA encoding inducible NO synthase or treated with organic compounds that generate NO. In mice, an inhibitor of NO synthase converted resolving ectromelia virus infection into fulminant mousepox. Thus, induction of NO synthase can be necessary and sufficient for a substantial antiviral effect of IFN-gamma.

Elevated secretion of reactive nitrogen and oxygen intermediates by inflammatory leukocytes in hyperacute experimental autoimmune encephalomyelitis: enhancement by the soluble products of encephalitogenic T cells.

Perivascular lesions within the central nervous system (CNS) of rats with hyperacute experimental autoimmune encephalomyelitis (HEAE) contained large numbers of peripheral blood mononuclear cells (PBMC) and polymorphonuclear leukocytes (PMN), cells enzymatically capable of producing reactive nitrogen and oxygen intermediates (RNI and ROI), which, in excess, are mediators of tissue damage. PBMC and PMN isolated from the CNS and periphery of HEAE-affected rats secreted significantly (p less than 0.01-0.0001) elevated levels of ROI and RNI compared with that of similar cell populations from pertussis- and saline-treated control animals. Coincubation of systemically derived PBMC and PMN with antigen-stimulated myelin basic protein-specific T cell lines led to further increases in ROI and RNI output of between 15.3 and 83.1%, an effect that could be largely attributed to heat-labile, soluble products released by these T cell lines. Our studies suggest a putative neuropathological role for ROI and RNI in HEAE, which may be mediated via cytokines emanating from autoreactive T lymphocytes.

Malaria mimicry with tumor necrosis factor. Contrasts between species of murine malaria and Plasmodium falciparum.

Because Plasmodium berghei ANKA induces cerebral malaria and P. vinckei does not, the former has often been studied as a model for human falciparum malaria. It lacks, however, many of the systemic changes seen in the human disease. Because both of these murine models and the human disease have now been defined in terms of excess tumor necrosis factor (TNF) production, the authors have more closely examined the two murine models in this light to see which provides the better overall model for falciparum malaria. Administering TNF to malaria-infected mice did not cause cerebral symptoms nor breakdown of the blood-brain barrier, which is the hallmark of P. berghei ANKA cerebral malaria and is generally absent in human cerebral malaria. Tumor necrosis factor did, however, induce hypoglycemia and liver injury, pathology that is seen in terminal P. vinckei and falciparum malaria, but is absent in terminal P. berghei ANKA malaria. Plasma TNF and interleukin-6 (IL-6) also were found to be consistently higher in infections caused by P. vinckei than in those caused by P. berghei ANKA. The pathology of P. vinckei malaria is thus consistent with raised systemic levels of TNF and other cytokines, as is falciparum malaria. The authors therefore conclude that P. vinckei malaria, although lacking a cerebral component, is the better model for the human disease.

TNF and Plasmodium berghei ANKA-induced cerebral malaria.

The cerebral pathology observed in Plasmodium berghei ANKA-infected CBA mice has been attributed to overproduction of TNF, the mice in which this syndrome is seen being those with the highest serum TNF levels. To investigate this further, we injected recombinant human TNF into malaria-primed mice to see if we could reproduce the cerebral changes observed in P. berghei ANKA infections. A range of doses, administered as a single or repeated injections, or via osmotic pumps, failed to reproduce these changes, but did induce hypoglycaemia, midzonal liver necrosis and neutrophil adhesion in pulmonary vessels. This pathology is seen in terminal Plasmodium vinckei infections, but absent in terminal P. berghei ANKA. In addition, the permeability of the blood-brain barrier to Evan's blue, which is present in P. berghei ANKA but not in normal or P. vinckei-infected mice, was not induced by exogenous TNF. Serum levels of TNF were measured in an ELISA assay, and found to be consistently higher in P. vinckei rather than P. berghei ANKA terminal infections. This is consistent with the pathological changes we could reproduce by injecting TNF. For these reasons we suggest that the cerebral pathology seen in mice infected with P. berghei ANKA may be governed by TNF produced locally by monocytes sequestered within the cerebral blood vessels, not simply by systemic levels of this cytokine.