Synergistic induction of the Tap-1 gene by IFN-gamma and lipopolysaccharide in macrophages is regulated by STAT1

Proper regulation of the Tap-1 gene is critical for the initiation and continuation of a cellular immune response. Analysis of the Tap-1/low molecular mass polypeptide 2 bidirectional promoter showed that the IFN-gamma activation site element is critical for the rapid induction of the promoter by IFN-gamma following transfection into the human macrophage cell line THP-1. Furthermore, activation of STAT1 binding to this site was important for the synergistic response seen following the stimulation with both IFN-gamma and LPS. Mutation of an IFN-stimulated regulatory element that binds IFN regulatory factor 1 appeared to enhance the response to IFN-gamma and LPS. These data show that STAT1 is necessary for the activation of Tap-1 gene expression in APCs and initiation of cellular immune responses. Furthermore, our data suggest that bacterial products such as LPS may enhance cellular immune responses through augmenting the ability of STAT1 to regulate IFN-gamma-inducible genes.     

Macrophage SR-BI regulates LPS-induced pro-inflammatory signaling in mice and isolated macrophages

Scavenger receptor BI (SR-BI), an HDL receptor, plays a key role in reverse cholesterol transport. In mice, disruption of SR-BI results in hypersensitivity to lipopolysaccharide (LPS) and bacteria-induced septic shock due to adrenal insufficiency and abnormal hepatic pathogen clearance. In this study, we identify an anti-inflammatory role of macrophage SR-BI. Using bone marrow transplantation, we report an enhanced pro-inflammatory response to LPS in wild-type (WT) mice receiving SR-BI-null compared with WT bone marrow cells and a reduced response in SR-BI-null mice receiving WT compared with SR-BI-null cells. Although significant, SR-BI deficiency limited to bone marrow-derived cells promoted a relatively modest enhancement of the inflammatory response to LPS in mice compared with the effect of whole-body SR-BI deletion. Consistent with earlier findings, SR-BI-null primary macrophages exhibited a greater inflammatory cytokine response to LPS than control macro phages. In addition, we showed that overexpression of SR-BI in J774 macrophages attenuated the inflammatory response to LPS. The LPS-induced cytokine expression in both WT and SR-BI-null macrophages was dependent not only on NFκB as previously reported but also on JNK and P38 cell signaling pathways. The increased inflammatory signaling in SR-BI-null cells was not related to alterations in cellular cholesterol content. We conclude that SR-BI plays an important function in regulating the macrophage inflammatory response to LPS.     

NF-κB signaling in fetal lung macrophages disrupts airway morphogenesis

Bronchopulmonary dysplasia is a common pulmonary complication of extreme prematurity. Arrested lung development leads to bronchopulmonary dysplasia, but the molecular pathways that cause this arrest are unclear. Lung injury and inflammation increase disease risk, but the cellular site of the inflammatory response and the potential role of localized inflammatory signaling in inhibiting lung morphogenesis are not known. In this study, we show that tissue macrophages present in the fetal mouse lung mediate the inflammatory response to LPS and that macrophage activation inhibits airway morphogenesis. Macrophage depletion or targeted inactivation of the NF-κB signaling pathway protected airway branching in cultured lung explants from the effects of LPS. Macrophages also appear to be the primary cellular site of IL-1β production following LPS exposure. Conversely, targeted NF-κB activation in transgenic macrophages was sufficient to inhibit airway morphogenesis. Macrophage activation in vivo inhibited expression of multiple genes critical for normal lung development, leading to thickened lung interstitium, reduced airway branching, and perinatal death. We propose that fetal lung macrophage activation contributes to bronchopulmonary dysplasia by generating a localized inflammatory response that disrupts developmental signals critical for lung formation.     

Tumor necrosis factor alpha negatively regulates hepatitis B virus gene expression in transgenic mice.

It is well known that several inflammatory cytokines can modulate hepatocellular gene expression in a complex physiological process known as the hepatic acute-phase response. Since hepatitis B virus (HBV) characteristically induces a vigorous lymphomononuclear inflammatory response in the liver during acute and chronic hepatitis, it is possible that hepatocellular HBV gene expression may also be modulated by one or more of the cytokines produced by these cells. Using bacterial lipopolysaccharide (LPS) as a surrogate inducer of inflammatory cytokines in vivo, we have tested this hypothesis in a transgenic mouse model system. In experiments with two independent transgenic mouse lineages that express the HBV envelope region under the control of either HBV or cellular promoters, we observed a 50 to 80% reduction in the hepatic steady-state content of a 2.1-kb HBV mRNA following administration of a single intraperitoneal dose of LPS. The regulatory influence of several inflammatory cytokines known to be induced by LPS was also examined in this system. The negative regulatory effect of LPS was consistently reproduced by the administration of a single nontoxic dose of tumor necrosis factor alpha, and it was occasionally observed following the administration of high doses of alpha interferon and interleukin-6, while no effect was detectable in response to high-dose interleukin-1 alpha or to gamma interferon. These observations suggest that tumor necrosis factor alpha and perhaps other cytokines may activate a heretofore unsuspected intracellular pathway that negatively regulates HBV gene expression. The intracellular mechanism(s) responsible for this effect and its pathophysiologic relevance remain to be elucidated.