Although a variety of potential sources for reactive oxygen species (ROS) exist in the CNS, brain macrophages, i.e., the microglia, generate large quantities of these reactive species, particularly in response to injury or inflammatory signals. In order to understand how microglia contribute to changes in oxidative status of the CNS and how this might related to disease states, such as Alzheimer disease (AD), we have examined the regulation of superoxide anion and nitric oxide production from rodent and human microglia. Our results indicate that microglia from all species we have studied release superoxide anion, but produce significantly different amounts in response to the same activating agents. Species differences are also found in the ability to generate nitric oxide (NO). In particular, mouse microglia generate large quantities of NO when stimulated, but human and hamster microglia do not produce measurable amounts under the same stimulation conditions. These species differences are important to consider when modeling human disease processes from rodent studies.
Microglial cell activation, myelin alteration, and abundant tumor necrosis factor (TNF)-alpha message have been observed in the brains of some human immunodeficiency virus type 1 (HIV-1)-infected and demented patients. We therefore used cultures of purified human microglia and oligodendrocytes derived from adult human brain to examine the role of TNF-alpha in HIV-1 encephalopathy. Human microglia synthesize TNF-alpha message and protein in vitro. When these cells were infected with HIV-1 JrFL and maintained in the presence of TNF-alpha antibodies, soluble TNF-alpha receptors, or the TNF-alpha inhibitor pentoxifylline, viral replication was delayed or strongly inhibited. Both human microglia and oligodendrocytes express the two TNF receptors, TNF-R1, which has been implicated in cytotoxicity, and TNF-R2. While TNF-alpha may enhance HIV-1 replication in an autocrine manner, it is not toxic for microglia. In contrast, recombinant human TNF-alpha causes oligodendrocyte death in a dose-dependent manner. In situ detection of DNA fragmentation in some cells indicated that oligodendrocyte death may occur by apoptosis. Addition of live microglia or medium conditioned by these cells also resulted in 30 to 40% oligodendrocyte death, which was largely prevented by TNF-alpha inhibitors. We propose that TNF-alpha plays a dual role in HIV-1 encephalopathy, enhancing viral replication by activated microglia and damaging oligodendrocytes. Thus, TNF-alpha inhibitors may alleviate some of the neurological manifestations of acquired immunodeficiency syndrome.
Fibrosis can be an undesired consequence of activated cellular immune responses. The purpose of this work was to determine whether CD40 ligation and the pro-fibrotic cytokine IL-4 interact in regulating fibroblast proliferation and collagen production, and, if so, the mechanisms used. This study found that the combination of IL-4 and ligation of CD40 on the fibroblast cell surface had synergistic effects in stimulating fibroblast proliferation. In contrast, CD40 ligation negated the inhibitory effects of IFN-γ on fibroblast proliferation. Western blotting analyses of fibroblast crude lysates revealed that a potential mechanism of the synergy between CD40 ligation and IL-4 was the phosphorylation of proteins at 130 kDa and, to a lesser degree, at 95, 85, and 75 kDa. Immunoprecipitation-Western blotting experiments showed that phosphorylation levels of IL-4Rα, Janus kinase 1, insulin receptor substrate 1, and insulin receptor substrate 2, factors with molecular mass close to the observed 130 kDa major phosphorylation band, increased in response to the combined CD40 ligation and IL-4 action. In contrast, there was no evidence that synergy was mediated by an increased expression of IL-4Rα chain, CD40, or the autocrine profibrotic cytokines IL-6 and TGF-β. These findings suggest that CD40-CD40 ligand contacts between fibroblasts and cells secreting IL-4 may promote the profibrotic effects of IL-4 by affecting signal transduction and reducing the anti-fibrotic effects of IFN-γ.
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