Stimulates Macrophage Activation Research Articles

The role of TNFα and lymphotoxin in demyelinating disease

Multiple sclerosis (MS) is an inflammatory demyelinating disease of central nervous system (CNS) white matter.1 The aetiology is unknown but the condition is probably the result of a misdirected immune...

Induction of a prenylated 65-kd protein in macrophages by interferon or lipopolysaccharide

Treatment of murine bone marrow-derived macrophages with interferon-gamma (IFN-gamma) and/or lipopolysaccharide (LPS) resulted in changes in the abundance of a number of prenylated proteins. The most significant change involved a protein of 65 kd (p65) that became one of the most abundant prenylated proteins following treatment. The 65-kd protein was induced by agents that stimulate macrophage activation (IFNs or LPS) but not by cytokines that promote macrophage proliferation, such as granulocyte-macrophage colony-stimulating factor (GM-CSF), M-CSF, or interleukin-3. The majority of p65 was localized to subcellular fractions containing internal and plasma membranes but was not detected in nuclear membranes. The farnesyltransferase inhibitor BZA-5B caused a dramatic decrease in p65 prenylation, suggesting that this protein may be modified by the C15 isoprenoid farnesyl. These observations provide the first direct evidence that interferons and LPS cause changes in the abundance of specific isoprenoid-modified proteins in macrophages.

Effect of PGE2 and of agents that raise cAMP levels on macrophage activation induced by IFN-gamma and TNF-alpha.

The effect of prostaglandin (PG) E2 on macrophage activation by interferon-gamma (IFN-gamma) and tumor necrosis factor-alpha (TNF-alpha) was evaluated. Murine macrophages infected with Leishmania enriettii or Leishmania major were activated by exposure to IFN-gamma (10-50 U/ml) and TNF-alpha (30-3000 U/ml), leading to intracellular parasite destruction within 24-48 h. Leishmanicidal activity was markedly increased when activation was performed in the presence of PGE2 (10(-9)-10(-7) M) or arachidonate (10(-5) M, a PG precursor), concomitant with enhanced nitrite release and glucose oxidation through the hexose monophosphate shunt pathway. Conversely, activation was reduced by indomethacin and hydrocortisone, two inhibitors of PG synthesis. Parasite killing and nitrite production were fully restored by exogenous PGE2, indicating that inhibition by these drugs was related to their ability to block PG production. PG can stimulate adenylate cyclase, thus raising intracellular cAMP levels. Accordingly, dibutyryl-cAMP, theophylline (which prevents cAMP breakdown), and forskolin (an activator of adenylate cyclase) all stimulated macrophage activation. Finally, PGE2 and cAMP enhanced expression of inducible nitric oxide synthase mRNA in response to IFN-gamma and TNF-alpha, and this effect was inhibited by the cAMP antagonist 2'-O-methyl adenosine. These findings are consistent with the hypothesis that PGE2 acts as a positive agonist in macrophage activation by IFN-gamma and TNF-alpha via its capacity to modulate intracellular cAMP levels.

Binding of bacterial endotoxins to the macrophage surface: visualization by fracture-flip and immunocytochemistry.

Endotoxins (lipopolysaccharides, LPS) are surface components of gram-negative bacteria that stimulate macrophage activation and cause endotoxic shock. How LPS is recognized by host cells is still an open question, but it is generally accepted that many effects of endotoxins follow the overproduction of cytokines by macrophages. In the present study, we used fracture-flip and immunolabeling to study the morphology of isolated commercial LPS (C-LPS), the endotoxin release from the bacterial wall in presence of serum (S-LPS), and the distribution of these two endotoxins on the macrophage surface. Cells treated with C-LPS exhibited large LPS aggregates bound to smooth and particulate areas of the membrane and to microvilli. In contrast, macrophages incubated with S-LPS showed a uniform monodispersed labeling over the free surface of the membrane. Our results show that fracture-flip provides high-resolution images of the binding of ligands to the cell surface. They also suggest the importance of using highly dispersed LPS suspensions when the mechanisms of cell activation and damage by endotoxins are studied.

Recognition and plasma clearance of endotoxin by scavenger receptors

Lipid A is the active moiety of lipopolysaccharide (LPS, also referred to as endotoxin), a surface component of Gram-negative bacteria that stimulates macrophage activation and causes endotoxic shock. Macrophages can bind, internalize and partially degrade LPS, lipid A and its bioactive precursor, lipid IVA. We report here that lipid IVA binding and subsequent metabolism to a less active form by macrophage-like RAW 264.7 cells is mediated by the macrophage scavenger receptor. Scavenger-receptor ligands inhibit lipid IVA binding to, and metabolism by, RAW cells, and lipid IVA binds to type I and type II bovine scavenger receptors on transfected Chinese hamster ovary cells. Although in vitro competition studies with RAW cells indicate that scavenger receptor binding is not involved in LPS or lipid IVA-induced stimulation of macrophages, in vivo studies show that scavenger-receptor ligands greatly inhibit hepatic uptake of lipid IVA in mice. Thus, scavenger receptors expressed on macrophages may have an important role in the clearance and detoxification of endotoxin in animals.

Interaction between macrophages and Schistosoma mansoni schistosomula: Role of IgG peptides and aggregates on the modulation of β-glucuronidase release and the cytotoxicity against schistosomula

Discharge of lysosomal enzymes, measured by release of β-glucuronidase and cytotoxicity against Schistosoma mansoni schistosomula, was studied when rat macrophages were incubated in the presence of either IgG peptides, resulting from the cleavage of nonimmune IgG by parasitic proteases, or nonimmune aggregated IgG. With peptides, the macrophage activity showed a dramatic decrease while they were stimulated by IgG aggregates. In contrast, the synthesis of lymphocyte activating factor by macrophages was unaffected. The hydrolysis of IgG is carried out by two distinct enzymatic molecules released into the medium by the larvae. The mechanism by which nonimmune IgG peptides or aggregates inhibit or stimulate macrophage activity, regulated by both parameters indicated above, is discussed and is suggested as a general regulation mechanism for the macrophage activity required for parasite survival in the host.

Modification of the effect of C. parvum on macrophage activity and tumour growth by X-irradiation.

The radiosensitivity of three forms of response to injection of C. parvum in mice has been investigated. The increase in phagocytin index evoked by IP or IV injection of 0.7 mg C. parvum (but not that evoked by 1.4 mg) was reduced but not abolished in mice given 350-500 rad whole-body irradiation 4 days before C. parvum injection. Irradiation (500-1,000 rad) 4 days after C. parvum injection had no such effect. The antitumour cytotoxicity in vitro of PE and spleen cells from C. parvum-treated mice was abolished by irradiation of the cell donor (400-800 rad) 4 days before C. parvum injection, but was not reduced by irradiation (800 rad) of the cell donor 4 days after C. parvum injection or of the effector cells in vitro. The antitumour response to systemic (IP) injection of C. parvum was reduced by 350-500 rad whole-body irradiation, irrespective of whether this was given 4 days before or 4 days after C. parvum injection. The response to intratumour injection of C. parvum was even more radiosensitive. It has been suggested in previous papers from this laboratory that the antitumour effect of C. parvum is related to its capacity to stimulate macrophage activity, although in addition T lymphocytes are necessary for local injection to be effective and non-T lymphocytes may be concerned in the response to both local and systemic injection. The present results in no way conflict with this view. They suggest in addition that the effect of C. parvum on the macrophage system is, to a considerable extent, due to stimulation of macrophage precursors to differentiate into actively phagocytic and cytotoxic mature cells.