Jacques Mauël

The in vitro cytotoxic effect of spleen cells of mice immunized by tumour allografts was studied by measuring target cell inactivation as a function of release of radioactive label ((51)Cr) or loss of cloning efficiency. When sensitized lymphoid cells were incubated with target cells at a ratio of 100:1, up to 90 per cent of the incorporated label was released within 6–9 hours, while the number of clone-forming cells was reduced by up to 99 per cent in the same time period. Isoantiserum from the graft recipients, as well as its 19S and 7S fractions, protected target cells against the toxic effect of the spleen cells, but a lipoprotein antigen isolated from the tumour cells failed to inhibit the cytotoxic reaction. Target cell lysis as measured by specific release of (51)Cr was partially inhibited by actinomycin-D and by cycloheximide at concentrations which effectively blocked DNA-dependent RNA and protein synthesis.

Cellular immunity induced by tumour allografts in inbred mice was studied with the help of an in vitro assay system measuring the cytotoxic effect of sensitized lymphocytes on (51)Cr-labelled target cells. It is shown that lymphoid cells from spleen, lymph nodes and blood of the allograft recipients reach a peak of cytotoxic activity on days 10–11 after immunization. Incubated with labelled target cells at a ratio of 100:1, the sensitized lymphocytes caused the specific release of up to 70 per cent of the radioactivity within 1 hour. A second population of target cells added to the same cell suspension was destroyed at a slightly accelerated rate, suggesting stimulation of the effector cells by the first interaction. The cytotoxic activity of circulating lymphocytes was found to reach a plateau between days 20 and 60 after immunization, while the activity of spleen cells dropped to low levels in the same time period. The specificity of target cell destruction by sensitized lymphocytes is demonstrated by the lack of lytic activity for syngeneic target cells, and by the selective destruction of target cells carrying a tumour specific antigen. Tumour cells, lymphocytes and embryonic fibroblasts of the donor strain are shown to differ considerably in their sensitivity to lysis by immune lymphocytes.

CD69, also known as activation inducer molecule, very early activation antigen, MLR-3 and Leu-23, is a member of the natural killer (NK) cell gene complex family of signal transducing receptors. CD69 is as a type II transmembrane glycoprotein with a C-type lectin binding domain in the extracellular portion of the molecule. CD69 expression is induced in vitro on cells of most hematopoietic lineages, including T and B lymphocytes, NK cells, murine macrophages, neutrophils and eosinophils, while it is constitutively expressed on human monocytes, platelets and epidermal Langerhans cells. Although a specific ligand for CD69 has not been identified, its wide cellular distribution and the induction of intracellular signals upon CD69 crosslinking suggest a role for the receptor in the biology of hematopoietic cells. Moreover, certain results indicate that CD69 may be involved in the pathogenesis of such diseases as rheumatoid arthritis, chronic inflammatory liver diseases, mild asthma, and acquired immunodeficiency syndrome.

Nitric oxide (NO) is a short-lived diffusable molecule now believed to participate in multiple physiologic functions in the CNS including neurotransmission and the maintenance of vascular tone. Previously, we reported that cell lines obtained by retroviral immortalization of tissue macrophages (M phi) could be induced to synthesize nitrite (NO2-), a stable end product of the NO synthetic pathway. We have further characterized the induction and activity of this pathway in a panel of seven microglial clones derived from primary embryonic mouse brain cultures. Like M phi, these clones were found to release high levels of NO2- in response to recombinant interferon-gamma (rIFN-gamma) as a priming signal together with either bacterial lipopolysaccharide (LPS) or exogenous recombinant tumor necrosis factor-alpha (rTNF-alpha). As previously demonstrated for M phi, phagocytosis of zymosan particles during induction of enzyme activity enhanced subsequent NO2- production, which is of interest in light of the postulated phagocytic role of microglia within the CNS. Biochemical characterization of enzyme activity in intact microglial clones and in isolated cytosolic fractions indicates that the microglial NO synthase present in these murine cell clones represents the M phi-like isotype. These findings suggest that microglial cells could represent a major source of NO within the CNS.

The experiments described in this report were aimed at determining whether L-arginine (L-arg)-derived nitrogen oxidation products (nitric oxide, nitrous acid, nitrites) are involved in the intracellular killing of Leishmania parasites by activated murine macrophages in vitro. Peritoneal or bone marrow-derived macrophages were infected with L. enriettii or L. major, then activated by exposure to recombinant murine interferon-gamma or to macrophage activating factor (MAF)-rich media in the presence of lipopolysaccharide. Activation of macrophages in regular (i.e., arginine-containing) culture medium led to complete destruction of the microorganisms within 24 h (L. enriettii) or 48 h (L. major), concomitant with accumulation of nitrites (NO2-) in the culture fluids. When macrophage activation was carried out in L-arg-free medium, however, neither parasite killing nor NO2- production was obtained. A similar inhibition of macrophage leishmanicidal activity and of NO2- release was observed using media treated with arginase (which converts L-arg to urea and ornithine), or supplemented with NG-monomethyl-L-arg or guanidine (which inhibit the conversion of L-arg to nitrogen oxidation products). In all these situations, an excellent correlation between the levels of NO2- production by macrophages and intracellular killing of Leishmania was observed, whereas no strict correlation was detectable between leishmanicidal activity and superoxide production. Intracellular parasite killing by activated macrophages could be prevented by addition of iron salts to the incubation fluids. Incubation of free parasites with NaNO2 at acid pH (which permits the production of nitrous acid) led to immobilisation, multiplication arrest, and morphological degeneration of the microorganisms. Similarly, exposure of infected cells to NaNO2 led to killing of the intracellular parasite without affecting macrophage viability. These experiments strongly suggest that the leishmanicidal effect of activated murine macrophages involves the agency of L-arg-derived nitrogen oxidation products.