Michael R. DiNapoli scite author profile

SummaryNitric oxide (NO) is a major effector molecule in the destruction of tumor cells by activated macrophages. However, in many cases, developing neoplasms appear to be capable of impairing steps in the complex process leading to NO production as a means of avoiding immune destruction. After activation with lipopolysaccharide (LPS), peritoneal-ehcited macrophages (PEM) from mice bearing mammary tumors display alterations in their ability to lyse tumor cells due to reduced production of NO. In contrast, when these same cells are stimulated with LPS in combination with interferon ~/(IFN-~/), they are able to produce NO and lyse targets at normal levels. Since tumor-associated macrophages are intimately associated with the cells of the developing tumor, their ability to produce NO and lyse tumor targets is likely to be more relevant to controlling tumor growth. This population of macrophages exhibited a more profound inability to produce NO and lyse targets and, unlike the PEM, was not able to upregulate these functions even when treated with combinations of LPS and IFN-~. Northern and Western blots revealed that inducible nitric oxide synthase (iNOS) mRNA and protein levels correlated directly with the ability of each macrophage population to produce NO, and the levels of these macromolecules were altered sufficiently in tumor bearers' macrophages to account for the diminished NO production described. These results indicate that a spatial gradient of suppression of macrophage cytolytic activity and iNOS expression exists in mammary tumor-bearing mice, whereby macrophages from within the tumor exhibit a more pronounced suppression than the more distally located PEM. This suppression may be due to proximity of the macrophages to the developing tumor, macrophage maturational state, or both.

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Decreased macrophage‐mediated cytotoxicity in mammary‐tumor‐bearing mice is related to alteration of nitric‐oxide production and/or release

Sotomayor

DiNapoli

Calderon

et al. 1995

Intl Journal of Cancer

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Peritoneal-exudate macrophages (PEM) from mammary-tumor-bearing mice have impaired cytotoxic activity against syngeneic and allogeneic tumor targets. The ability of PEM from normal and tumor-bearing mice to bind tumor targets was found to be similar in the presence or the absence of surrogate receptors, which enhanced the binding but not the killing of tumor targets by PEM from tumor-bearing mice, suggesting that other mechanisms are involved in their impaired cytolytic activity. Soluble and membrane-bound TNF-alpha, as well as H2O2, were found in higher amounts in PEM from tumor bearers upon stimulation with LPS, as compared with PEM from normal mice. However, tumor-bearers' macrophages displayed decreased capacity to produce and/or release nitric oxide, which could be reversed by the addition of increasing levels of IFN-gamma. These results indicate that the lack of macrophage cytotoxicity in mammary-tumor-bearing mice is related to impaired production and/or release of NO by these effector cells, possibly aggravated by the insufficient IFN-gamma production previously reported in these animals. Moreover, mammary-tumor progression results in dis-regulation of synthesis of macrophage-mediators, with over-production of molecules to which mammary-tumor cells are insensitive and deficient production of NO, the crucial molecule to which these cells appear to be highly sensitive.

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Involvement of protein kinase C and not of NFκB in the modulation of macrophage nitric oxide synthase by tumor-derived phosphatidyl serine

et al. 2008

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Nitric oxide (NO) is one of the main cytotoxic effector molecules involved in the killing of tumor cells by macrophages. In macrophages, lipopolysaccharide (LPS) alone or in combination with IFN-γ causes the generation of NO by an inducible form of NO synthase (iNOS). We have previously reported that macrophages from mammary tumor bearers have a downregulation of their NO production leading to a diminished cytotoxic activity. Further studies lead to the isolation and characterization of phosphatidyl serine (PS) as a NO inhibitory factor produced by mammary tumor cells. Pretreatment of macrophages with PS was shown to downregulate their cytotoxic potential and NO production upon stimulation with LPS. Activation of PS-pretreated macrophages with LPS and IFN-γ resulted in higher levels of NO than those observed with LPS alone, but lower than those of untreated macrophages activated with LPS and IFN-γ. These results correlated with the levels of iNOS RNA as detected by Northern blot analyses. A study of the expression and binding activity of the transcription factor NFκB in macrophages pretreated with PS revealed no differences with untreated macrophages. Investigation of the possible signaling pathways leading to the induction of iNOS revealed that in LPS-stimulated macrophages, increases in internal calcium concentration [Ca 2+ ]i were not observed, while NO was normally produced even under calcium-deprived conditions. In contrast, an effective synergism of IFN-γ with LPS in the production of NO by macrophages required an optimal increase in [Ca 2+ ]i stimulated by IFN-γ. This increment in [Ca 2+ ]i was significantly reduced in PS-pretreated macrophages. Further experiments demonstrated that pretreatment of macrophages with PS did not change the normal pattern of tyrosine phosphorylation stimulated by LPS but strikingly inhibited PKC activity. Combinations of LPS and IFN-γ did not alter the latter result, suggesting that IFN-γ enhances LPS-induction of iNOS through a pathway other than activation of PKC. Importantly, expression of PKC isozymes in both untreated and PS-pretreated macrophages stimulated with LPS remained constant. Out data suggest that, in tumor bearers, PKC and not NFκB is the main target for PS to exert its NO inhibitory action on LPS-activated macrophages. An excess of PS in PS-PKC interaction may be responsible, at least in part, for this type of PKC inhibition. Furthermore, PS also appears to downregulate the rise in [Ca 2+ ]i promoted by IFN-γ in macrophages, reducing the synergism of this cytokine with LPS and leading to a less effective production of NO.

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Phosphatidyl serine is involved in the reduced rate of transcription of the inducible nitric oxide synthase gene in macrophages from tumor-bearing mice.

DiNapoli

Calderon

López

1997

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Upon stimulation with LPS, peritoneal-elicited macrophages (PEM) from mammary tumor-bearing mice display a diminished ability to produce nitric oxide (NO) and lyse tumor targets. In contrast, when these cells are stimulated with LPS in combination with IFN-gamma, they perform these functions at normal levels. Kinetic studies revealed that these defects became more pronounced with tumor progression and were accompanied by similar changes in inducible nitric oxide synthase (iNOS) mRNA levels. Since this tumor is known to produce PGE2, granulocyte-macrophage CSF (GM-CSF), and phosphatidyl serine, we evaluated the effects of these products on NO production and cytolytic activity. Pretreatment of normal PEM with PGE2 or recombinant GM-CSF had negligible effects on NO production and cytolytic capacity. In contrast, phosphatidyl serine caused a concentration-dependent inhibition of these functions in response to LPS, which could be partially overcome by the addition of IFN-gamma. Moreover, iNOS mRNA levels paralleled these changes and were analogous to the alterations observed in the tumor-bearers' PEM. iNOS mRNA stability was not reduced in these cells; however, the rate of transcription was diminished relative to normal levels, suggesting that the defects causing these alterations are occurring at or before the level of iNOS transcription. These data implicate tumor-derived phosphatidyl serine in the alterations observed in tumor-bearers' macrophages and suggest that reduced iNOS transcription is responsible for the diminished capacity of these macrophages to produce NO and lyse tumor targets.

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