Serum amyloid P-component-induced enhancement of macrophage listericidal activity.

Purified serum amyloid P component (SAP), the major acute-phase reactant of mice, augmented the in vitro listericidal activity of inflammatory (elicited) macrophages, bone marrow-derived monocytes, and macrophages from a subcutaneous site of inflammation. Monocytes and macrophages from C57BL/B6 mice, which are relatively resistant to Listeria monocytogenes, exhibited a significantly greater enhanced killing capacity for listeria than macrophages from listeria-susceptible A/J mice. SAP did not alter the extent of phagocytosis by macrophages of opsonized L. monocytogenes, nor was SAP opsonic for listeria. Mannose-derived simple sugars inhibited the binding of SAP to macrophages and consequently prevented the enhanced SAP-dependent listericidal activity. Macrophages from lipopolysaccharide-hyporesponsive mice also had increased microbicidal activity following incubation with SAP. SAP activated macrophages independently of lymphokine. Therefore, SAP may serve as a mediator of the heightened nonspecific host defense response that is associated with the acute phase of the systemic inflammatory response.     

The relative difference in anti-Listeria resistance of C57BL/6 and A/J mice is not eliminated by active immunization or by transfer of Listeria-immune T cells.

In this study, we examined the effects of active and adoptive immunization on the anti-Listeria resistance of innately resistant C57BL/6 and innately susceptible A/J mice. Although active immunization with a sublethal dose of viable Listeria monocytogenes markedly enhanced the anti-Listeria resistance of both C57BL/6 and A/J mice, the 100-fold difference between the two strains in innate anti-Listeria resistance was not diminished. Following immunization with an equivalent sublethal dose (0.1 LD50) of L. monocytogenes, both C57BL/6 and A/J mice generated T cells that could transfer significant and comparable protection to syngeneic recipients that were challenged with up to a 10 LD50 dose of L. monocytogenes. When the absolute number of viable Listeria was compared, however, it was clear that T cells from immunized C57BL/6 mice were capable of transferring protection to syngeneic recipients at Listeria challenge doses that were more than 100-fold greater than could T cells from Listeria-immunized A/J mice. Both active immunization and adoptive transfer of syngeneic Listeria-immune T cells enhanced the accumulation of inflammatory neutrophils and macrophages in C57BL/6 and A/J mice. More inflammatory neutrophils were recovered from actively immunized C57BL/6 than from A/J mice, whereas more inflammatory macrophages were obtained from adoptively immunized C57BL/6 than from A/J mice. These results provide further evidence for the beneficial role of inflammation in genetically determined innate resistance and T-cell mediated resistance to listeriosis. These data also suggest that some mechanism in addition to inflammatory responsiveness may be responsible for limiting the expression of acquired anti-Listeria resistance in genetically susceptible A/J mice.     

Genetically determined resistance to listeriosis is associated with increased accumulation of inflammatory neutrophils and macrophages which have enhanced listericidal activity.

The C57BL/6 and A/J inbred strains of mice differ markedly in their resistance to the facultative intracellular bacterium Listeria monocytogenes. One possible explanation for this genetically determined resistance is that phagocytes from Listeria-resistant strains of mice can kill L. monocytogenes more effectively than phagocytes from Listeria-susceptible strains of mice. We report here that inflammatory neutrophils and macrophages from Listeria-resistant mice (C57BL/6) exhibit a slight but significantly enhanced ability to kill L. monocytogenes in vitro as compared to inflammatory phagocytes from Listeria-susceptible mice (A/J). More importantly, however, Listeria-resistant mice recruited more inflammatory neutrophils and macrophages to the peritoneal cavity in response to i.p. injection of heat-killed Listeria than did Listeria-susceptible mice. These data suggest that genetically determined resistance to listeriosis is dependent on the enhanced inflammatory responsiveness of Listeria-resistant mice. Further support for this hypothesis was provided by experiments in which the passive transfer to A/J mice (C5-deficient) of plasma from C57BL/6 mice (C5-sufficient) enhanced the ability of the recipient A/J mice both to recruit inflammatory neutrophils to the peritoneal cavity in response to i.p. injection of heat-killed Listeria, and to clear L. monocytogenes from the spleen after a sublethal challenge of viable Listeria.     

Genetic control of murine listeriosis expressed in the macrophage response

Susceptibility to murine listeriosis is genetically regulated. For example, A/J, C3H, CBA, DBA/1, DBA/2 and 129/J mouse strains are classed as susceptible and demonstrate an early net bacterial growth rate which is significantly higher than that seen in strains classed as resistant, namely, C57BL-derived strains, NZB and SJL. These strain differences in susceptibility are expressed during the phase of natural resistance, as a property of the macrophage response. Genetic analysis in progeny derived from resistant C57BL-derived strains and susceptible A/J or BALB/c strain mice has indicated that a major gene is responsible for determining resistance/susceptibility to listeria. The genetic advantage of the resistant phenotype is attributed to a prompt influx of young (radiosensitive) inflammatory macrophages which control the early bacterial multiplication in infective sites. Such cells reportedly have superior listericidal activity in vitro, as compared to mature macrophages. Mononuclear phagocyte production, emigration and accumulation at infective foci are all increased in resistant C57BL, but not in susceptible A/J mice, shortly following infection. Thus, resistance to listeriosis is associated with an efficient macrophage inflammatory response and, conversely, susceptibility is attributed to a sluggish response. Genetic studies have demonstrated linkage between these two traits (listeria resistance/susceptibility and the macrophage inflammatory response). In all probability, different gene loci are responsible for susceptibility amongst the various mouse strains. In A/J mice, susceptibility is attributed to C5 deficiency (specified by Hc locus) while, for C5-sufficient strains, another genetic defect is presumably responsible.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic control of natural resistance in mouse macrophages regulating intracellular Legionella pneumophila multiplication in vitro.

It is known that Legionella pneumophila proliferates in peritoneal macrophage cultures derived from A/J mice but not in macrophage cultures derived from many other strains, including C57BL/6 mice. To analyze the genetic control of this trait and the location of the Legionella resistance-susceptibility gene, we prepared segregating progeny of A/J and C57BL/6 mice and determined the levels of susceptibility of individual mice. Peritoneal macrophages were collected by injecting thioglycolate medium, and macrophage monolayers were infected in vitro with L. pneumophila Philadelphia-1. Counting of colonies on buffered charcoal yeast extract agar plates and Gimenez staining of macrophage monolayers were carried out daily. There was a 10-fold increase in bacterial burden 1 day after infection and a 100-fold increase after 2 days in A/J (susceptible) macrophages. The increase in bacterial burden was always less than 10-fold in macrophages from C57BL/6 (resistant) progenitors, A/J x C57BL/6 F1 hybrids, and C57BL/6 x F1 backcross progeny. The ratios of resistant individuals to susceptible individuals were 22:6 for F2 progeny and 20:22 for A/J x F1 backcross progeny. The fact that the organism did not proliferate in macrophages from B10.A mice demonstrated that major histocompatibility antigens did not regulate the macrophage resistance of C57BL/6-derived mice. The sex and coat color genes of mice were not linked to the resistance-susceptibility gene. We suggest that resistance and susceptibility are controlled by a single gene or closely linked genes which are autosomal and that the resistance allele is dominant. The results of a comparison of the strain distribution pattern of this trait with the distribution pattern of 185 allelic markers in A/J x C57BL/6 and C57BL/6 x A/J recombinant inbred strains suggest that this susceptibility-resistance gene is located in the proximal part of chromosome 15.     

Activation of non-specific cytotoxic cells in Listeria-susceptible and -resistant mouse strains.

An increase in macrophage tumouricidal activity in the spleen was demonstrated following intravenous infection of genetically resistant C57BL/10 mice with Listeria monocytogenes, but not after infection of BALB/c mice. However, tumouricidal macrophages appeared in the peritoneal cavity of both strains after infection, while NK cell activity was generally higher in BALB/c mice. The activation of tumouricidal macrophages and NK cells in the C57BL/B10 mice was T independent and, at least in the peritoneal cavity, radioresistant (600 rads). The relevance of these results to the genetic control of resistance to Listeria is discussed.     

Killing of Listeria monocytogenes by inflammatory neutrophils and mononuclear phagocytes from immune and nonimmune mice

Acquired resistance to the facultative intracellular bacterium Listeria monocytogenes is thought to require immunologically activated macrophages. Using peritoneal exudate cells from nonimmunized mice in a suspension bactericidal assay, however, we found that peritoneal neutrophils obtained early during the inflammatory process (4 hr after elicitation) and macrophages obtained later during inflammation (maximal listericidal activity at 48 hr after elicitation) were able to kill Listeria in vitro. The kinetics of expression of bactericidal activity by inflammatory neutrophils and macrophages against both L monocytogenes and E coli were similar. Although intraperitoneal immunization or intravenous hyperimmunization markedly enhanced resistance of mice to Listeria in vivo, immunization did not increase the ability of inflammatory peritoneal phagocytes to kill Listeria in vitro. However, in response to intraperitoneal injection of proteose-peptone or dead Listeria, immunized mice mobilized more neutrophils and monocytes into the inflamed peritoneum. These data suggest that, rather than systemic activation of mononuclear phagocyte bactericidal activity, increased mobilization of neutrophils and mononuclear phagocytes into sites of infection may be of prime importance in resistance to listeriosis.     

Macrophage activation during Plasmodium chabaudi AS infection in resistant C57BL/6 and susceptible A/J mice.

Macrophage activation was examined in resistant C57BL/6 and susceptible A/J mice during the course of blood-stage infection with Plasmodium chabaudi AS. Three parameters of macrophage activation (lipopolysaccharide [LPS]- and malaria antigen-induced tumor necrosis factor [TNF] production in vitro, phorbol myristate acetate [PMA]-induced production of oxygen metabolites in vitro, and Ia antigen expression) were assessed during infection in populations of peritoneal and splenic macrophages recovered from infected mice of the two strains. The peak level of LPS-induced TNF production in vitro by splenic macrophages from both infected C57BL/6 and infected A/J mice occurred on day 7, which was 3 days before the peak of parasitemia. Although the kinetics of TNF production in vitro in response to either LPS, soluble malaria antigen, or intact parasitized erythrocytes varied in some of the other macrophage populations during infection, there was no significant difference in the peak level of production. Peritoneal and splenic macrophages from infected C57BL/6 mice exhibited significantly increased PMA-induced production of H2O2 in vitro on day 7. Peritoneal macrophages from infected A/J mice also exhibited significant PMA-induced H2O2 production on day 7, while production by splenic macrophages from these hosts was not increased in comparison with production by cells from normal animals. Only peritoneal macrophages from infected C57BL/6 mice produced significantly increased levels of O2-, and this occurred on day 7 postinfection. Ia antigen expression by both peritoneal and splenic macrophages from resistant C57BL/6 and susceptible A/J mice was significantly increased during P. chabaudi AS infection. However, the percentage of Ia+ peritoneal macrophages on days 8 and 10 postinfection and Ia+ splenic macrophages on day 3 postinfection was significantly higher in C57BL/6 than in A/J mice. Thus, these results demonstrate that macrophages from P. chabaudi AS-infected A/J mice exhibit defects in oxygen metabolism and Ia antigen expression which may contribute to the susceptibility of these hosts to this intraerythrocytic parasite. The cause-and-effect relationship between these defects and the susceptibility of A/J mice to P. chabaudi AS is unknown.     

Susceptibilities of macrophage populations to infection in vitro by Leishmania donovani.

Many studies have demonstrated differences in the resistance of strains of mice to infection by Leishmania donovani, Salmonella typhimurium, and Mycobacterium bovis BCG; this resistance/susceptibility phenotype seems to be controlled by a single gene. The present study investigated the susceptibility of liver, lung, peritoneal, and spleen macrophages to infection by L. donovani promastigotes in vitro; the objective was to determine if the susceptibility of animals was expressed by their macrophages when infected in vitro. This study indicated that the Lsh phenotype was only expressed by liver macrophages. The liver macrophages of the susceptible C57BL/6J strain were significantly more phagocytic than those of the resistant C57L/J strain; infection affected the phagocytic activity of the macrophage population. These results indicated that only liver macrophages can express the Lsh gene. Recognition of expression is in part due to its effect on the phagocytic activity of the macrophages.     

Effects of gonadotrophin on resistance to Listeria monocytogenes infection in mice.

It was demonstrated that exogenous GH suppressed the resistance to L. monocytogenes infection in Listeria resistant C57Bl/6 and susceptible A/J mice. However, different parameters of the immunological reaction to Listeria were affected by GH treatment in these mouse strains. In C57Bl/6 mice GH decreased accumulation of macrophages at the inflammatory site. On the contrary, a depression of anti-listerial activity of the phagocytes and a reduction of DTH reaction to Listeria antigen was demonstrated in GH treated A/J mice.     

Colony-stimulating factors increase resistance to atypical mycobacteria in resistant mice, whereas they decrease resistance in susceptible strains of mice

Inbred strains of mice, notably the susceptible C57BL/6 and the resistant A/J strains of mice, were infected with a strain of Mycobacterium evium. The infection in the visceral organs of mice was then studied, and the effect of colony-stimulating factors, i.e., interleukin-3 (IL-3), granulocyte-macrophage colony-stimulating factor (GM-CSF), and macrophage colony-stimulating factor (CSF-1) on the infectious process was evaluated. Infusion of GM-CSF, CSF-1, and IL-3 led to a significant, albeit rather modest, increase in the mycobacterial resistance of A/J mice, as seen by a decrease in the number of colony-forming units (CFU) in the organs. Conversely, these CSFs dramatically increased the susceptibility of C57BL/6 mice, as seen by increased bacterial numbers in the spleens and livers. In vitro studies demonstrated that resident peritoneal macrophages from susceptible mice were more permissive than cells from resistant mice for mycobacterial growth. Application of CSFs on peritoneal macrophage monolayers led to an increased growth in both A/J and C57BL/6 monolayers for IL-3 and CSF-1 and a small microbiostatic effect for GM-CSF. Cytokine treatment did not, however, change the resistance/susceptibility phenotype of isolated macrophages. Our results indicate that CSFs may exert beneficial or detrimental effects on resistance to mycobacteria depending on the host genetic make up.     

Intravenous injection of interferon-gamma inhibits the proliferation of Listeria monocytogenes in the liver but not in the spleen and peritoneal cavity.

In the present study the effects of intravenous administration of recombinant interferon-gamma (IFN-gamma) on both the proliferation of Listeria monocytogenes in the liver and spleen of mice and the listericidal activity of their peritoneal macrophages were investigated. A single intravenous injection of 1 x 10(6) U or three injections of 2 x 10(5) U recombinant IFN-gamma (rIFN-gamma) induced optimal activation of resident and exudate peritoneal macrophages, as judged by their ability to inhibit the intracellular proliferation of Toxoplasma gondii and their enhanced release of H2O2 and NO2-. The rate of intracellular killing of L. monocytogenes by the rIFN-gamma-activated resident and exudate macrophages was not higher than that by resident macrophages. Addition of 10 ng lipopolysaccharides (LPS) to the rIFN-gamma also did not enhance the bactericidal activity of the activated peritoneal macrophages. The decrease in the number of L. monocytogenes in the peritoneal cavity of mice that had received an i.p. injection of 1 x 10(4) U rIFN-gamma was similar to that in control mice. Intravenous administration of 1 x 10(5) rIFN-gamma activated cells in the liver, as indicated by the increased expression of Ia antigen, and reduced the rate of proliferation of L. monocytogenes in the liver relative to that in control mice when 0.1 LD50 or 1 LD50 L. monocytogenes were injected. However, when 10 LD50 L. monocytogenes were administered there was no effect on their proliferation. The number of L. monocytogenes found initially in the spleen of rIFN-gamma-treated mice was 20-30% of that in the spleen of control mice, but the rate of proliferation of L. monocytogenes was not reduced. These divergent results for the proliferation of L. monocytogenes in the liver, spleen and peritoneal cavity indicate that cells other than macrophages and/or as yet unknown local factors play an important role in the listericidal activity.     

Complement and immunity to viruses

Summary: It is not known why some macrophages can kill certain microbes, such as the facultative intracellular bacterium Listeria monocytogenes (L. monocytogenes), while other macrophages cannot. Perhaps listericidal activity is a property of macrophages at specific stages of differentiation; maybe the ability to kill this bacterium is regulated by the microenvironment of the cell; or it is possible that other regulatory forces are important. We describe here three characteristics that distinguish macrophages which can kill I. monocytogenes from those which cannot. First, listericidal macrophages must have neither too much nor too little intracellular iron - they must have an intermediate amount. Second, the receptor a macrophage uses to phagocytose L. monocytogenes seems to influence the intracellular fate of this bacterium. And third, macrophages which have cell-surface interleukin-10 (IL-10), a known down regulator of macrophage function, can-not kill L. monocytogenes. These trails of macrophages and their effects on listericidal activity are reviewed here, and the possibility that these properties might interact to control macrophage bactericidal activity is discussed.     

Macrophage activity in resistant and susceptible mouse strains infected with Mycobacterium lepraemurium.

The level of activation of peritoneal macrophages following subcutaneous inoculation of resistant (C57BL) and susceptible (BALB/c) mice was assessed by monitoring superoxide anion and hydrogen peroxide production and also tumour cell cytostasis. The level of systemic macrophage activation appeared to correlate with bacterial load, rather than resistance to infection. It was observed that the more susceptible (BALB/c) strain developed higher and more sustained levels of systemic macrophage activation, whereas the more resistant (C57BL) strain showed only low transient levels of macrophage activation. In contrast, in vivo challenge of subcutaneously infected C57BL mice, via the intra-peritoneal route, with heat-killed Mycobacterium lepraemurium and thioglycollate resulted in a high level of macrophage activation compared with similarly treated uninfected mice. Similar treatment of susceptible BALB/c mice, however, did not result in enhanced macrophage activation. It was also observed that high levels of macrophage activation occurred in T-cell deprived C57BL mice following infection with M. lepraemurium.     

Mechanism of the bactericidal action of myeloperoxidase: increased permeability of the Escherichia coli cell envelope.

A sensitive and highly reproducible assay was utilized to study in vitro interactions of Listeria monocytogenes with resident and activated macrophages. The technique is not compromised by extracellular events and can readily differentiate between the efficiency of ingestion and the postphagocytic fate of bacteria. Heat-labile factors in human or homologous serum markedly enhanced the phagocytosis of Listeria without noticeably affecting the intracellular fate of the microorganisms. The behavior of Listeria within macrophages cultivated from C57BL/6 and BALB/c mouse strains corresponded to previous reports of in vivo growth patterns in inbred mice. Thioglycolate- or caseinate-elicited macrophages, although highly phagocytic, were unable to prevent the proliferation of Listeria. A bactericidal macrophage population was derived from from C57BL/6 mice which had been immunized intraperitoneally with a sublethal dose of L. monocytogenes and subsequently boosted with heat-killed homologous organisms. Elicitation of immune animals produced an increase in the percentage of peroxidase-positive macrophages, but this activity could not be correlated with restriction of intracellular bacterial growth.     

Fate of Listeria monocytogenes in murine peritoneal macrophage subpopulations.

Peritoneal macrophages derived from CD-1 and C57BL/6 mice were separated into distinct groups based on their buoyant densities on discontinuous gradients of Percoll and assayed for antibacterial activity against Listeria monocytogenes. Subpopulations of peritoneal macrophages derived from Listeria-immune mice present a wide variation in their ability to control intracellular infection. Distinct subsets were found which exhibited bacteriostatic and listericidal activity. The fractionation procedure yielded a population of peroxidase-positive macrophages which were devoid of antilisterial action. Subpopulations of resident and elicited macrophages were also functionally heterogeneous in their ability to restrict intracellular growth of bacterial. In some experiments, subclasses were examined for secretion of plasminogen activator and phagocytosis of latex particles. These activities varied considerably with the status of activation of the macrophages, but failed to correlate with antimicrobial activity within given subpopulations.     

Gentamicin kills intracellular Listeria monocytogenes.

The purpose of the experiments described here was to test whether membrane-impermeant antibiotics present in the extracellular milieu could kill bacteria within macrophages. For this, mouse macrophage hybrids and elicited mouse peritoneal macrophages first were allowed to phagocytose the facultative intracellular bacterium Listeria monocytogenes. The cells were incubated with or without gentamicin, and their bactericidal activity was measured. The results show that gentamicin caused normally nonbactericidal macrophages to kill L. monocytogenes. In addition, gentamicin caused listericidal cells to kill significantly more bacteria. To determine whether gentamicin accumulated within macrophages during culture, we tested whether lysates of macrophage hybrids cultured for 72 h in gentamicin-containing medium and then washed could kill Listeria cells. When cultured with 50 to 100 micrograms of gentamicin per ml, but not when cultured with 0 to 5 micrograms of gentamicin per ml, cell lysates were extremely listericidal, demonstrating the presence of intracellular gentamicin. Because gentamicin does not penetrate cell membranes, we hypothesized that it can be internalized by the cell through pinocytosis and can enter the same intracellular compartment as does phagocytosed L. monocytogenes. To test this, macrophages which had phagocytosed L. monocytogenes were incubated with the fluorochrome lucifer yellow to trace pinocytosed medium. About half of the Listeria cells within the macrophages were surrounded by lucifer yellow, indicating delivery of pinocytosed fluid, which could contain antibiotics, to phagosomes containing bacteria. The experiments described here indicate that membrane-impermeant antibiotics can enter macrophages and kill intracellular bacteria. Thus, the use of gentamicin in macrophage bactericidal assays can interfere with the results and interpretation of experiments designed to study macrophage bactericidal activity.     

Effect of macrophage activation on killing of Listeria monocytogenes. Roles of reactive oxygen or nitrogen intermediates, rate of phagocytosis, and retention of bacteria in endosomes.

The role of macrophage activation in the killing of L. monocytogenes is unclear. Some studies suggest that activation for enhanced production of reactive oxygen and nitrogen intermediates may not be of central importance. Recent data have indicated an important role for interferon-gamma (IFN-gamma) induced retention of L. monocytogenes in endosomes. Data from the present study indicate that proteose peptone-elicited macrophages from DBA2/J, CD-1, and C3H/HeN mice are listericidal. Activation of these cells in vitro for 20 h by IFN-gamma (20 or 500 U/ml) increased H2O2 or nitrite production, but did not increase the number of L. monocytogenes killed during a subsequent 6-h or 7-h culture. Incubation of macrophages with IFN-gamma plus lipopolysaccharide (LPS) caused greater activation and increased the number of Listeria killed during a 6-h or 7-h culture. However, this seems primarily attributable to enhanced phagocytosis. Proteose peptone-elicited macrophages were significantly more effective than resident macrophages in preventing the escape of L. monocytogenes from endosomes into the cytoplasm. This capability was not significantly enhanced by IFN-gamma in vitro, but was enhanced by IFN-gamma plus LPS. This correlates well with the effects of these activation stimuli on killing of L. monocytogenes by proteose peptone-elicited macrophages. These results indicate that enhanced retention of L. monocytogenes in endosomes is induced by proteose peptone elicitation and that further macrophage activation in vitro by IFN-gamma does not improve listericidal activity.     

Role of macrophage scavenger receptors in response to Listeria monocytogenes infection in mice

Type I and type II macrophage scavenger receptors (SR-A I/II) recognize a variety of polyanions including bacterial cell-wall products such as lipopolysaccharide, suggesting a role for SR-A I/II in immunity against bacterial infection. SR-A I/II-deficient (MSR-A-/-) mice were more susceptible to infection with listeriolysin-O (LLO)-producing Listeria monocytogenes. After infection, Kupffer cells in wild-type (MSR-A+/+) mice phagocytized larger numbers of Listeria than those in MSR-A-/- mice. The number and the diameter of hepatic granulomas were larger in MSR-A-/- mice than MSR-A+/+ mice. L. monocytogenes replicated at higher levels in the liver of MSR-A-/- mice compared with MSR-A+/+ mice, and macrophages from MSR-A-/- mice showed impaired ability to kill Listeria in vitro. However, macrophages from MSR-A+/+ and MSR-A-/- mice showed similar levels of listericidal activity against isogenic mutant L. monocytogenes with an inactivated LLO gene. The listerial phagocytic activities of MSR-A+/+ macrophages treated with an anti-SR-A I/II antibody (2F8) and MSR-A-/- macrophages were significantly impaired compared with untreated MSR-A+/+ macrophages, indicating that SR-A I/II function as a receptor for L. monocytogenes. Electron microscopy revealed that most L. monocytogenes had been eliminated from the lysosomes of MSR-A+/+ macrophages in vivo and in vitro. In contrast, L. monocytogenes rapidly lysed the phagosomal membrane and escaped to the cytosol in MSR-A-/- macrophages and in MSR-A+/+ macrophages treated with 2F8 before phagosome-lysosome fusion. These findings imply that SR-A I/II plays a crucial role in host defense against listerial infection not only by functioning as a receptor but also by mediating listericidal mechanisms through the regulation of LLO-dependent listerial escape from the macrophages.     

Influence of phospholipids from Listeria monocytogenes and Aspergillus fumigatus on the bactericidal and fungicidal activity of mouse peritoneal macrophages

Investigations were carried out on an influence of phospholipids from A. fumigatus and L. monocytogenes on the bactericidal and fungicidal activity of mouse peritoneal macrophages. L. monocytogenes bacilli and C. neoformans fungi served as the experimental microorganisms. Phospholipids from A. fumigatus and L. monocytogenes were shown to significantly increase macrophage activity under in vivo and in vitro conditions. This was accompanied by an intensified bactericidal and fungicidal activity of extracts from the lysosomal fraction of phagocyte examined. Phospholipid-stimulated macrophages were observed to liberate bactericidal factors into the culture fluid. Lymphocytes had no influence upon this process.