In vivo and in vitro induction of natural killer cells by cloned human tumor necrosis factor

Summary The natural killer (NK) cell activity of mice in the peritoneal cavity is very low or undetectable and testing peritoneal NK cells is a useful model for studying the influence of activating substances upon local injection. Injection of tumor necrosis factor (TNF) at doses of 10–200 ng caused a marked activation of NK cell activity which was maximal after 24 h and declined rapidly on day 2. A similar effect was observed when interferons alpha and beta were injected, and there were additive results when interferon was injected together with TNF. The NK cell nature of the effector cells activated by TNF was substantiated by the finding that previous injection with anti-asialo GM 1 antibody prevented activation. Interferon could not be detected in the peritoneal wash fluid after injection of TNF suggesting interferon-independent activation. In further experiments after i.p. injection of TNF peritoneal exudate cells (PECs) only killed YAC-1 targets in a 4-h assay. There was no additional killing in an 18-h assay towards neither YAC-1 cells or P815 cells, suggesting that macrophages were not involved. Furthermore TNF was also active in vitro by activating NK cells in isolated human peripheral blood cells. However in the PECs stimulated in vitro no significant induction of cytotoxic capacities by TNF was measured. Our data suggest that the action of TNF is not restricted to the lysis of tumor cells but can also induce immunological properties in the host defense against virus infections and neoplasms.     

Lysis of murine macrophages by lymphokine-activated killer-like cells induced by BCG in vitro.

The lymphokine-activated killer (LAK)-like activity was found to be induced in mouse splenocytes cultured together with Bacillus Calmette-Guérin (BCG). The killer cells induced by BCG were capable of killing both NK-sensitive (YAC-1, P388D1) and NK-resistant (P815) tumor cells. As an important finding, they also lysed syngeneic macrophages (M phi). The anti-M phi killer activity appeared on day 2, and reached a peak on day 5 of culture. Phenotype analysis of the killer cells by depletion techniques using monoclonal antibody (mAb) and complement indicated that the majority of these anti-M phi killer cells were Thy-1+ and asialo GM1+. This M phi cytolysis could be inhibited by the addition of cold M phi, YAC-1 tumor cells, and P815 tumor cells, suggesting that the same population of the effector cells recognize M phi and tumor cells. The addition of anti-MHC class I, anti-MHC class II, anti-L3T4, or anti-Ly-2 mAb directly to assay cultures did not affect anti-M phi cytolysis, suggesting that the MHC molecules are not involved in the cytolysis of M phi by the BCG-induced killer cells. The addition of anti-LFA-1 mAb partially inhibited the cytotoxicity, suggesting importance of the contact between targets and effectors in the cytolysis. Our present data suggest that activation of murine lymphocytes with BCG induces LAK-like cells capable of killing a wide variety of tumor cells as well as M phi and this anti-M phi cytolysis is mediated by nonspecific killer cells.     

High cytotoxic activity against herpes simplex virus type 1 infected targets found in murine peritoneum

Unelicited murine peritoneal cells (PC) were found to efficiently lyse the natural cytotoxic (NC) cell target, WEHI-164, as well as herpes simplex virus-type 1 (HSV-1)-infected WEHI-164 and 3T3 cells but not the natural killer (NK) target, YAC-1. Lysis by PC of HSV-1-infected WEHI-164 and 3T3 cells required longer culture times than splenic cell lysis of YAC-1 cells. The PCs which lysed these targets were found to be slightly adherent to nylon wool but non-phagocytic, and were not augmented by preincubation with interferon. Also, PC effectors lacked Qa-5 and asialo GM1 markers which are found on splenic NK cells which lysed YAC-1 targets. We found that there was no correlation between peritoneal NC activity and genetic resistance to HSV-1.     

Appearance of a Cell Surface Antigen Associated with the Activation of Peritoneal Macrophages in Mice

A relatively large population of murine peritoneal exudate macrophages induced with viable BCG or heat-killed Corynebacterium parvum was stained by the antiserum prepared against purified gangliotetraosyl ceramide (asialo GM1), while only a small population of peritoneal resident macrophages or peritoneal exudate macrophages induced with proteose peptone was stained. The cytotoxicity assay of those macrophages with anti-asialo GM1 plus complement supported these results. Peritoneal macrophages induced with BCG or C. parvum showed strong cytotoxicity for EL4 cells in vitro, while resident or peptone-induced peritoneal macrophages showed no cytotoxicity. BCG- or C. parvum-induced peritoneal cells contained both NK cells and cytotoxic macrophages, and either in vivo or in vitro pretreatment of the cells with anti-asialo GM1 and complement abolished the activities of both types of cells. Peptone-induced peritoneal macrophages incubated with lymphokines (LK) or lipopolysaccharide (LPS) were cytotoxic for EL4 cells and contained an increased number of cells stained by anti-asialo GM1. The cytotoxicity of these in vitro activated macrophages was reduced by treatment with anti-asialo GM1 plus complement. When peptone-induced peritoneal macrophages were incubated with LK, the number of cells stained by anti-Ia antiserum increased, but the number did not increase when the macrophages were incubated with LPS. Pretreatment of peptone-induced macrophages with anti-asialo GM1 plus complement did not affect the ability of the macrophages to be activated by LK. These results taken together strongly suggest that the antigen (s) reactive with anti-asialo GM1 is expressed on the cell surface of cytotoxic peritoneal macrophages in mice.     

In vivo significance of NK cell on resistance against virus (HSV-1) infections in mice

Susceptibility to infection with herpes simplex virus type 1 (HSV-1) was examined in euthymic as well as athymic nude mice which were continuously depleted of natural killer (NK) cell activity by i.v. injection of anti-asialo GM1. In those NK cell activity-depleted mice, the mortality rate of infection with HSV-1 and the virus titers in the brain, liver, and spleen were notably higher than in the control mice. The enhanced susceptibility was demonstrated only in the mice receiving anti-asialo GM1 and HSV-1 simultaneously, but not in the mice in which NK cell deletion was postponed by injecting the antisera 5 days after the virus inoculation. Interferon (IFN) production of peritoneal exudate cells was also reduced in the anti-asialo GM1-injected mice. The decline of resistance against HSV-1 infection proved to be primarily due to deletion of NK cells, but not due to the inability to produce IFN, because repeated injections of IFN increased the NK cell activity and prolonged the life of HSV-1-infected mice with an intact NK cell activity. In the NK cell activity-depleted mice, however, neither the NK cell activity nor the life span was improved by the administration of IFN.     

Involvement of natural killer cells in coxsackievirus B3-induced murine myocarditis

The role of natural killer cells in the temporal development of coxsackievirus B3-induced myocarditis in adolescent CD-1 male mice was examined. Inoculation of purified CVB3m induced maximum NK cell activity in the splenic populations at 3 days postinoculation (p.i.) as assessed by lysis of YAC-1 cells; maximum virus titers in heart tissues were also found at day 3 p.i. Mice depleted of NK cells after injection of anti-asialo GM1 antiserum i.v. had decreased NK cell activity, increased CVB3m titers in heart tissues, and exacerbated myocarditis. Although lesion number was not increased in heart tissues of the latter mice, lesions in these mice exhibited increased myocyte degeneration and dystrophic calcification above that found in lesions of mice inoculated with CVB3m only. No alteration in interferon titers were observed in CVB3m-infected mice treated with anti-asialo GM1 antiserum as compared with normal CVB3m-infected mice. Measurements of splenic NK cell activity in mice inoculated with doses of 10(2) to 10(8) PFU of CVB3m per mouse or UV-irradiated virus suggest that replication of CVB3m is required for NK cell activation. An amyocarditic variant of CVB3m (ts5R) was shown to replicate in heart tissues and to elicit NK cell activity comparable to that elicited by CVB3m. Therefore, the data suggest that NK cell activation depends on virus replication and that these cells provide some protection against CVB3m-induced myocarditis by limiting virus replication in heart tissues.     

Induction of LAK-like cells in the peritoneal cavity of mice by inactivated Candida albicans

We have investigated the effect of multiple administrations of inactivated Candida albicans (CA) cells on induction of non-MHC-restricted antitumor cytotoxic responses both in normal and congenitally athymic (nude) mice. Intraperitoneal inoculation of CD2F1 mice with five doses of 2 x 10(7) CA cells over a 2-week interval was associated with the induction of peritoneal exudate cells (PEC) that mediated natural killer cell activity. These cells, in contrast to those elicited by a single dose of CA, killed both NK-sensitive and NK-resistant tumor target cells in vitro. This broad-spectrum, antitumor cytotoxicity peaked 1 day after the last injection of CA, and decreased to control values within 6 (NK-resistant) or 14 (NK-sensitive target cells) days. Cytotoxicity could be recalled to a high level by a boosting injection of CA or a major mannoprotein-soluble antigen (MP) from the Candida cell wall, given 30 days after multiple CA treatment. Upon a 24-hr in vitro incubation, CA-induced peritoneal immunoeffectors lost their killing activity unless human recombinant interleukin-2 (rIL-2) was added to cultures. The non-MHC-restricted cytotoxic PEC activity induced by CA was mainly associated with nonadherent, nonphagocytic large granular lymphocytes (LGL) which exhibited the following phenotypes: (i) asialo GM1+, Lyt 2.2-, and partially Thy 1.2+ (effectors active against NK-sensitive targets) and (ii) asialo GM1+, Lyt 2.2-, and Thy 1.2+ (effectors active against NK-resistant targets). Nude mice also responded to multiple CA inoculations by displaying high cytotoxic activity against NK-sensitive targets and significant cytotoxicity against NK-resistant targets. This cytotoxicity could be recalled on Day +30, and the cytotoxic effectors involved were highly sensitive to anti-asialo GM1 plus complement treatment. Overall, the results add further experimental evidence to the wide range of immunomodulatory properties possessed by C. albicans, and demonstrate that the majority of antitumor cytotoxic activity induced by fungal cells was due to lymphokine-activated killer (LAK)-like effectors.     

Augmentation of NK cell activity in tissue specific sites by liposomes incorporating MTP-PE

Liposomes incorporating a variety of immunomodulators have been shown to activate macrophages and monocytes for tumoricidal activity both in vivo and in vitro. We report that in addition to the activation of macrophages, the i.v. injection of liposomes (multilamellar vesicles) that have encapsulated muramyl tripeptide-phosphatidylethanolamine (MTP-PE) could also augment interstitial natural killer (NK) cell activity in the lung and the liver. In contrast, liposomes incorporating MTP-PE were unable to augment NK cell activity in the spleen, peripheral blood, or peritoneal cavity (after i.p. injection). In addition, liposomes did not augment splenic NK cell activity in vitro. This suggests that the augmentation of NK cell activity in the lungs and liver was not due to direct effects of the liposomes but may have been a secondary effect mediated by a monokine. The augmentation of pulmonary NK cell activity was paralleled by the nonspecific immunoprophylaxis of experimental pulmonary metastases. The augmented NK cell activity, as well as the enhanced nonspecific immunoprophylactic activity, was reduced by pretreatment of the mice with anti-asialo GM1 antiserum. Thus, the augmentation of organ-associated NK cell activity by liposomes incorporating MTP/PE plays a major role in the host's increased resistance to the formation of experimental metastases.     

A homogeneous population of lymphokine-activated killer (LAK) cells is incapable of killing virus-, bacteria-, or parasite-infected macrophages

Previous reports have suggested a role for natural killer (NK) cells in directly lysing host cells infected with bacteria and other intracellular microorganisms. Here, we determined the inability of a highly homogeneous population of lymphokine activated killer (LAK) cells to kill macrophages infected with the following intracellular parasites: Mycobacterium avium, Listeria monocytogenes, Legionella pneumophila, Toxoplasma gondii, and Trypanosoma cruzi. In parallel cytotoxicity assays, LAK cells lysed the tumor targets YAC-1 and P815 effectively. Furthermore, we were able to demonstrate that influenza-specific cytotoxic T lymphocytes (CTL), but not LAK cells, were efficient killers of influenza virus-infected macrophages.     

Origin and differentiation of natural killer cells. I. Characteristics of a transplantable NK cell precursor

To study the origin and differentiation of natural killer (NK) cells, we developed an assay for the transplantable precursor of NK(YAC-1) cells present in the bone marrow. Mice were depleted of endogenous NK(YAC-1) cells by injection of anti-asialo GM1 antibody, followed by lethal whole body irradiation. Normal syngeneic bone marrow cells were transplanted into such pretreated mice. Regeneration of NK(YAC-1) activity in the recipient mice was monitored by two different assays: the ability of spleen cells to lyse YAC-1 cells in vitro and the ability to clear i.v. injected, 125IUdR-labeled YAC-1 cells from the lungs. With both assays, a dose-response relationship between the number of bone marrow cells injected and the degree of NK(YAC-1) activity generated could be demonstrated. However, the lung clearance assay appeared superior because the NK regeneration could be detected earlier and with lower numbers of injected marrow cells. With this assay, several characteristics of the NK precursors and their differentiation could be defined. 1) The generation of mature, lytic NK cells from their transplantable precursor requires an intact "marrow microenvironment" in the recipient mice, because differentiation failed to occur in mice rendered osteopetrotic by estradiol treatment. 2) The NK(YAC-1) precursors lack the surface antigens (NK-2.1, asialo GM1, Qa-5, Thy-1) that are characteristically seen on mature NK cells. 3) The NK-precursors could be eliminated from the bone marrow with anti-Qa-2 or anti-H-2 antisera + complement, indicating that these two antigens are expressed on the precursors. The relationship between NK(YAC-1) precursors and multipotent myeloid stem cells (CFU-S) was investigated by utilizing W/Wv and Sl/Sld mutant mice. Bone marrow cells of W/Wv anemic mice, although markedly deficient in CFU-S, have a normal frequency of NK(YAC-1) precursors. Sl/Sld mice that lack a suitable microenvironment for the development of CFU-S allowed normal differentiation of NK(YAC-1) precursors when transplanted with normal bone marrow cells. Together, these data suggest that multipotent myeloid progenitor cells, as defined by the CFU-S assay, and the NK(YAC-1) precursors are not closely related.     

Murine natural killer cells limit coxsackievirus B3 replication

Previous indirect evidence suggested that natural killer (NK) cells play a role in coxsackie virus B3 serotype 3, myocarditic variant (CVB3m)-induced myocarditis by limiting virus replication. In this study, we present direct evidence that NK cells can limit CVB3m replication both in vitro and in vivo. Virus titers are lowered in primary murine neonatal skin fibroblast (MNSF) cultures incubated with activated splenic large granular lymphocytes (LGL) taken from mice 3 days postinoculation of CVB3m, a time of maximal NK cell activity. The antiviral effect of this cell population is diminished by complement-mediated lysis with the use of anti-asialo GM1 antiserum but not with anti-Lyt-2 monoclonal antibody. Neither interferon nor anti-CVB3m-neutralizing antibody was detected in these cultures. Although activated LGL initiate lysis within CVB3m-infected MNSF in vitro within 3 hr of addition, they do not lyse uninfected MNSF cultures. CVB3m replication is required for expression of surface changes on MNSF that result in lysis by NK cells because cell cultures treated with compounds that prevent CVB3m replication are not killed by LGL. LGL also do not lyse MNSF cultures inoculated with UV-inactivated virus. Mice inoculated with activated LGL and subsequently challenged with CVB3m had reduced titers of virus in heart tissues in comparison to titers of CVB3m in heart tissues of mice not given LGL. The antiviral activity of the LGL preparation was abolished by prior treatment with anti-asialo GM1 antiserum plus complement but not by prior treatment with anti-Lyt-2 monoclonal antibody and complement. These data suggest that NK cells can specifically limit a nonenveloped virus infection by killing virus-infected cells.     

Identification of functional subpopulations of murine natural killer cells based on their cell surface asialo GM1 phenotype

HSV-1 infection renders a mouse fibroblast cell line (MCN) sensitive to murine splenic NK killing which is independent of interferon (IFN) induction during the assay. This NK (HSV-1) activity is distinctive from conventional NK (YAC-1) in that they cannot be aborted by anti-asialo GM1 (anti-ASGM1) antibody plus complement treatment as NK (YAC-1) does. Further characterization of these two subpopulations was carried out by fluorescence-activated cell sorting (FACS) technique based on their cell surface asialo GM1 (ASGM1) phenotype. While almost all NK (YAC-1) activity resides within FACS-positive population, both ASGM1 positive and negative cell populations can kill the virally infected MCN equally well. One interesting observation is that only the ASGM1 positive cells respond significantly to IL-2 NK boosting. Five different mouse strains (CD-1, C57BL/6J, C57BL/6J-BG, SM/J, and SJL) were compared on their FACS profile with anti-ASGM1 antibody as well as their NK function. The differences observed are discussed.     

Virulizin, a novel immunotherapy agent, activates NK cells through induction of IL-12 expression in macrophages

Virulizin, a novel biological response modifier, has demonstrated significant antitumor efficacy in a variety of human tumor xenograft models including melanoma, pancreatic cancer, breast cancer, ovarian cancer and prostate cancer. The significant role of macrophages and NK (Natural killer) cells was implicated in the antitumor mechanism of Virulizin where expansion as well as increased activity of macrophages and NK cells were observed in mice treated with Virulizin. Depletion of macrophages compromised Virulizin-induced NK1.1⁺ cell infiltration into xenografted tumors and was accompanied by reduced antitumor efficacy. In the present study, involvement of macrophages in NK cell activation was investigated further. We found that depletion of NK cells in CD-1 nude mice by anti-ASGM1 antibody significantly compromised the antitumor activity of Virulizin. Cytotoxicity of NK cells isolated from Virulizin-treated mice was enhanced against NK-sensitive YAC-1 cells and C8161 human melanoma cells, but not against NK-insensitive P815 cells. An increased level of IL-12 was observed in the serum of mice treated with Virulizin. IL-12 mRNA and protein levels were also increased in peritoneal macrophages isolated from Virulizin-treated mice. Moreover, Virulizin-induced cytotoxic activity of NK cells isolated from the spleen was abolished when an IL-12 neutralizing antibody was co-administered. In addition, depletion of macrophages in mice significantly impaired Virulizin-induced NK cell cytotoxicty. Taken together, the results suggest that Virulizin induces macrophage IL-12 production, which in turn stimulates NK cell-mediated antitumor activity.     

Induction of tumor cytotoxic immune cells using a protein from the bitter melon (Momordica charantia)

The fruit and seeds of the bitter melon (Momordica charantia) have been reported to have anti-leukemic and antiviral activities. This anti-leukemic and antiviral action was associated with an activation of murine lymphocytes. A partially purified protein factor from the bitter melon caused an infiltration and activation of peritoneal exudate cells in C57B1/6J, C3H/HeJ, and C3H/HeN mice. When the extract was injected twice a week at 8 micrograms of protein per ip injection for 0-4 weeks, the peritoneal exudate cells from the treated mice were cytotoxic in a long-term (18-hr) 51Cr-release assay against a range of labeled targets: L1210, P388, and MOLT-4 tumor cells. Cytotoxicity was also observed against YAC-1 targets in a short-term (4-hr) assay. Fractionation of the cytotoxic immune cells implicated a nonadherent cell population which was capable of killing an NK-sensitive cell line in a 4-hr 51Cr-release assay. Unit gravity sedimentation studies indicated that the cytotoxicity was due to either a neutrophil or a large lymphocyte. Antibody depletion experiments using antibody to asialo GM1, an NK cell-specific antibody, depleted cytotoxicity observed in nonadherent, Ficoll/Hypaque-separated PEC. This suggests that at least part of the anti-leukemic activity of the bitter melon extract is due to the activation of NK cells in the host mouse.     

Identification of effector cells for TNFalpha-mediated cytotoxicity against WEHI164S cells

WEHI164S cells were found to be very sensitive targets for in vitro killing in a 6-h culture when liver or splenic lymphocytes were used as effector cells in mice. Of particular interest, a limiting cell-dilution analysis showed that effector cells were present in the liver with a high frequency (1/4,300). In contrast to YAC-1 cells as NK targets, perforin-based cytotoxicity was not highly associated with WEHI164S killing. The major killer mechanism for WEHI164S targets was TNFalpha-mediated cytotoxicity. By cell sorting experiments, both NK cells and intermediate T cells (i.e., TCR(int) cells) were found to contain effector cells against WEHI164S cells. However, the killer mechanisms underlying these effector cells were different. Namely, NK cells killed WEHI164S cells by perforin-based cytotoxicity, TNFalpha-mediated cytotoxicity, Fas ligand cytotoxicity, and other mechanisms, whereas intermediate T cells did so mainly by TNFalpha-mediated cytotoxicity. These results suggest that TNFalpha-mediated cytotoxicity mediated by so-called natural cytotoxic (NC) cells comprised events which were performed by both NK and intermediate T cells using somewhat different killer mechanisms. Intermediate T cells which were present in the liver were able to produce TNFalpha if there was appropriate stimulation.     

Protection of OK-432, a Streptococcus pyogenes preparation, against lethal infection of mice with herpes simplex virus

We have studied the protective effect of OK-432, a biological response modifier (BRM) of Streptococcus pyogenes origin, on the lethal infection of mice with herpes simplex virus (HSV)-1. A single intraperitoneal (i.p.) injection of more than 10 micrograms of OK-432, when given at least two days before the infection, gave a marked effect yielding nearly 100% protection against ordinarily lethal infection. The protection was independent of the amount of infected virus inoculated. When given after the infection, the agent even at the maximal dose (100 micrograms), produced only a marginal effect. A single i.p. administration of OK-432 augmented the natural killer (NK) activity of peritoneal exudate cells and spleen mononuclear cells in mice 2 to 3 days after injection of OK-432, coinciding with the times when it induced a survival effect on HSV-infection. Treating OK-432-treated mice with a combination of an anti-macrophage agent, silica, and an anti-NK cell agent, anti-asialo GM1 serum, before infection diminished the antiviral effect of OK-432. The OK-432 protection against HSV infection was also markedly diminished in athymic nude mice. Thus, the protective effect of OK-432 on lethal HSV infection seems to be based on the activation of NK cells, macrophages, and T lymphocytes.     

Augmentation of Mouse Natural Killer Cell Activity by Lactobacillus casei and Its Surface Antigens

Lactobacillus casei YIT 9018 (LC 9018) augmented the natural killer (NK) cell activity of spleen cells from inbred BALB/c mice injected intravenously with LC 9018 or intraperitoneally with polyinosinate-polycytidylate. Augmentation of this activity by LC 9018 was also observed in male C3H/He, CBA/N, and C57BL/6 mice. The spleen cells exhibited no cytolytic activity against P815, a cell line insensitive to NK cells. The cytolytic activity of the spleen cells increased 2 days after the injection of 250 μg of LC 9018/mouse, peaked on day 3, and gradually declined thereafter. The increase caused by LC 9018 was also observed in normal and Meth A-bearing mice. In vitro treatment with anti-asialo GM1 antibody plus complement completely-abrogated the LC 9018-augmented murine NK cell activity. The NK activity on the 3rd day after LC 9018 injection was reduced by in vitro treatment with anti-Thy 1.2 monoclonal antibody plus complement to half of that observed when treatment was with complement alone. This suggests that there were two populations of NK cells in the spleen cell suspension derived from LC 9018-treated mice. One population was asialo GM1-positive and Thy 1-negative, the other was asialo GM1-positive and Thy 1-positive.     

Flow cytometric analysis reveals the presence of asialo GM1 on the surface membrane of alloimmune cytotoxic T lymphocytes

Previous studies have demonstrated that natural killer (NK) cells express the glycolipid asialo GM1, as evidenced by the sensitivity of NK cells to treatment with anti-asialo GM1 serum and complement. Because alloimmune cytotoxic T lymphocytes (CTL) were found to be insensitive to treatment with anti-asialo GM1 serum and complement, it was concluded that asialo GM1 is expressed by NK but not by CTL. However, fluorescence studies indicated that a significant proportion of peripheral T cells did express asialo GM1. Flow cytometric studies were undertaken to determine the extent to which alloimmune CTL express asialo GM1. Affinity-purified, monospecific IgG anti-asialo GM1 antibodies were used to label cells from mixed lymphocyte cultures. Separation of asialo GM1-positive and -negative fractions by cell sorting revealed that the majority of CTL activity resides in the asialo GM1-positive population. When these studies are compared with similar studies of splenic NK activity, it is apparent that, despite the relative insensitivity of CTL to treatment with anti-asialo GM1 and complement, both CTL and NK activity are enriched in the asialo GM1-positive cell population obtained by cell sorting.     

The role of natural killer cells in experimental murine salmonellosis

This study was designed to determine if murine natural killer (NK) cells play a role in host protection against a Salmonella typhimurium challenge infection. Outbred ICR mice injected intravenously with either attenuated (RIA strain) or virulent (SR-11 strain) salmonellae elicited enhanced killing of YAC-1 targets, which was maximal at 24 h after challenging. When NK cells were depleted with antiasialo GM1 prior to challenging, the splenic bacterial numbers were significantly less in this group of mice compared to sham-injected and challenged animals. The rabbit antiasialo GM1 sera had no detectable direct or indirect effect on the salmonellae. Our results indicate that the NK or natural suppressor cells may be functioning as down-regulators.     

Suppression of splenic macrophage Candida albicans phagocytosis following in vivo depletion of natural killer cells in immunocompetent BALB/c mice and T-cell-deficient nude mice

The resistance of mice to systemic infections caused by Candida albicans is associated with activated splenic macrophages. In addition, there is a correlation between natural killer (NK) cell activation and the resistance to systemic candidiasis. The present study was designed to clarify the role of NK cells in the control of splenic macrophage C. albicans phagocytosis by either depleting NK cells (anti-asialo GM(1) treatment) or maintaining them in an activated state (tilorone treatment) in both immunocompetent BALB/c mice and T-cell-deficient nude mice. The results of the in vitro phagocytosis assays were analyzed by flow cytometry and demonstrate the pivotal role of NK cells in controlling the capacity of splenic macrophages to phagocytose C. albicans. In summary, these data provide evidence that the NK cells are the main inducers of phagocytic activity of splenic macrophages and that they mediate the protection against C. albicans systemic infection.