Development of hyporesponsiveness to augmentation of natural killer cell activity after multiple doses of maleic anhydride divinyl ether: association with decreased numbers of large granular lymphocytes

A single injection of mice with maleic anhydride divinyl ether (MVE-2) resulted in significantly augmented natural killer (NK) activity. However, multiple injections with MVE-2 led to a hyporesponsive to boosting of NK activity. Stimulation of prostaglandin E secretion of induction of suppressor macrophages (M phi) or lymphocytes were shown not to be responsible for the depressed NK cell responses. Rather the hyporesponsiveness to NK boosting was associated with a decreased number of large granular lymphocytes (LGLs). Percoll discontinuous-density-gradient studies showed that the augmented NK activity of spleen cells after a single injection with MVE-2 was associated with an increase in the percentage of LGLs in the lower-density fractions (Fraction 1 and 2). In contrast, the NK activity and percentage of LGLs in the lower-density fractions were markedly decreased after multiple injections with MVE-2. Polyinosinic: polycytidylic acid stabilized with poly(L-lysine) in carboxymethylcellulose, another BRM capable of augmenting NK activity, was able to substantially augment NK activity in mice hyporesponsive to MVE-2 and this was accompanied by an increase in the percentage of LGLs in the lower-density Percoll fractions.     

Augmentation of mouse liver-associated natural killer activity by biologic response modifiers occurs largely via rapid recruitment of large granular lymphocytes from the bone marrow

A variety of biologic response modifiers (BRM) can potently augment NK activity in nonlymphoid organs. By using the liver as a model organ, we have shown that this augmentation of organ-associated NK activity is coincident with a 10- to 15-fold increase in the number of large granular lymphocytes (LGL) which can be isolated. The present study was designed to investigate the mechanism by which BRM induce this increase in liver-associated LGL and the coincident increase in hepatic NK activity. Initial studies confirm that a single dose of the pyran copolymer, maleic anhydride divinyl ether (MVE-2), augmented hepatic NK activity and increased the number of liver-associated LGL from 3 x 10(4)/liver to 5 x 10(5)/liver (a 17-fold increase). Multiple injections of MVE-2 further augmented total liver-associated NK activity and LGL number (to 13 x 10(5)/liver). As expected, both the NK activity and detectable LGL were eliminated by treatment of the mice with antiasialo GM1 (asGM1) serum. Three possible mechanisms for the BRM-induced increase in liver-associated LGL have been investigated, including 1) the rapid proliferation of resident hepatic LGL, 2) the redistribution of mature LGL from peripheral sites such as the spleen, or by 3) a rapid output and subsequent hepatic localization of LGL or their precursors recently derived from the bone marrow (BM). Our results demonstrated that the contribution of in situ proliferation to the BRM-induced increase in liver-LGL was relatively small, since the number of cells expressing NK-associated markers (i.e., asGM1, Thy-1.2, and NK1.1) and in G2/M phase (as assessed by propidium iodide uptake) was only 4 to 8%. Further experiments demonstrated that splenectomy before the administration of MVE-2 did not inhibit the augmentation of liver-associated NK activity. This result argued against a recruitment of mature LGL from the spleen. In contrast, selective depletion of the BM following administration of 89Sr decreased the ability of MVE-2 to augment liver-associated NK activity by greater than 80%. This procedure also significantly decreased the ability of Propionibacterium acnes (85%) and multiple doses of IL-2 (49%) to augment liver-associated NK activity. These results demonstrate that the rapid augmentation of liver-associated NK activity by BRM is largely due to localization and accumulation in the liver of LGL recently derived from the BM.     

Augmentation of natural cell activity in tumor-bearing and normal mice by MVE-2

Summary Mice bearing advanced Lewis lung carcinoma were found to have significantly decreased natural killer (NK) cell activity in spleen and blood. The same pattern of lowered spontaneous NK cell activity was observed in nude mice with advanced human colon carcinoma LS 174 and in C3H mammary tumor virus-positive mice that spontaneously developed mammary adenocarcinomas. Maleic anhydride divinyl ether (MVE-2) usually augments NK cell activity in normal mice. We found that the lower level of spontaneous NK cell activity in tumor-bearing mice could be boosted by a single injection of MVE-2; however, this response was much weaker than that observed in age-matched normal mice. Multiple treatments with MVE-2 which are known to induce hyporesponsiveness to further augmentation of NK cell activity in spleen and blood of normal mice, also produced NK cell hyporesponsiveness in the spleen, bone marrow, and blood of tumor-bearing mice.Wladyslaw Budzynski is a guest researcher in the Preclinical Screening Laboratory from the Institute of Immunology and Experimental Therapy, Czerska Street 12, Wroclaw, Poland     

Regulation of natural killer cell activation: implementation for the control of tumor metastasis

The cellular interactions that regulate natural killer (NK) cell-mediated cytotoxicity and antimetastatic activity following treatment with biological response modifiers (BRM) were studied. The transient activation of NK cells by a single injection of Corynebacterium parvum is followed by a refractory period during which a second injection of BRM fails to stimulate the already depressed NK cell activity. During this hyporesponsive period, the in vivo NK cell-dependent BRM-induced antimetastatic activity is markedly reduced and cannot be enhanced by multiple injections of BRM. A correlation exists between the generation of hyporesponsiveness to NK cell activation and the activation of suppressor macrophages by C. parvum. BRM that selectively activate NK cells without subsequently activating suppressor macrophages do not induce hyporesponsiveness to further activation of NK cells in vivo and, when given in multiple injections, retain the ability to inhibit hematogenous tumor metastasis.     

Role of organ-associated NK cells in decreased formation of experimental metastases in lung and liver

Mice treated with anti-asialo GM1 (asGM1) serum exhibited increased formation of experimental metastases in lung and liver after i.v. challenge with B16 melanoma or Lewis lung carcinoma. This increased metastasis formation coincided with decreased splenic NK activity and increased survival of i.v. injected radiolabeled tumor cells. In contrast, the injection of mice with the pyran copolymer maleic anhydride divinyl ether (MVE-2) augmented NK activity in the spleen and significantly depressed the formation of experimental metastases in the lungs and liver. However, a single or double administration of anti-asGM1 antiserum to MVE-2-pretreated mice failed to inhibit the immunoprophylaxis associated with MVE-2 administration, although it did decrease splenic NK activity and also increased the survival of i.v.-injected radiolabeled tumor cells. To address the mechanism for this dichotomy, we examined NK activity not only in the spleen but also in the blood, lungs, and livers of MVE-2-treated mice. Levels of NK activity in the lungs and liver were several-fold higher than those observed in spleen and blood. However, MVE-2-augmented NK activity in lung and liver was more resistant to depletion by the standard regimen of anti-asGM1 treatment than was NK activity in blood and spleen, and required two high-dose administrations of a higher titered antiserum for depletion of the augmented response. This high-dose regimen removed all detectable NK activity from the lung and liver, and concomitantly eliminated the metastasis-inhibiting effect of MVE-2. These data are consistent with a role for organ-associated NK cells in inhibiting metastasis formation during the extravasation and/or early postextravasation phases of the metastatic process. The results also suggest that biologic effects of NK activity in spleen and blood can be dissociated from those mediated by NK activity in other organs by use of different treatment regimens with anti-asGM1 serum. Finally, because NK activity in target organs can be augmented to an even greater extent than in the blood and spleen by at least some biologic response modifiers (BRMs), organ-associated NK activity should be considered as a possible mechanism for the therapeutic effects of BRM treatment.     

Development of hyporesponsiveness of natural killer cells to augmentation of activity after multiple treatments with biological response modifiers

Summary Four biological response modifiers (BRMs), MVE-2 (maleic anhydride divinyl ether), Corynebacterium parvum (C. Parvum), PolyICLC (polyinosinic:polycytidylic acid stabilized with poly-l-lysine), and mouse -interferon (-IFN), were tested to assess whether repeated treatments would repeatedly induce or sustain augmented levels of natural killer (NK) cell activity and/or macrophage (M0)-mediated inhibition of tumor cell growth. In contrast to a significant increase in splenic NK activity obtained with a single treatment with each of the agents, multiple treatments with these BRMs led to a progressive decrease in the degree of augmentation of NK activity. In contrast, multiple injections with these agents resulted in sustained augmentation of M0-mediated reactivity. Separation of the spleen cells by Percoll discontinuous density gradient centrifugation indicated that with mice treated once with each BRM high levels of NK activity were detected in the lower density fractions and that these fractions contained a higher percentage of large granular lymphocytes (LGLs) than that found in comparable fractions from normal mice. In contrast, cells in the lower density fractions from mice that received multiple treatments had decreased NK activity and an appreciably lower proportion of LGLs. These results indicate that the development of hyporesponsiveness to augmentation of splenic NK-cell activity following multiple treatments with BRMs may be attributable to a decreased percentage of LGLs, the effector cell population responsible for NK cell-mediated cytotoxicity. Abbreviations used in this paper: BRMs, biological response modifiers; MVE-2, maleic anhydride divinyl ether of molecular weight 15,500; C. parvum, Corynebacterium parvum; PolyICLC, polyinosinic-polycytidylic acid stabilized with poly-l-lysine in carboxymethylcellulose; IFN, interferon; NK cells, natural killer cells; M0, macrophage; LGLs, large granular lymphocytes; PGE, prostaglandin E; FBS, fetal bovine serum; PBS, phosphate-buffer saline composed of 4.86 g NaCl, 0.306 g KH₂PO₄, and 2,417 g NaHPO₄ in 100 ml H₂O adjusted to pH 7.2; LPS, lipopolysaccharide     

Augmentation of NK activity and/or macrophage-mediated cytotoxicity in the liver by biological response modifiers including human recombinant interleukin 2

Summary Administration of several biological response modifiers (BRMs) to mice strongly augmented natural killer (NK) activity of leukocytes isolated from the liver. This augmentation of NK activity was induced by two synthetic molecules (MVE-2 and poly ICLC), by two BRMs of bacterial origin (formalin-fixed Propionibacterium acnes: P. acnes and a streptococcal cell wall preparation designated OK-432), as well as a single injection of human recombinant interleukin-2 (hrIL 2). All of these BRMs augmented NK activity in the liver to a greater degree than in the spleen. In addition, adherent leukocytes (>90% macrophages) isolated from the liver following P. acnes administration also exhibited augmented macrophage-mediated cytotoxicity. This cytotoxicity was characterized as macrophage mediated and distinguished from NK activity, on the basis of adherence purification, kinetics of cytotoxicity, and target cell selectivity. The results demonstrate that a variety of BRMs induce augmented natural immunity in the liver and suggest that such organ-associated immune responses may play an important role in the antimetastatic effects of BRMs.This project has been funded at least in part with Federal funds from the Department of Health and Human Services, under contract number NO1-CO-23910 with Program Resources, Inc. the contents of this publication do not necessarily reflect the views or policies of the Department of Health and Human Services nor does mention of trade names, commercial products, or organizations imply endorsement by the U.S. GovernmentSupported by Grant SA 364/1-1 from the Deutsche Forschungsgemeinschaft, FRG     

Changes in number and density of large granular lymphocytes upon in vivo augmentation of mouse natural killer activity

NK activity of mice as well as humans and rats has been clearly associated with large granular lymphocytes (LGL). To better understand the effects of interferon (IFN) and IFN inducers on natural killer (NK) cells, we have compared the LGL in the spleens of normal and boosted mice. Cells were fractionated by centrifugation on discontinuous Percoll density gradients, and each fraction was tested for NK activity against YAC-1 targets and for the presence of LGL. In vivo treatment with C. parvum (0.7 mg/mouse, i.p., day-3), MVE-2 (25 mg/kg, i.p., day-3), poly I:C (4 mg/kg, i.p., day-3), or IFN (10(5) U/mouse, i.p., day-1) resulted in a marked augmentation and a change of distribution of cytotoxic activity. Most of the NK activity of boosted spleen cells was associated with lower density fractions 1 and 2, whereas active normal spleen cells had somewhat higher density (fractions 2 and 3). In parallel to their increased reactivity, the boosted spleens had a marked increase in the percentage of LGL, particularly in fractions 1 and 2. The augmented activity appeared to be mediated by the LGL, because treatment with anti-asialo GM1 or anti-Thy-1.2 plus complement reduced NK as well as the number of LGL. These results indicate that IFN-mediated boosting of NK activity in the spleen is due to an increase in the lower density LGL, as well as to an increase in the function of preexisting NK cells.     

Studies on the mechanism of natural killer cytotoxicity. III. Activation of NK cells by interferon augments the lytic activity of released natural killer cytotoxic factors (NKCF)

The mechanism by which interferon (IFN) pretreatment of effector cells augments natural killer (NK) cell-mediated cytotoxicity (CMC) was examined by determining whether IFN has any effect on the production of natural killer cytotoxic factors (NKCF). NKCF are released into the supernatant of co-cultures of murine spleen cells and YAC-1 stimulator cells, and their lytic activity is measured against YAC-1 target cells. It was demonstrated that pretreatment of effector cells with murine fibroblast IFN or polyinosinic-polycytidylic acid (pIC) resulted in the release of NKCF with augmented lytic activity. Evidence indicated that the IFN-induced augmentation of NKCF activity required protein synthesis during the IFN pretreatment period, because concurrent pretreatment with both IFN and cycloheximide abrogated the IFN effect. Protein synthesis, however, is not required for the production of base levels of NKCF because emetine pretreatment of normal spleen cells did not result in a decrease in NKCF production. Furthermore, substantial levels of NKCF activity could be detected in freeze-thaw lysates of freshly isolated spleen cells. Cell populations enriched for NK effector cells, such as nylon wool-nonadherent nude mouse spleen cells, produced lysates with high levels of NKCF activity, whereas lysates of CBA thymocytes were devoid of NKCF activity. Pretreatment of spleen cells with either IFN or pIC resulted in an augmentation of the NKCF activity present in their cell lysates. Taken altogether, these findings suggest that freshly isolated NK cells contain preformed pools of NKCF. Pretreatment of these cells with IFN causes de novo synthesis of additional NKCF and/or activation of preexisting NKCF. According to our model for the mechanism of NK CMC, target cell lysis is ultimately the result of transfer of NKCF from the effector cell to the target cell. The evidence presented here suggests that the IFN-induced augmentation of NK activity could be accounted for by an increase in the synthesis, activation, and/or release of NKCF.     

Pulmonary compartmentalization of interferon and natural killer cell activity

Studies were performed to determine if natural killer (NK) activity in the mononuclear cells harvested from infected lungs was dependent on local or systemic factors. Mice were inoculated by intratracheal (it), intraperitoneal (ip), or intravenous (iv) routes with (a LD50 dose of) influenza virus A PR/8/34. At various days postinoculation cells from lungs, spleens, and peripheral blood were assayed for NK activity, and lung wash, lung homogenates, and serum were assayed for interferon. After it inoculation there was three- to fourfold increase of NK activity in the lung with little or no increase in NK activity in spleens or peripheral blood. The local augmentation of NK activity in the lung correlated with an increase in interferon (IFN) titer in the lung wash and lung homogenate of PR8 inoculated mice. The virus failed to induce IFN or augment NK activity when it was inoculated systemically. The observed local augmentation of NK activity and local induction of interferon production following it inoculation suggests that the NK population in the lung is capable of responding to locally derived regulatory factors.     

Interleukin 2 induces gamma-interferon production: participation of macrophages and NK-like cells

Interleukin 2 (IL 2) has been shown to be a potent stimulator of natural killer (NK) cells. In the present studies, partially purified mouse and human IL 2 preparations were also found to induce interferon (IFN) from mouse spleen cells. By the criteria of sensitivity to treatment at pH 2 and failure to be neutralized by a potent anti-alpha, beta IFN serum, the species of IFN produced was of type gamma. Cooperation between two types of cell, a macrophage and an NK-like cell, was required for IFN production by murine spleen cells treated with IL 2. The requirement for macrophages could be replaced with supernatant obtained by incubating macrophages for 24 hr with lymphokine preparations containing IL 2. Interestingly, mature T cells apparently played no role in the process. Furthermore, the beige (bg/bg) mutation, which severely impairs NK cell lytic activity, had no effect on the ability of NK-like cells to participate in IFN production. Cell fractionation experiments revealed no dissociation between the requirements for augmentation of NK cytotoxic activity and for IFN production, and it is concluded that at least a portion of the NK boosting induced by IL 2-containing preparations is mediated through gamma-IFN.     

Induction of interferon and activation of NK cells and macrophages in mice by oral administration of Ge-132, an organic germanium compound

After oral administration of an organic germanium compound, Ge-132 (300 mg/kg), a significant level of interferon (IFN) activity was detected in the sera of mice at 20 hr and it reached a maximum of 320 U/ml at 24 hr. This IFN activity was lost after heat- or acid-treatment, suggesting that the induced IFN is of gamma-nature. The molecular weight of this IFN was estimated to be 50,000 daltons by gel filtration. The NK activity of spleen cells was increased 24 hr after the oral administration of Ge-132, and cytotoxic macrophages were induced in the peritoneal cavity by 48 hr. In the mice receiving an intraperitoneal (ip) injection of trypan blue or carrageenan 2 days before oral administration of Ge-132, neither induction of IFN nor augmentation of NK activity occurred, and X-ray irradiation of mice also rendered the mice incapable of producing IFN, all indicating that both macrophages and lymphocytes are required for this IFN induction. Both NK and cytotoxic macrophages appeared 18 hr after ip administration of the induced IFN with a titer as low as 20 U/ml. These facts suggest that both the augmentation of NK activity and activation of macrophages in mice after oral administration of Ge-132 are mediated by the induced IFN.     

Protective effect of biological response modifiers on murine cytomegalovirus infection

Pretreatment with two biological response modifiers (BRM), OK-432 and PS-K, protected mice from lethal infection by murine cytomegalovirus (MCMV). This was evidenced by an increase in 50% lethal doses and a decrease in titers of infectious viruses replicated in the liver and spleen. Spleen cells from the BRM-treated mice augmented the natural killer (NK) cell activity and suppressed the replication of MCMV in vitro. During MCMV infection, the NK cell activity of the spleen cells was maintained at a high level in the BRM-treated mice, whereas it was severely impaired in untreated mice. The BRM-induced protection was nullified by concomitant administration of antiasialo GM1 antibody. Interferon was neither induced by BRM treatment nor enhanced in BRM-pretreated and MCMV-infected mice. Thus, the protective effect of OK-432 and PS-K seems to be based on activation of NK cells and prevention of MCMV-induced inhibition of the NK cell activity.     

Differences in murine gut-associated lymphoid tissues in generating broadly nonspecific cytotoxic cells in response to interferon alpha A/D and interleukin 2

We examined the response of cells of murine gut-associated lymphoid tissues to agents that augment the activity of natural killer (NK) cells. Specifically, we studied the effect of polyinosinic: polycytidylic acid (Poly I:C) in vivo, and recombinant interferon alpha A/D (rIFN alpha A/D) and recombinant interleukin 2 (rIL2) in vitro on lymphoid cells of mesenteric lymph nodes (MLN) and Peyer's patches (PP) in generating cytotoxicity against NK-sensitive (YAC-1) and NK-insensitive (B16BL6) tumor targets. The effect of these agents on spleen cells was examined for comparison with their effect on MLN and PP cells and as a positive control. MLN and PP cells lacked spontaneous NK activity: however, NK activity could be augmented to different levels by the three agents. The treatment of mice in vivo with Poly I:C induced considerable cytotoxicity in the spleen and MLN but only a weak cytotoxic response in PP. The in vitro enhancement of NK activity by rIFN alpha A/D was strong in the spleen, intermediate in MLN, and consistently poor in PP. The weak NK augmentation by rIFN alpha A/D in PP was not restricted to a single mouse strain. PP cells from five strains of mice responded poorly to rIFN alpha A/D. Furthermore, NK augmentation by rIFN alpha A/D in PP cells did not improve after passing the responder cells through nylon wool, indicating that the lack of augmentation of NK activity was not the result of a preponderance of B cells or the masking of NK cells by adherent lymphoid populations in PP. In contrast to weak augmentation of NK activity by rIFN alpha A/D, considerable IL2-induced lymphocyte-activated killer (LAK) activity against NK-insensitive B16BL6 tumor cells was induced in PP. Limiting-dilution analysis showed that the frequency of LAK precursors in the MLN and PP was not markedly different from that of the spleen. The differences among spleen, MLN, and PP lymphoid populations in generating the broadly nonspecific cytotoxic effector cells in response to rIFN alpha A/D or rIL2 may result from differences in the pools of different pre-NK cells or to differential sensitivity of the same pool of pre-NK cells to rIFN alpha A/D and rIL2 in different anatomical locations.     

Lipid-DNA complexes induce potent activation of innate immune responses and antitumor activity when administered intravenously.

Cationic lipid-DNA complexes (CLDC) are reported to be safe and effective for systemic gene delivery, particularly to the lungs. However, we observed that i.v. injection of CLDC induced immunologic effects not previously reported. We found that even very low doses of CLDC administered i.v. induced marked systemic immune activation. This response included strong up-regulation of CD69 expression on multiple cell types and systemic release of high levels of Th1 cytokines, from both lung and spleen mononuclear cells. CLDC were much more potent immune activators on a per weight basis than either LPS or poly(I:C). The remarkable potency of CLDC appeared to result from enhancement of the immune stimulatory properties of DNA, since cationic lipids alone were without immune stimulatory activity. Systemic treatment with CLDC controlled tumor growth and significantly prolonged survival times in mice with metastatic pulmonary tumors. NK cells accumulated to high levels in the lungs of CLDC-treated mice, were functionally activated, and released high levels of IFN-gamma. The antitumor activity induced by CLDC injection was dependent on both NK cells and IFN-gamma. Thus, DNA complexed to cationic liposomes becomes highly immunostimulatory and capable of inducing strong antitumor activity when administered systemically.     

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.     

The efficacy of biological response modifiers against murine cytomegalovirus infection in normal and immunodeficient mice

The host-mediated antiviral effect of two biological response modifiers (BRM), OK-432 and PS-K, against murine cytomegalovirus (MCMV) was evaluated in normal and immunologically deficient mice of the same litters. In normal littermate mice, BALB/c (nu/+) or C57BL/6 (bg/+), the BRM-induced resistance against MCMV infection was evidenced by increase in fifty percent lethal doses, decrease in titers of viruses replicated in the target organs and augmentation of natural killer (NK) cell activity of the spleen cells. In T cell-deficient, athymic nude mice, BALB/c (nu/nu), the protective effect was manifested by prolongation of the survival, decrease in the virus titers, and increase in the NK-cell activity, but without decrease in mortality. In NK cell-deficient, beige mutant mice, C57BL/6 (bg/bg), the BRM-induced protection was nullified or minimized, and there was little difference in those parameters between BRM-treated and untreated mice. However, with higher doses of OK-432, but not PS-K, or with sublethal doses of MCMV, the NK cell activity was slightly augmented in the beige mutant mice. Thus both NK cell and T cell activity are essential for mice to overcome acute MCMV infection and it is likely that the protective effect of BRM manifests itself fully, at least in immunologically intact mice.     

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.     

Consecutive oral administration of Bifidobacterium longum MM‐2 improves the defense system against influenza virus infection by enhancing natural killer cell activity in a murine model

Bifidobacterium, one of the major components of intestinal microflora, shows anti‐influenza virus (IFV) potential as a probiotic, partly through enhancement of innate immunity by modulation of the intestinal immune system. Bifidobacterium longum MM‐2 (MM‐2), a very safe bacterium in humans, was isolated from healthy humans and its protective effect against IFV infection in a murine model shown. In mice that were intranasally inoculated with IFV, oral administration of MM‐2 for 17 consecutive days improved clinical symptoms, reduced mortality, suppressed inflammation in the lower respiratory tract, and decreased virus titers, cell death, and pro‐inflammatory cytokines such as IL‐6 and TNF‐α in bronchoalveolar lavage fluid. The anti‐IFV mechanism of MM‐2 involves innate immunity through significant increases in NK cell activities in the lungs and spleen and a significant increase in pulmonary gene expression of NK cell activators such as IFN‐γ, IL‐2, IL‐12 and IL‐18. Even in non‐infected mice, MM‐2 administration also induced significant enhancement of both IFN‐γ production by Peyer's patch cells (PPs) and splenetic NK cell activity. Oral administration of MM‐2 for 17 days activates systemic immunoreactivity in PPs, which contributes to innate immunity, including NK cell activation, resulting in an anti‐IFV effect. MM‐2 as a probiotic may function as a prophylactic agent in the management of an IFV epidemic.     

Natural killer activity in cloned cytotoxic T lymphocytes: regulation by interleukin 2, interferon, and specific antigen

It has previously been shown that monoclonal antigen-specific mouse CTL lines can be induced to express cytolytic activity with the same specificity as that of splenic natural killer (NK) cells following culture in high concentrations of concanavalin A-induced spleen cell supernatants. In the present experiments, we made use of this in vitro system to explore the regulation of NK activity at the clonal level. Interferon-alpha and interferon-beta and interleukin 2 (IL 2) were potent inducers of NK activity in CTL, demonstrating that these substances can activate NK functions directly without the participation of other cell types. By comparison, IFN-gamma was a poor activator of NK activity in CTL (and also in fresh spleen cells). Three major differences between induction of NK activity by IFN-alpha,beta and IL 2 were noted: IFN induced NK activity selectively without affecting specific cytolysis, whereas IL 2 also enhanced specific killing; IFN acted much more rapidly than IL 2; and IFN did not induce the cells to enter the cell cycle nor were there any obvious morphologic changes. Specific antigen was also a strong inducer of NK activity in CTL, but studies with antisera against the various classes of IFN revealed that this effect was mediated, at least in part, via the release of IFN-beta. By contrast, the same antisera had no effect on NK induction by crude TCGF or by highly purified IL 2, indicating that the regulation of NK activity by IL 2 occurs at the clonal level in an IFN-independent manner. Although, IL 2, IFN, and Ag could apparently act alone to induce NK activity, much greater (synergistic) induction was obtained by various combinations of these regulators, suggesting that the delivery of two (or more) signals to the responder cell was required for full expression of the NK state. As with fresh splenic NK cells, the induced NK state in cloned CTL was intrinsically labile as revealed by its rapid decay in the absence of inducers, but it could nonetheless be maintained indefinitely at very high levels in the continued presence of inducers. This clonal system thus displays a responsiveness to regulatory signals exactly analogous to that of splenic NK cells and provides a unique and exciting opportunity to evaluate the biochemistry of the regulation of NK activity.