Induction of natural killer cell activity of thoracic duct lymphocytes by polyinosinic-polycytidylic acid (poly(I:C)) or interferon

Natural killer (NK) cell activity of thoracic duct lymphocytes (TDL) was examined in normal mice and in mice treated with polyinosinic-polycytidylic acid (poly(I:C) and interferon (IFN). TDL from mice treated with phosphate-buffered saline (PBS) expressed little or no NK cell activity against YAC-1 target cells at effector-to-target ratios of up to 200:1, even after in vitro treatment with murine L-cell IFN. In contrast, TDL from poly(I:C)- or IFN-treated mice expressed significant NK activity, which correlated with the significantly higher NK activity of splenocytes from these mice compared to the NK activity of splenocytes from PBS-treated mice. These data indicate that although TDL from normal mice express no detectable NK cell activity, NK cell activity can be induced in TDL by in vivo treatment with poly(I:C) or IFN.     

Influence of interferon on the functional expression of natural killer target structures of murine lymphoma cells

Murine lymphoma cells (YAC-1), induced by Moloney leukemia virus, nontreated (YAC) or pretreated in vitro with interferon (YAC-IF), were tested for their susceptibility to natural killer (NK)-mediated cytolysis. In line with previous reports YAC-IF were less susceptible to NK lysis than YAC cells. In cold competition assay, YAC-IF inhibited cytotoxicity to a lesser extent than YAC lymphoma when labeled target YAC cells were used. However, when radioactive YAC-IF cells were used as targets, cold competition attained with both YAC and YAC-IF was essentially the same. Furthermore, effector splenocytes, depleted of NK effector cells through immunoabsorption on YAC monolayer, were inactive against both YAC and YAC-IF targets. On the other hand, effector lymphocytes, absorbed on YAC-IF monolayer, retained NK activity against YAC cells but not against YAC-IF targets. These results are compatible with the hypothesis that interferon (IF) modulates negatively a subset of "interferon-susceptible" (IFS) NK target structure(s) (TS) of YAC cells, which would then express membrane determinants not functionally present on YAC-IF cells. On the other hand YAC and YAC-IF cells share "interferon-resistant" (IFR) TS not affected by pretreatment with IF. In order to test whether IFS X TS and IFR X TS are present on the same cell or clonally distributed, YAC cells were cloned and tested for NK susceptibility following IF pretreatment. The results did not support the hypothesis of a clonal distribution of both IFS X TS and IFR X TS since IF pretreatment of all clones, obtained by limiting dilution, resulted in a net impairment of target susceptibility to NK effector cells.     

Natural killer (NK) cells are present in mice with severe combined immunodeficiency (scid)

Spleen cells from C.B- 17 scid mice with severe combined immunodeficiency disease exhibit natural killer cell (NK) activity against YAC lymphoma targets in a standard 4-hr 51Cr release assay. The cytolytic activity is demonstrable only at high effector to target ratios but can be augmented at least sevenfold by the interferon inducer poly I:C. The pattern of target lysis is specific, because splenocytes from poly I:C-primed C.B-17 scid mice lyse NK-sensitive YAC cells and not the insensitive P815 mastocytoma. The presence of several NK-associated antigens on C.B-17 scid splenocytes was tested by pretreating cells with the appropriate antiserum plus complement before testing for NK activity. The results indicate that a proportion of NK effectors in C.B-17 scid mice bear surface NK 2.1 and Asialo GM1 but are negative for Thy-1.     

Strain difference in mouse natural killer activity augmented by mouse interferon and poly I.C

The level of natural killer (NK) activity was found to vary considerably among several mouse strains. In vivo and in vitro, interferon (IFN) and IFN inducers have been shown to augment mouse NK activity. C3H/He mice showed high NK activity, DDD/1 and A/J mice low NK activity, and C57BL/6, BALB/c and DBA/2 mice intermediate NK activity after injection with polyinosinic polycytidylic acid (poly I. C.). The same NK activity correlation was observed in nontreated mice, but the NK activities were lower compared with the poly I. C.-injected mice. Moreover, the DDD/1 and A/J mice showed almost no augmentation of NK activity on injection with poly I.C. In vivo, C3H/He, BALB/c and C57BL/6 mice injected with IFN showed augmented NK activity, but DDD/1 mice showed no such reaction. In vitro, C3H/He, BALB/c and C57BL/6 mouse spleen cells treated with IFN also showed augmented NK activity, but DDD/1 mouse spleen cells showed almost none. F1 hybrids between high (C3H/He) and low (DDD/1) NK-activity strains showed high NK activity. Thus, activity is dominant over low activity. The segregation of (DDD/1 X C3H/He) Fl X DDD/1 back-cross mice suggested that the strain differences in NK activity are under polygenic control.     

Proliferation inhibition of murine pluripotent haemopoietic stem cells by interferon or poly I:C

The effect of mouse serum interferon (IF) in vitro and an inducer in vivo on the proliferation of a pluripotent stem cell population with high turnover rate was studied. Proliferation rate was characterized by the number of CFUs in the S phase of the cell cycle. Increased proliferation of bone marrow stem cell populations was produced either by irradiating the donor mice with 3.36 Gy (336 rad) 60Co-gamma rays 7 days before the experiment or by incubating normal bone marrow cells with 10(-11) M concentration of isoproterenol. IF considerably reduced the number of CFUs in S phase in both cases without reducing the CFUs content of the samples. Injection of IF inducer (4 mg/kg poly I:C) into regenerating mice also inhibited the proliferation of CFUs without decreasing the femoral CFUs level. Regeneration kinetics of CFUs from irradiated poly I:C-treated mice ran parallel with that of irradiated untreated animals but showed a characteristic delay corresponding to approximately one CFUs doubling. A transient, non-cytotoxic proliferation inhibitory effect of IF or IF inducer is, therefore, proposed.     

Suppression of in vitro maintenance and interferon-mediated augmentation of natural killer cell activity by adherent peritoneal cells from normal mice

The ability of adherent peritoneal cells (APC) to inhibit murine natural killer (NK) cell activity was examined. Nylon wool-nonadherent splenic effector cells were incubated overnight with or without different numbers of APC. NK activity was then measured against YAC-1 in a 4-hr 51Cr-release cytotoxicity assay. Proteose peptone-elicited or unstimulated resident APC from normal mice markedly suppressed NK activity of splenic effector cells in the presence or absence of exogenously added interferon. The suppression was dependent on the number of APC added with 10% APC, relative to the number of effector cells, resulting in a greater than 65% inhibition of cytotoxicity. The effector phase of cytotoxicity was not the target of the suppressor cells, because APC did not suppress NK activity when they were present only during the cytotoxicity assay. The addition of APC to alloimmune cytotoxic T cells under similar conditions resulted in no inhibition of cytotoxicity. Both syngeneic and allogeneic APC suppressed NK activity, but several murine macrophage-like cell lines lacked this property. In contrast to APC, incubation of effector cells with adherent spleen cells from normal mice resulted in no inhibition of NK activity. APC from mice injected with C. parvum were less inhibitory for NK activity than normal resident APC. In contrast, C. parvum APC suppressed concanavalin A-induced lymphoproliferation and were directly cytotoxic to tumor target cells in vitro, whereas normal APC lacked these properties. The results indicate that the peritoneum of untreated mice contains suppressor cells that can inhibit the in vitro maintenance and IFN-mediated augmentation of NK activity. In addition, these results indicate a broader spectrum of immune reactivities regulated by APC and suggest that, depending on their level of activation, APC can preferentially inhibit different immune functions.     

Regulation of human natural killing. III. Mechanism for interferon induction of loss of susceptibility to suppression by cyclic AMP elevating agents

In this study we demonstrated that human NK cells activated by IFN or poly I:C were partially resistant to suppression by PGE2, PGD2, PGA2, PGI2, dibutyryl cAMP, isoproterenol, and theophylline. This partial loss of inhibition was not due to endogenous PG production because the addition of indomethacin to cultures stimulated with IFN or poly I:C did not prevent the partial loss of sensitivity to PGE2. NK cells incubated in the presence of PGE2 overnight, however, were not sensitive to inhibition. IFN or poly I:C did not stimulate PG synthesis nor elevate intracellular cAMP levels of NK cells. On the other hand, IFN or poly I:C diminished the accumulation of intracellular cAMP levels in NK cells in response to PGE2 stimulation. Dibutyryl cAMP and theophylline suppressed the cytolytic activity of the unstimulated cells more than that of the activated cells. A possible mechanism for the IFN-induced unresponsiveness to PGE2 may be a compartmentalized loss of cAMP responsiveness. Cycloheximide, puromycin, emetine, and actinomycin D blocked NK activation by IFN and poly I:C as well as the acquisition of resistance to PGE2-mediated suppression.     

An analysis of the natural killer cell defect in beige mice

Although C57BL/6 bg^J/bg^J mice exhibit very low or undetectable levels of endogenous natural killer cell activity, such activity can be induced by the administration of BCG or tilorone hydrochloride to these animals. This cytotoxic activity has been shown to be due to NK cells by the criteria of nylon-wool nonadherence and of effector cell sensitivity to treatment with either anti-asialo GM₁ serum or high concentrations of anti-Thy 1.2 serum, in the presence of complement. Even after the administration of inducing agents, however, beige mice continue to display significantly less NK activity than do their heterozygous littermates. In an attempt to ascertain what cell might be defective in responding to induction, we utilized an in vitro system in which the induction of NK activity by poly I:C in a nylon-wool nonadherent population is dependent upon plastic-adherent cells. We found that adherent cells from either beige or heterozygous mice were indistinguishable in their ability to restore the NK response of nylon-wool-nonadherent spleen cells stimulated with poly I:C. This was true when either beige or heterozygous mice were used as the source of responder cells. Thus, it appears that the defect in responsiveness to inducing agents may reside in the beige NK cell itself.     

The role of Ia antigens in the activation of T cells by concanavalin A: an evidence for the species restriction between T cells and accessory cells

Comparisons were made between the characteristics of cytotoxicity activation in mouse spleen cells, induced by specific anti-H-2 antiserum, interferon (IF), interferon inducer (poly (I:C)), and mitogens (concanavalin A (Con A), pokeweed mitogen (PWM)). Important differences were found in the cytotoxicity activation associated with these agents: (a) The cytotoxic enhancing effect of anti-H-2 antiserum was comparatively rapid and was more pronounced in the first 4 hr of the assay, whereas, IF, poly (I:C), and the mitogens were most effective at 20 hr. (b) Anti-IF antiserum could neutrilize the stimulatory effects of IF and poly (I:C) on the cytotoxic activity of mouse spleen cells but had no influence on the stimulatory effects of anti-H-2 antiserum, PWM, and succinyl Con A. (c) The stimulatory effect of anti-H-2 antiserum was target specific and was observed when the K562 cell line was used as the target but not when YAC, P815, or WFu/G1 target cell lines were used. Stimulatory effects of all the other agents were nonspecific and did not depend on the target cells employed. (c) Cellular fractionation studies suggested that the alloantisera and interferon directly activated the natural killer (NK) cells without any participation of T-cells, B-cells, or macrophages. Both T-cells and NK cells, however, contributed to the mitogen-enhanced cytotoxicity of mouse spleen cells. These results indicated that the mechanism by which anti-H-2 antisera induce NK augmentation in mouse spleen cells is distinct from that of interferon and mitogens.     

Distinct requirements for IFNs and STAT1 in NK cell function

NK cell functions were examined in mice with a targeted mutation of the STAT1 gene, an essential mediator of IFN signaling. Mice deficient in STAT1 displayed impaired basal NK cytolytic activity in vitro and were unable to reject transplanted tumors in vivo, despite the presence of normal numbers of NK cells. IL-12 enhanced NK-mediated cytolysis, but poly(I:C) did not, and a similar phenotype occurred in mice lacking IFNalpha receptors. Molecules involved in activation and lytic function of NK cells (granzyme A, granzyme B, perforin, DAP10, and DAP12) were expressed at comparable levels in both wild-type and STAT1(-/-) mice, and serine esterase activity necessary for CTL function was normal, showing that the lytic machinery was intact. NK cells with normal cytolytic activity could be derived from STAT1(-/-) bone marrow progenitors in response to IL-15 in vitro, and enhanced NK lytic activity and normal levels of IFN-gamma were produced in response to IL-12 treatment in vivo. Despite these normal responses to cytokines, STAT1(-/-) mice could not reject the NK-sensitive tumor RMA-S, even following IL-12 treatment in vivo. Whereas in vitro NK cytolysis was also reduced in mice lacking both type I and type II IFN receptors, these mice resisted tumor challenge. These results demonstrate that both IFN-alpha and IFN-gamma are required to maintain NK cell function and define a STAT1-dependent but partially IFN-independent pathway required for NK-mediated antitumor activity.     

TLR7/8-mediated activation of human NK cells results in accessory cell-dependent IFN-gamma production

NK cells express receptors that allow them to recognize pathogens and activate effector functions such as cytotoxicity and cytokine production. Among these receptors are the recently identified TLRs that recognize conserved pathogen structures and initiate innate immune responses. We demonstrate that human NK cells express TLR3, TLR7, and TLR8 and that these receptors are functional. TLR3 is expressed at the cell surface where it functions as a receptor for polyinosinic acid:cytidylic acid (poly(I:C)) in a lysosomal-independent manner. TLR7/8 signaling is sensitive to chloroquine inhibition, indicating a requirement for lysosomal signaling as for other cell types. Both R848, an agonist of human TLR7 and TLR8, and poly(I:C) activate NK cell cytotoxicity against Daudi target cells. However, IFN-gamma production is differentially regulated by these TLR agonists. In contrast to poly(I:C), R848 stimulates significant IFN-gamma production by NK cells. This is accessory cell dependent and is inhibited by addition of a neutralizing anti-IL-12 Ab. Moreover, stimulation of purified monocyte populations with R848 results in IL-12 production, and reconstitution of purified NK cells with monocytes results in increased IFN-gamma production in response to R848. In addition, we demonstrate that while resting NK cells do not transduce signals directly in response to R848, they can be primed to do so by prior exposure to either IL-2 or IFN-alpha. Therefore, although NK cells can be directly activated by TLRs, accessory cells play an important and sometimes essential role in the activation of effector functions such as IFN-gamma production and cytotoxicity.     

Activation Mechanisms of Natural Killer Cells during Influenza Virus Infection

During early viral infection, activation of natural killer (NK) cells elicits the effector functions of target cell lysis and cytokine production. However, the cellular and molecular mechanisms leading to NK cell activation during viral infections are incompletely understood. In this study, using a model of acute viral infection, we investigated the mechanisms controlling cytotoxic activity and cytokine production in response to influenza (flu) virus. Analysis of cytokine receptor deficient mice demonstrated that type I interferons (IFNs), but not IL-12 or IL-18, were critical for the NK cell expression of both IFN-γ and granzyme B in response to flu infection. Further, adoptive transfer experiments revealed that NK cell activation was mediated by type I IFNs acting directly on NK cells. Analysis of signal transduction molecules showed that during flu infection, STAT1 activation in NK cells was completely dependent on direct type I IFN signaling, whereas STAT4 activation was only partially dependent. In addition, granzyme B induction in NK cells was mediated by signaling primarily through STAT1, but not STAT4, while IFN-γ production was mediated by signaling through STAT4, but not STAT1. Therefore, our findings demonstrate the importance of direct action of type I IFNs on NK cells to mount effective NK cell responses in the context of flu infection and delineate NK cell signaling pathways responsible for controlling cytotoxic activity and cytokine production.     

Depletion of T cells by type I interferon: differences between young and aged mice

Type I IFN (IFN-I or IFN-alphabeta) plays an important role in the innate immune response against viral infection. Here we report that a potent inducer of IFN-alphabeta, polyinosinic-polycytidylic acid [poly(I:C)], led to the depletion of T cells in young, but not aged mice, and that this depletion was limited to central memory, but not effector memory, T cells. Although early activation of T cells in vivo by poly(I:C), as demonstrated by CD69, was not impaired with aging, the expression of active caspase-3 was higher in young compared with aged mice. This depletion of T cells and induction of active caspase-3 in young mice and of CD69 in both young and aged mice by poly(I:C) were blocked by anti-IFN-alphabeta Ab. Although poly(I:C) stimulated lower circulating levels of IFN-alphabeta in aged mice, administration of IFN-alphabeta after poly(I:C) did not induce depletion of T cells in aged mice. These results indicate that IFN-alphabeta plays a critical role in the depletion of T cells of young mice, and further suggest that the lower level of functional IFN-alphabeta and decreased induction of active caspase-3 in T cells of aged mice after poly(I:C) may be responsible for the increased resistance of T cells of aged mice to depletion.     

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.     

NKG2D-RAE-1 receptor-ligand variation does not account for the NK cell defect in nonobese diabetic mice

NK cells from NOD mice induced with poly(I:C) in vivo exhibit low cytotoxicity against a range of target cells, but the genetic mechanisms controlling this defect are yet to be elucidated. Defects in the expression of NKG2D and its ligands, the RAE-1 molecules, have been hypothesized to contribute to the reduced NK function present in NOD mice. In this study, we show that segregation of the NK-mediated killing phenotype did not correlate with the NOD Raet1 haplotype and that the large alterations in NKG2D expression previously reported on NK cells expanded in vitro were not observed in primary, poly(I:C)-elicited NK cells in vivo. Additional studies indicate a complex genetic control of defective NOD NK cells including genes linked to the MHC and possibly those that are associated with an altered cytokine response to the TLR3-agonist poly(I:C).     

Changes in the host natural killer cell population in mice during tumor development. 2. The mechanism of suppression of NK activity

Our earlier studies revealed that a rapid and progressive loss of splenic NK activity in mice during the development of a number of transplanted tumors as well as of spontaneous tumors was due to an inactivation of natural killer (NK) lineage cells rather than to their disappearance. The mechanism of this inactivation have now been explored in CBA/J mice receiving transplanted Ehrlich ascites tumors and in C3H/HeJ mice bearing spontaneous mammary tumors or receiving transplants of syngeneic mammary tumor lines of recent origin. A poor activation state or maturation arrest of NK lineage cells due to a low interferon level in vivo was ruled out, since the host NK activity could not be restored after administration of either an interferon inducer poly(I:C) or interferon-alpha, although such treatments enhanced the activity in tumor-free mice by four- to eightfold. Possible presence of host suppressor cells acting on the effector or preeffector stage of NK cells was explored by mixing spleen cells from tumor bearers with normal spleen cells either during the NK assay, or for a 20-hr period of in vitro short-term culture prior to the NK assay. Mixing during the NK assay led to a reduction of NK activity explicable by a simple dilution of active NK cell concentration rather a suppression of active NK cells. On the other hand, a 20-hr coculture of the mixed population at various ratios led to a complete abrogation of the NK activity, indicating that the suppressor cells acted on the preeffector stage of the NK Lineage. A further characterization of suppressor cells revealed that they were (1) contained in the adherent fraction of the spleen of tumor bearers, (2) of monocyte/macrophage morphology, (3) capable of phagocytosing latex particles, and (4) positive for surface Mac-1 antigen, as noted from a radioautographic binding of 125I-labeled monoclonal anti-Mac-1 antibody. The mechanism of the suppression was identified, at least in part, as being mediated by prostaglandin-like molecules, since the presence of indomethacin, a prostaglandin-inhibitor, during the 20-hr coculture period completely abrogated the suppression. Indomethacin exerted no direct effect on the recruitment or killer activity of NK lineage cells in vitro. NK cell suppression may be another normal immunoregulatory mechanism which alters the host-tumor balance in favor of the tumor rather than the host.     

Natural killer cell regulation of murine embryonic pulmonary fibroblast survival in vivo

We examined the role of the natural killer (NK) cell in controlling the survival of embryonic pulmonary fibroblasts in vivo. In vitro, both primary embryonic fibroblasts and an embryonic fibroblast line (10T1/2) were lysed by syngeneic C3H/HeN splenocytes threefold more efficiently than primary adult fibroblasts. The membrane phenotype of the effector cells was typical of NK cells. It was asialo GM1+, Lyt2.1-, Lyt 1.1-, Thy 1.2-. The cytotoxicity of the effector cell could be enhanced by IFN-alpha/beta but was deficient in the C3H/HeJ bg/bg mutant. Iododeoxyuridine (131I-dUrd)-labeled embryonic fibroblasts were injected intravenously into syngeneic mice with either enhanced or deficient NK function and their survival in the lung was quantitated. Enhanced fibroblast survival was detected in the NK deficient C3H/HeJ beige (bg/bg) mutant strain compared to its normal littermate C3H/HeJ (bg/+). A second method of NK depletion by pretreatment with rabbit anti-asialo GM1 antiserum also produced a striking increase in fibroblast survival. Poly(I:C) significantly enhanced the elimination of pulmonary fibroblasts from the lung between 4 and 24 hr after injection. Poly(I:C) did not enhance clearance of pulmonary fibroblasts in the C3H/HeJ (bg/bg) mutant, but did so in the normal littermate C3H/HeJ (bg/+). In conclusion, we have shown that the survival of embryonic pulmonary fibroblasts was inversely correlated with in vivo NK activity suggesting a possible role for this cytotoxic cell in the control of fibroblast growth in vivo.     

The reciprocal interaction of NK cells with plasmacytoid or myeloid dendritic cells profoundly affects innate resistance functions

A reciprocal activating interaction between NK cells and dendritic cells (DC) has been suggested to play a role in the functional regulation of these cells in immunity, but it has been studied only using in vitro generated bone marrow- or monocyte-derived DC. We report that human peripheral blood plasmacytoid DC (pDC) and myeloid DC are necessary to induce NK cell function depending on the type of microbial stimulus. pDC and myeloid DC are required for strongly increased NK cytolytic activity and CD69 expression, in response to inactivated influenza virus or CpG-containing oligonucleotides and poly(I:C), respectively. Secreted type I IFN is required and sufficient for the augmentation of NK cell cytolytic activity in the coculture with pDC or myeloid DC, whereas CD69 expression is dependent on both type I IFN and TNF. In addition, in response to poly(I:C), myeloid DC induce NK cells to produce IFN-gamma through a mechanism dependent on both IL-12 secretion and cell contact between NK cells and myeloid DC, but independent of type I IFN. IL-2-activated NK cells have little to no cytolytic activity for immature myeloid DC and pDC, but are able to induce maturation of these cells. Moreover, IL-2-activated NK cells induce, in the presence of a suboptimal concentration of CpG-containing oligonucleotides, a strong IFN-alpha and TNF production. These data suggest that the reciprocal functional interaction between NK cells and either pDC or myeloid DC may play an important physiological role in the regulation of both innate resistance and adaptive immunity to infections.     

Experimental immunotherapy with NK-like cells

Summary Natural killer (NK) cell activity was generated in the spleen of C3H/HeN mice by i.p. administration of poly I:C, while i.p. injection of BCG primarily promoted the generation of NK-like cells in peritoneal exudates (PE). A single injection of 10 mg of BCG 9 days before s.c. challenge with the MBT-2 murine bladder cancer was found to induce a 45% protection against tumor take. However, a single injection of 100 g poly I:C 16 h before tumor cell challenge did not protect the animals against tumor take. Intratumoral injection of either PE cells from BCG-immunized or spleen cells from poly I:C-treated mice into mice developing tumor, was capable of suppressing tumor growth in vivo. The mean tumor diameters of these two experimental groups of animals on day 40 were significantly smaller (P<0.005) than in the controls, and they survived approximately 10 days longer than the controls. Since this in vivo tumor suppressive effect by the lymphoid cell population correlated with the increase in NK-like cell activity assayed in vitro, and most of the adherent cells had been removed before injection, it is suggested that the antitumor function of the lymphoid cell population may be mostly due to the presence of activated NK or NK-like cells. These results support the concept of NK therapy for cancer.This study was supported by a grant from the Cancer Research Institute of New York     

Regulation of human natural killing. II. Protective effect of interferon on NK cells from suppression by PGE2

Activation of human natural killer (NK) cells in vitro with interferon (IFN) and poly I:C results in a partial loss of sensitivity of these cells to suppression by PGE2. The acquired resistance to suppression can be induced with the large granular lymphocytes (LGL) in the absence of monocytes. With K562, HSB, and CEM used as NK target cells, the IFN-induced resistance to suppression by PGE2 is observed with all three target cells. Furthermore, ADCC activity of IFN-activated cells against tumor (SB-TNP) and erythroid (CRC-TNP) target cells is also less susceptible to suppression by PGE2. The dual effect of IFN on NK cells is prompt; the augmentation of NK activity and the acquired resistance to suppression by PGE2 can be seen after 3 hr of treatment with IFN. Both of these characteristics seem to be quite stable for at least 24 hr. Spleen cells from mice (CBA, C3H, and BALB/c nude) treated in vivo with poly I:C also acquire partial resistance to suppression by PGE2. Our data therefore suggest that IFN-stimulated NK cells are protected from suppression by PGE2. Biologically, the IFN-induced protective effect may be beneficial to host resistance to neoplasia.