Activation of human natural killer cells by lipopolysaccharide and generation of interleukin-1 alpha, beta, tumour necrosis factor and interleukin-6. Effect of IL-1 receptor antagonist.

The presence in the body of an antigen species or a bacterial lipopolysaccharide (LPS) has a pleiotropic effect on the immune system activating macrophages, lymphocytes and natural killer (NK) cells. Recently it has been reported that human macrophages not only secrete interleukin-1 (IL-1) but also its inhibitor, called IL-1 receptor antagonist (IL-1ra), structurally similar to IL-1 beta, but with no IL-1-like activity and which binds to the IL-1 receptor. In this study we show that LPS stimulates NK cell activity and IL-1ra potentiates the stimulatory effect of human recombinant interleukin-2 (hrIL-2) on NK cell activity. In addition, we found that hrIL-1ra inhibits DNA synthesis in lymphocyte culture stimulated with phytohaemagglutinin (PHA) (20 micrograms/ml), presumably via IL-1 inhibition. We also found that LPS is a potent stimulator of monokines: IL-6, tumour necrosis factor-alpha (TNF-alpha), and IL-1 beta, as determined by radioimmunoassay method, and interferon-gamma (IFN-gamma), IL-2, TNF-alpha and IL-1 alpha, as determined by ELISA method, in peripheral blood mononuclear cells (PBMC). We used PBMC as effector cells since LPS requires the presence of accessory cells to activate lymphocytes and bind to the HLA-DR molecule on accessory cells. The effect of LPS on PBMC cytotoxicity has been compared with an endotoxin-free extract of Escherichia coli, OM-8990, which did not provoke cytokine production nor did it cause enhancement of NK cell activity. We found that human recombinant IL-1ra potentiates the stimulatory effect of IL-2 on NK cell activity, similar to hrIL-1 beta. The potentiation of IL-2 in stimulating NK cell activity by IL-1ra is not yet understood. Since IL-1ra is a part of the IL-1 family, it may work in a similar fashion to IL-1, which also potentiates IL-2 to enhance NK cell activity but has been shown not to be directly important in tumour cell killing. In addition, hrIL-1ra can amplify the effect of IL-2 on NK activity, possibly by inhibiting the cyclo-oxygenase products, which are immunosuppressive and are generated in antigen-stimulated PBMC cultures. The generation of IFN-gamma by PBMC after treatment with LPS strongly suggests that the enhancement of NK cell activity may be indirectly due to IFN production.     

NK cells recognize and lyse Ewing sarcoma cells through NKG2D and DNAM-1 receptor dependent pathways

INTRODUCTION: Ewing sarcoma (EWS) is a malignant bone-associated sarcoma, with poor prognosis in case of metastasis or relapse. To explore the feasibility of natural killer (NK) cell mediated immunotherapy and to identify molecular mechanisms involved, the susceptibility of EWS to NK cells was investigated. METHODS AND RESULTS: All EWS cell lines tested (n=7) were lysed by purified allogeneic NK cells from healthy donors, and the efficacy of lysis was increased by activating NK cells with interleukin-15 (IL-15). FACS analysis and immunohistochemistry revealed that EWS cell lines as well as primary tumor cells expressed ligands for the activating NK cell receptors NKG2D and DNAM-1. NK cell cytotoxicity to EWS cells critically depended on the combination of NKG2D and DNAM-1 signaling, since blocking either of these receptors abrogated lysis by resting NK cells. Cytokine-activated NK cells more efficiently recognized EWS cells, since only combined, but not single blockade of NKG2D and DNAM-1 by antibodies inhibited lysis of EWS cells. Induction or blockade of HLA class I on EWS cells did not significantly influence lysis. This suggests that predominantly activating, rather than inhibitory signals on EWS cells determined susceptibility to NK cell cytotoxicity. NK cell cytotoxicity to EWS cells and K562 was reduced in EWS patients at diagnosis (n=11) compared to age matched controls, despite normal NK cell numbers and increased expression of NKG2D. The impaired function of these NK cells was restored after activation with IL-15 in vitro. CONCLUSION: These results demonstrate that EWS cells are potentially susceptible to NK cell cytotoxicity due to the expression of activating NK cell receptor ligands. The use of cytokine-activated NK cells rather than resting NK cells in immunotherapy may be instrumental to optimize NK cell reactivity to EWS.     

The marginating-pulmonary immune compartment in mice exhibits increased NK cytotoxicity and unique cellular characteristics

To test whether marginating-pulmonary (MP) leukocytes in mice have a unique potential to identify and destroy aberrant circulating cells, we compared MP to circulating leukocytes with respect to natural killer (NK) cytotoxicity, proinflammatory characteristics, molecular determinants of activation, and response to IL-12 immunostimulation. Cytotoxicity was assessed employing the YAC-1, B16F10, and 3LL target lines. C57BL/6 mice were injected with either saline or murine IL-12 (0.1 or 0.5 µg/mouse), either once or three times 48-h apart. Twenty-four hours after last injection, cardiac blood was withdrawn and MP leukocytes were collected by forced lung perfusion. NK cytotoxicity, cellular composition, and surface molecular markers were studied. MP leukocytes exhibited greater NK cytotoxicity than circulating leukocytes against the syngeneic B16F10 and 3LL tumor lines, but not against the allogeneic YAC-1 line. NKG2D and IL-12 receptor expression predicted NK cytotoxicity in circulating leukocytes, but not in MP leukocytes. IFNγ-receptor, IL-12-receptor, CD69, CD11a, and CD11b showed different patterns of expression in the two leukocyte populations, suggesting pro-inflammatory characteristics of the MP compartment. IL-12 stimulation caused differential effects on these markers and also elevated cytotoxicity in both compartments, but in different effector: target ratio-dependent patterns. MP leukocytes may play a critical role in eliminating aberrant circulating cells due to their enhanced NK cytotoxicity and given their strategic location in the lungs vasculature, which forces physical interactions with all circulating aberrant cells. MP-NK cells are unique in their cytotoxic mechanisms against syngeneic targets and in their activation profile and response to immunostimulatory agents.     

The protozoan Neospora caninum directly triggers bovine NK cells to produce gamma interferon and to kill infected fibroblasts

Natural killer (NK) cells are considered to be key players in the early innate responses to protozoan infections, primarily indirectly by producing gamma interferon (IFN-gamma) in response to cytokines, like interleukin 12 (IL-12). We demonstrate that live, as well as heat-inactivated, tachyzoites of Neospora caninum, a Toxoplasma-like protozoan, directly trigger production of IFN-gamma from purified, IL-2-activated bovine NK cells. This response occurred independently of IL-12 but was increased by the addition of the cytokine. A similar IFN-gamma response was measured in cocultures of NK cells and N. caninum-infected autologous fibroblasts. However, no NK cell-derived IFN-gamma response was detected when cells were cultured with soluble antigens from the organism, indicating that intact tachyzoites or nonsoluble components are necessary for NK cell triggering. Furthermore, N. caninum-infected autologous fibroblasts had increased susceptibility to NK cell cytotoxicity compared to uninfected fibroblasts. This cytotoxicity was largely mediated by a perforin-mediated mechanism. The activating receptor NKp46 was involved in cytotoxicity against fibroblasts but could not explain the increased cytotoxicity against infected targets. Interestingly, N. caninum tachyzoites were able to infect cultured NK cells, in which tachyzoites proliferated inside parasitophorous vacuoles. Together, these findings underscore the role of NK cells as primary responders during a protozoan infection, describe intracellular protozoan infection of NK cells in vitro for the first time, and represent the first functional study of purified bovine NK cells in response to infection.     

Regulation of NK92-MI cell cytotoxicity by substance P

The neuropeptide substance P (SP) can regulate a number of immunological functions in vitro and in vivo and may regulate natural killer (NK) cell activity. Here, we investigated whether SP has a role in regulating NK92-MI cell function in vitro, and how it influences NK cell activity. We found that SP dose dependently increased the cytotoxicity of NK92-MI cells and had a maximal effect at a concentration of 10(-12) and 10(-10) m. Furthermore, the expression of cytotoxic-associated molecules (perforin, granzyme) and activating receptor NKp46 [a member of natural cytotoxicity receptors (NCRs)] was observed to be upregulated by SP at optimal concentration, at which SP enhanced the cytotoxicity of NK92-MI cells. Neurokinin-1 receptor (NK-1R), a functional receptor of SP, was found on NK92-MI cells, and the observed effects of SP on NK92-MI cells could be more partially blocked by an NK-1R antagonist. Our data suggest that SP induces NK92-MI cell cytotoxicity by directly increasing the expression of cytotoxic granules and upregulates NK92-MI cell receptor-mediated functions indirectly. Thus, SP may regulate NK cell function mainly through NK-1R.     

Divergent effects of FcγRIIIA ligands on the functional activities of human natural killer cells in vitro

The Fcγ receptor (R)IIIA (CD16) plays an important role in regulating the cytotoxic and non-cytotoxic functions of human natural killer (NK) cells. Some anti-CD 16 monoclonal antibodies (mAb) have been shown to stimulate NK activity, while human monomeric (m) IgG induces dose-dependent inhibition of NK activity. To explore further these interactions mediated via FcγRIIIA, purified NK cells were cultured for 2–3 days in the presence of mIgG, 3G8 mAb, interleukin-2 (IL-2) or a combination of mIgG or 3G8 with IL-2. Binding of mIgG or 3G8 to FcγRIIIA induced divergent effects of functions of cultured NK cells: 3G8 mAb + IL-2 induced dose-dependent inhibition of proliferation attributable to apoptosis; in contrast, mIgG + IL-2 significantly increased NK cell proliferation. Incubation of NK cells in the presence of mIgG up-regulated expression of surface activation markers (CD69, IL-2Rα, ICAM-1), cytotoxicity, cytokine production (IL-1β, IFN-γ and TNF-α) and release of soluble IL-2R. Thus, mIgG binding to FcγRIIIA induced stimulatory signals in human NK cells, leading to up-regulation of IL-2Rα expression, cell proliferation and cytokine release.     

Enhancing effect of natural killer cell stimulatory factor (NKSF/interleukin-12) on cell-mediated cytotoxicity against tumor-derived and virus-infected cells

Natural killer cell stimulatory factor (NKSF) or interleukin-12 (IL-12) is a heterodimeric cytokine with pleiomorphic effects on T and NK cells, including induction of lymphokine production, mitogenesis, and enhancement of spontaneous cytotoxic activity. Similarly to IL-2, NKSF/IL-12 enhances NK cell-mediated cytotoxicity within a few hours and independently from induced proliferation. This effect is independent from other induced cytokines, because it is not prevented by antibodies neutralizing interferon (IFN)-α, IFN-β IFN-γ, IL-2 or tumor necrosis factor (TNF)-α and, unlike the induction of IFN-γ production by peripheral blood lymphocytes, it does not require HLA class II-positive accessory cells. Enhanced cytotoxicity is accompanied by morphologic changes in NK cells, including a significant increase in the number of cytoplasmic granules. In addition to the previously described ability to enhance the cytotoxic activity of NK cells against tumor-derived target cells, NKSF/IL-12 is also a potent stimulator of cytotoxicity against virus-infected cells, either fibroblasts acutely infected with herpes viruses or T cell lines chronically infected with human immunodeficiency virus-1. NK cell-mediated antibody-dependent cytotoxicity or anti-CD16 antibody-redirected lysis is not significantly enhanced by NKSF/IL-12. However, the ability of resting peripheral blood T cells to mediate anti-CD3 antibody-redirected lysis is enhanced by 18-h incubation with NKSF/IL-12, indicating that this lymphokine can modulate the cytotoxic capability of both NK and T cells.     

Human NK1 and NK2 subsets determined by purification of IFN-gamma-secreting and IFN-gamma-nonsecreting NK cells

The in vivo existence of human NK cell subsets similar to Th1 and Th2 cells was demonstrated in freshly isolated IFN-gamma-secreting and IFN-gamma-nonsecreting NK cells. The IFN-gamma-secreting NK subset showed a typical cytokine pattern with predominant expression of IFN-gamma, but almost no IL-4, IL-5 and IL-13. In contrast, the IFN-gamma-nonsecreting NK subset was composed of IL-4, IL-5 and IL-13-producing NK cells. Short-time stimulation or 2 weeks of in vitro differentiation of NK cells led to distinct patterns of cytokine production similar to freshly-purified IFN-gamma (+) or IFN-gamma (-) NK cell subsets. NK cells stimulated with IL-12 produced increased levels of IFN-gamma and decreased levels of IL-4. In contrast, stimulation of NK cells with IL-4 inhibited IFN-gamma, but increased IL-13 production. Freshly-purified IFN-gamma (+) and IFN-gamma (-) or in vitro differentiated NK1 and NK2 subsets showed similar cytotoxicity to K562 cells. These results demonstrate that circulating NK cells retain effector subsets in humans with distinct cytokine profiles and may display different inflammatory properties.     

Vav-1 regulates NK T cell development and NK cell cytotoxicity

The hematopoietic-specific Rho-family GTP exchange factor Vav-1 is a regulator of lymphocyte antigen receptor signaling and mediates normal maturation and activation of B and T cells.Recent findings suggest that Vav-1 also forms part of signaling pathways required for natural and antibody dependent cellular cytotoxicity (ADCC) of human NK cells. In this study, we show that Vav-1 is also expressed in murine NK cells. Vav-1(-/-) mice had normal numbers of splenic NK cells, and these displayed a similar expression profile of NK cell receptors as wild-type mice. Unexpectedly, IL-2-activated Vav-1(-/-) NK cells retained normal ADCC. Fc-receptor mediated activation of ERK, JNK, and p38 was also normal. In contrast, Vav-1(-/-) NK cells exhibited reduced natural cytotoxicity against EL4, C4.4.25, RMA and RMA/S. Together, the results demonstrate that Vav-1 is dispensable for mainstream NK cell development, but is required for NK natural cytotoxicity. Unlike the findings for NK cells, NK T cells were dramatically diminished in Vav-1(-/-) mice and splenocytes from Vav-1 mutant mice failed to produce IL-4 in response to in vivo CD3 stimulation. These data highlight the important role of Vav-1 in NK T cell development and NK cell function.     

High-density oligonucleotide array analysis reveals extensive differences between freshly isolated blood and hepatic natural killer cells

Hepatic NK cells are more cytotoxic than blood NK cells against tumor cells. To understand the basis of this difference in cytotoxicity we analyzed RNA derived from freshly isolated rat blood and hepatic NK cells [high-density (HD) and low-density subpopulations] by high-density oligonucleotide arrays (Affymetrix), containing about 9,000 genes and expressed sequence tags. IL-2-treated blood NK (A-NK) cells and IL-2-treated hepatic HD cells were used as a reference of NK cell activation. About 150 genes and expressed sequence tags were differentially expressed between hepatic and blood NK cells. Surprisingly, more than half of the increased expressed genes in hepatic NK cells were not increased in A-NK cells. Differentially expressed genes like the stem cell factor receptor c-kit and the chemokine receptor CCR5 can contribute to the homing and differentiation of hepatic NK cells in the liver sinusoids. Several of the differentially expressed genes can possibly contribute to the enhanced cytotoxic activity of hepatic NK cells: cell membrane receptors like NKG2D, NKG2C, CD94, ecto-ATPase; signaling molecules like phosphatidylinositol 3-kinase; granule-associated effector molecules like granzymes and defensin NP3. Moreover, it appears that redirection of cytotoxic granules and increase in intracellular Ca2+ are convergence points of several of these genes.     

Modulation of the surface expression of CD158 killer cell Ig-like receptor by interleukin-2 and transforming growth factor-beta

Killer cell Ig-like receptor (KIR) binds to HLA class I molecules on the surface of target cells, and it confers inhibitory signals to NK cells. Although NK cytotoxicity can be affected by the change of the surface expression of KIR on NK cells, the effect of cytokines on the regulation of KIR expression has not been thoroughly investigated. Here in our study, we investigated the effect of several cytokines, including IL-2, TGF-beta, IFN-gamma, IL-12 and IL-18, on the surface expression of CD158 KIR, which binds to HLA-C, by the use of FACS analysis. In the isolated NK cells, IL-2 obviously increased the surface expression of CD158 KIR after 72 hr in vitro culture, and this was evidenced by the increased percentage of CD158(+) NK cells and the increased mean fluorescence intensity of CD158 in CD158(+) NK cells. In contrast, TGF-beta decreased the surface expression of CD158 KIR after 72 hr culture. However, IFN-gamma, IL-12 and IL-18 did not change the expression of CD158 KIR. The modulated expression of KIR by IL-2 and TGF-beta can be associated with the changed NK-cytotoxic target-discriminating ability of NK cells upon their exposure to IL-2 and TGF-beta.     

Interleukin-10 promotes NK cell killing of autologous macrophages by stimulating expression of NKG2D ligands

Under inflammatory conditions, the pleiotropic cytokine interleukin-10 (IL-10) is released in many tissues. It mediates anti-inflammatory effects in particular by inhibiting the release of T helper type 1 (Th1) cytokines. In contrast, we show here that NK cell cytotoxicity against autologous macrophages is elevated if both cell types are cultured with IL-10. The expression of most activatory NK receptors is increased after culture in the presence of IL-10. On the other hand, macrophages cultured in the presence of IL-10 show elevated expression of the NKG2D ligands major histocompatibility complex (MHC) class 1-like molecules (MIC) - A and - B, as well as UL-16 binding proteins (ULBP) - ULBP-1, ULBP-2 and ULBP-3. By masking the interaction of NK cells with macrophages through interruption of the NKG2D receptor with its ligands, we could reverse the IL-10-induced lysis of macrophages. Our data therefore reveal that IL-10 may exert a novel immunomodulatory role by stimulating NKG2D ligand expression on macrophages, thereby rendering them susceptible to NK cell elimination. This suggests that NK cells would delete macrophages and potentially other immature antigen-presenting cells (APC) or their precursors under inflammatory conditions as a feedback mechanism to shut off uncontrolled immune responses.     

Interleukin-12 induces cytotoxic NK1+ alpha beta T cells in the lungs of euthymic and athymic mice.

We recently reported that interleukin-12 (IL-12) stimulated hepatic NK1.1 Ag+ alpha beta T cells with intermediate T-cell receptor (TCR; NK1+ TCRint cells) and enhanced their NK1 expression (NK1high TCRint), and that these cells acquire strong major histocompatibility complex (MHC) unrestricted cytotoxicity in C57BL/6 mice, both +/+ and nu/nu. In the present study, we find that although murine lung normally has few NK1+ TCRint cells, NK1high TCRint cells are induced in+/+ and nu/nu mice after systemic administration of IL-12; these cells exhibit strong MHC unrestricted cytotoxicity against NK-sensitive and -resistant targets. A small number of NK1high TCRint cells was also found in peripheral blood after increased amounts of IL-12 were administered. Cytotoxicity tests in vitro revealed that the cytotoxic activity of the lung mononuclear cells (MNC) of C57BL/6 mice induced by IL-12 was abrogated by the depletion of either NK1+ or CD3+ cells, but not of CD8+ cells, as reportedly was the case of hepatic MNC, suggesting that NK1high TCRint cells are an antimetastatic population not only in the liver but also in the lung of mice. IL-12 injection into mice markedly elevates serum interferon-gamma (IFN-gamma) levels. However, although IL-12-induced cytotoxicity of NK1high TCRint cells was significantly reduced by anti-IFN-gamma antibody injection (which decreased serum IFN-gamma to an undetectable level), the appearance of NK1high TCRint cells in the lung and liver was not so affected. These results suggest that IFN-gamma is an important mediator of the cytotoxicity of NK1high TCRint cells but is not an essential factor for induction of these cells. We also added data showing that IL-12 has a broad antimetastatic effect against various liver and lung metastatic tumours intravenously injected into several strains of mice, including NK-deficient bg/bg mice. It can be considered that, in addition to NK cells, CD8+ cytotoxic T cells and gamma delta T cells, NK1+ TCRint cells can be categorized as one of the cytotoxic effector populations. These novel type cells distinct from regular T cells may play an important role in monitoring intra- and perivascular areas.     

Non-adaptive cellular immune responses as studied in euthymic and athymic nude rats

Summary The athymic nude (rnu) rat lacks a functional thymus and normal alloreactive T cells. These animals, therefore, have been widely used as tools for studying thymus-independent immune responses. The absence of functional T cells would, to most investigators, indicate that these rats have a defective cellular immune defence. However, although rnu rats accept organ allografts infinitely, they are nevertheless capable of rejecting allografts consisting of lymphocytes or bone marrow cells with increased vigour, and this via antibody-independent mechanisms. These rejection phenomena have operationally been termed allogeneic lymphocyte cytotoxicity (ALC) and allogeneic bone marrow cell cytotoxicity (ABC). Unlike organ allograft immunity this kind of rejection requires no presensitization of the recipient and is surprisingly rapid: it commences within a few hours of i.v. injection of the allogeneic cells and is usually complete by 24 h. Moreover, products coded for by genes within, or closely linked to the major histocompatibility complex (MHC), are clearly involved in the interaction between effector and target cells, as grafted cells from MHC-congenic rat strains are vigorously rejected.In contrast to the defective T cell immune responses in athymic nude rats, the natural killer (NK) cell function is not impaired, and it has been suggested that the spontaneous rejection of MHC-incompatible lymphohematopoietic cells is in fact mediated by NK cells. If the MHC antigens themselves serve as targets in this kind of allorejection, this hypothesis is in apparent contrast with the prevailing view that recognition by NK cells is not guided by, or directed against, MHC-antigens on the target cell surface.Ageing athymic nude mice and rats generate cells that rearrange and express T cell receptor (TCR) genes, and this has raised the possibility that T cells or T-like cells in athymic nude animals are responsible for ALC and ABC. This possibility urged the device of an in vitro test system for identification and further characterization of the effector cells in these rejection phenomena. Under appropriate conditions, cells from the rnu rat spleen or liver with natural killer function, i.e. the ability to lyse certain kinds of tumor cells in vitro, are also spontaneously cytotoxic for allogeneic small lymphocytes and bone marrow cells in vitro. Furthermore, these cells can be grown in vitro in the presence of interleukin 2 (IL-2) to generate populations of lymphokine-activated killer (LAK) cells, and these cells have the same spectrum of alloreactivity in ALC and ABC as the native NK cells. We have characterized these cells extensively for rearrangement and expression of TCR genes and expression of cell surface molecules characteristic of T cells and NK cells. All these data argue strongly against any role of T cells in ALC and ABC, but show that NK cells are involved. All these pieces of information have led to the novel idea that NK cells, the main effector cells within the non-adaptive immune system, in addition to their ability to recognize a wide range of tumor cells through ill-defined target antigens, also can recognize and kill normal hematopoietic cells through the recognition of MHC-incompatibilities. These observations raise the intriguing possibility that these two features of NK cells are closely related, or perhaps different manifestations of the same recognition mechanism. However, the biological function of a putative allorecognition system connected to NK cells is still the center of as much speculation as the biological significance of T cell alloaggression was some years ago. The deeper understanding of which biological functions of NK cells underly the phenomena of ABC and ALC must await the characterization of receptor molecules and target cell structures involved in these reactions.Abbreviations ABC allogeneic bone marrow cell cytotoxicity - ALC allogeneic lymphocyte cytotoxicity - ADCC antibody dependent cellular cytotoxicity - GVH graft-vs-host - Ig immunoglobulins - IL-2 interleukin-2 - IDC interdigitating cells - LAK cells Lymphokine activated killer cells - LGL Large granular lymphocytes - Mab monoclonal antibody - MHC major histocompatibility complex - NK cells natural killer cells - PBL periphered blood lymphocytes - TCR T cell receptor complex - T_h T helper cells - Tc T cytotoxic cells     

IL-10 enhances NK cell proliferation, cytotoxicity and production of IFN-gamma when combined with IL-18.

Previous studies have shown that IL-10 inhibits the accessory cell functions required for production of IFN-gamma by T cells and NK cells. Our results show that although IL-10 did not induce the production of IFN-gamma by NK cells, it did enhance the ability of IL-18 to stimulate NK cell production of IFN-gamma. In addition, IL-10 augmented NK cell proliferation and cytotoxic activity when combined with IL-18. However, IL-10 did not affect the ability of IL-12 to stimulate NK cells to produce IFN-gamma or proliferate, but there was an additive effect with IL-12 to increase NK cell cytotoxic activity. Interestingly, the type I IFN, whose receptors (R) are related to the IL-10R, also enhanced the effects of IL-18 on NK cell production of IFN-gamma and NK cell cytotoxicity. The ability of IL-10 to elevate the production of IFN-gamma appeared to be specific for NK cells since IL-10 had no effect on the production of IFN-gamma by Th1 clones stimulated with IL-18 or IL-12 in the presence of a monoclonal antibody specific for CD3. These latter results correlated with lower mRNA levels for the alpha and beta chains of the IL-10R in Th1 cells than observed in NK cells. Thus, the ability of IL-10 and IL-18 to up-regulate NK cell function, but not Th1 cell activity, appears to be based on expression of the IL-10R.