Regulation of B lymphocytes by natural killer cells. Role of IFN-gamma

Using a co-culture system of fractionated B cells and highly purified NK cells, we have demonstrated direct interactions between B lymphocytes and NK cells. B cells are able to stimulate the production of IFN-gamma by NK cells. This stimulatory ability is restricted to a subpopulation of large, presumably in vivo activated B lymphocytes. The secreted IFN-gamma in turn inhibits polyclonally induced B cell proliferation. Small resting B cells neither stimulate IFN-gamma production nor are they measurably affected by NK cells.     

Release of lymphokines after Epstein Barr virus infection in vitro. I. Sources of and kinetics of production of interferons and interleukins in normal humans

Infection of human lymphocytes with Epstein Barr virus (EBV) activates the release of lymphokines. Previous experiments have emphasized the ability of interferon-gamma (IFN-gamma) to prevent EBV-induced B cell transformation. However, the factors that regulate IFN-gamma synthesis and release during in vitro EBV infection are controversial. In the present investigation we have systematically evaluated the kinetics of production, cellular origins, and accessory cell requirements for IFN-alpha and IFN-gamma and for IL 1 and IL 2, after EBV infection. Our data indicate that IFN-alpha is released entirely by natural killer (NK) cells and B cells, in the absence of accessory cells, independently of the other lymphokines and within 24 hr of infection. In contradistinction, IFN-gamma secretion is exclusively of T cell origin, is absolutely dependent on the prior elaboration of IL 1 and IL 2, and is maximal 8 days after EBV infection. IL 2 secretion by T cells peaks on day 5 and requires the earlier release of IL 1. Both NK cells and monocytes are a source of IL 1. Secretion of IL 2 and IFN-gamma occurs in the presence of either one of these cell types but not in the absence of both. Antibody against IL 1 blocks EBV-induced IL 2 and IFN-gamma generation, and antibody against IL 2 decreases production of IFN-gamma. Thus, the production of IFN-gamma, the lymphokine that prevents EBV-induced B cell transformation, is the final outcome of a cascade of lymphokine-mediated events that involve interactions between virus-infected B lymphocytes that serve as antigen-presenting cells, NK cells and monocytes as sources of IL 1, and T lymphoblasts. Dysfunctions of any or all of these cell types would be expected to impair the regulation of EBV transformation.     

Impaired NK cell development in an IFN-gamma transgenic mouse: aberrantly expressed IFN-gamma enhances hematopoietic stem cell apoptosis and affects NK cell differentiation

Aberrant expression of IFN-gamma has been demonstrated to cause a wide variety of alterations in cell function and development. Previously we reported that constitutive expression of IFN-gamma in bone marrow (BM) and thymus results in a total absence of B cells and a substantial decrease in the number of hematopoietic progenitor cells. In this study, we demonstrate a severe deficiency of NK1.1(+)CD3(-) cells in this transgenic mouse model. Compared with normal control littermates, we found a pronounced reduction of NK cells in IFN-gamma transgenic mouse spleen and liver despite maintenance of normal function. In addition, we observed a reduced number of BM cells in the IFN-gamma transgenic mouse despite normal expression of hematopoietic growth factors in the BM. Interestingly, these cells were less responsive to stem cell factor (SCF) despite c-kit expression on hematopoietic stem cells (HSCs). We observed that addition of exogenous IFN-gamma inhibited proliferation of HSCs and differentiation of NK precursors from HSCs in normal mice in response to SCF, IL-7, fms-like tyrosine kinase 3 ligand, and IL-15. Furthermore, we found that HSCs express the IFN-gammaRalpha subunit and undergo apoptosis in response to exogenous IFN-gamma. Thus, we have demonstrated the occurrence of a severe deficiency of NK cells and lower numbers of BM cells in an IFN-gamma transgenic mouse model. Furthermore, because exogenous IFN-gamma affects the responsiveness to hematopoietic growth factors such as SCF in vitro, our results indicate that chronic expression of IFN-gamma in vivo leads to widespread immune system defects, including alterations in NK cell differentiation.     

A role for natural killer cells in intestinal inflammation caused by infection with Salmonella enterica serovar Typhimurium

Acute gastroenteritis caused by Salmonella infection is a significant public health problem. Using a mouse model of this condition, the authors demonstrated previously that the cytokine gamma interferon (IFN-gamma) is required for a normal intestinal inflammatory response to the pathogen. In the present study, these experiments are extended to show that natural killer (NK) cells constitute an early source of intestinal IFN-gamma during Salmonella infection, and that these cells have a significant impact on intestinal inflammation. It was found that infection of mice with Salmonella increased both intestinal IFN-gamma production and the numbers of NK cells in the intestine and mesenteric lymph nodes. NK cells, along with other types of lymphocytes, produced IFN-gamma in response to the bacteria in vitro, while antibody-mediated depletion of NK cells in vivo resulted in a significant reduction in Salmonella-induced intestinal IFN-gamma expression. In a mouse strain lacking NK cells and T and B lymphocytes, intestinal production of IFN-gamma and Salmonella-induced intestinal inflammation were both significantly decreased compared with a strain deficient only in T and B cells. The authors' observations point to an important function for NK cells and NK-derived IFN-gamma in regulating the intestinal inflammatory response to Salmonella.     

Distinct roles of dendritic cells and B cells in Va14Ja18 natural T cell activation in vivo

Va14Ja18 natural T (iNKT) cells are innate, immunoregulatory lymphocytes that recognize CD1d-restricted lipid Ags such as alpha-galactosylceramide (alpha GalCer). The immunoregulatory functions of iNKT cells are dependent upon either IFN-gamma or IL-4 production by these cells. We hypothesized that alpha GalCer presentation by different CD1d-positive cell types elicits distinct iNKT cell functions. In this study we report that dendritic cells (DC) play a critical role in alpha GalCer-mediated activation of iNKT cells and subsequent transactivation of NK cells. Remarkably, B lymphocytes suppress DC-mediated iNKT and NK cell activation. Nevertheless, alpha GalCer presentation by B cells elicits low IL-4 responses from iNKT cells. This finding is particularly interesting because we demonstrate that NOD DC are defective in eliciting iNKT cell function, but their B cells preferentially activate this T cell subset to secrete low levels of IL-4. Thus, the differential immune outcome based on the type of APC that displays glycolipid Ags in vivo has implications for the design of therapies that harness the immunoregulatory functions of iNKT cells.     

Basic fibroblast growth factor and interleukins 4 and 6 stimulate the release of IFN-gamma by individual NK cells.

Both the secretory and cytotoxic activity of natural killer (NK) cells are known to be regulated by such cytokines as interleukin-2 (IL-2) and interferon-gamma (IFN-gamma). In the present study we have used the reverse hemolytic plaque assay to investigate either the direct effects of the protein kinase activator, phorbol myristate acetate (PMA), or exposure to recombinant human interleukins 2, 4, and 6 (IL-2, IL-4, and IL-6) tumour necrosis factor alpha (TNF-alpha) and basic fibroblast growth factor (bFGF) on the release of IFN-gamma by individual, immunoidentified NK cells isolated from peripheral blood. This sensitive immunoassay was adapted and coupled with immunocytochemistry not only to immunophenotype and enumerate cells secreting IFN-gamma in a given cell population, but also to quantify the amount of this cytokine released per individual cell. These studies have confirmed mononuclear cells with the morphology of large granular lymphocytes and the immunophenotype of CD3-/CD16+ NK cells to be the predominant source of spontaneously released IFN-gamma in vitro. In contrast to this, fewer than 2% of the CD3+ T cells secreted detectable levels of this cytokine during the assay, irrespective of the stimulus applied. Whilst TNF-alpha had no significant effect on IFN-gamma release by NK cells, a 6-hr exposure to IL-2 or PMA stimulated an increase in the amount secreted per single cell. Furthermore, bFGF and interleukins 4 and 6 elicited a marked, dose-dependent stimulation of IFN-gamma secretion by this cell type. However, exposure to these cytokines did not alter the number of cells capable of releasing detectable levels of IFN-gamma during the assay. These studies demonstrate that (i) both the spontaneous and stimulated release of IFN-gamma by NK cells can be visualized and quantified at the single-cell level using this sensitive immunoassay, and (ii) bFGF and interleukins 2, 4, and 6, but not TNF-alpha, are potent stimulants of IFN-gamma secretion by CD3-/CD16+ NK cells.     

B cell induction of IL-13 expression in NK cells: role of CD244 and SLAM-associated protein

NK cells are an important component of the innate immune system that can also interact with B cells in a mutually productive manner. We have previously shown that activated B cells can induce NK cells to up-regulate their secretion of IFN-gamma. In this study, we show that B cells, and, particularly, marginal zone B cells, can, in addition, induce NK cells via direct cell-cell interactions to express mRNA encoding the Th2 cytokine IL-13. The induction of NK cell IL-13 mRNA expression requires the ligation of the CD244 receptor by the CD48 ligand on B cells via signaling pathways that depend upon expression of the X-linked lymphoproliferative disease gene product, SH2D1A/DSHP/SAP (SLAM-associated protein, or SAP) in NK cells. Thus, the positive signals attributed to the B cell activation of CD244 on murine NK cells appears to be more similar to the activity of CD244 on human cells. The induction of IL-13 mRNA by B cells may account for the effect of NK cells on the generation of Th2-type responses in the presence of some adjuvants.     

Target cell induced activation of NK cells in vitro: cytokine production and enhancement of cytotoxic function

This study examines the effect of fixed AK-5 tumour cells on rat NK cells. Co-culture of NK cells with fixed tumour cells augmented the cytotoxicity of NK cells against NK-sensitive targets, YAC-1 and AK-5, and induced the secretion of IFN-gamma by NK cells. Antibody against IFN-gamma suppressed the anti-tumour activity of NK cells, whereas the addition of T cells during co-culture enhanced this activity. However, macrophages and B cells had no significant effect when present during co-culture with NK cells. All the inducible cytotoxicity was contained within the NK (CD161+) and NKT (CD3+, CD161+) subsets of lymphocytes. However, in the presence of T cells, the cytolytic potential of NKT cells was higher than that of NK cells alone. The augmentation of cytotoxic activity of NK cells by AK-5 cells in presence of T cells was dependent on IL-2 and IFN-gamma secretion. NK cell activation was blocked by specific antibodies to IL-2 and IFN-gamma in the presence of T cells. Interaction between fixed AK-5 cells with NK and T cell populations induced the expression of Fas-L and perforin in NK cells. These data demonstrate that fixed AK-5 cells initiated cytokine synthesis by NK cells, and the enhanced cytotoxic activity in the presence of T cells was induced as a consequence of the products secreted by activated T lymphocytes. The present observations reflect the possible interactions taking place in vivo after the transplantation of AK-5 tumour in animals. They also suggest direct activation of NK cells after their interaction with the tumour cells.     

Natural killer cells can enhance the proliferative responses of B lymphocytes

In addition to lytic activity against malignant and virally transformed target cells, recent evidence has suggested that natural killer (NK) cells can modulate immune activities such as the suppression of B cell responses through noncytotoxic means. Using human B cells and highly purified autologous NK cells, we have demonstrated that NK cells can substantially augment the proliferative responses of B cells stimulated with the surface immunoglobulin crosslinking agents anti-IgM or Staphylococcus aureus Cowan strain I (SAC). This "enhancer" activity of NK cells was quite potent and was observed at an NK:B cell ratio as low as 0.05. Peak blastogenic responses of B cells cocultured with NK cells in the presence of B cell activators were observed at 2-3 days, similar to the responses of B cells in the absence of NK cells. Using the inhibitor of DNA synthesis mitomycin C, we determined that B cells and not NK cells were proliferating in cocultures of these lymphocytes stimulated with SAC. Activated B cells neither prevented the lysis of the isotope-labeled NK-sensitive target cell line K562 nor formed conjugates with NK cells, suggesting that cell contact was not a prerequisite for the effect. These studies have further expanded the functional repertoire of NK cells to include enhancer as well as suppressor and lytic activities.     

Mycobacteria induce IFN-gamma production in human dendritic cells via triggering of TLR2

IFN-gamma is of central importance for the induction of robust cell-mediated immunity and for the activation of APC. Recent studies using experimental murine systems have now suggested a fundamental role for APC-derived IFN-gamma during infection with intracellular pathogens. It is currently unknown whether human dendritic cells (DC) can respond to bacterial stimulation with production of IFN-gamma. To test this question, we used human monocyte-derived DC stimulated by Mycobacterium bovis bacillus Calmette-Guérin as a model system. We demonstrate production of IFN-gamma mRNA and protein on the single cell level. IFN-gamma in DC cultures was not simply produced by contaminating lymphocytes because production of DC-IFN-gamma could also be demonstrated in highly purified DC cultures containing virtually no T, B, and NK cells. TLR2 was identified as a key receptor involved in triggering production of DC-IFN-gamma. Interestingly, DC-IFN-gamma seems to participate in an autocrine DC activation loop, and production of DC-IFN-gamma could be enhanced by costimulation of DC with IL-12/IL-15/IL-18. In conclusion, we have demonstrated production of IFN-gamma by human DC on the single cell level, identified TLR2 as a pattern recognition receptor involved in this process, and elucidated some of the functional consequences of autocrine IFN-gamma production by human DC.     

CD48 stimulation by 2B4 (CD244)-expressing targets activates human NK cells

Human NK cells can be activated by a variety of different cell surface receptors. Members of the SLAM-related receptors (SRR) are important modulators of NK cell activity. One interesting feature of the SRR is their homophilic interaction, combining receptor and ligand in the same molecule. Therefore, SRR cannot only function as activating NK cell receptors, but also as activating NK cell ligands. 2B4 (CD244) is the only SRR that does not show homophilic interaction. Instead, 2B4 is activated by binding to CD48, a GPI-anchored surface molecule that is widely expressed in the hemopoietic system. In this study, we show that 2B4 also can function as an activating NK cell ligand. 2B4-expressing target cells can efficiently stimulate NK cell cytotoxicity and IFN-gamma production. Using soluble receptor fusion proteins and SRR-transfected cells, we show that 2B4 does not bind to any other SRR expressed on NK cells, but only interacts with CD48. Lysis of 2B4-expressing target cells can be blocked by anti-CD48 Abs and triggering of CD48 in a redirected lysis assay can stimulate NK cell cytotoxicity. This demonstrates that 2B4 can stimulate NK cell cytotoxicity and cytokine production by interacting with NK cell expressed CD48 and adds CD48 to the growing number of activating NK cell receptors.     

Human B cell activation by autologous NK cells is regulated by CD40-CD40 ligand interaction: role of memory B cells and CD5+ B cells.

NK cells are a subpopulation of lymphocytes characterized primarily by their cytolytic activity. They are recognized as an important component of the immune response against virus infection and tumors. In addition to their cytolytic activity, NK cells also participate either directly or indirectly in the regulation of the ongoing Ab response. More recently, it has been suggested that NK cells have an important role in the outcome of autoimmune diseases. Here, we demonstrate that human NK cells can induce autologous resting B cells to synthesize Ig, including switching to IgG and IgA, reminiscent of a secondary Ab response. B cell activation by the NK cell is contact-dependent and rapid, suggesting an autocrine B cell-regulated process. This NK cell function is T cell-independent, requires an active cytoplasmic membrane, and is blocked by anti-CD40 ligand (anti-CD154) or CD40-mIg fusion protein, indicating a critical role for CD40-CD40 ligand interaction. Depletion studies also demonstrate that CD5+ B cells (autoreactive B-1 cells) and a heterogeneous population of CD27+ memory B cells play a critical role in the Ig response induced by NK cells. The existence of this novel mechanism of B cell activation has important implications in innate immunity, B cell-mediated autoimmunity, and B cell neoplasia.     

Robust NK cell-mediated human immunodeficiency virus (HIV)-specific antibody-dependent responses in HIV-infected subjects

Antibody-dependent cellular cytotoxicity (ADCC) is a potentially effective adaptive immune response to human immunodeficiency virus (HIV) infection. The study of ADCC responses has been hampered by the lack of simple methods to quantify these responses and map effective epitopes. We serendipitously observed that standard intracellular cytokine assays on fresh whole blood from a cohort of 26 HIV-infected subjects identified non-T lymphocytes expressing gamma interferon (IFN-gamma) in response to overlapping linear peptides spanning HIV-1 proteins. The effector cells were CD3(-) CD4(-) CD8(-) CD14(-) CD2(+) CD56(+/-) NK lymphocytes and degranulated granzyme B and perforin in response to antigen stimulation. Serum transfer assays demonstrated that the specific response was mediated by immunoglobulin G. Fresh blood samples from half of the HIV-infected cohort demonstrated robust HIV peptide-specific IFN-gamma expression by NK cells, predominately to Env, Pol, and Vpu HIV-1 proteins. Responses were readily mapped to define minimal epitopes utilizing this assay. Antibody-dependent, HIV-specific NK cell recognition, involving components of both innate and adaptive immune systems, represents a potentially effective immune response to induce by vaccination.     

The excitotoxic effect of NMDA on human lymphocyte immune function

N-Methyl-d-aspartate (NMDA)-activated glutamate receptors are expressed in lymphocytes, but their roles have not yet been defined. We show that incubation of human peripheral blood lymphocytes with NMDA resulted in increased intracellular calcium and reactive oxygen species (ROS) levels through effects on NMDA-activated glutamate receptors. In terms of ROS production, T cells were most affected, followed by NK cells, whereas B cell ROS levels were not increased. In unstimulated T and NK cells, interferon-gamma (IFN-gamma) production was unaffected by NMDA, whereas interleukin-2 stimulation of IFN-gamma production was significantly suppressed by NMDA. Simultaneous incubation of the cells with NMDA and IL-2 resulted in a dramatic increase in the amount of cells expressing the NR1 subunit of the NMDA-activated receptors. We conclude that NMDA-activated glutamate receptor activation, accompanied by the changes in intracellular calcium and ROS levels, may be involved in the modification of immune functions of human T and NK cells.     

The augmentation of human natural killer cell activity by interferon-gamma is not associated with the induction of the interferon-alpha-inducible proteins

Treatment of partly purified large granular lymphocytes (LGL) with either IFN-alpha or IFN-gamma for 2 hr augmented their NK cell activity. This augmentation was completely inhibited by the addition of 10 micrograms/ml of cycloheximide. In contrast, when the effects of IFN-gamma on the synthesis of specific proteins in these cells was directly studied by use of two-dimensional gel electrophoresis, we found that IFN-gamma was unable to induce any of the earlier detected, IFN-alpha/IFN-beta-inducible proteins within 18 hr of incubation. No additional, IFN-gamma-induced proteins were detected in either the partly purified LGL or purified T cells. In contrast, the effects of the two factors were comparable in the glioma cell line 251 MG. This shows i) that the effects of IFN-alpha and IFN-gamma are dependent on the responder cell type, ii) that there exists at least one mechanism that can augment NK cell activity that is not dependent on the increased synthesis of the IFN-alpha-inducible proteins, and iii) that either the nine IFN-alpha-inducible proteins are not involved in any leukocyte function that is augmentable by both IFN-alpha and IFN-gamma, or that the two factors exert their actions in leukocyte through different mechanisms.     

NK cells and innate immunity to malaria

Innate immune response against Plasmodium falciparum (Pf), a causative agent of human malaria, is the result of several thousand years of co-evolution between the parasite and his host. An early IFN-gamma production during infection is associated with a better evolution of the disease. Natural killer (NK) cells are among the first cells in peripheral blood to produce IFN-gamma in response to Pf-infected erythrocytes (Pf-E). NK cells are found in blood, in secondary lymphoid organs as well as in peripheral non-lymphoid tissues. They participate in host innate responses that occur upon viral and intracytoplasmic bacterial infections, but also during the course of tumor development and allogeneic transplantation. These lymphocytes are not only important players of innate effector responses, but also participate in the initiation and development of adaptive immune responses. In addition, direct sensing of Pf infection by NK cells induces their production of the proinflammatory chemokine IL-8, suggesting a role for NK cells in the recruitment and the activation of other cells during malaria infection. Several other cell subsets are involved in the innate immune response to Pf. Dendritic cells, macrophages, gamma delta T cells, NKT cells are able to sense the presence of the parasite. Along this line, the presence of IL-12 is necessary to NK cell IFN-gamma production and a functional cooperation takes place between macrophages and NK cells in the context of this parasitic infection. In particular, IL-18 produced by macrophages is a key factor for this NK response. However, the molecular basis of Pf-E recognition by NK cells as well as the functional role of NK cell responses during the course of the disease remain to be adressed.     

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.     

Role of the production of natural killer cell stimulatory factor (NKSF/IL-12) in the ability of B cell lines to stimulate T and NK cell proliferation.

We have previously used human Epstein Barr virus (EBV)-transformed B lymphoblastoid cell lines for the identification and purification of a novel cytokine, natural killer cell stimulatory factor (NKSF/IL-12), that has pleiotropic effects on human lymphocytes. B cell lines are also routinely employed as feeder cells for the culture of T and natural killer (NK) cells. In this report we describe the ability of two NKSF/IL-12 producing B cell lines (RPMI-8866 and Cess) and two nonproducing lines (Raji and Daudi) to stimulate the proliferation of T and NK cells in 8-day PBL cultures. We demonstrate, using an anti-NKSF/IL-12 neutralizing monoclonal antibody, that the endogenous production of NKSF/IL-12 in these cultures can significantly enhance the proliferation and cytotoxic activity of T and NK cells. We also report that the addition of exogenous rNKSF/IL-12 can greatly increase the number of T and NK cells obtained from the cultures following stimulation by the B cell lines. Aside from the possible practical applications, the enhanced proliferation of T and NK cells consistently observed in the presence of endogenously produced NKSF/IL-12 or exogenously added rNKSF/IL-12 in this system may further our understanding of the role of this cytokine during an in vivo immune response.