Renewal of natural killer cells in mice having elevated natural killer cell activity

The present study was designed to examined the dynamics of splenic natural killer (NK) cells under two conditions of enhanced NK cell activity: (1) CBA/J mice given polyinosinic-polycytidylic acid (poly-I:C), an NK-cell-enhancing agent, and 62) untreated athymic nude (nu/nu) mice. The 'total NK cell activity' of the spleen (percentage specific lysis corrected for changes in organ cellularity) increased 5-fold and 2.7-fold after poly-I:C treatment for 1 day and 4 days, respectively. An injection of hydroxyurea (HU), a cell-cycle-toxic drug, given together with either poly-I:C or saline to CBA/J mice resulted in both cases in a 25% reduction in total NK cell activity 1 day later. This suggests that the renewal rate of nondividing NK cells is similar in poly-I:C-treated and saline-injected mice, and that the NK-enhancing effect of poly-I:C is not due to a stimulation of proliferation among NK cell precursors. HU administered simultaneously with poly-I:C or saline for 4 days eliminated NK cell activity in both cases, indicating that spleen NK cell activity is mediated almost entirely by newly formed (less than or equal to 4 days) cells. In nude mice, NK cell activity was assayed at various intervals after an HU depletion period of 2 days. NK depletion was initially more rapid in nu/nu mice than in control (nu/+) mice, although equally profound, and the subsequent recovery of NK cell activity after cessation of HU was also more rapid than in control (nu/+) mice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Productive interactions between B and natural killer cells

In this report, we have established that natural killer (NK) cells can increase IgG2a secretion by B lymphocytes as well as alter the distribution of the remaining immunoglobulin isotypes. The effect of NK cells on B cell differentiation is similar to that obtained by the direct addition of recombinant interferon-gamma (IFN-gamma) and, therefore, most likely results from the elaboration of IFN-gamma by NK cells, this is a clear demonstration that NK cells can regulate cell function(s) via a mechanism other than cytotoxicity. In addition, we have shown that the induction of NK cells by B lymphocytes requires close interactions between the two cell types. Further, while only low-density B lymphocytes activated in vivo are effective inducers of NK cells, high-density, resting B cells can be rendered effective by preactivation with either interleukin-4 or anti-mu.     

Adherent lymphokine-activated natural killer cells in normal and severe combined immunodeficiency mice: large granular lymphocytes with natural killer cell phenotype and high cytolytic activity

Plastic-adherent lymphokine-activated natural killer (LANK) cells were generated from nylon wool-nonadherent murine splenocytes cultured in recombinant interleukin-2 (IL-2). Under such conditions, adherent lymphokine-activated killer cells capable of killing natural killer (NK)-resistant targets were not generated. Adherent LANK cells proliferated rapidly and closely resembled NK cells in their morphology, cytotoxic reactivity, and surface marker expression. Mice with severe combined immunodeficiency (scid) were used to generate adherent LANK cells to define the role of T cells in LANK cell development. Scid lymphocytes responded to IL-2 by becoming adherent LANK cells with potent NK-like activity, suggesting that soluble lymphokines other than IL-2 that may have been produced by T cells were not required for the generation of LANK cell activity in mice.     

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.     

Evidence that lymphokine-activated killer cells and natural killer cells are distinct based on an analysis of congenitally immunodeficient mice

The in vitro incubation of lymphoid cells in RIL 2 results in the generation of LAK cells that are broadly lytic to autologous, syngeneic, and allogeneic fresh tumor cells, but which do not lyse fresh, normal cells. Strains of mice with congenital immunodeficiencies were tested both for the presence of NK cells and for their capacity to generate LAK cells after in vitro incubation with IL 2. Splenocytes obtained from two immunodeficient mouse strains (NIH-Beige-Nude and NIH-Beige-Nude-XID) failed to generate LAK cells, but displayed significant activity. Splenocytes from another immunodeficient mouse strain (NIH-Beige-XID) generated LAK cells but did not display NK cell activity. This dissociation of activation of LAK cells from NK cells among the immunodeficient strains indicates that the LAK and NK cell lytic systems are distinct.     

Ontogeny of thymic B cells in normal mice.

Ontogeny of thymic B cells and their surface characteristics were analyzed using monoclonal antibodies (mAbs) against B220 molecules (CD45, CD45R). A small number of B cells were detected in fetal thymus on Gestation Day 14 (approximately 3.5% of the low-density fraction). Similarly, the percentage of B cells in the low-density fraction was 3.2% on Gestation Day 18, and 3.5% on Day 1 after birth. These were the same level as that of adult mice. CD5+ B cells, which form the major population of thymic B cells, were also found in the fetal life (0.5% on Day 14 and 2.2% on Day 16 in the low-density cells). The percentage of CD5+ B cells in B cell-enriched fraction was about 65% on Day 1 after birth, which is the same level as that in adult mice. These results indicate that a small number of B cells or cells in the B-cell lineage are present in the fetal thymus and also suggest the importance of these thymic B cells in the negative selection of T cells during early developmental stages.     

Murine natural killer cells limit coxsackievirus B3 replication

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

Cellular tumorigenicity in nude mice. Role of susceptibility to natural killer cells

The athymic nude mouse is a useful animal model for assaying the neoplastic growth potential in vivo of animal cells transformed in vitro. Despite the demonstrated absence of thymus-dependent immunological functions, however, the nude mouse has now been shown to reject transplants of certain highly malignant heterologous tumors. In addition, a few transformed mammalian cell lines that exhibit all or most of the cellular phenotypes usually associated with malignancy fail to grow as tumors when injected into nude mice. In a continuing study to identify the in vitro phenotypes associated with tumor-forming ability in vivo, we investigated the role of cellular susceptibility to the naturally occurring, thymus-independent lymphocytes (natural killer or NK cells) in determining tumor induction by animal cells in nude mice. A representative collection of animal cells (ranging from normal human diploid cell strains to highly tumorigenic clonal cell lines, either transformed in vitro or derived from experimental tumors) was tested to see if the ability of cells to form tumors is consistently correlated with their susceptibility to NK cell-mediated lysis measured in vitro with splenic leukocytes from nude mice. If the physiological role of the NK cells in vivo were to recognize, and possibly to destroy, incipient tumor cells in situ, a direct association between cellular tumorigenicity and susceptibility to NK activity, might be expected. If, on the other hand, the formation of growing tumors by animal cells in nude mice depended on their ability to escape the cytolytic activity of NK cells, cellular tumorigenicity would be associated with cellular resistance to NK cells. Results obtained in this study failed to confirm either of these associations. Thus, cellular suscepbibility to NK cells, at least as determined by direct cytotoxicity assay in vitro, is not a useful predictive indicator of cellular tumorigenicity in nude mice.     

Asialo-GM1+ natural killer cells directly suppress antibody-producing B cells

Natural killer (NK) cells were tested for their ability to suppress antigen-induced antibody responses in vitro. Asialo-GM1+ (ASGM1+) cells were prepared from nylon-wool-nonadherent spleen cells obtained from normal mice. After depletion of Ig+, L3T4+ and Lyt-2+ cells, the ASGM1+-enriched cell population had high NK activity which was abrogated by treatment with anti-ASGM1 and C'. This NK-enriched ASGM1+ cell fraction significantly suppressed the generation of antibody-producing cells when added to in vitro immunization cultures of primed spleen cells. Treatment of the NK-enriched cell population with anti-ASGM1 and C' abrogated the ability of these cells to suppress antibody responses. In vitro antibody production by purified B cells was also suppressed in the presence of the NK-enriched cell population, although the kinetics of the suppression differed from that observed with unfractionated spleen cells. In addition, the NK-enriched cell population suppressed the proliferation of the B cell line WEHI-279.1. Suppression of WEHI-279.1 cells was abrogated when the NK-enriched cell population was treated with anti-ASGM1 and C'. These results suggest that normal NK cells suppress the generation of antibody-producing B cells and that this occurs, at least in part, through a direct regulation of the B cell.     

Characterization of a subset of human B lymphocytes interacting with natural killer cells

Tonsil B cells were analyzed for their capacity to interact directly with NK cells in vitro. A specific, direct interaction between NK cells and B cells could be detected by direct conjugation and by cold target inhibition using the B lymphoblastoid cell line BJA.B as a labeled target. The data further suggest that the B cell interaction with NK cells specifically activates the NK effectors and induces their production of IFN-gamma. The NK-interactive population of tonsil B cells were characterized as low-buoyant density cells (by Percoll gradient fractionation) that stained more brightly with Hoechst 33342, both characteristics of activated B cells. Immunofluorescent staining of NK cell-B cell conjugates allowed determination of the cell-surface antigenic phenotype of conjugate-forming B cells. B cell targets were ICAM-1bri, 4F2+, TfR+, CD32+, BB1+, and CD77-. They tended to be CD38-, but overlapped the CD38+ population. No correlation was seen with CD37, CD44, CD75, CD76, HC2, or Ig kappa. This phenotype is most consistent with a late activation stage of differentiation, just before and overlapping the expression of CD38. These B cells do not appear significantly sensitive to NK-mediated cytolysis, suggesting that NK cell cytokine synthesis and secretion (e.g., IFN-gamma) may be more important in the NK cell regulation of the humoral response.     

Effects of adriamycin on the activity of mouse natural killer cells

Adriamycin, a widely employed anti-neoplastic agent, was found to have either inhibitory or stimulatory effects on NK activity, depending on the site examined. A single i.p. administration of ADM resulted in a rapid increase of cytolytic activity by PEC of various mouse strains. The effector cells appeared to be NK cells, being nonadherent and nonphagocytic; they expressed low amounts of Thy 1.2 antigen and had the same pattern of specificity as splenic NK cells. In contrast to the stimulatory effects of NK activity of PEC, ADM caused a transient dose-dependent depression of NK activity in the spleen, with a peak reduction at day 3 and recovery within a few days thereafter. The depressed NK activity could be reversed by removal of adherent cells by passage through a nylon column. Moreover, ADM induced cytostatic activity against tumor cells by macrophages, suggesting that activated macrophages may be responsible for suppression of splenic NK activity. The possible modulation of the levels of NK activity by ADM-induced macrophages was supported by mixture experiments, in which plastic adherent spleen cells from ADM-treated mice, but not from normal mice, inhibited the NK activity of normal spleen cells.     

Defective differentiation of natural killer cells in SJL mice. Role of the thymus

As previously shown, three distinct phenotypes exist in murine natural killer (NK) cell activity when it is evaluated by the endogenous levels of activity and the susceptibility to augmentation by interferon (IFN) and IFN inducers. The "low" phenotype has low levels of activity which can be poorly augmented by IFN, as in mice of SJL strain. The "inducible" phenotype exhibits low endogenous levels but can vigorously respond to IFN-mediated augmentation, as in A.SW strain. The "high" NK phenotype shows high levels of endogenous activity which can be augmented to still higher levels by IFN, as in B10.S mice. Since SJL mice with congenital absence of the thymus (nude) were of the inducible type, the effect of neonatal thymectomy was examined in the present study. Neonatal thymectomy was found to convert the low phenotype of SJL mice to the inducible, mimicking the effect of nu/nu genotype. Thymectomy as late as 25 days after birth was effective, but retransplantation of a syngeneic newborn or adult thymus, or thymocytes, failed to reverse the effect of thymectomy. The poor responsiveness of NK activity to IFN in SJL, therefore, is extrinsic to the NK cell lineage and is attributable to suppression or maturational block of NK cell differentiation by the thymus during the first few weeks of neonatal life. A series of experiments with bone marrow chimeras showed that the SJL recipients did not allow the expression of inducible or high phenotype by bone marrow progenitors from allogeneic donors with either phenotype. Therefore, the SJL recipients provide an environment which suppresses not only the development of IFN-sensitive NK cell precursors, but also the levels of endogenous NK cell activity. SJL bone marrow cells gave rise to NK activity of inducible phenotype in B10.S recipients, confirming the crucial role of the environment in which NK cell differentiation takes place.     

Suppressive effect of interferon-beta-activated natural killer cells on lipopolysaccharide-induced B cell differentiation of MRL/Mp-lpr/lpr mice

The suppressive effects of mouse recombinant interferon-beta (IFN-beta) on B cell differentiation of MRL/Mp-lpr/lpr (MRL/1) mouse, a model of autoimmune diseases, and C3H/H2 mice, a normal situation, were investigated. Spleen mononuclear cells were cultured in the presence of lipopolysaccharide (LPS), and the suppressive effect of IFN-beta was examined on differentiation of B cells to plaque-forming cells (PFCs) by highly sensitive reversed hemolytic plaque assay. IFN-beta (5,000-10,000 units/ml) suppressed more than 50% of PFCs of both MRL/1 and C3H/H2 mice. This suppressive activity as well as the cytotoxicity of natural killer (NK) cells enhanced by IFN-beta was abrogated by treatment of the spleen cells with anti-asialo GM1 antibody in the presence of complement. This suppressive activity was also abrogated by intravenous administration of 20 microliter/mouse of anti-asialo GM1 12 hr before cultivation of spleen cells. These results suggest that NK cells activated by IFN might be responsible for the immunoregulation in autoimmune diseases.     

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.     

Suppressive effect of human natural killer cells on pokeweed mitogen-induced B cell differentiation

The suppressive effect of human natural killer (NK) cells on B cell differentiation induced by pokeweed mitogen (PWM) was investigated. By using Percoll discontinuous density gradient centrifugation, peripheral blood nonphagocytic and nonadherent mononuclear cells were divided into low and high density fractions for which NK cells (Large granular lymphocytes, LGL) and T cells were enriched, respectively. These fractionated mononuclear cells were co-cultured with purified autologous B cells in the presence of PWM, and were examined for their helper and suppressor activities on differentiation of B cells to immunoglobulin-(IgM and IgG) producing cells by a highly sensitive reversed hemolytic plaque assay. The T cell-enriched high density fractions provided help for B cell differentiation to levels higher than that of unfractionated mononuclear cells. On the other hand, the NK-enriched low density fractions did not show helper activity, and when added to the culture of B cells plus helper T cells, they markedly suppressed B cell differentiation. This suppressive activity, as well as the NK cytotoxicity of the NK-enriched fractions, was abrogated by treatment of the cells with monoclonal antibody against human NK cells (HNK-1), but not against T cells (OKT3) in the presence of complement. NK cells also suppressed PWM-driven B cell differentiation in the presence of T4+ (helper/inducer T) but not T8+ (cytotoxic/suppressor T) cells; however, they showed no inhibition of soluble factor-induced B cell differentiation assayed in the absence of helper T cells. It is thus concluded that human peripheral blood NK cells exhibit an ability to suppress PWM-driven B cell differentiation, possibly by acting through the effect on helper T cells but not directly on B cells.     

Homeostatic regulation of marginal zone B cells by invariant natural killer T cells

Marginal zone B cells (MZB) mount a rapid antibody response, potently activate naïve T cells, and are enriched in autoreactive B cells. MZBs express high levels of CD1d, the restriction element for invariant natural killer T cells (iNKT). Here, we examined the effect of iNKT cells on MZB cell activation and numbers in vitro and in vivo in normal and autoimmune mice. Results show that iNKT cells activate MZBs, but restrict their numbers in vitro and in vivo in normal BALB/c and C57/BL6 mice. iNKT cells do so by increasing the activation-induced cell death and curtailing proliferation of MZB cells, whereas they promote the proliferation of follicular B cells. Sorted iNKT cells can directly execute this function, without help from other immune cells. Such MZB regulation by iNKTs is mediated, at least in part, via CD1d on B cells in a contact-dependent manner, whereas iNKT-induced proliferation of follicular B cells occurs in a contact- and CD1d-independent manner. Finally, we show that iNKT cells reduce ‘autoreactive’ MZB cells in an anti-DNA transgenic model, and limit MZB cell numbers in autoimmune-prone (NZB×NZW)F1 and non-obese diabetic mice, suggesting a potentially new mechanism whereby iNKT cells might regulate pathologic autoimmunity. Differential regulation of follicular B cells versus potentially autoreactive MZBs by iNKT cells has important implications for autoimmune diseases as well as for conditions that require a rapid innate B cell response.     

Homeostasis of natural killer cells

Natural killer (NK) cells are important players of innate immunity, dedicated to the host defense against viruses and also involved in the immune surveillance of tumors. NK cells are widely distributed in the body and their number may increase locally during infection. They develop mainly in the bone marrow and perhaps in other lymphoid organs. They are constantly renewed, with a half-life of about 17 days at the periphery. In this article, we review the factors that regulate the homeostasis of NK cells including their development, differentiation, export to the periphery, their turnover, their homeostatic or antigen-induced proliferation and their survival before or after activation. In addition, we discuss the homeostasis of recently described so-called "memory" NK cells.