Enhanced natural killer (NK) cell activity and NK-sensitive thymic cells in murine muscular dystrophy

Studies have shown that there is an abnormality in the thymus of dystrophic mice with respect to age-dependent thymus weight changes and altered morphology (T. DeKretser and B. Livett, Nature (London), 263, 682, 1976). Recently, others have shown that natural killer (NK) cells can lyse cells of a large, immature, rapidly dividing cell subpopulation within the thymus of normal young (3 weeks of age) mice (M. Hansson, K. Karre, R. Kiessling, J. Roder, B. Anderson, and P. Hayry, J. Immunol., 123, 765, 1979). The NK susceptibility of dystrophic mouse thymocytes as targets was therefore studied. Spleen cells from normal (+/+) and dystrophic ($\text{dy}{}^{\mathrm{2J}}\text{dy}{}^{\mathrm{2J}}$) male C57BL/6J mice 8–10 weeks old were passed over nylon wool and the nonadherent cells were incubated with ⁵¹Cr-labeled YAC-1 lymphoma target cells or thymocytes in a ⁵¹Cr-release assay. Spleen cells from dystrophic mice killed twofold more YAC-1 target cells than did spleen cells from normal mice. Thymocytes from 3- to 4-week-old dystrophic mice were three to four times more susceptible to NK lysis by dystrophic mouse spleen cells as compared with normal mouse spleen cells. Spleen cells from dystrophic mice had the same NK activity against dystrophic and normal mouse thymocytes as targets. Normal mouse spleen cells killed three- to fourfold more dystrophic mouse thymocytes than that of normal mouse thymocytes as targets. Target cellbinding studies revealed that conjugate-forming cells from nylon nonadherent dystrophic mouse spleen cells were found to be two- to fourfold greater than for normal mouse spleen cells using YAC-1 tumor cells as targets. The number of lymphocytes bound per YAC-1 target cell ranged from 2 to 5 for dystrophic mouse spleen cells as compared with 1 to 2 for the normal control group. Using both normal and dystrophic mouse thymocytes as targets, the conjugate-forming cells from dystrophic mouse spleen cells were also found to be twofold greater than in the normal control group. Cold target inhibition studies revealed that the natural killing of dystrophic mouse thymocytes was due to a YAC-1-reactive NK cell. Effector cell depletion studies using monoclonal anti-Thy-1.2 plus complement treatment and plastic petri dish adherence also revealed that the natural killing of dystrophic mouse thymocytes was not due to either T lymphocytes or macrophages. Taken together, these results show an increase in NK-sensitive thymocyte targets in dystrophic mice, in combination with an increase in splenic NK activity.     

Natural cytolytic activity in mice with natural or induced cellular defects. I. Differential ability of in vitro interleukin-2 addition to augment natural cytolytic function

The ability of in vitro addition of recombinant interleukin 2 (rIL-2) to differentially enhance natural cytotoxicity was assessed using cells from mice with natural and induced cellular defects. In vivo treatment with most immunosuppressive or cytoreductive agents, anti-asialo-GM1 antibody, or gamma irradiation dramatically reduced in vitro cytotoxicity against natural killer (NK) sensitive targets by direct reduction in either percentage specific lysis or lytic units per spleen. In most cases, in vitro addition of rIL-2 (at concentrations causing augmented NK function in cells from naive Balb/C mice) enhanced cytotoxic activity of cells from treatment groups to a normal value but not within the rIL-2-enhanced range of nontreated animals. Additionally, cytotoxic activity of cells from animals treated with certain drugs or gamma irradiation could be augmented by rIL-2 when measured by percentage lysis but not lytic units per spleen. In vivo treatment with cyclosporin A did not affect natural cytotoxic activity and addition of rIL-2 augmented the NK activity in a similar fashion to the profile of naive cells. In experiments using cells from beige (C57Bl/6-bg) mice which have a natural defect in NK activity against YAC-1 targets, addition of rIL-2 (at concentrations causing augmented natural cytotoxic function in cells from C57Bl/6 mice) could not effectively enhance in vitro natural cytotoxic function.     

Host-mediated antiviral activity of Lactobacillus casei against cytomegalovirus infection in mice

The protective effect of heat-killed Lactobacillus casei (LC) against murine cytomegalovirus (MCMV) infection was examined. ICR mice treated once with LC 1 day or 2 days before challenge survived lethal infection, but untreated or Lactobacillus fermentum (LF)-treated mice did not. The protective effect was evidenced by an increase in plaque-forming units (PFU) per 50% lethal dose (LD50) and a decrease in titers of infectious viruses replicated in the target organs. This was further confirmed by severity of histopathological damage to the target organs, especially the liver. LC neither inactivated MCMV nor inhibited its replication in mouse embryonic fibroblasts (MEF). The spleen cells from LC-treated mice inhibited its replication in MEF on co-cultivation. Augmentation by LC of splenic natural killer (NK) cell activity correlated with survival of mice from otherwise lethal MCMV infection. Cytotoxic activity of peritoneal cells and level of serum interferon (IFN) were elevated after MCMV infection, but they were not associated with survival of mice nor with treatment of LC. The protective effect of LC was not clear in NK-deficient beige mutant (bgJ/bgJ) mice, when compared with that in their littermate (bgJ/+) mice. Poor protection of bgJ/bgJ mice by LC treatment correlated with failure to induce NK cell activity by LC treatment in the mutant mice. Thus, it is likely that LC protects mice from MCMV infection by augmentation of NK cell activity.     

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

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

Natural cytotoxicity against mouse hepatitis virus-infected target cells. I. Correlation of cytotoxicity with virus binding to leukocytes

Spleen cells from uninfected control mice selectively lysed BALB/c 3T3 fibroblasts infected with mouse hepatitis virus (MHV), a murine coronavirus. Lysis of infected cells occurred within 3 hr, and histocompatibility between effector and target cells was not required. This natural, cell-mediated, virus-associated cytotoxicity differed from NK cell- and T cell-mediated lysis. Spleen cells from animals infected with MHV were enriched in NK activity and were more cytotoxic to YAC-1 target cells, but did not show enhanced cytotoxicity for MHV-infected target cells. Spleen cells from beige mice, which are deficient in NK cell activity, were able to lyse MHV-infected target cells, as were spleen cells from nude mice, which are deficient in T cell activity. Lysis of MHV-infected target cells could be mediated by cells from the spleen and, to a lesser extent, by cells from the bone marrow, but not by resident peritoneal cells or thymocytes. We suggest the term "virus killer (VK) activity" for this phenomenon. VK activity of splenocytes from different mouse strains correlated with the ability of the splenocytes to bind purified radiolabeled MHV virions. MHV virions caused agglutination of spleen leukocytes from susceptible mouse strains, indicating that leukocyte agglutination or adsorption may provide a useful assay for coronaviruses such as MHV which lack hemagglutinating activity. SJL mouse splenocytes did not bind MHV and did not lyse infected targets. MHV bound relatively well to splenocytes of other mouse strains, but poorly to thymocytes and erythrocytes. Binding of MHV to leukocytes was not influenced by 6 mM EDTA or EGTA, indicating a lack of requirement for Mg++ or Ca++. VK activity was also resistant to EDTA and EGTA, in contrast to NK activity, which was sensitive to those chelating agents. VK activity was also unaffected by actinomycin D, cycloheximide, or puromycin, indicating that new protein synthesis was not required for lysis. Antibody to interferon-alpha/beta did not block lysis, nor was there substantially enhanced lysis mediated by leukocytes from mice infected with virus and thus exposed to high levels of interferon. VK activity was blocked by antibody directed against the peplomeric glycoprotein E2 of MHV. VK activity required infected target cells, because cells with adsorbed MHV virions were not lysed by splenocytes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Murine trophoblast can be killed by lymphokine-activated killer cells

The ability of fetal trophoblast cells in the placenta to resist cell-mediated lysis may be important for successful pregnancy. Previous studies in this laboratory demonstrated that cultured midterm mouse trophoblast cells are not susceptible to allospecific CTL generated by standard in vitro protocols, to antibody-dependent cell-mediated cytotoxicity, or to naive or IFN-activated NK cells, despite expressing the requisite target structures. However, we now report that murine trophoblast can be killed, in a non-MHC-specific manner, by LAK cells. Normal mouse spleen cells cultured for 4 days in IL-2-containing lymphokine preparations characteristically killed both NK-sensitive (YAC-1) and NK-resistant (EL4, P815) target cells, and mediated significant lysis of both cultured and freshly isolated trophoblast cells (35 to 55%, E/T 100/1). Pretreatment of the LAK cells with anti-ASGM1 antibody and C markedly reduced the lysis of trophoblast and YAC-1 targets, suggesting that the responsible cells belonged to the NK lineage. The ability of IL-2-activated NK cells to kill midterm murine trophoblast cells was confirmed using a population of highly lytic NK cells generated by culturing spleen cells from severe combined immunodeficiency mice in 500 U/ml rIL-2 for 5 days. These effector cells killed YAC-1, EL4 and P815 target cells at much lower E/T ratios than was achieved with the normal splenic LAK cells, and mediated significant lysis of both freshly isolated (45 to 50%, E/T 20/1) and cultured trophoblast cells (68 to 76%, E/T 20/1). The susceptibility of trophoblast to LAK cells and IL-2-activated NK cells supports the need for suppressor mechanisms regulating IL-2 activity at the maternal-fetal interface.     

Augmentation of mouse natural killer cell activity by LS 2616, a new immunomodulator

The quinoline-3-carboxamide LS 2616 administered to mice in drinking water increased spontaneous cytotoxicity against YAC-1 cells in a dose-dependent manner. The enhancement of spontaneous cytotoxicity was found to be mediated by NK cells, as judged by their lack of adherence to nylon wool columns, relative resistance to treatment with antibodies to Thy-1.2 and complement, and almost total abrogation after depletion of asialo-GM1+ cells. Enhancement of NK activity was evident after 2 days of treatment, was maximal after 4 days, and remained elevated during the 14-day exposure period studied. NK activity returned to control levels 4 days after cessation of treatment. NK activity was significantly increased in spleen, peripheral blood, lymph nodes, and bone marrow of LS 2616-treated mice, while activity in peritoneal exudate cells and thymus remained low. LS 2616 was able to elevate NK activity in several mouse strains studied, including mice homozygous for the beige gene. Serum interferon levels were not increased during treatment with LS 2616. Combined injection of the interferon inducer Poly I:C and LS 2616 did not increase NK activity above that of animals injected with Poly I:C alone. However, Poly I:C, in contrast to LS 2616, increased NK activity in peritoneal exudate cells. Studies at the single cell level revealed that LS 2616 increased NK activity by increasing the number of lytically active cells via recruitment of new target-binding cells and not by increasing the lytic activity of pre-existing binders.     

The heat shock protein HSP70 promotes mouse NK cell activity against tumors that express inducible NKG2D ligands

The stress-inducible heat shock protein (HSP) 70 is known to function as an endogenous danger signal that can increase the immunogenicity of tumors and induce CTL responses. We show in this study that HSP70 also activates mouse NK cells that recognize stress-inducible NKG2D ligands on tumor cells. Tumor size and the rate of metastases derived from HSP70-overexpressing human melanoma cells were found to be reduced in T and B cell-deficient SCID mice, but not in SCID/beige mice that lack additionally functional NK cells. In the SCID mice with HSP70-overexpressing tumors, NK cells were activated so that they killed ex vivo tumor cells that expressed NKG2D ligands. In the tumors, the MHC class I chain-related (MIC) A and B molecules were found to be expressed. Interestingly, a counter selection was observed against the expression of MICA/B in HSP70-overexpressing tumors compared with control tumors in SCID, but not in SCID/beige mice, suggesting a functional relevance of MICA/B expression. The melanoma cells were found to release exosomes. HSP70-positive exosomes from the HSP70-overexpressing cells, in contrast to HSP70-negative exosomes from the control cells, were able to activate mouse NK cells in vitro to kill YAC-1 cells, which express NKG2D ligands constitutively, or the human melanoma cells, in which MICA/B expression was induced. Thus, HSP70 and inducible NKG2D ligands synergistically promote the activation of mouse NK cells resulting in a reduced tumor growth and suppression of metastatic disease.     

Studies on the mechanism of low natural killer cell activity in infant and aged mice

NK activity in mice is high between about 6 and 10 weeks of age. In contrast, infant mice and mice older than 12-14 weeks of age usually have quite low or undetectable NK activity. Studies were performed to analyze the mechanisms underlying this characteristic age-related regulation of NK activity. Spleen cells from infant mice did not develop appreciable NK activity upon incubation for 12-18 h with either interferon (IFN) or interleukin-2 (IL-2). Analysis of the frequency of IL-2-dependent progenitors of NK cells, in a limiting dilution assay, also indicated that the spleens of infant mice are deficient in precursors of NK cells. In contrast, spleen cells from old mice (30 weeks old) developed substantial levels of NK activity upon incubation with either IFN or IL-2, and they showed a frequency of IL-2-dependent progenitors of effector cells that was similar to that of young mice. Both infant and old mice had plastic-adherent suppressor cells in their spleens, which could strongly inhibit NK activity. In addition, both infant and old mouse spleen cells contained nonadherent suppressor cells, which had a higher density on Percoll gradients than NK cells. Thus, several factors appear to contribute to the age-related regulation of NK activity in mice.     

Purification and target cell range of in vivo elicited blast natural killer cells

Blast natural killer (NK) cells were elicited in the spleens of mice by treatments with the interferon inducers lymphocytic choriomeningitis virus (LCMV) or polyinosinic-polycytidylic acid (poly I:C). The blast-NK cells, separated on the basis of size by centrifugal elutriation, were compared with blast cytotoxic T lymphocytes (CTL) generated during infection with LCMV. In vivo treatments with antibody to asialo GM1 (AGM1) blocked the appearance of blast-NK cells but not blast-CTL. Antibody and complement depletion experiments indicated that the blast-NK cells were AGM1+, NK 1.2+/-, Lyt-5+/-, Thy+/-, Qa-5/NK 1.1+, Lyt-2-, B23.1-, and J11d-. Blast-NK cells could be unequivocally distinguished from blast-CTL, because the blast-CTL were completely sensitive to treatments with anti-Lyt-2 and complement, whereas the blast-NK cells were completely resistant. The blast-NK cells were purified from populations of large-size cells by antibody and complement treatments that depleted the co-eluting monocyte/macrophages and polymorphonuclear leukocytes. The population resulting after separation from dead cells over Percoll gradients represented approximately 1% of the total spleen cells, contained greater than 60% large granular lymphocytes and mediated greater than 15% killing of YAC-1 target cells in a 4-hr 51Cr release assay at an effector to target cell ratio of 1:1. The purified blast-NK cells lysed a broad range of target cells at relatively low effector to target cell ratios. The order of sensitivity of the target cells was YAC-1 much greater than K562 approximately equal to L-929 much greater than P815, consistent with that reported for NK cell-mediated lysis. The ability of the blast-NK cells to mediate lysis of NK cells also was examined. The purified NK cells mediated significant levels of lysis against the NK-like cloned line, NK1B6B10, in a 51Cr release assay. Furthermore, the purified blast-NK cells mediated lysis of bound blast-NK cells in a single-cell agarose assay. These results indicate that highly purified blast-NK cells are exceptionally efficient at mediating lysis and suggest that NK cells may act to negatively regulate the proliferation of NK cells by lysing other NK cells.     

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

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

Modulation of natural cytotoxicity by alloantibodies: III. Augmentation of natural killer activity by alloantisera directed against K,D, and I regions of the murine H-2 complex

Natural killer activity of mouse spleen cells toward a human myeloid leukemia cell line, K562, can be enhanced by alloantisera directed against individual antigens in the H-2 region. By using a panel of 13 antisera (8 directed against antigens in the K and D regions and 5 directed against antigens in the I region) and four strains of mice (C57BL/6J, CBA, DBA/2, and A/J) it was found that certain antisera would stimulate target cell lysis by spleen cells only if the antisera had specificity for antigens which were a part of the haplotype represented on the spleen NK effector cells. Anti Ia antisera could stimulate the anti K562 NK activity of nude mouse spleen cells which lack mature T cells. Depletion of B cells and macrophages from nude spleen cells, by passing through a nylon-wool column also did not abolish the effect of anti-Ia antiserum. It appears likely therefore that the anti-Ia antibodies exert this effect directly on NK cells and that Ia antigens may be expressed on NK cells. Since the antisera directed against different antigens in H-2 complex irrespective of subregion specificity (K, D, or I) stimulated the NK activity of mouse spleen cells, the phenomenon offered an interesting method for testing the presence of a given alloantigen on mouse spleen cells. Log-dose response curves for the augmentation of lysis induced by appropriate alloantisera were linear over a dilution range of 1:320 to 1:5120. By using the dose-response curves, potency ratios of two preparations of antisera (directed against antigen 33 of the K region) could be successfully determined. Besides the K562 cell line, many human lymphoblastoid cell lines could also be used as target cells in this assay system.     

Origin and differentiation of natural killer cells. I. Characteristics of a transplantable NK cell precursor

To study the origin and differentiation of natural killer (NK) cells, we developed an assay for the transplantable precursor of NK(YAC-1) cells present in the bone marrow. Mice were depleted of endogenous NK(YAC-1) cells by injection of anti-asialo GM1 antibody, followed by lethal whole body irradiation. Normal syngeneic bone marrow cells were transplanted into such pretreated mice. Regeneration of NK(YAC-1) activity in the recipient mice was monitored by two different assays: the ability of spleen cells to lyse YAC-1 cells in vitro and the ability to clear i.v. injected, 125IUdR-labeled YAC-1 cells from the lungs. With both assays, a dose-response relationship between the number of bone marrow cells injected and the degree of NK(YAC-1) activity generated could be demonstrated. However, the lung clearance assay appeared superior because the NK regeneration could be detected earlier and with lower numbers of injected marrow cells. With this assay, several characteristics of the NK precursors and their differentiation could be defined. 1) The generation of mature, lytic NK cells from their transplantable precursor requires an intact "marrow microenvironment" in the recipient mice, because differentiation failed to occur in mice rendered osteopetrotic by estradiol treatment. 2) The NK(YAC-1) precursors lack the surface antigens (NK-2.1, asialo GM1, Qa-5, Thy-1) that are characteristically seen on mature NK cells. 3) The NK-precursors could be eliminated from the bone marrow with anti-Qa-2 or anti-H-2 antisera + complement, indicating that these two antigens are expressed on the precursors. The relationship between NK(YAC-1) precursors and multipotent myeloid stem cells (CFU-S) was investigated by utilizing W/Wv and Sl/Sld mutant mice. Bone marrow cells of W/Wv anemic mice, although markedly deficient in CFU-S, have a normal frequency of NK(YAC-1) precursors. Sl/Sld mice that lack a suitable microenvironment for the development of CFU-S allowed normal differentiation of NK(YAC-1) precursors when transplanted with normal bone marrow cells. Together, these data suggest that multipotent myeloid progenitor cells, as defined by the CFU-S assay, and the NK(YAC-1) precursors are not closely related.     

The thiol proteinase inhibitors improve the abnormal rapid down-regulation of protein kinase C and the impaired natural killer cell activity in (Chediak-Higashi syndrome) beige mouse

Protein kinase C (PKC) is essential in intracellular signal transduction for various cell functions including natural killer (NK) cell activity. This enzyme is hydrolysed by calpain, which is Ca2+-dependent thiol proteinase. We showed here that in NK activity-deficient beige (bg/bg) mouse, the model of Chediak-Higashi syndrome, the translocated membrane-bound PKC activity declined rapidly in NK cell-enriched lymphocytes after TPA stimulation. However, the rapid decline was abolished by the pretreatment of cells with leupeptin (a thiol and serine proteinase inhibitor) or E64 (a thiol proteinase inhibitor). Furthermore, these reagents improved the impaired NK cell activity in beige mouse whereas they did not affect NK cell activity in C57BL/6 (+/+) and the heterozygous (+/bg) mice. Meanwhile, TPA stimulation induced only low levels in NK cytotoxic factors (NKCF) release from beige NK cells, but these reagents augmented the lowered NKCF release. These results suggest that the improvement of impaired NK cell activity in beige mouse by the thiol proteinase inhibitors may be due to the elimination of abnormal rapid down-regulation of PKC, resulting in the augmentation of the lowered PKC activity.     

Tight conjugate formation is not always required for natural killer cell-mediated lysis.

We have utilized several clonal cell lines, derived from the murine lymphoma ASL1w, to investigate the early events in NK-mediated lysis. The studies described here examine the relationship between NK recognition, NK cell:tumor cell conjugate formation, and NK-mediated lysis. The AW4F and AW4D tumor lines were susceptible to NK-mediated lysis and efficiently inhibited NK recognition in competitive inhibition assays, whereas the AW5J tumor, which is relatively resistant to NK-mediated lysis, did not. In contrast, the AW5E tumor was NK resistant but inhibited NK recognition almost as well as the NK-sensitive tumors, suggesting that it was deficient in a postbinding event required for NK-mediated lysis. These findings demonstrate a correlation, with one exception, between the susceptibility of the ASL1w-derived tumor lines to NK-mediated lysis and their ability to inhibit NK recognition. In contrast, there was no apparent correlation between tight conjugate formation, as assessed in three independent target binding assays, and the susceptibility of these tumors to NK-mediated lysis, showing that tight conjugate formation is not required for either efficient NK recognition or lysis.     

A short synthetic peptide fragment of human interleukin-1 beta increases both human and murine natural killer activity

The effect of a short synthetic fragment of human interleukin-1 beta (hu IL-1 beta) on natural killer (NK) activity was examined. Peripheral-blood mononuclear cells (PBMC) from normal donors showed a significant increase in NK activity against K562 leukemia cells after preincubation for 18 h with the IL-1 peptide. A similar augmentation was not observed after culturing the cells in the presence of hu IL-1 beta. The increase in tumor cell lysis could not be ascribed to a cytolytic activity of the synthetic fragment on target cells, since the peptide caused no direct lysis of various tumor cell lines. Although the peptide enhanced NK cytotoxicity of PBMC, highly purified large granular lymphocytes were not susceptible to its stimulatory effect. The addition to the cultures of antibodies to human interleukin-2 (hu IL-2) completely blocked the peptide-induced boost of NK cytotoxicity, suggesting that IL-2 is mainly involved in the activation process. The ability of the IL-1 peptide to increase NK activity was further confirmed in vivo in the mouse. Cytotoxicity against YAC-1 lymphoma cells, which was very low in the spleen of untreated BALB/c mice, was in fact significantly increased after a single inoculation of the peptide. These data thus indicate that a short synthetic peptide fragment of hu IL-1 beta is able to increase both human and murine NK activity.     

Mechanism of loss of natural killer activity in P815 ascites tumor bearing DBA/2 mice

P815 tumor cells (10(7] were administered intraperitoneally to DBA/2 mice. As the ascites tumor grew in the syngeneic host, a decline leading to a total loss of host spleen natural killer (NK) activity could be demonstrated. Removal of T and B cells or macrophages from the tumor-bearing (TB) mouse spleen cells did not raise the level of NK activity. Spleen cells from TB mice did not inhibit the NK activity of normal spleen cells. Comparable target (YAC cells) binding capacity could be demonstrated in spleen cells derived from normal or TB mice, but interferon failed to significantly stimulate the NK activity of TB mouse spleen cells. In adoptive transfer experiments, transfer of spleen or bone marrow cells from TB mice resulted in the development of significant levels of spleen NK activity in lethally X-irradiated recipient DBA/2 mice. These results indicate that the impairment of NK cell differentiation pathway rather than active suppression at the level of effector cells may be the mechanism of loss of NK activity in P815 TB DBA/2 mice.     

Augmentation of mouse natural killer cell activity by muramyl dipeptide and its analogs

The ability of muramyl dipeptide (MDP) and its structural analogs (des-MDP, abu-MDP, and des-abu-MDP) to influence mouse natural killer (NK) cells in two different strains of mice was examined. In CBA/J mice, administration of MDP by both intraperitoneal (ip) and intravenous (iv) routes enhanced splenic NK cell activity. Maximum augmentation of NK cell activity was observed 3 days after MDP treatment. NK cell activity was also stimulated upon in vitro culture of CBA/J mouse spleen cells with MDP. Only iv inoculation of MDP to C57BL/6 mice 7 days previously enhanced NK cell activity of spleen cells. Peritoneal NK cell activity was not affected in either strain of mice, regardless of the route of inoculation of MDP. Two structural analogs of MDP, abu-MDP and des-abu-MDP, enhanced peritoneal NK cell activity, whereas des-MDP had no effect when tested 3 days after ip treatment of CBA/J mice with these compounds. Peritoneal NK cell activity of C57BL/6 mice was not modulated by des-MDP, abu-MDP, or des-abu-MDP. A synergistic effect on peritoneal NK cell activity was observed in both CBA/J and C57BL/6 mice treated first with MDP and then with lipopolysaccharide (LPS) or Bacillus Calmette-Guerin (BCG).     

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)     

Recognition specificities, development, and possible biological function of natural killer cells in the mouse. I. Spleen focus forming assay for natural killer activity and analysis of lectin-like recognition structures on the surface of murine natural killer cells

A number of simple sugars have been tested and found to be effective in blocking lysis of YAC-1 tumor target cells by nonimmune murine natural killer (NK) effector cells. Using a spleen fragment culture system an assay has been developed which allows us to compare the inhibition of lysis observed in replicate culture wells prepared from cells contained in one spleen fragment (less than or equal to 1 X 10(6) cells). The inhibition pattern of any well was found to fall naturally into 1 of 25 (of the total 128 possible tested) patterns. Using this panel analysis of NK activity in individual mice of the same or different strain has been compared. Our data suggest that within any given strain the inhibition pattern of NK effector cells is quite uniform. Consistent differences are seen between strains which are interpreted in terms of a genetic control of the final expression of the NK recognition repertoire. In adult F1 hybrid individuals the pattern of recognition by NK cells is best considered a result of the codominant expression of genes contributed by each parent.