Rat natural killer cell and cytotoxic T cell lysis of H-2-negative murine embryonal carcinoma cells

H-2-lacking murine embryonal carcinoma (EC) cells have been proposed as universal targets for natural killer (NK) effectors from different species because their killing appeared to be uncomplicated by potential T cell effector mechanisms (Stern, P. L. et al., Int. J. Cancer 1981. 27:679). While some previous studies had shown that murine cytotoxic T cells were unable to lyse EC cells, rat T killers are shown here to be active against these targets and to be distinguishable from NK cells. Percoll density fractionation of rat peripheral blood lymphocytes enriches in parallel for NK-mediated lysis of both EC or YAC target cells. These NK cells unlike T cells, do not mediate lectin-dependent and cell-mediated cytotoxicity (LDCC) of NK-insensitive target cells. This procedure is thought to reveal the total cytolytic potential of stimulated T cell populations, regardless of specificity. In contrast to previous results with mice, we found that allogeneically primed rat cytotoxic T cells can kill murine EC cells in LDCC and, further, that rat cytotoxic T cells, generated by stimulation with mouse spleen cells in vitro, can lyse murine EC cells directly. This demonstration of T cell lysis of EC cells suggests that either there is a novel mechanism of lysis operating without requirement for major histocompatibility complex (MHC) structures, or EC cells express some hitherto unidentified MHC-like structures on their cell surface.     

小鼠子宫uNK细胞的分离及其特性研究

目的：建立小鼠子宫淋巴细胞分离方法，并初步观察小鼠子宫uNK细胞的特性。方法：分别用机械法和酶消化法制备单细胞悬液分离小鼠子宫淋巴细胞，用二色或三色荧光标记技术检测子宫uNK细胞的比例及相关特征。结果：机械法分离淋巴细胞技术相对稳定、纯度较高；酶消化法未降低DX5 细胞所占的比例，但酶的消化过程容易使淋巴细胞活化水平升高，表现为活化分子CD69的表达上调。子宫中存在大量的uNK细胞(NK1．1 CD3-或DX5 CD3-细胞)，小鼠怀孕早期和中期，uNK细胞占子宫淋巴细胞的比例随着怀孕天数的增长而增长，到怀孕的第10天达到高峰(uNK细胞比例达到48.74％)，之后比例开始迅速下降。结论：成功建立了小鼠子宫uNK细胞分离方法，子宫uNK细胞作为重要的天然免疫淋巴细胞，可能参与妊娠子宫对半同种异体胚胎的保护性免疫反应。     

Self class I molecules protect normal cells from lysis mediated by autologous natural killer cells

The surface expression of given HLA class I alleles protects target cells from lysis mediated by natural killer (NK) clones specific for these (or related) alleles. We could define two groups of NK clones specifically recognizing either Cw4 and related C alleles (“group 1”) or Cw3 and related C alleles (“group 2”), respectively. Monoclonal antibodies (mAb) to class I molecules should interfere with the interaction between NK receptors and class I molecules, thus resulting in lysis of protected target cells. However, none of the numerous available mAb to class I molecules had this effect. Therefore, we attempted to select new mAb on the basis of their ability to induce lysis of Cw4- or Cw3-protected lymphoblastoid cell lines by “group 1” or “group 2” NK clones, respectively. From mice immunized with phytohemagglutinin (PHA)-activated lymphocytes expressing either Cw3 or Cw4 alleles, two mAb were selected, the 6A4 (IgG1) and the A6-136 (IgM), on the basis of their ability to induce lysis of protected target cell. Both mAb immunoprecipitated molecules which, in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gave two bands of 45 and 12 kDa, typical of the class I heavy chain and β2 microglobulin, respectively. It has been proposed (but not proven), that self major histocompatibility complex class I molecules protect normal cells from autologous NK cell lysis. Thus, we used the 6A4 and A6-136 mAb to assess this possibility directly. Cw4-specific (“group 1”) and Cw3-specific (“group 2”) NK clones were isolated from donors expressing the corresponding (or related) protective C alleles. None of these clones lysed autologous PHA-induced blasts, used as target cells. However, addition of the F(ab′)₂ of 6A4 mAb or the A6-136 mAb resulted in lysis of autologous target cells by “group 1” or “group 2” NK clones, respectively. These data provide direct evidence that the expression of class I molecules protects normal cells from lysis by autologous NK cells.     

Perforin- and Fas-dependent mechanisms of natural killer cell-mediated rejection of incompatible bone marrow cell grafts

Natural killer (NK) cells eliminate target cells infected with intracellular pathogens and tumor cells by employing the granule exocytosis and death receptor pathways. They also mediate the acute rejection of incompatible bone marrow cell (BMC) grafts. However, the cytotoxic mechanisms employed during acute BMC graft rejection are obscure. Throughout these studies, BMC graft rejection was compared between two inbred strains of mice: 129 mice, which apparently use perforin- and Fas-dependent cytotoxicity, and C57BL/6 (B6) mice, which are able to exploit perforin- and/or Fas-independent mechanisms. Using perforin-knockout (PKO) mice, we have determined that the granule exocytosis pathway can play a major role in NK cell-mediated rejection of allogeneic and MHC class I-deficient BMC, depending upon the genetic background of the recipient and the environmental housing conditions. Although the granule exocytosis pathway seems to be the most potent cytolytic mechanism of NK cell-mediated rejection, alternative perforin-independent mechanisms, such as death receptor-induced apoptosis, also exist. By preventing both perforin- and Fas-mediated interactions concurrently, we observed that 129 mice were impaired in mediating MHC class I-deficient BMC rejection, while B6 mice maintained strong rejection capacities. The administration of neutralizing TNF antibodies to B6PKO mice before challenging with Fas and MHC class I double-deficient BMC still did not reverse rejection. Thus, our studies reveal the relative importance of perforin-, Fas-, and TNF-based cytotoxicity in NK cell-mediated rejection of incompatible BMC.     

Inhibition of natural killer cell-mediated lysis of tumor cells by normal and regenerating bone marrow

The natural killer (NK) cells which can lyse certain tumor cells during brief incubation in vitro have also been postulated to be the cells responsible for natural resistance to transplanted hemopoietic cells in vivo. To test this hypothesis, we have now measured: 1) the ability of bone marrow cells to compete with tumor cells as targets for spleen NK cells and 2) the effect of a brief incubation with spleen cells on the hemopoietic grafting potential of bone marrow cells. Firstly, when CBA/J mouse spleen cells were incubated with 51Cr-labelled YAC tumor cells together with DBA/2 mouse bone marrow cells, tumor cell lysis was reduced compared with incubation of spleen cells with tumor cells alone. Tumor cell lysis was even less when post-irradiation regenerating bone marrow was used. Secondly, C57B1/6 mouse bone marrow cells incubated with an excess of DBA/2 mouse spleen cells showed a reduced ability to produce hemopoietic spleen colonies in irradiated 129/J mice, whereas incubation with either thymus cells or fewer spleen cells produced no such effect. The results show that, when incubated with spleen cells under the conditions of a standard NK cell assay, regenerating bone marrow cells competitively inhibit the killing of YAC tumor cells and bone marrow progenitor cells are rendered ineffective in their hemopoietic colony-forming potential (CFU-s). These findings suggest that certain hemopoietic progenitor cells and YAC tumor cells can both serve as targets for NK cells, consistent with the view that the spontaneous cytolysis of tumor cells in vitro and natural resistance to bone marrow transplantation in vivo are mediated by cells of a common lineage.     

Role of natural killer cells in experimental murine myocarditis

Conclusions Infection of adolescent CD-1 mice with CVB3 activates NK cells. These activated NK cells can lyse infected fibroblasts in vitro and their transfer into mice prior to inoculation with CVB3 can reduce virus titers in heart tissues. If mice are depleted of NK cells prior to and throughout a CVB3 infection, myocarditic lesions show a comparatively greater pathology in the form of severe dystrophic calcification than in infected mice with an intact NK cell system. Also NK cell-depleted mice have significantly higher virus titers in heart tissues. These data suggest a role for NK cells in the infected mouse, i. e., that they reduce virus titers through lysis of infected cells and thereby reduce the severity of myocarditis. In keeping with such a defensive role is the finding of NK cells among the first inflammatory cells forming the nascent CVB3-induced focal myocarditic lesion. Paradoxically, NK cells remain in the mature lesion up to 10 days p.i. and may thus contribute to pathology. Further studies on whether these long-term residents release cytotoxic factors which continue to damage myocytes in absence of significant virus titers in heart tissues must be performed. These studies are now feasible because of the recent development of monoclonal antibodies against NK cytotoxic factor [30]. Finally, diet can adversely effect generation of activated NK cells in CVB3-inoculated mice and this finding may have significance for health-conscious human beings.     

Specific lysis of murine cells expressing HLA molecules by allospecific human and murine H-2-restricted anti-HLA T killer lymphocytes

The lysis by human and murine anti-HLA cytolytic T lymphocytes (CTL) of murine cells expressing class I HLA molecule after gene transfection has been studied using two different murine cells: LMTK- and P815-HTR-TK-. Weak but significant HLA-A11-specific lysis was found occasionally with human CTL on the HLA-A11+ L cells. On the contrary, P815-A11 or P815-A2 cells were lysed strongly and specifically by HLA-A11 or HLA-A2-specific human CTL. The T8+T4- phenotype of the effector cells was confirmed and the reaction was inhibited by anti-HLA class I monoclonal antibodies. Despite their higher sensitivity to human CTL, the P815-HLA+ cells did not express higher levels of HLA antigens than L cells, and the presence or the absence of human beta 2 microglobulin was irrelevant. Anti-human LFA-1 antibodies abrogated the lysis of P815-A11+ cells showing that the LFA-1 receptor which is apparently lacking on the L cell surface was on the contrary expressed on P815 cells. On the other hand, murine anti-HLA CTL have been prepared by immunizing mice against syngeneic HLA-A11+ L cells. They lysed very efficiently and specifically these cells, but appeared completely devoid of activity against human HLA-A11 target cells. This barrier was apparently due to the H-2 restriction of these H-2k anti-HLA murine CTL, as shown by their inability to lyse allogeneic H-2d cells expressing HLA-A11, and by the blocking of their activity by anti H-2k antibodies. By contrast, xenogeneic anti-HLA CTL obtained by immunizing murine lymphocytes against human cells lysed both human and murine HLA+ cells but they reacted with a monomorphic epitope of the HLA molecule in a nonrestricted way. These results show that human cells lyse very efficiently P815 murine cells expressing HLA class I antigens; the higher sensitivity of P815 cells compared to L cells is probably due to the presence of a LFA-1 receptor on these cells; a class I molecule of human origin can be seen as an H-2-restricted minor histocompatibility antigen in another species.     

Function of NKG2D in natural killer cell-mediated rejection of mouse bone marrow grafts

Irradiation-resistant natural killer (NK) cells in an F(1) recipient can reject parental bone marrow, and host NK cells can also prevent engraftment of allogeneic bone marrow. We show here that repopulating bone marrow cells in certain mouse strains expressed retinoic acid early inducible 1 proteins, which are ligands for the activating NKG2D NK cell receptor. Treatment with a neutralizing antibody to NKG2D prevented rejection of parental BALB/c bone marrow in (C57BL/6 x BALB/c) F(1) recipients and allowed engraftment of allogeneic BALB.B bone marrow in C57BL/6 recipients. Additionally, bone marrow from C57BL/6 mice transgenic for retinoic acid early inducible 1epsilon was rejected by syngeneic mice but was accepted after treatment with antibody to NKG2D. If other stem cells or tissues upregulate expression of NKG2D ligands after transplantation, NKG2D may contribute to graft rejection in immunocompetent hosts.     

Human natural killer cell lysis of Salmonella typhi intracellularly-infected U937 cells

Peripheral blood mononuclear cell (PBMC) cytotoxicity against S. typhi (wild type or mutant strain TYT1231)-infected U937 cells was significantly higher than its lytic effect against noninfected cells (control) at the various effector-to-target cell ratio used (30:1, 50:1 and 70:1). Natural killer cell activity [expressed as % specific lysis (mean +/- SEM); 30:1 (25.4 +/- 3.6, 25.1 +/- 4.2 and 16.3 +/- 3.3); 50:1 (27.8 +/- 3.7, 26.7 +/- 4.5 and 20.9 +/- 2.9) and 70:1 ratio (33.2 +/- 5.9, 29.4 +/- 4.2 and 22.8 +/- 2.8), respectively] appeared to be dependent on such ratios and independent of the S strain studied. Most (80%) of individual samples tested showed at least a 20% specific lysis increase over their own control; essentially no changes or smaller increases in NKC activity were observed in all other samples. Similar results were obtained when using highly purified NKC (HPNKC) preparations as effector cells [NKC activity (mean +/- SEM); 5:1 (46.2 +/- 4.7, 43.2 +/- 5.0 and 25.2 +/- 2.3) and 10:1 effector-to-target cell ratio (49.3 +/- 4.9, 44.7 +/- 5.2 and 27.2 +/- 2.6, respectively)]. All individual samples tested showed at least a 20% specific lysis increase over their own control. These results show that S. typhi-infected U937 cells are a significantly better target for NKCs than control cells and indicate that intracellular bacteria survival capacity is not a critical factor for infected cells becoming a NKC target.     

Targeted lysis of HIV-infected cells by natural killer cells armed and triggered by a recombinant immunoglobulin fusion protein: implications for immunotherapy

Natural killer (NK) cells play an important role in both innate and adaptive antiviral immune responses. The adaptive response typically requires that virus-specific antibodies decorate infected cells which then direct NK cell lysis through a CD16 mediated process termed antibody-dependent cellular cytotoxicity (ADCC). In this report, we employ a highly polymerized chimeric IgG1/IgA immunoglobulin (Ig) fusion protein that, by virtue of its capacity to extensively crosslink CD16, activates NK cells while directing the lysis of infected target cells. We employ HIV as a model system, and demonstrate that freshly isolated NK cells preloaded with an HIV gp120-specific chimeric IgG1/IgA fusion protein efficiently lyse HIV-infected target cells at picomolar concentrations. NK cells pre-armed in this manner retain the capacity to kill targets over an extended period of time. This strategy may have application to other disease states including various viral infections and cancers.     

The immunobiology of natural killer cells and bone marrow allograft rejection.

Natural killer (NK) cells mediate the acute rejection of bone marrow cell (BMC) allografts, but not solid tissue grafts, in lethally irradiated mice. However, the mechanisms underlying this capability for rejecting BMC remain unclear. NK cells express (1) inhibitory receptors specific for major histocompatibility complex (MHC) class I molecules and (2) activating receptors with diverse specificities. Inhibitory NK receptors confer to NK cells the ability to discriminate between MHC class I-positive and -negative target cells and are therefore involved in the control of NK cell tolerance to self, as well as in the elimination of cells that have downregulation of MHC class I molecules. Preclinical studies in mice have provided good evidence that subsets of NK cells that bear different combinations of both inhibitory and activating Ly49 receptors can interact with each other and target specific BMC rejection, as well as NK cell responses toward tumor cells. Recent clinical studies have also shown that the use of killer cell immunoglobulin-like receptor ligand incompatibility in patients with leukemia who received hematopoietic stem cell transplants correlated not only with the elimination of graft rejection, but also with eradication of tumor and prevention of graft-versus-host disease; this offers a significant advantage for survival. In this review, we attempt to bring together literature regarding the biology of NK cells and discuss the current issues in bone marrow transplantation and the potential clinical role of NK cell alloreactivity in the efficacy of this procedure for immunotherapy of cancer and infectious states.     

Functional role of phosphatidylinositol 3-kinase in direct tumor lysis by human natural killer cells

Cytotoxicity is a key function of natural killer (NK) and T cells; yet the molecular mechanism is unclear. We have biological, biochemical and molecular evidence to demonstrate that phosphatidyl-inositol (PI) 3-kinase is critical for direct NK lysis of tumor cells, via control of intracellular granule movement. Tumor cell engagement rapidly activated PI 3-kinase in NK cells within 5 min, as demonstrated by p85 subunit tyrosine phosphorylation and its ability to generate phosphatidylinositol 3-phosphate, PI(3)P, from PI. Wortmannin and LY294002 effectively inhibited NK cells to lyse 51Cr-labeled tumor cells at the same doses that blocked PI-phosphorylating function in tumor-activated NK cells. Immunostaining demonstrated that tumor engagement for only 5 min mobilized perforin and granzyme B from NK cells unidirectionally towards the target, and prior treatment of NK cells with either PI 3-kinase inhibitor effectively stopped this intracellular polarization. Lastly, ectopic expression of dominant-negative p85 or p110 mutant markedly suppressed NK lytic capacity. These results taken together demonstrate that PI 3-kinase may control NK lytic function via granule polarization towards the contacted target cell.     

Human natural killer cells: Molecular mechanisms controlling NK cell activation and tumor cell lysis

Natural killer cells represent a highly specialized lymphoid population with a potent cytolytic activity against virus-infected or tumor cells. Their function is regulated by a series of inhibiting or activating signals. The mechanisms by which NK cells kill susceptible target cells was thought to be elucidated after the discovery of inhibitory receptors specific for MHC-class I molecules: NK cells would kill those target cells that lack MHC-class I molecules. However, the actual scenario revealed more complex with the discovery of activating receptors and their ligands. Thus, in certain pathological conditions, corticosteroid treatment or exposure to TGFbeta, NK cells may under-express activating receptors. In addition, target cells may lack ligands for activating receptors and thus fail to activate NK cells upon cell-to-cell contact. This clearly implies that activation of NK cells and of their potent effector mechanism are under the control of different checkpoints.     

Effect of cyclosporin A on murine natural killer cells.

In mice, cyclosporin A decreased the natural killer cell-enhancing effect of two interferon inducers, infective murine cytomegalovirus and nonreplicating Newcastle disease virus. It also inhibited murine cytomegalovirus replication at doses greater than 20 mg/kg, but it did not significantly inhibit interferon induction by Newcastle disease virus. In cell culture, cyclosporin A had no direct effect on the natural killer activity of spleen mononuclear cells derived from normal or murine cytomegalovirus-infected animals. However, at 50 micrograms/ml it significantly reduced the ability of interferon to enhance the natural killer activity of normal spleen cell suspensions. The inhibitory effect of cyclosporin A on natural killer cell activity in infected mice may be partly explained by its ability to block the action of interferon.     

Suppression of murine natural killer cell activity by adherent cells from aging mice

Natural killer (NK) cell activity declines with age in mice. The purpose of this study was to investigate the effect of peritoneal and splenic adherent cells from young and old mice on NK activity to determine whether adherent cell suppressor function might contribute to this decline. Peritoneal adherent cells from old mice suppressed NK activity of young splenic non-adherent indicator cells more than peritoneal cells from young mice. Splenic adherent cells from old but not from young mice also suppressed this activity. That (1) the suppressive activity of the adherent cell populations was not affected by treatment with anti-Thy-1 plus complement, and that (2) the adherent cell population contained 77-92% cells positive for alpha-naphthyl acetate esterase activity, suggests that the active adherent suppressor cell may be a macrophage. Therefore, the age-related decline in NK activity in mice can be explained, in part, by an increase in adherent cell suppressor function.     

Human adipose-derived stem cells impair natural killer cell function and exhibit low susceptibility to natural killer-mediated lysis

Human adipose-derived stem cells (hASCs) have been successfully used in treating numerous diseases. However, several aspects need to be considered, particularly in the context of allogeneic cell therapy. To better understand hASCs-host interactions, we studied the phenotype of hASCs and their modulatory effect on natural killer (NK) cells by using bone marrow-mesenchymal stem cells (hBM-MSCs) as a reference. The hASCs displayed a lower susceptibility to NK cell-mediated lysis and a lower expression of ligands for DNAM-1 when compared with hBM-MSCs. Moreover, here we demonstrated that hASCs and hBM-MSCs can modulate NK cells through the action of soluble factors such as indoleamine 2,3-dioxygenase. Altogether, these results suggest that for an adoptive cell therapy based on the transfer of allogeneic hASCs, the NK-hASCs crosstalk will not result in an immediate recognition of the transferred cells. Thus, hASCs may remain in the tissue long enough to balance the immune response before being cleared.