Mechanisms of nonspecific cytotoxic cell regulation of apoptosis: cytokine-like activity of Fas ligand

The role of FasL/FasR pathways of immunoregulation of programmed cell death in teleost cytotoxic innate immunity has not been previously examined. In the present study, constitutive cytosolic soluble FasL (sFasL) was detected in anterior kidney (AK), peripheral blood (PBL) and liver NCC obtained from tilapia. Ligation of NCC by tumour cells caused the release of sFasL that was associated with lysis of HL-60 targets in 14 h killing assays. Evidence that sFasL mediated this activity was that anti-(human) FasL inhibited tilapia and catfish (cf.) NCC lysis of FasR+ HL-60 tumour cells. Inhibition was concentration dependent. Lysis of IM-9 targets (12% positive for FasR) by (cf.) anterior kidney and PBL NCC was only partially inhibited by anti-FasL mab. Activated NCC from both species were negative for the expression of membrane FasL and FasR. These data confirmed that NCC lyse sensitive tumour cells by multiple effector pathways. Pretreatment of (FasR+) HL-60 cells with anti-FasR mab completely inhibited cf. cytotoxicity at low (100:1) E:T ratios. Anti-FasR mab did not inhibit the lysis of IM-9 targets by cf. NCC. This study demonstrated that for catfish and tilapia, initial target cell conjugate formation was required; however, the terminal killing mechanism depended on at least two different pathways of cytotoxicity. One pathway depended on the release of preformed soluble FasL by activated NCC in the presence of FasR positive target cells. A second pathway has yet to be determined.     

Role of nonspecific cytotoxic cells in the induction of programmed cell death of pathogenic protozoans: participation of the Fas ligand-Fas receptor system

Numerous different species of parasites and pathogenic microorganisms produce programmed cell death (PCD) and apoptosis in eukaryotic targets. How ever, only a few studies have demonstrated that effector cells, cytokines, growth factors, or soluble apoptosis-inducing factors are capable of initiating apoptosis in protozoan parasites. Certain Tetrahymena spp. in teleosts are opportunistic pathogens. In the present study these pathogenic protozoans were developed as a model system to describe the potential role of the Fas ligand (FasL)-Fas receptor (FasR) system as a means of innate immunity in teleosts. Nonspecific cytotoxic cells (NCC) constitutively express soluble FasL (sFasL). Binding of the antigen receptor (i.e., NCCRP-1) on NCC to target cells caused the release of sFasL into the milieu. The presence of functional sFasL in these supernatants was determined by Western blot analysis and by demonstrating the lysis of FasR(+) HL-60 but not IM-9 (FasR(-)) targets. Soluble FasL containing supernatants generated by tumor cell-activated NCC also produced a reduction in 2 N DNA (i.e., DNA hypoploidy) of T. furgasoni. The induction of DNA hypoploidy by NCC supernatants could be neutralized by adsorption of the supernatants with anti-FasL antibody (but not with an isotype control). Experiments were next done to determine the expression of FasR on Tetrahymena and study the effects of anti-FasR monoclonal crosslinkage and treatment with soluble human recombinant FasL (huFasL) on initiation of PCD in Tetrahymena. Cell cycle analysis revealed that both crosslinkage and soluble huFasL binding to Tetrahymena produced DNA hypoploidy. The reduction in diploid DNA was confirmed by observing oligonucleosome fragmentation (DNA laddering) following anti-FasR treatment. Additional evidence for FasR expression on Tetrahymena was obtained using fluorescence microscopy and flow cytometry. Both methods showed that all Tetrahymena examined (three species consisting of four isolates) expressed membrane FasR. These studies demonstrated the potential of the FasL-FasR system in teleosts for initiation of antiparasite innate immunity. Effector NCC may initiate PCD of Tetrahymena that express a FasR-like protein. Induction of apoptosis may be a major mechanism of homeostatic control of protozoan parasite infestations/infections.     

Use of Sequence-Specific Antisense Oligodeoxynucleotides to Determine the Protozoan Parasite Antigen Recognized by Nonspecific Cytotoxic Cells

The antigen on the protozoan parasite Tetrahymena pyriformis recognized by catfish nonspecific cytotoxic cells (NCC) is a 46- to 48-kDa protein referred to as NKTag. The complete cDNA-derived amino acid sequence of NKTag has been obtained. The antigenic determinant of NKTag corresponding to the NCC binding site has been determined with synthetic peptides in target cell competition experiments. To more directly characterize the mechanism of parasite:effector cell interaction, we applied NKTag sequence-specific antisense oligodeoxynucleotides to Tetrahymena in vitro. NKTag mRNA translation by Tetrahymena was blocked by specific antisense (AS) oligodeoxynucleotides. 5′-3′ sense (S) oligodeoxynucleotide sequences were synthesized corresponding to the first 17 N-terminal amino acids of NKTag (in addition to −2 untranslated codons plus the start codon). Complimentary AS oligodeoxynucleotides were likewise synthesized. To determine the optimum in vitro conditions for AS treatment, we tested parasites at various phases of their growth cycle for the effects of a single AS treatment. At 9 h post-AS treatment (during the linear phase of the growth curve), maximum reduction in membrane expression of NKTag was observed. Eighty-five percent of Tetrahymena were positive for expression of NKTag at 0 time post-AS treatment versus 13% positive at 9 h. Membrane expression of AS-treated parasites returned to normal levels by 24 h post-treatment. In cold target inhibition experiments, the reduced NKTag expression by Tetrahymena at 9 h AS treatment was confirmed by observing a complete inability (compared with S-treated parasites) to compete with IM-9 cells for binding with NCC. These data demonstrated a unique experimental in vitro system to define the antigen determinant on target cells responsible for recognition by cytotoxic effector cells that participate in innate immune responses. Received: 14 June 1999 / Accepted: 4 September 1999     

Nonspecific cytotoxic cells as effectors of immunity in fish

Nonspecific cytotoxic cells (NCC) may be the teleost fish equivalent of mammalian natural killer (NK) cells. Although significant differences exist between species regarding many characteristics of these cells, both NCC and NK cells share similarities: in the types of target cells sensitive to lysis; in mechanisms of target cell recognition; in the requirements for a competent lytic cycle; and both types of effectors participate in mediating the lysis of infectious microorganisms. A putative antigen binding receptor obtained from catfish NCC has now been characterized using monoclonal antibodies (mabs). This receptor is a vimentin-like protein. Preliminary studies indicate that NCC recognize a 40 kD protein on the membranes of susceptible target cells. Solubilized target cell protein can specifically bind to NCC and inhibit killing.Similar to NK cells, NCC require cell contact with the target cell to deliver the lethal cytotoxic hit. NCC appear to be the more potent cytotoxic cells because fewer are required to kill an individual target cell and less time is required for this action to occur than for NK cells. Unlike NK cells, NCC do not recycle under experimental conditions. Preliminary studies were also reviewed to characterize signal transduction responses. Monoclonal antibody against the vimentin-like protein receptor activates NCC cytotoxicity, initiates the production of significant increased levels of free cytoplasmic calcium, and causes the production of inositol lipid intermediates (specifically phosphotidylinositol 1, 4–5 trisphosphate). NCC may be important effectors of anti-parasite immunity. Although these cells probably do not elicit memory responses, data suggest that they do recognize antigen and can be activated and recruited into peripheral tissue where they mediate cytolytic responses.     

Flow cytometry-based assay for determination of teleost cytotoxic cell lysis of target cells.

BACKGROUND: The nonradiometric assays previously developed to detect cellular cytotoxic activity have been hindered by many difficulties. Among the problems are the requirement for expensive commercial kits and the use of techniques that produce high background noise and decreased sensitivity. In addition, these assays did not account for bidirectional apoptosis (activation-induced cell death [AICD]). Most attempts to derive cytometry-based cytotoxicity assays have been unsuccessful because individual effectors and targets could not be identified (i.e., "separated") using gating techniques. METHODS: In the present study, teleost nonspecific cytotoxic (NCC) and mammalian target cells were each sufficiently different in size to identify them by flow cytometry (FCM). Using appropriate gating and discriminator techniques, these two cell populations were differentiated based on scatter properties and propidium iodide (PI) binding. Total capacity for PI binding was obtained by permeabilization of the targets with ice-cold acetone. Spontaneous PI binding was relatively low. This technique detected cytotoxicity at effector-to-target ratios (E:T) of 1:1 and after only 30 min cocultivation. RESULTS: Tilapia NCC from peripheral blood kill human transformed target cells by necrosis and apoptosis as identified by PI binding. Maximum killing of HL-60 targets (approximately 100%) occurred by 180 min cocultivation. For the same time, the killing of IM-9 did not exceed 60%. Almost 90% of IM-9 targets are lysed following 14 h of cocultivation. The maximum killing of both HL-60 and IM-9 targets was observed at a 25:1 E:T ratio after 14 h. Comparisons of the chromium(>51) release assay with flow detection of cytotoxicity revealed that FCM detected 55% lysis of the target cells compared with 2% cytotoxicity by chromium release, after a cocultivation time of 240 min. DISCUSSION: FCM detection of (teleost) NCC lysis of target cells using PI uptake is more sensitive than standard chromium release assays. This level of sensitivity was observed because NCC and targets were sufficiently different in size such that they could be resolved by scatter plots. Using FCM, cytotoxicity was detected earlier and at lower E:T ratios than previously reported for chromium release assays. Although tilapia were reported previously to be not capable of lysing IM-9 targets by chromium release detection, the more sensitive method of FCM detected cytotoxicity using PI uptake. HL-60 lysis by tilapia NCC exhibited saturable kinetics but occurred at different times post-cocultivation.     

Characterization by monoclonal antibodies of a target cell antigen complex recognized by nonspecific cytotoxic cells

Fish nonspecific cytotoxic cells (NCC)3 recognize and lyse a large variety of human and mouse transformed cells. In an effort to determine the Ag recognized by NCC on these targets, mAb were raised against NC-37 target cells. Four anti-NC-37 mAb were chosen for further characterization based on their effects on NCC lysis of target cells. Purified mAb 18C2 and 1E7 (IgM isotype) inhibited NCC killing of the following targets: U937, MOLT-4, K562, HL-60, DAUDI, NC-37, P815, and YAC-1. The dose-dependent inhibitory activity occurred at the target cell level and ranged from 50 to 70% at a concentration of 50 micrograms/well when compared to noninhibitory mAb 7C6 and 1D4 (IgG isotype). Similarly, mAb 18C2 protected the fish parasite Tetrahymena pyriformis from lysis by NCC when compared to mAb 7C6. Adsorption experiments demonstrated that the inhibitory effect on NC-37 lysis by NCC could be removed in a titratable fashion by incubation of mAb 1E7 with any one of the other target cell lines, but it could not be removed by incubation with effector cells. The inhibitory activity of mAb 1E7 and 18C2 was shown to be caused by the inhibition of conjugate formation between effector and NC-37 target cells. The relative membrane concentration of the antigenic determinants recognized by these mAb on the target cells was studied by flow cytometry using FITC-labeled mAb. These experiments showed that all four mAb bound to the surface of the cells tested. Biochemical analysis with Western blots and immunoprecipitation showed that mAb 18C2 and 1E7 recognize two Ag in NC-37 lysates: a larger protein of around 80 kDa and a smaller one of 42 kDa.     

Natural cytotoxic cells of gilthead seabream: maximum percentage of lysis

The maximum percentage of lysis of head-kidney non-specific cytotoxic cells (NCC) against mammalian tumour cells (L1210 and K562) in the marine teleost gilthead seabream (Sparus aurata L.) was studied. The present data indicate the short period of time necessary for gilthead seabream NCC to form conjugates and deliver a lethal hit. The maximum percentage of lysis observed demonstrates that seabream NCC activity against L1210 tumour cells is faster than against K562 tumour cells. This kinetic parameter suggests that fish NCC show a less efficient cytotoxic activity than their mammalian counterparts. The possibility of applying theoretical treatments to systems consisting of lower vertebrate non-specific cytotoxic cells and tumour targets, similar to those applied to mammals, is considered, and the phylogenetic implications of our findings are discussed.     

Investigating the lysis of small-cell lung cancer cell lines by activated natural killer (NK) cells with a fluorometric assay for NK-cell-mediated cytotoxicity

Activation of natural killer (NK) cells with interleukin-2 (IL-2) and IL-12 leads to an enhanced lysis of tumour cells. We investigated the ability of NK cells, with or without prior activation, to lyse a variety of small-cell lung cancer (SCLC) target cells. Specific lysis was measured with a fluorometric assay for NK-cell-mediated cytotoxicity: target cells were labelled with 3,3′-dioctadecyloxacarbocyanine, a green membrane dye. After co-incubation with NK cells, dead target cells were stained with propidium iodide, a red DNA dye that only penetrates dead cells. Of all eight SCLC cell lines tested, three were susceptible to lysis by non-activated NK cells, three were only susceptible to lysis by NK cells activated with IL-2 and IL-12 and two were not even susceptible to lysis by activated NK cells. The differences in target cell susceptibility showed no correlation with the expression of MHC-I on the surface of the target cells or with the expression of the adhesion molecules CD50, CD54, CD58 or CD102. Comparing the kinetics of the lysis of one SCLC cell line sensitive to non-activated NK cells and one sensitive only to activated NK cells, we found that maximum lysis of the former was obtained after 1 h, whereas significant lysis of the latter was only obtained after 4 h of incubation. This might be due to different mechanisms engaged in target cell lysis. Received: 23 December 1998 / Accepted: 8 April 1999     

Selective MHC expression in tumours modulates adaptive and innate antitumour responses

Progress towards developing vaccines that can stimulate an immune response against growing tumours has involved the identification of the protein antigens associated with a given tumour type. Epitope mapping of tumour antigens for HLA class I- and class II-restricted binding motifs followed by immunization with these peptides has induced protective immunity in murine models against cancers expressing the antigen. MHC class I molecules presenting the appropriate peptides are necessary to provide the specific signals for recognition and killing by cytotoxic T cells (CTL). The principle mechanism of tumour escape is the loss, downregulation or alteration of HLA profiles that may render the target cell resistant to CTL lysis, even if the cell expresses the appropriate tumour antigen. In human tumours HLA loss may be as high as 50%, inferring that a reduction in protein levels might offer a survival advantage to the tumour cells. Alternatively, MHC loss may render tumour cells susceptible to natural killer cell-mediated lysis because they are known to act as ligands for killer inhibitory receptors (KIRs). We review the molecular features of MHC class I and class II antigens and discuss how surface MHC expression may be regulated upon cellular transformation. In addition, selective loss of MHC molecules may alter target tumour cell susceptibility to lymphocyte killing. The development of clinical immunotherapy will need to consider not only the expression of relevant CTL target MHC proteins, but also HLA inhibitory to NK and T cells. Received: 20 March 1999 / Accepted: 3 May 1999     

Bactericidal and tumoricidal activities of synthetic peptides derived from granulysin

Granulysin, a 9-kDa protein localized to human CTL and NK cell granules, is cytolytic against tumor cells and microbes. Molecular modeling predicts that granulysin is composed of five alpha-helices separated by short loop regions. In this report, synthetic peptides corresponding to the linear granulysin sequence were characterized for lytic activity. Peptides corresponding to the central region of granulysin lyse bacteria, human cells, and synthetic liposomes, while peptides corresponding to the amino or carboxyl regions are not lytic. Peptides corresponding to either helix 2 or helix 3 lyse bacteria, while lysis of human cells and liposomes is dependent on the helix 3 sequence. Peptides in which positively charged arginine residues are substituted with neutral glutamine exhibit reduced lysis of all three targets. While reduction of recombinant 9-kDa granulysin increases lysis of Jurkat cells, reduction of cysteine-containing granulysin peptides decreases lysis of Jurkat cells. In contrast, lysis of bacteria by recombinant granulysin or by cysteine-containing granulysin peptides is unaffected by reducing conditions. Jurkat cells transfected with either CrmA or Bcl-2 are protected from lysis by recombinant granulysin or the peptides. Differential activity of granulysin peptides against tumor cells and bacteria may be exploited to develop specific antibiotics without toxicity for mammalian cells.     

Enhanced MHC I antigen expression on tumour target cells is inversely correlated to lysis by allogenic but not by xenogenic NK cells

Relationship between the levels of MHC class 1 antigen expressed on tumour cells and their susceptibility to allogenic and xenogenic NK cells was investigated. Mouse and human natural killer-resistance inducing factor (NK-RIF) preparations were used for augmenting/inducing MHC 1 antigen expression on murine YAC and human K562 tumour cells, respectively YAC cells with augmented MHC I antigen expression became relatively resistant to lysis by murine NK cells but not to rat NK cells. Similarly, induction of MHC I antigens on K562 cells reduced their susceptibility to human NK cells but not to monkey NK cells. These results indicate that the inverse correlation of MHC I antigen expression and NK susceptibility does not hold true for xenogenic pairs of NK effector and target cells.     

Effects of beta-adrenergic receptor activation, cholera toxin and forskolin on human natural killer cell function.

Membranes from highly purified natural killer (NK) cells were ADP-ribosylated by treatment with cholera toxin (CTX). CTX resulted in a single band of specific 32P incorporation at Mr 43,600. CTX treatment of intact NK cells caused a 9-fold increase in cyclic AMP (cAMP) concentrations. Pretreatment of NK cells with CTX diminished their ability to lyse K562 tumour cells by up to 79%. Forskolin treatment elevated NK cell cAMP levels 8-fold and decreased lysis of K562 cells by up to 45%. Adrenaline and isoprenaline (isoproterenol) both inhibited lysis of K562 cells by approx. 35% and elevated cAMP by at least 2.5-fold, and their inhibition of lysis was reversed by propranolol. These data suggest that the stimulatory guanine-nucleotide-binding protein GS coupled to beta-adrenergic receptors is involved in transducing signals which inhibit NK cell lysis of tumour cells. CTX and forskolin also diminish the ability of NK cells to bind K562 cells (binding is necessary for lysis). This suggests that the NK-cell receptor(s) for the tumour cell may be altered as a consequence of cAMP-mediated events or by activation of GS.     

Missing self by heterogeneous natural killer cells

Some murine (YAC, P815 and SP20) and human (Molt4, Raji and HR7) tumour cell lines were (i) treated with IFN-γ for inducing enhanced expression of MHC class I antigen, or (ii) given a brief treatment with citrate buffer (pH 3.0), which resulted in denaturation of class I MHC antigens on these tumour cells. IFL-γ or acid treated tumour cells were used as unlabelled competing targets in cold target inhibition assays. The results indicated that the competing ability of acid-treated tumour cells remained unaltered, whereas IFN-γ treated tumour cells competed with significantly less efficiency. These results have been evaluated in light of the current view of NK cell development and the expression of inhibitory receptors for MHC class I molecules (IRMs), on NK cells. A modified view on NK cell heterogeneity based upon IRM expression has been proposed which reconciles several apparently discordant observations about the activity and role of NK cells. Two classes of NK cells have been proposed. Type I NK ceils have target recognition receptors which do not recognize autologous normal cells, lack IRMs, and may participate in first line of defence against transformed cells in vivo. Type II NK cells have target recognition receptors for autologous normal cells and express at least one self-reactive IRM in order to prevent auto-killing. Type II NK cells participate in killing those transformed cells which down-regulate their MHC class I expression in order to escape cytotoxic T-cell surveillance. It is also postulated that mechanism of inverse correlation of target cell MHC class I expression levels and their susceptibility to NK cells, involves interference model of missing self hypothesis for type I NK cells and inhibitory signal model of missing self hypothesis for type II NE cells. Finally, it is proposed that acid treatment of tumour cells enhances their lysis susceptibility by making them additionally susceptible to type II NK cells, rather than enhancing their killing by type I NK cells. This proposition would explain the lack of effect of acid treatment on the competing ability of tumour cells, when target cells are only lysed by type I NE cells.     

Investigating the morphology, function and genetics of cytotoxic cells in bony fish

Bony fish (teleosts) possess multiple cytotoxic cell lineages that recognize and destroy virally infected and transformed cells. In general, these lineages parallel their functional equivalents in mammals and include neutrophilic granulocytes, macrophages, cytotoxic T lymphocytes (CTL) and natural killer (NK) cells. These four cell types have been morphologically identified in multiple fish species but only limited information is available about their function. In contrast, much work has gone into examining the function of a fifth cytotoxic cell lineage, termed nonspecific cytotoxic cells (NCC), that has been referred to as the bony fish equivalent of NK cells. However, evidence suggesting that NCC do not represent the NK lineage has come through the development of multiple cytotoxic catfish cell lines that are morphologically and functionally similar to human NK cells and are distinct from NCC. In addition to characterizing cytotoxic cells from fish, recent work has identified the novel immune-type receptors (NITR) and cichlid killer leukocyte receptors (cKLR) that are structurally related to mammalian NK receptors and likely play a role in cytotoxic function in fish. This review summarizes the morphological and functional evidence for cytotoxic cells within bony fish and discusses future directions for examining cytotoxicity through genomics and transgenics.     

NK cell lysis of HIV-1-infected autologous CD4 primary T cells: requirement for IFN-mediated NK activation by plasmacytoid dendritic cells

In vivo, several mechanisms have been postulated to protect HIV-1-infected cells from NK surveillance. In vitro, previous research indicates HIV-1-infected autologous CD4(+) primary T cells are resistant to NK lysis. We hypothesized that NK lysis of HIV-1-infected target cells would be augmented by the presence of accessory cells and/or accessory cell factors. In this study, we show that stimulation of plasmacytoid dendritic cells (PDC) with the TLR9 agonist, CpG ODN 2216, triggered NK lysis of HIV-1-infected autologous CD4(+) primary T cells. PDC-stimulated NK lysis was dependent upon MHC class I (MHC-I) down-regulation on infected cells, and primary HIV-1 isolates that exhibited enhanced MHC-I down-regulation were more susceptible to NK-mediated lysis. PDC-stimulated NK lysis of HIV-1-infected autologous CD4(+) primary T cells was blocked by neutralizing Abs to type 1 IFN and was perforin/granzyme dependent. Overall, our data suggest that HIV-infected cells are not innately resistant to NK lysis, and that exogenous NK stimulation derived from PDC can trigger NK cytotoxicity against HIV-1-infected autologous CD4(+) primary T cells.     

Molecular cloning of rat NK target structure--the possibility of CD44 involvement in NK cell-mediated lysis

The nature of target molecules of natural killer (NK) cell-mediated lysis remains to be elucidated. As we previously reported, mAb 109 recognizes one of the tumor-associated antigens, designated as 109 antigen (Ag), expressed on the cell surface of rat fibrosarcomas W31 and W14, which are transformants of WFB (rat fetal fibroblast cell line) with H-ras oncogene. 109Ag was thought to be a target structure of NK cells since mAb 109 inhibited NK cell-mediated lysis against W31 and W14. Here, we demonstrate by molecular cloning that 109Ag is identical to rat CD44. Immunoprecipitation and immunoblotting studies also showed that mAb 109 and anti-rat CD44 mAb OX-50 recognize the same protein of W31 cell lysates with an 86 kDa molecular size. CD44 was suggested to be a target structure of NK cell-mediated lysis; however, rat CD44 cDNA transfection alone into CD44 null cell lines did not result in up-regulation of target cell susceptibility to NK cell-mediated lysis. Our results therefore indicated that CD44 may play a crucial role as one of the target structures in our rat fibrosarcoma system though the cell surface expression of CD44 alone does not affect NK susceptibility of the target cells.     

HER-2/neu peptide specificity in the recognition of HLA-A2 by natural killer cells

Although natural killer (NK) cells have been described as non-MHC-restricted, new evidence suggests that NK activity can be either up- or down-regulated after interaction with the peptide–MHC-class-I complex expressed on target cells. However, the epitope(s) recognized by NK cells have remained ill-defined. We investigated NK cell recognition of synthetic peptides representing a portion of a self-protein encoded by the HER-2/neu (HER-2) proto-oncogene and presented by HLA-A2. HER-2 nonapeptides C85, E89, and E75 were found partially to protect T2 targets from lysis by freshly isolated and interleukin-2(IL-2)-activated NK cells (either HLA-A2⁺ or A2⁻). This inhibition was not solely due to changes in the level of HLA-A2 expression or conformation of serological HLA-A2 epitopes. Using single-amino-acid variants at position 1 (P1) of two HER-2 peptides, we observed that protection of targets was dependent on the sequence and the side-chain. These results suggest similarities in the mechanism of target recognition by NK and T cells. This information may be important for understanding the mechanisms of tumor escape from immunosurveillance and could help explain the aggressiveness of HER-2-overexpressing tumor cells. Received: 16 March 1999 / Accepted: 3 June 1999     

Expression of conformationally constrained adhesion peptide in an antibody CDR loop and inhibition of natural killer cell cytotoxic activity by an antibody antigenized with the RGD motif.

We report that an antibody engineered to express three Arg-Gly-Asp (RGD) repeats in the third complementarity-determining region of the heavy chain (antigenized antibody) efficiently inhibits the lysis of human erythroleukemia K-562 cells by natural killer (NK) cells. Synthetic peptides containing RGD did not inhibit. Inhibition was specific for the (RGD)3-containing loop and required simultaneous occupancy of the Fc receptor (CD16) on effector cells. The antigenized antibody inhibited other forms of cytotoxicity mediated by NK cells but not cytotoxicity mediated by major histocompatibility complex-restricted cytotoxic T lymphocytes (CTL). A three-dimensional model of the engineered antibody loop shows the structure and physicochemical characteristics probably required for the ligand activity. The results indicate that an RGD motif is involved in the productive interaction between NK and target cells. Moreover, they show that peptide expression in the hypervariable loops of an antibody molecule is an efficient procedure for stabilizing oligopeptides within a limited spectrum of tertiary structures. This is a new approach towards imparting ligand properties to antibody molecules and can be used to study the biological function and specificity of short peptide motifs, including those involved in cell adhesion.     

Cutting edge: expression of functional CD94/NKG2A inhibitory receptors on fetal NK1.1+Ly-49- cells: a possible mechanism of tolerance during NK cell development.

Fetal liver- and thymus-derived NK1.1+ cells do not express known Ly-49 receptors. Despite the absence of Ly-49 inhibitory receptors, fetal and neonatal NK1.1+Ly-49- cells can distinguish between class Ihigh and class Ilow target cells, suggesting the existence of other class I-specific inhibitory receptors. We demonstrate that fetal NK1. 1+Ly-49- cell lysates contain CD94 protein and that a significant proportion of fetal NK cells are bound by Qa1b tetramers. Fetal and adult NK cells efficiently lyse lymphoblasts from Kb-/-Db-/- mice. Qa1b-specific peptides Qdm and HLA-CW4 leader peptide specifically inhibited the lysis of these blasts by adult and fetal NK cells. Qdm peptide also inhibited the lysis of Qa1b-transfected human 721.221 cells by fetal NK cells. Taken together, these results suggest that the CD94/NKG2A receptor complex is the major known inhibitory receptor for class I (Qa1b) molecules on developing fetal NK cells.     

Sensitivity of simian virus 40-transformed C57BL/6 mouse embryo fibroblasts to lysis by murine natural killer cells

The susceptibility of mouse cells expressing full-length or truncated transforming protein (T antigen) of simian virus 40 (SV40) to lysis by murine natural killer (NK) cells was assessed. For these studies, C57BL/6 mouse embryo fibroblasts (B6/MEF) were transformed by transfection with SV40 DNA encoding the entire T antigen. The transformed cell lines were tested for susceptibility to lysis by nonimmune CBA splenocytes as a source of NK cells and to lysis by C57BL/6, SV40-specific cytolytic T cells (CTL). It was found that 13 of 15 clonally derived, SV40-transformed H-2b cell lines were susceptible to lysis by NK cells. However, there was some variation in their susceptibility to lysis by NK cells. There was no correlation between susceptibility to lysis by SV40-specific CTL and to lysis by NK cells. Cells transfected with a plasmid which encodes only the N-terminal half of the SV40 T antigen were consistently less susceptible to lysis by NK cells, suggesting that expression of only the N-terminus of the T antigen was insufficient for optimal susceptibility to lysis by NK cells. Primary mouse embryo fibroblasts transformed by human adenovirus type 5 E1 region DNA were also found to be susceptible to NK cell-mediated lysis. Lysis of SV40-transformed cells by nonimmune CBA splenocytes was mediated by NK cells because: lysis was augmented when the effector cells were treated with interferon before assay; and lysis was abrogated when the effector cells were obtained from mice that had been depleted of NK activity by treatment with antiserum against the asialo GM1 surface marker. These results indicate that primary mouse cells which are transformed by SV40 and which express the native T antigen are susceptible to lysis by mouse NK cells. Conversely, cells transformed by a plasmid encoding only the N-terminal half of the T antigen express reduced susceptibility to lysis by NK cells.