Antigenic, functional, and molecular genetic studies of human natural killer cells and cytotoxic T lymphocytes not restricted by the major histocompatibility complex

Cytotoxicity not restricted by the major histocompatibility complex (MHC) is mediated by two distinct types of lymphocyte: natural killer (NK) cells and non-MHC-restricted cytotoxic T lymphocytes (CTL). These two types of cytotoxic lymphocytes can be distinguished by antigenic phenotype, function, and molecular genetic studies. In human peripheral blood, NK cells are identified by expression of the Leu-19 and/or CD16 cell surface antigens, and lack of CD3/T cell antigen receptor (Ti) complex expression (i.e., CD3-,Leu-19+). Peripheral blood non-MHC-restricted CTL express both CD3 and Leu-19 (i.e., CD3+, Leu-19+, referred to as Leu-19+ T cells). Both Leu-19+ T cells and NK cells lyse "NK-sensitive" hematopoietic tumor cell targets, such as K562, without deliberate immunization of the host. However, most "NK activity" in peripheral blood is mediated by NK cells, because they are usually more abundant and more efficient cytotoxic effectors than Leu-19+ T cells. The cytolytic activity of both NK cells and Leu-19+ T cells against hematopoietic targets was enhanced by recombinant interleukin 2 (rIL 2). NK cells, but not peripheral blood Leu-19+ T cells, were also capable of lysing solid tumor cell targets after short-term culture in rIL 2. Southern blot analysis of NK cells revealed that both the T cell antigen receptor beta-chain genes and the T cell-associated gamma genes were not rearranged, but were in germ-line configuration. These findings indicate that NK cells are distinct in lineage from T lymphocytes and do not use the T cell antigen receptor genes for target recognition.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human neuroblastoma cell lines are susceptible to lysis by natural killer cells but not by cytotoxic T lymphocytes

The susceptibility of human neuroblastoma cells to direct cellular cytotoxicity has not been previously established. This is of particular interest because of their aggressive growth and low HLA expression. Neuroblastoma lines CHP 100 and CHP 126 were found to be excellent targets in 4-hr CML assays. Natural killer (NK) cells from fresh PBL and from an NK clone, 3.3, have high lytic activity against both cell lines. We also studied mixed lymphocyte culture-generated cytotoxic lines containing allo-specific cytotoxic T lymphocytes (CTL) directed against HLA antigens present on the neuroblastoma target cell lines. These lines did show excellent lytic activity, but cold target competition studies indicated that all of the lysis resulted from NK activity. This was verified by using inhibition studies with the use of monoclonal antibodies. OKT 3 and anti-HLA antibodies that block CTL function caused no reduction in kill. In contrast, anti-lymphocyte function antigen-1 (anti-LFA-1), which blocks both NK and CTL function, significantly inhibited lysis. These results serve as a functional confirmation of earlier findings of a very weak expression of HLA-A,B,C and beta 2-microglobulin on neuroblastoma cells.     

Inhibition of erythroid progenitor growth is mediated by cytotoxic lymphocytes and not by natural killer cells or IFN-gamma

Alloantigen primed T cells (PTC) were recovered from MLR at day 6 and 12, then added to cultures of erythroid progenitors, erythroid burst-forming units, BFU-E. The PBMC source of BFU-E was prepared either to retain or deplete APC by treatment with appropriate mAb and C. BFU-E grown in cocultures were counted at day 14 and replicate cultures assayed for IFN-gamma production on days 1 to 7. Analysis of MLR cells indicated that large, rapidly cycling cells recovered from MLR at day 6 have significant NK activity, whereas CTL activity is minimal, and production of IFN-gamma requires reexposure to APC. The smaller, noncycling cells recovered from MLR at day 12 have comparable NK activity, also require reexposure to APC for IFN-gamma production, but in addition have significant CTL activity. The addition of day 12 MLR cells to BFU-E cultures results in MHC restricted inhibition of BFU-E growth, suggesting that the CTL activity and not the NK activity contained within this population of cells is responsible for BFU-E inhibition. Studies using enriched population of BFU-E indicated that appropriate APC are needed to trigger both IFN-gamma production and BFU-E inhibition by the PTC. By using various APC-BFU-E combinations it was determined that after reexposure of PTC to appropriate APC, the inhibition of BFU-E was still target-specific indicating a direct effect between the PTC and BFU-E.     

OK-432 and IL-2-augmental cytotoxicity of human natural killer cells and cytotoxic T lymphocytes at the clonal level

Abstract The biology response modifiers OK-432 and interleukin-2 (IL-2) were found to enhance the lytic capacity of cloned CD3⁻ natural killer (NK) cells and CD3⁺ T cells. With respect to NK cells, only those clones with a high proliferative capacity and cultured without phytohaemagglutinin (PHA) responded with enhaced lytic capacity to OK-432. OK-432, but not IL-2, was found to augment the antibody-dependent cellular cytotoxicity of cloned NK cells. With T-cell clones, OK-432 augmented the cellular cytotoxicity of CD3⁺8⁺ but not that of CD3⁺4⁺ cytotoxic T lymphocytes, while IL-2 augmented the cytotoxicity of both types of clone. Taken together, these results indicate that OK-432-augmented lytic capacity is not restricted to NK cells and its pathway of action may be independent of IL-2.     

Studies on the mechanism of natural killer cell-mediated cytotoxicity. VII. functional comparison of human natural killer cytotoxic factors with recombinant lymphotoxin and tumor necrosis factor

The present study was undertaken to evaluate the possible contribution of other cytokines to the lytic activity of NKCF-containing supernatants. We compared some of the functional properties of human NKCF and purified recombinant human rLT and rTNF. It was found that the target cell specificity of rLT was quite different from NKCF in that rLT was neither species specific nor NK specific. Furthermore, antibodies against rLT did not affect the lytic activity of NKCF. These results demonstrate that LT does not significantly contribute to the lytic activity mediated by NKCF. The target specificity of rTNF was found to be related to that of NKCF with the exception of one NK-resistant cell line that was lysed by rTNF in a 20-hr 51Cr-release assay. However, rTNF was not toxic to any of the target cells tested as assessed by trypan blue exclusion in a 20-hr assay unless the targets were labeled with 51Cr. In contrast, NKCF did kill target cells as detected by trypan blue exclusion that were not labeled with 51Cr. Further analysis of this mechanistic difference in the lytic activity of rTNF and NKCF revealed that rTNF in combination with either cycloheximide or mitomycin C but not IFN-gamma could lyse unlabeled U937 target cells. In addition, pretreatment of U937 target cells with nonradioactive Na2CrO4 at concentrations equivalent to that used to 51Cr-labeled cells resulted in their susceptibility to lysis by rTNF as assessed by trypan blue exclusion. These findings suggest that lysis of several susceptible target cells in 20 hr by rTNF requires the presence of additional agents that may be sublethally toxic and/or inhibitory to macromolecular synthesis. Antibody inhibition studies revealed that anti-TNF mediated from partial to complete inhibition of lysis of U937 by unfractionated supernatants containing NKCF. However, fractionation of such supernatants on chromatofocusing columns yielded two distinct peaks of activity eluting in the pH range of 5 to 6 and 7 to 8. Anti-TNF could inhibit the acidic form of NKCF but not the neutral form. It is concluded that NKCF activity is mediated in part by TNF or an antigenically related molecule as well as some other distinct factor(s). The lack of consistent inhibition of NK CMC by anti-TNF suggests that TNF alone is not sufficient to mediate NK activity, or else it is inaccessible to the added antibody.     

A novel negative regulator molecule, Cho-1, is involved in the cytotoxicity by human natural killer cells but not in cytotoxic T lymphocytes.

We previously reported the cytotoxic negative regulatory molecule, Cho-1, that was expressed on the cell surface of rat fetal fibroblast cells in the cytotoxicity by natural killer (NK) cells. This molecule was IFN-gamma-inducible, but appeared to be different from MHC class I. It was expressed on NK-resistant cells but not on NK-sensitive murine target cells such as YAC-1. In this paper, first we determined whether Cho-1 could also act as the negative regulatory molecule in a human NK-resistant HEPM line. Our data strongly suggested that Cho-1 could act as such a negative regulatory molecule in human NK cytotoxicity. The immunoprecipitates made with HEPM cell lysate and anti-MHC class I monoclonal antibody (mAb) did not react against anti-Cho-1 mAb, indicating that Cho-I was different from MHC class I. Second, an assessment was made as to whether or not this molecule is involved in the cytotoxicity of CD8 (+) cytotoxic T lymphocytes (CTL) against human autologous tumor cells. The data indicated that although this cell surface molecule was expressed on certain tumor lines, it was not involved in the cytotoxic mechanism of CTL. Thus, Cho-1 appeared to be the novel regulatory molecule in the NK cytotoxic mechanism.     

Antibody-mediated targeting of human single-chain class I MHC with covalently linked peptides induces efficient killing of tumor cells by tumor or viral-specific cytotoxic T lymphocytes

Soluble forms of human MHC class I HLA-A2 were produced in which the peptide binding groove was uniformly occupied by a single tumor or viral-derived peptides attached via a covalent flexible peptide linker to the N terminus of a single-chain -2-microglobulin-HLA-A2 heavy chain fusion protein. A tetravalent version of this molecule with various peptides was found to be functional. It could stimulate T cells specifically as well as bind them with high avidity. The covalently linked single chain peptide-HLA-A2 construct was next fused at its C-terminal end to a scFv antibody fragment derived from the variable domains of an anti-IL-2R subunit-specific humanized antibody, anti-Tac. The scFv–MHC fusion was thus encoded by a single gene and produced in E. coli as a single polypeptide chain. Binding studies revealed its ability to decorate Ag-positive human tumor cells with covalent peptide single-chain HLA-A2 (scHLA-A2) molecules in a manner that was entirely dependent upon the specificity of the targeting Antibody fragment. Most importantly, the covalent scHLA-A2 molecule, when bound to the target tumor cells, could induce efficient and specific HLA-A2-restricted, peptide-specific CTL-mediated lysis. These results demonstrate the ability to generate soluble, stable, and functional single-chain HLA-A2 molecules with covalently linked peptides, which when fused to targeting antibodies, potentiate CTL killing. This new approach may open the way for the development of new immunotherapeutic strategies based on antibody targeting of natural cognate MHC ligands and CTL-based cytotoxic mechanisms.Kfir Oved and Avital Lev contributed equally to this work     

Studies on the mechanism of natural killer cytotoxicity. II. coculture of human PBL with NK-sensitive or resistant cell lines stimulates release of natural killer cytotoxic factors (NKCF) selectively cytotoxic to NK-sensitive target cells

This investigation has employed the "innocent bystander" type of experimental design to determine whether soluble cytotoxic factor(s) are released during interactions between human peripheral blood lymphocytes (PBL) and NK-sensitive target cells. PBL cocultured with NK-sensitive Molt-4 or K562 target cells in the lower well of a miniaturized Marbrook culture released natural killer cytotoxic factors (NKCF), which diffused across a 0.2-mu Nucleopore membrane and lysed Molt-4 or K562 target cells cultured in the upper chamber. Coculture of PBL with the NK-resistant Raji or WI-L2 cell lines also induced release of NKCF. These factors were selectively cytotoxic to NK-sensitive targets and lysed Molt-4 and, to a lesser extent, K562 cells. However, Raji, WI-L2, and RPMI 1788 cells were all resistant to lysis. In addition, low density fractions from Percoll density gradients that were enriched for NK effector cells also released increased levels of NKCF during coculture with Molt-4 cells. Lysis of Molt-4 and K562 targets was observed after exposure to NKCF for 48 hr and 60 to 70 hr, respectively. Cellfree supernatants containing NKCF were obtained after a short time of incubation (i.e., within 5 hr of coculture of PBL with NK target cells). The factors were nondialyzable, stable at 56 degrees C for 3 hr, and showed partial loss of activity on storage at 4 degrees C or -20 degrees C for 7 days. These data suggest that NKCF may be involved in the lytic mechanism of human NK cell-mediated cytotoxicity.     

IL-4 inhibits IL-2-mediated induction of human lymphokine-activated killer cells, but not the generation of antigen-specific cytotoxic T lymphocytes in mixed leukocyte cultures

Human rIL-4 was studied for its capacity to induce lymphokine-activated killer (LAK) cell activity. In contrast to IL-2, IL-4 was not able to induce LAK cell activity in cell cultures derived from peripheral blood. IL-4 added simultaneously with IL-2 to such cultures suppressed IL-2-induced LAK cell activity measured against Daudi and the melanoma cell line MEWO in a dose-dependent way. IL-4 also inhibited the induction of LAK cell activity in CD2+, CD3-, CD4-, CD8- cells, suggesting that IL-4 acts directly on LAK precursor cells. IL-4 added 24 h after the addition of IL-2 failed to inhibit the generation of LAK cell activity. Cytotoxic activity of various types of NK cell clones was not affected after incubation in IL-4 for 3 days, indicating that IL-4 does not affect the activity of already committed killer cells. No significant differences were observed in the percentages of Tac+, NKH-1+ and CD16+ cells after culturing PBL in IL-2, IL-4 or combinations of IL-2 and IL-4 for 3 days. IL-4 also inhibited the activation of non-specific cytotoxic activity in MLC, as measured against K-562 and MEWO cells. In contrast, the Ag-specific CTL activity against the stimulator cells was augmented by IL-4. Collectively, these data indicate that IL-4 prevents the activation of LAK cell precursors by IL-2, but does not inhibit the generation of Ag-specific CTL.     

Studies on the mechanism of natural killer cell-mediated cytotoxicity. V. Lack of NK specificity at the level of induction of natural killer cytotoxic factors in cultures of human, murine, or rat effector cells stimulated with mycoplasma-free cell lines

We have proposed that lysis of target cells by NK cells is mediated by NK cytotoxic factors (NKCF). According to our model, for a target cell to be NK-sensitive, it must be recognized by the NK cell, it must stimulate the release of NKCF, and it must be sensitive to lysis by these factors. This report examines whether the ability to stimulate release of NKCF is a characteristic restricted to NK-sensitive tumor cells or whether it is also a property of NK-resistant target cells. Many different types of cell lines were tested for their ability to stimulate release of NKCF in the human, rat, and murine systems. It was found that mycoplasma-free NK-sensitive cell lines, resistant cell lines, and Con A could stimulate the release of NKCF. Many different types of cell lines grown in suspension or in monolayers were found to be effective stimulators, including T or B lymphoid, myeloid, and those of histiocytic origin. Cells cultured in the absence of serum stimulated NKCF release, thus ruling out the possible involvement of serum components in stimulation. NKCF was also produced by xenogeneic combinations of effector and stimulator cells, demonstrating lack of species specificity in NKCF production. Factors stimulated by NK-resistant cell lines or by Con A exhibited the same NK target specificity as supernatants stimulated by NK-sensitive tumor cells. The finding that many different NK-resistant cell lines can stimulate the release of NKCF indicates that there is no apparent NK specificity at the level of induction of NKCF release from human, rat, or murine effector cells. Therefore, the NK specificity of a target cell is determined ultimately by its sensitivity to lysis by NKCF.