Similarities between LAK cells derived from human thymocytes and peripheral blood lymphocytes: expression of the NKH-1 and CD3 antigens

Human thymocytes are devoid of NK cells but develop lymphokine-activated killer (LAK) activity after culture with recombinant interleukin-2 (rIL-2). The most active precursor for this activity appears to be a CD3-negative cell. The purpose of these studies was to compare the phenotype and functional activities of thymocyte and peripheral blood lymphocyte (PBL) LAK cells. Following culture, rIL-2-activated thymocytes resemble PBL-generated LAk and PBL NK cells. For each of these populations, lytic activity is highest in NKH-1-positive cells. Two-color fluorescence of each population also indicates that NKH-1+ cells are highly granular, as measured by staining with the lysosomotropic vital dye quinacrine. PBL, PBL-derived LAK cells, and thymus-derived LAK cells have a portion of cells that express both CD3 and NKH-1. However, approximately 60-80% of NKH-1+ cells lack detectable CD3. This suggests that both CD3+ and CD3- cells may be capable of LAK activity. Thymic-derived LAK cells respond to interferon in a manner very similar to NK and PBL-derived LAK cells, but lack the NK-associated CD16 antigen. Thus, despite the absence of NK cells in the thymus, it is possible to generate thymocyte LAK activity which bears a strong resemblance to LAK activity derived from peripheral blood lymphocytes.     

Phenotypic characterization of lymphokine-activated killer cells from human lymph node lymphocytes

We previously reported that lymphokine-activated killer (LAK) activity can be generated in human lymph node lymphocytes (LNL) at the same level as that in peripheral blood lymphocytes (PBL), despite the absence of active natural killer (NK) cells. In the present study, we investigated the surface phenotype of LNL-LAK cells by fractionation of lymphocytes, using a panning method. LNL isolated from lung cancer patients were cultured in the presence of recombinant interleukin 2 for 8 days and separated into T cells and non-T cells according to the expression of CD3 antigen. LAK effectors were enriched in the CD3- non-T cells. However, the CD3+ cells also mediated a low but substantial level of LAK activity, which was attributed to a CD8+ T-cell subset. Further investigation of the CD3- cells revealed that most of the CD3- effector cells expressed neither B-cell (CD20) nor NK-cell (CD16) markers. Precursors of this CD3-CD20-CD16- (null) population appeared to be also CD3-, CD20-, and CD16-. From these results, we would stress the significant contribution of CD3-CD20-CD16- null cells to the LAK phenomenon, which has not been focused on in PBL.     

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.     

The relationship of CD16 (Leu-11) and Leu-19 (NKH-1) antigen expression on human peripheral blood NK cells and cytotoxic T lymphocytes

We examined the antigenic and functional characteristics of human peripheral blood lymphocytes that differentially express the CD16 (Leu-11) and Leu-19 (NKH-1) antigens. Leu-19 is a approximately 220,000 daltons protein expressed on approximately 15% of freshly isolated peripheral blood lymphocytes. Within the Leu-19+ subset, three distinct populations were identified: CD3-,CD16+,Leu-19+ cells; CD3+,CD16-,Leu-19+ cells; and CD3-,CD16-,Leu-19bright+ cells. Both the CD3+,CD16-,Leu-19+ and CD3-,CD16+,Leu-19+ populations mediated non-major histocompatibility complex (MHC)-restricted cytotoxicity against the NK-sensitive tumor cell K562 and were large granular lymphocytes. CD3-,CD16+,Leu-19+ NK cells were the most abundant (comprising approximately 10% of peripheral blood lymphocytes) and the most efficient cytotoxic effectors. The finding that CD3+,Leu 19+ lymphocytes mediated cytotoxicity against K562 unequivocally demonstrates that a unique subset of non-MHC-restricted cytotoxic CD3+ T lymphocytes are present in the peripheral blood of unprimed, normal individuals. However, CD3+,CD16-,Leu-19+ cells comprised less than 5% of peripheral blood lymphocytes, and the cytotoxic activity of this subset was significantly less than CD3-,CD16+,Leu-19+ NK cells. Most CD3+,Leu-19+ T cells co-expressed the CD2, CD8, and CD5 differentiation antigens. The antigenic and functional phenotype of peripheral blood CD3+,Leu-19+ cytotoxic T lymphocytes corresponds to the interleukin 2-dependent CD3+ cell lines that mediate non-MHC-restricted cytotoxicity against NK-sensitive tumor cell targets. A small population of Leu-19bright+ lymphocytes lacking both CD3 and CD16 was also observed. This population (comprising less than 2% of peripheral blood lymphocytes) contained both large agranular lymphocytes and large granular lymphocytes. CD3-,CD16-,Leu-19bright+ lymphocytes also mediate non-MHC-restricted cytotoxicity. The relationship of these CD3-CD16-,Leu-19bright+ lymphocytes to CD3+ T cells or CD16+ NK cells is unknown.     

Human lymphokine-activated killer (LAK) cells: identification of two types of effector cells

We analyzed the antigenic phenotype of lymphokine-activated killer (LAK) effector cells. Human blood lymphocytes were cultured for 3 days with 100 U/ml recombinant interleukin 2 (rIL 2), subpopulations isolated with monoclonal antibodies and a fluorescence-activated cell sorter (FACS) and assayed for cytotoxic activity against 51chromium labeled noncultured melanoma tumor cells. Initial experiments compared the LAK effector function of CD5+ T lymphocytes vs CD5- cells (predominantly CD16+ NK cells). The mean percent specific release at a 10:1 effector:target (E:T) ratio was 25% +/- 16 for CD5- cells, 10% +/- 6 for CD5+ cells, and 22% +/- 9 for unsorted cells. In contrast, when lymphocyte subpopulations were isolated before rIL 2 culture (LAK precursors), CD5- cells but not CD5+ cells developed LAK activity (28% +/- 12 vs 1% +/- 1, mean percent specific release, 10:1 E:T ratio), confirming our previous results showing that only CD16+ cells were LAK precursors. The discrepancy between LAK effector and precursor phenotypes suggested that LAK precursors acquired CD5 determinants during rIL 2 culture; however, double label immunofluorescence of rIL 2 cultured CD16+ cells showed that this was not the case. The data suggested that in the presence of other cell types, some T lymphocytes may develop LAK activity, but purified blood T lymphocytes do not develop LAK function when cultured with rIL 2 alone. We also analyzed LAK effector function in lymphocyte subpopulations defined by CD4 and CD8 antigens. The data showed that lymphocytes with a low density expression of CD8 and no expression of CD4 were enriched for LAK effector cells, whereas CD4+ and CD8- had less activity than unsorted cells. Lymphocytes with a high density expression of CD8 had activity similar to unsorted cells. We also assessed the contribution of Leu-7 (HNK-1) granular lymphocytes to LAK effector function. After culture with IL 2, lymphocytes were depleted of Leu-7+ cells by antibody and complement treatment and then were sorted into CD5+ and CD5- fractions. The cytotoxic activity of Leu-7-CD5+ cells was a mean 5% +/- 5 vs a mean 14% +/- 8 for the total CD5+ population (20:1 E:T ratio). The activity of Leu-7- CD5- was slightly less than the total CD5- fraction (21% +/- 9 vs 28% +/- 14, 10:1 E:T ratio). In conclusion, LAK effector function was highest in non-T cell (CD5- CD16+) populations and some activity was also present in T cell populations (CD5+ and predominantly Leu-7+).     

Generation of lymphokine-activated killer cell activity from non-NK precursor cells

It is possible to generate high levels of lymphokine-activated killer (LAK) activity in short-term culture from cells enriched for natural killer (NK) activity. To determine whether LAK activity can also be generated from non-NK cells, we have depleted peripheral blood lymphocytes (PBL) of NK cells prior to culture with IL-2. NK activity in PBL is correlated with the intensity of staining with the lysosomotropic vital dye quinacrine. Quinacrine dim PBL, which are devoid of lytic NK cells, are capable of developing LAK activity following culture with IL-2. We have also separated PBL using the NK-associated NKH-1 marker. Depleting NKH-1+ cells eliminates NK activity but the ability to develop LAK activity is retained. NKH-1-depleted cells generate less LAK activity than unseparated or NKH-1-positive cells and do not proliferate as well as unseparated cells to IL-2. When NK-depleted cells are subsequently examined for the expression of the NKH-1 antigen, this marker is absent from most cells at Day 3 of IL-1 culture, but is expressed on an increasing number of cells by Days 6-8. These results suggest that LAK derived from non-NK cells is functionally and phenotypically similar to LAK from PBL-containing NK cells, and may be the result of the activation of an NK precursor population.     

Interleukin 2-activated human killer cells are derived from phenotypically heterogeneous precursors

When cultured with native or recombinant human interleukin 2 (IL 2), human peripheral blood non-adherent mononuclear cells (NAMNC) acquire the ability to lyse both NK-sensitive and NK-resistant tumor target cells. The development of these IL 2-activated killer (IAK) cells, also known as LAK, is observed in the absence of exogenous antigen or mitogen. This study describes the ability of various subpopulations of human peripheral blood NAMNC with defined surface phenotype to generate the IAK activity. Human NAMNC were separated into various subpopulations on the basis of the ability to bind monoclonal antibodies, activated with IL 2, and were examined for the cytolytic effect on various tumor target cells. Although CD16+ (Leu-11+) NK cells from NAMNC could become IAK cells when cultured with IL 2, removal of these cells from NAMNC had no effect on the latter's ability to generate the IAK effect. When CD16- NAMNC were separated into CD2+ E rosette-forming T cells (ERFC) and CD2- non-T (non-ERFC) subpopulations, both subpopulations generated the IAK activity. The ability of monoclonal antibody-defined subpopulations of T and non-T cells to generate IAK cells was then examined. Both CD4+ and CD8+ subsets isolated by either positive or negative selection generated the IAK activity. Similarly, CD20+ (B1+) B cells and CD20- non-T (null) cells developed into IAK cells when cultured with IL 2. In contrast, Leu-7+ T cells failed to generate the IAK activity. CD4+ and CD8+ subsets were additionally separated into narrower subpopulations by using monoclonal antibodies anti-Leu-8 and 9.3 respectively, and were examined for their ability to generate IAK cells. Precursors of IAK cells were derived from each of the four: CD4+, Leu-8+ (inducer), CD4+, Leu-8- (helper/amplifier), CD8+, 9.3+ (cytolytic), and CD8+, 9.3- (suppressor) subpopulations of T cells. Thus, the IAK activity appears to be derived from phenotypically heterogeneous and otherwise functionally diverse human lymphoid cells and is not confined to any single subpopulation.     

In vivo effects of recombinant IL-2. I. Isolation of circulating Leu-19+ lymphokine-activated killer effector cells from cancer patients receiving recombinant IL-2

This study was designed to isolate and phenotypically characterize lymphokine-activated killer (LAK) cells generated in vivo during administration of high dose rIL-2 to cancer patients. The development of circulating LAK effector cells in these patients was demonstrated by the ability of fresh PBL to exhibit lytic activity against the NK-resistant Daudi cell line and fresh tumor cells without prior in vitro culture with rIL-2. Kinetic studies demonstrated that circulating LAK effector cells are detectable 4 to 6 wk after the initiation of rIL-2 therapy. Cells isolated by FACS revealed that circulating LAK cells are Leu-19+, Leu-17+ but CD5-. We have previously reported that circulating Leu-19+ cells are heterogeneous with regard to the expression of CD16 and CD8. Since sorting of cells expressing Leu-19 and either low quantities of CD8 or CD16 resulted in cytolytic activity in both the positive and negative fractions, these latter two markers do not identify subpopulations of Leu-19+ cells with or without LAK cytolytic activity. Although all LAK cells generated in vivo were Leu-19+, we generated LAK cells from the Leu-19- subpopulation after in vitro culture with rIL-2, suggesting that at least some of in vitro generated LAK cells are derived from Leu-19- precursor cells. These LAK cells did not, however, express the Leu-19 surface marker. Based on the functional data reported in this paper, we conclude that circulating LAK effector cells are a phenotypically heterogeneous population that express surface Ag in association with NK cells and not T lymphocytes.     

Long-term culture growth of CD4-CD8- lymphocytes exhibiting elevated non-MHC-restricted cytotoxic activity.

We have developed a culture system for "long-term" growth of human lymphokine-activated killer (LAK) cells exhibiting an elevated, wide-spectrum anti-tumor cytotoxicity. The system allows the exponential growth of monocyte- and B-lymphocyte-depleted CD4-CD8- lymphocytes in the presence of human AB serum and recombinant human interleukin-2 (IL-2) (2 x 10(2) U/ml) combined with interleukin (IL-1) beta (50 ng/ml). After 21 days in culture, these cells undergo massive amplification (i.e., the cell yield rises up to 30-120 times the starting values), and exhibit a marked anti-tumor cytotoxic activity against a panel of natural killer (NK)-resistant tumor cell lines. Interestingly, this activity correlates with the high level of perforin RNA. The membrane phenotypes of the final cell population, assessed by a panel of monoclonal antibodies (MoAbs) indicate a mixed population comprising two cell types in variable proportions (i) NKH-1+, T cell receptor (TCR) alpha/beta-, TCR gamma/delta-, CD3-, Leu 23+; (ii) NKH-(+), TCR alpha/beta-, TCR gamma/delta+, CD3+, Leu 23+. This culture system may provide a tool for cellular and molecular studies on the mechanisms of anti-tumor cytotoxicity, as well as the basis for new adoptive immunotherapy protocols in advanced cancers.     

Phenotypic and functional heterogeneity of thymic and splenic lymphokine activated killer cells relative to ornithine sensitivity

We have previously reported the selective inhibition of cytotoxic T lymphocytes (CTL) by 10 mM ornithine (ORN) relative to natural killer (NK) cell-derived lymphokine activated killer cells (LAK). To determine if this were due to differences in the progenitor cells or the type of stimulus, we used cortisone-resistant thymocytes (CRT) as a source of mature T cells for induction of LAK and CTL, and compared the results with spleen. Thymic and splenic CTL precursors (CTLp) from C57B1/6 (B6) mice were CD8+, ASGM1-, ORN sensitive. Splenic LAK precursors (LAKp) were CD8-, ASGM1+, ORN resistant when assayed against both YAC-1 and P815 tumor targets. In contrast, CRT-derived LAKp were CD8-, ASGM1+, ORN resistant against YAC-1, whereas LAKp against P815 were CD8+, ASGM1+, ORN sensitive. ORN sensitivity was also observed among CTL and LAK in DBA/2 mice and was associated with CD8+ phenotype. Therefore, our initial observation of differential ORN sensitivity in CTL vs LAK was a function of the progenitor cells; furthermore, CD8+ cytolytic cells are ORN sensitive whether activated by antigen (CTL) or IL-2 (T-LAK).     

Expression of Leu-19 (NKH-1) antigen on IL 2-dependent cytotoxic and non-cytotoxic T cell lines

The Leu-19 (NKH-1) antigen is expressed on human peripheral blood NK cells and a subset of peripheral blood cytotoxic T lymphocytes that kill "NK-sensitive" tumor cell targets without major histocompatibility complex restriction. In the present study, we demonstrate that the Leu-19 (NKH-1) antigen is also expressed on most interleukin 2 (IL 2) dependent T cell lines and clones that have been maintained in long term culture. The Leu-19 (NKH-1) antigen expressed on an antigen-specific, class I directed cytotoxic T lymphocyte cell line was an approximately 200,000 to 220,000 dalton protein, similar to Leu-19 (NKH-1) protein expressed on natural killer cells and KG1a, an immature stem cell leukemia cell line. Furthermore, Leu-19 (NKH-1) was expressed on both CD4+ and CD8+ IL 2 dependent T cell clones, and was present on both cytotoxic and non-cytotoxic T cell clones. Thus expression of Leu-19 (NKH-1) antigen on cultured cell lines does not directly correlate with cytotoxic function, antigenic specificity, or cell lineage.     

Generation of lymphokine-activated killer cell activity from human thymocytes

We have generated lymphokine-activated killer (LAK) cells from human thymocytes in order to assess the relationship between LAK cells and T cells. Fresh thymocytes lack natural cytotoxic activity, and cytotoxicity cannot be stimulated by short term (1 hr) incubation with interferon or recombinant interleukin 2 (rIL-2). In addition, thymocytes are phenotypically devoid of cells bearing the natural killer (NK)-associated markers cluster designation (CD) 16 and NKH-1. After culture for 5 to 8 days with rIL-2, thymocytes display high levels of cytotoxic activity against both NK-sensitive and NK-resistant targets. Thymocytes require slightly more IL-2 than do peripheral blood lymphocytes to generate LAK activity. We have examined the phenotype of the thymocyte LAK precursor and effector cells. Thymocyte LAK precursors are of low to medium density, CD1-negative, and predominantly CD3-negative. Although CD3-positive cells proliferate in response to rIL-2, they are low in cytolytic capabilities. The effector cells, like the LAK precursors, are low to medium density lymphocytes. The cytotoxic cells are predominantly CD3-negative, and cytotoxic activity cannot be blocked with the use of anti-CD3 monoclonal antibodies. The effector cells also lack most NK-associated markers (HNK-1, and the CD16 markers Leu-11b and B73.1) but possess the NK-associated marker NKH-1 (N901). The responsive cell appears to be at a very early stage of thymic development, and it does not appear to either require or express the CD3-T cell receptor complex.     

Gamma-irradiated peripheral blood mononuclear cells can express LAK activity

Peripheral blood mononuclear cells (PBMC) irradiated with high dose gamma-radiation (1000-5000 rad) are commonly used as feeder cells during the cloning of T lymphocytes, natural killer (NK) and lymphokine activated killer (LAK) cells. We report here that such gamma-irradiated PBMC can be stimulated with interleukin 2 (IL-2) to express the ability to lyse a variety of tumor cell targets. The non-major histocompatibility complex (MHC) restricted cytotoxicity demonstrated by irradiated PBMC is, however, lower than that expressed by their non-irradiated counterparts. The numbers of viable, gamma-irradiated LAK cells are significantly increased by the addition of the mitogen, phytohemagglutinin (PHA). Purification of the gamma-irradiated cells expressing cytotoxic activity by flow cytometry determined that the effector cells were predominantly CD3- cells, although some CD3+ cells also expressed moderate LAK activity. The ability of gamma-irradiated cells to proliferate in the presence of PHA alone, or with IL-2 + PHA, was maximal at day 4-5; but proliferation, as detected by 3H-thymidine uptake, was not detectable beyond 12-15 days of in vitro culture. Because many of the LAK, T cell and NK cell cloning procedures require the presence of feeder layers, growth factors (usually IL-2) and mitogens, the presence of residual feeder cells expressing cytotoxic activity may affect the specificity of such clones. Thus, efforts should be made to ensure that such gamma-radiation-resistant cells capable of expressing cytotoxic activity are completely eliminated before the cloned cells are used for further experiments.     

Comparative studies of CD3- and CD3+ CD56+ cells: examination of morphology, functions, T cell receptor rearrangement, and pore-forming protein expression.

Both CD3- and CD3+ CD56+ effector cells can mediate non-MHC-restricted lysis in the absence of activation. Previous studies have shown that both of these subsets can be augmented with IL-2. In the present study, we have examined further the phenotypic markers expressed on these cells as well as the functional capacities of these subsets, including LAK activity, cytokine expression, and pore-forming protein (PFP) production. In addition, these populations were analyzed for clonality by Southern blot analysis of the T cell receptor beta chain gene constant region. The CD3-, CD56+ and CD3+, CD56+ lymphocytes were quite similar in their phenotypic markers, although the CD3+, CD56+ lymphocytes lacked high levels of IL-2 receptor beta chain and did not express CD16. The CD3+, CD56+ lymphocytes mediated non-MHC-restricted lysis, but failed to express LAK activity or be induced by IL-2 to secrete IFN gamma, a characteristic of the CD3-, CD56+ lymphocytes. The T cell receptor beta chain gene pattern of the CD3+, CD56+ lymphocytes was characteristic of a polyclonal cell population. Of interest, both populations of cells appeared morphologically to be large granular lymphocytes that contain PFP in their cytoplasmic granules. Therefore these CD56+ subsets provide a new model to study several questions related to non-MHC-restricted target cell lysis, including the identification of novel receptors involved in target cell recognition and/or triggering as well as the biochemical pathways implicated in cellular lysis.     

Bacterial activation of human natural killer cells. Characteristics of the activation process and identification of the effector cell

We showed previously that contact of human peripheral blood lymphocytes with glutaraldehyde-fixed Salmonella bacteria augmented their cytotoxic capacity against NK-sensitive targets. We have now analyzed the characteristics of the activation and also identified the subsets of lymphocytes responding to bacterial contact. Blocking of protein synthesis with cyclohexamide totally abrogated bacterial induction of activated killing (AK), whereas inhibition of DNA synthesis with mitomycin C did not significantly affect the capacity of lymphocytes to respond to bacterial contact. Both the induction and the effector phase of AK were radioresistant. The AK cells exhibited efficient lytic activity, comparable to that induced by recombinant IL 2 (rIL 2), against NK-resistant targets (including both hematopoietic and solid tumor cell lines). All inducible cytotoxic activity was contained within the subset of lymphocytes expressing Leu-19 (NKH-1) antigen. Leu-19- lymphocytes exhibited no significant NK activity and could not be further stimulated by bacterial contact, rIL 2, or IFN-alpha. Within the Leu-19+ lymphocyte subset, two distinct cell types were present; CD3-, Leu-19+ NK cells and CD3+. Leu-19+ T cells. The CD3+, Leu-19+, T cells mediated low levels of non-MHC-restricted cytotoxicity against K562, but did not respond to bacterial contact, even though rIL 2 could augment their lytic activity slightly. However, the cytotoxic activity of CD3-, Leu-19+ NK cells was significantly augmented by bacterial contact. Within the CD3-, Leu-19+ NK cell population both CD16+ and CD16- cells responded to bacterial activation. The CD3-, CD16-, Leu-19+ cells constituted 1 to 4% of the Percoll-fractionated low buoyant density lymphocytes and accounted for the activation seen within the CD16- lymphocyte population. Thus bacterial stimulation of NK activity seems to be mediated for the most part via CD16+, Leu-19+ cells, and a minor overall contribution is mediated via CD3-, CD16-, Leu-19+ cells. No apparent involvement of T cells was seen in the lytic response of lymphocytes to bacterial contact.     

Autologous tumor cell killing activity of tumor-associated lymphocytes in patients with head and neck carcinomas

In order to select the most cytotoxic effector cells for adoptive immunotherapy, lymphokine activated killer (LAK) cells, tumor infiltrating lymphocytes (TILs) and autologous mixed lymphocyte tumor cell culture (MLTC) cells derived from peripheral blood mononuclear cells (PBMC) in the same subject with head and neck carcinomas were prepared. The autologous tumor cell killing activity and cell surface phenotypes of each of the three effector cells were studied. MLTC cells cultured with interleukin-2 (IL-2) showed the strongest cytotoxic activity among these three different effector cells. Although TILs had suppressed killing activity immediately after isolation, after successive cultivations with IL-2, a cytotoxic activity against autologous tumor cells stronger than that of LAK cells appeared. Both IL-2 stimulated MLTC cells and TILs showed an enrichment of CD8 positive and CDU negative cells in a CD3 positive subpopulation.Abbreviations CD cluster differentiation - IL-2 interleukin-2 - LA lymphokine activated - LAK lymphokine activated killer - MLTC mixed lymphocyte tumor cell culture - NK natural killer - PBMC peripheral blood mononuclear cells - TILs tumor infiltrating lymphocytes     

Lymphokine-activated killer (LAK) cells. VI. NK1.1+, CD3+ LAK effectors are derived from CD4-, CD8-, NK1.1- precursors.

Normal murine splenocytes cultured with IL2 for 6, but not 3, days contained an NK1.1+, CD3+ lytically active subset. These lymphocytes were not derived from NK1.1+ precursors since NK1.1+ cells, purified by flow cytometry, failed to express CD3, as determined by the 145-2C11 mAb, on their surface even after culture with IL2 for 6 days. Instead, the precursors of the NK1.1+, CD3+ effectors were contained in a B cell-depleted CD4-, CD8-, NK1.1- splenic subset. Freshly obtained CD4-, CD8-, NK1.1- splenocytes were mostly CD3+, CD5+, B220-, had no spontaneous lytic activity against YAC-1, and were unable to mediate anti-CD3 directed lysis against FcR-bearing target cells. Culture of the CD4-, CD8-, NK1.1- splenocytes with IL2, for 6 days, resulted in the development of NK1.1+, CD3+, B220+ effectors 40% of which were CD5dim and 20-25% of which expressed TCR-V beta 8 as determined by the F23.1 mAb. The acquisition of NK1.1, B220, and lytic activity by this triple-negative subset was readily inhibited by cyclosporine A (CSA). On the other hand, CSA had no effect on the acquisition of B220 or lytic activity by NK1.1+ precursors obtained by flow cytometry sorting. Moreover, all of the NK1.1+ cells generated by IL2 culture of splenocytes obtained from mice depleted of NK1.1+ lymphocytes (by in vivo injection of anti-NK1.1 mAb) coexpressed CD3 on their surface and were thus distinct from classical NK cells. These findings demonstrate that splenic NK cells do not express or acquire CD3; that the NK1.1+, CD3+ LAK effectors are derived from an NK1.1- precursor; and that CSA is exquisitely selective in its inhibitory effect on LAK generation.     

Studies on the relationship of human natural killer and lymphokine-activated killer cells with lysosomal staining and analysis of surface marker phenotypes

We have previously demonstrated that natural killer (NK) cells are lysosome-rich and stain more intensely with lysosomotropic agents such as neutral red and quinacrine (Qu) than do non-NK cells. In this study we combined the quantitation of Qu staining with surface marker staining to define subpopulations of NK cells. While all NK activity was contained within the Qu+ population, most but not all NK cells expressed the surface marker CD16. A subpopulation of NK cells was found to be Qu+CD16- composed of medium- to large-sized cells with a granular appearance on Giemsa staining. Culture with interleukin-2 (IL-2) induced enhanced cytotoxicity in peripheral blood lymphocytes (PBL) against NK-sensitive and NK-resistant tumor cells. Like NK cells, these lymphokine-activated killer (LAK) cells were predominantly Qu+CD16+. However, some LAK cells were Qu+CD16-. The Qu+CD16+ cells were typical large granular lymphocytes (LGL). The Qu+CD16- cells were also large lymphocytes, more than 50% of which were proliferating. However, the granulation in some Qu+CD16- cells, as detected by Giemsa staining, was more prominent and numerous than others in the same population. No LAK activity was ever detected in Qu- cells, which were uniformly small lymphocytes. Quantitation of Qu staining in effector cells was therefore demonstrated to have a good correlation with NK and LAK functions, and with surface markers can help to characterize both types of cells. Moreover, these results indicate that both NK and LAK populations include a small subset of CD16- cells in each.     

Human lymphokine-activated killer cells: further isolation and characterization of the precursor and effector cell

In a series of experiments we have demonstrated the progressive enrichment (5- to 40-fold) in lymphokine-activated killer (LAK) precursor activity by adherence depletion, sheep red cell rosetting, and depletion of CD3- and DR-positive lymphocytes. The LAK precursor cell thus appears to fall within the 'null' cell population. CD16 and CD11 are cell surface antigens expressed on the surface of the LAK precursor as demonstrated in sorting experiments. A 6- to 100-fold enrichment compared to unseparated peripheral blood was noted when sorted cells positive for CD16 and CD11 were tested. The LAK effector has been identified as being primarily CD3- and CD2+. Similar sorting equipment demonstrated a 7- to 500-fold difference in lytic activity for fresh tumor when comparing CD2+/CD3- and CD2+/CD3+ cells. The CD16+/CD11+ lymphocyte can proliferate in response to interleukin-2 (IL-2) alone in the absence of accessory cells and can be expanded in IL-2 alone with maintenance of lytic activity.     

Effects of IL-7 and IL-2 on highly enriched CD56+ natural killer cells. A comparative study.

IL-7 has been shown to induce low levels of lymphokine-activated killer cell (LAK) activity in bulk PBMC populations. We report here that immunomagnetically purified CD56+ cells from peripheral blood generated high LAK activity in response to IL-7. The LAK activity induced by IL-7 was comparable to, or slightly lower than, the LAK activity induced by IL-2. When analyzing cells from the same donor, no detectable LAK-generating effect of IL-7 was registered in the PBMC population, in contrast to a substantial effect in the CD56+ population. IL-2 induced 8- to 15-fold higher proliferative activity in CD56+ cells, relative to IL-7. At suboptimal concentrations of IL-2, IL-7 had a synergistic effect on the proliferation. IL-2-neutralizing antibodies did not abrogate the IL-7-induced proliferation or LAK generation. Both IL-7 and IL-2 induced comparable levels of 75-kDa TNFR expression, whereas IL-2R alpha expression was higher in IL-7-stimulated CD56+ cells. Low levels of TNF were produced in response to IL-7 at day 5, as opposed to a 50-fold higher TNF production in response to IL-2. No IL-2 or IL-6 production was detected. Our data indicate that IL-7 has profound and direct effects on CD56+ cells.