Interleukin-1 augments the interleukin-2-dependent generation of natural killer cells from bone marrow precursors

We have studied the possible role of interleukin-1 (IL-1) on the interleukin-2 (IL-2) dependent development of mouse natural killer (NK) cells from primitive bone marrow (BM) precursors. Results indicate that both IL-1 alpha and IL-1 beta (1-10 U/ml) are able to stimulate the generation of NK cells from 5-fluorouracil (5-FU) resistant BM progenitors. These precursor cells are asialoGM1-, Thy-1+, Lyt-1- and Lyt-2-. Effector cells generated by culturing with IL-2 (40 U/ml) and IL-1 (5 U/ml) are Thy-1+, asialoGM1+, Lyt-5+, Lyt-1-, Lyt-2- and lyse only NK-susceptible targets. Generation of NK cells is blocked by addition of anti-IL-2/r. These data indicate that IL-1 may play a role in the generation of mature NK cells from undifferentiated BM precursors.     

In vitro generation of natural killer cells from SJL/J bone marrow precursors

The development of natural killer (NK) cells from undifferentiated bone marrow (BM) precursors of low-NK-reactive SJL/J mice was studied. Results indicate that BM cells of untreated mice are not able to generate NK effector cells in cultures supplemented with recombinant interleukin-2 (IL-2). On the other hand in the presence of IL-2, NK cells are generated in cultures of BM from mice pretreated with 5-fluorouracil (5-FU, 150 mg/kg iv 4 days before harvesting), a treatment which has been shown to eliminate more differentiated but spare less differentiated BM precursors. The 5-FU resistant BM progenitor is asialoGM1-, Thy.1+, Lyt.1- and Lyt.2-. The cells generated by culturing with IL-2 are asialoGM1+, Thy.1+, Lyt.5+, Lyt.1-, Lyt.2- and lyse only NK-susceptible targets. Generation of NK cells is blocked by addition of anti-IL-2 receptor (IL-2/r) antibodies. These studies demonstrate that it is possible to generate NK effectors from SJL/J BM cells by in vitro culturing with IL-2.     

Role of interleukin 2 (IL 2) and hemopoietin-1 (H-1) in the generation of mouse natural killer (NK) cells from primitive bone marrow precursors

The development of natural killer (NK) cells from bone marrow (BM) precursors was studied. Recombinant interleukin 2 (IL 2) was able to induce the in vitro development of NK cells when added to cultures of mouse BM cells. Treatment of donor mice with 5-fluorouracil (150 mg/kg i.v.), which eliminates more differentiated cells but spares less differentiated cells, appears to augment NK cell development. The "NK stem cell" was found to be asialo GM1-, Thy-1+, Lyt-2-, and Lyt-1-. The cells generated in vitro had a typical phenotype of NK cells, being asialo GM1+, Lyt-5+, Thy-1+, Lyt-2-, and Lyt-1-. These effector cells also had specificity characteristics of NK cells lysing the NK-susceptible YAC-1 and K562 targets, but not the NK-resistant EL/4 or allogeneic and syngeneic blasts. Hemopoietin-1 (H-1), a factor which acts on very primitive multipotent BM cells, was able to cooperate with IL 2, increasing the development of NK cells. In contrast, other factors such as interleukin 3 or colony-stimulating factor did not cause induction of NK activity when added to cultures of BM cells, indicating that this effect, i.e., induction of NK cell development, is peculiar to IL 2. These results indicate that IL 2 can act as a differentiation as well as growth factor for NK cells, and that H-1 can promote the development of functional activity in a lymphocyte subpopulation as well as affect the differentiation of myelomonocytic and other cell lineages. This experimental system appears quite useful for characterization of BM precursors for NK cells, and should help to better understand the relationship of the NK cell lineage to the T cell or other lineages.     

The NK-1.1(-) mouse: a model to study differentiation of murine NK cells

The NK-1.1(-) mouse was constructed by weekly injections of monoclonal anti-NK-1.1 antibody from birth through adulthood. Spleen cells from these mice have decreased NK-1.1+ cells and null (Thy-1- and B220-) cells. Their splenic NK activity to YAC targets was low and was not enhanced by IFN-alpha or IFN-beta. Bone marrow (BM) of these NK-1.1(-) mice have normal precursors to NK cells: 1) NK activity could be generated from NK-1.1(-) BM cells cultured in rIL 2 for 5 to 6 days. These cultured BM cells expressed Qa-5, Thy-1, AsGm-1, and NK-1.1 antigens. The precursor cells of these BM cytotoxic cells are NK-1.1-; 2) transfer of BM cells from the NK-1.1(-) mice reconstituted the NK activity of irradiated, NK-depleted recipients. Lymphokine-activated killer cells could also be generated from spleens of these NK-1.1(-) mice. Therefore, the NK-1.1(-) mice were specifically depleted of mature cytotoxic NK cells, but not the NK-1.1- precursors of NK cells. This mouse model is valuable to study ontogeny and physiologic relevance of NK cells.     

Murine granulated metrial gland cells at uterine implantation sites are natural killer lineage cells

Granulated metrial gland (GMG) cells, a population of morphologically distinct, bone marrow-derived cells in murine decidua that react with mAb 4H12, are shown in this report to express NK-specific Ag and to become cytolytic to the NK cell target YAC-1 when cultured in the lymphokine IL-2. When 1-mm3 explants of 8-day decidual tissue were cultured with IL-2, large numbers of 4H12+ GMG cells migrated out of the tissue. Migration was dependent on the amount of IL-2 used. This explant technique was used to isolate a pure population of GMG cells. The migratory activated GMG cells were phenotypically 4H12+, NK1.1+, LGL-1+/-, CD3-, and MAC-1-. Furthermore, the IL-2-activated GMG cells killed YAC-1 but not P815 cells in a 4-h 51Cr-release cytotoxicity assay. 4H12+ GMG cells from collagenase-digested decidual tissue also were analyzed for the presence of NK lineage Ag by flow cytometry and shown to coexpress the NK-associated Ag NK1.1 and ASGM1 but not the T cell Ag CD3 or macrophage Ag MAC-1 or F4/80. GMG cells isolated by collagenase digestion did not express LGL-1, an Ag associated with lytic NK cells. Our results demonstrate that GMG cells express Ag and functions characteristic of NK cells, and thus GMG cells can be assigned to the NK lineage. The possible relevance of NK cells at implantation sites is discussed.     

IL-15-high-responder developing NK cells bearing Ly49 receptors in IL-15-/- mice

In mice lacking IL-15, NK cell development is arrested at immature stages, providing an opportunity to investigate the earliest developing NK cells that would respond to IL-15. We show in this study that immature NK cells were present in the spleen as well as bone marrow (BM) and contained IL-15-high-responder cells. Thus, mature NK cells were generated more efficiently from IL-15(-/-) than from control donor cells in radiation BM chimeras, and the rate of IL-15-induced cell division in vitro was higher in NK cells in the spleen and BM from IL-15(-/-) mice than in those from wild-type mice. Phenotypically, NK cells developed in IL-15(-/-) mice up to the minor but discrete CD11b(-)CD27(+)DX5(hi)CD51(dull)CD127(dull)CD122(hi) stage, which contained the majority of Ly49G2(+) and D(+) NK cells both in the spleen and BM. Even among wild-type splenic NK cells, IL-15-induced proliferation was most prominent in CD11b(-)DX5(hi) cells. Notably, IL-15-mediated preferential expansion (but not conversion from Ly49(-) cells) of Ly49(+) NK cells was observed in vitro only for NK cells in the spleen. These observations indicated the uneven distribution of NK cells of different developing stages with variable IL-15 responsiveness in these lymphoid organs. Immature NK cells in the spleen may contribute, as auxiliaries to those in BM, to the mature NK cell compartment through IL-15-driven extramarrow expansion under steady-state or inflammatory conditions.     

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.     

Generation of cytotoxic cells from murine bone marrow by human recombinant IL 2

Murine bone marrow (BM) cells were cultured in recombinant IL 2 (rIL 2) and interferon-alpha, -beta, and -gamma, and cytotoxic activity against YAC cells was determined in a 4-hr 51Cr-release assay. rIL 2 at 20 U/ml was the only lymphokine that consistently induced significant cytotoxic activity within 3 days of culture, peaking around 5 to 7 days. The cytotoxic cells generated are heterogeneous, consisting of at least two populations of cells: a) NK-1+, Qa-5+, AsGm-1+ Thy-1+/-, Lyt-2- cells, similar to natural killer (NK) cells, and b) NK-1-, Qa-5+, AsGm-1+ Thy-1+, Lyt-2+ cells, similar to cytotoxic T lymphocytes. The precursor/accessory cells of these BM cytolytic cells maintained in 20 U/ml of rIL 2 were Qa-2+, Qa-5+, Thy-1+/-, AsGM-1+/-, and NK-1+/- but Lyt-2-. They also lysed NK-resistant targets, P815 and BW5147, and the antigenic phenotypes of these cells were similar to those that lysed YAC cells. These studies indicate that IL 2 alone is adequate to generate cytotoxic activity from BM and that these cytotoxic cells were similar to splenic NK cells.     

Effect of interleukin-4 on interleukin-2-dependent generation of natural killer cells

We have previously shown that interleukin-2 (IL-2) is able to induce the generation of natural killer (NK) activity in bone marrow (BM) cells from mice pretreated with 5-fluorouracil. IL-2 alone could dose-dependently induce NK activity in marrow cells and interleukin-4 (IL-4) has dual effect on the NK activity in that, depending on the concentration of IL-2, IL-4 inhibits or stimulates development of NK cells. The inhibitory effect was in part antagonized by interleukin-1 alpha. These effects were not obtained when NK-reactive spleen cells were cultured with the same concentrations of IL-2 or IL-2 plus IL-4 with or without irradiated BM cells as feeders. The effects of IL-4 were also obtained by preincubation for 6-24 hr before culturing with IL-2 alone and correlated with the expression of interleukin-2 receptor (IL-2/r), suggesting that IL-4 might play a regulatory role in the IL-2-dependent generation of NK cells in BM.     

Natural cytotoxicity against mouse hepatitis virus-infected cells. II. A cytotoxic effector cell with a B lymphocyte phenotype

The effector cell in mouse spleen which mediates natural cytotoxicity against mouse hepatitis virus (MHV)-infected target cells was characterized. The target cells were MHV-infected BALB/c 3T3, and the assay time was 3 hr. The effector cell, designated virus killer (VK) cell for the purpose of discussion, had the following phenotype: lymphocyte morphology, plastic-nonadherent, nylon wool-adherent, nonphagocytic, cyclophosphamide-sensitive; by antibody plus complement (C) depletion studies, it was asialo GM1-, NK 1.2 alloantigen-negative, Thy-1.2-, Lyt-5-, and macrophage antigen-negative; by rosetting techniques, it was Fc receptor-positive and surface Fab+; by flow cytometry (FACS) analysis, it was Lyt-2-, MAC-1-, Ia+, IgG (gamma)+, IgM (mu)+, IgD (delta)+, and B cell lineage antibody B-220+. NK cells, measured for cytotoxicity on YAC-1 cells, were similarly tested and were found to differ from the VK cell in the following properties: nylon wool-nonadherent, asialo GM1+, NK alloantigen-positive, Lyt-5+, surface Fab-, MAC-1+, Ia-, IgG-, IgM-, IgD-, and B-220-. The VK effector cell had a phenotype highly distinguishable from NK cells, effectors most commonly associated with antiviral natural cytotoxicity. The VK cell had a phenotype identical to that of a B lymphocyte and was identified as such. Although the effector cells displayed cell surface antibody, the antibody did not appear to be involved in lysis, because lysis could not be blocked by F(ab)'2 directed against Fab, mu, or delta. Cytotoxicity was more likely associated with recognition of the B lymphocyte surface by the MHV glycoprotein E2, as shown in the accompanying companion paper. This is the first demonstration that natural cytotoxicity can be mediated by B lymphocytes.     

Propagation of cytotoxic effectors from chronic myeloid leukemia patients and cloning of cytotoxic T cells

Summary Cytotoxic cells (CTCs) generated from peripheral blood lymphocytes of 5 chronic myeloid leukemia (CML) patients in remission on stimulation with autologous leukemic cells and allogeneic lymphocytes (3-cell assay), were propagated in vitro in interleukin-2 (IL-2)-containing medium and periodic stimulation with autologous leukemic cells, for a period of 4 to 6 months. During this period, the cells were assessed for phenotype and for cytotoxic responses in a 4-h ⁵¹Cr release microcytotoxicity assay. The CTCs continued to show specific lysis of autologous leukemic cells and bone marrow (BM) cells. However, the nonspecific lysis of natural killer (NK) targets and the proportion of cells showing NK phenotype (HNK-1 antigen) increased progressively on cultivation in IL-2-containing medium. Therefore cells showing CD8 phenotype and specific cytotoxic function were segregated by cloning CTCs under the condition of limiting dilution in the presence of allogeneic feeder cells and IL-2-containing medium. Three cytotoxic T cell (CTL) clones expressing CD3+, CD8+, and HLA DR+ phenotypes were obtained from CTCs of 2 CML patients. These clonoid populations, maintained in IL-2-containing medium and periodic antigenic stimulation with autologous leukemic cells, showed specific lysis of autologous leukemic cells and BM cells even at lower (10:1) effector:target ratios. They did not kill K562 (erythroblastoid leukemic NK target cell line) cells and autologous phytohemagglutinin-induced blasts. These clones apparently functioned in an MHC-restricted manner as they did not lyse allogeneic CML cells which would also express a similar set of maturation antigens if sensitization was, as it appeared, against these antigens. Finally, interaction of autologous BM cells with CTL clones reduced the colony forming potential of BM cells only to the extent of 18%–30%. The results therefore indicate that such CTL clones can possibly be used in adoptive immunotherapy as they showed minimal BM toxicity.     

Interleukin 2 induces interferon alpha/beta production in mouse bone marrow cells

We have previously reported that mouse bone marrow (BM) cells stimulated with alloantigen produce cytotoxic effector T-cell activity and produce interferon (IFN-)alpha/beta. In this report we show evidence suggesting that interleukin 2 (IL-2) may play a role in this IFN-alpha/beta production by alloantigen-stimulated BM cells. Alloantigen-induced IFN production by bone marrow cells was completely inhibited when cultures were supplemented with antisera to IL-2. Cell-free supernatants obtained at 2 days from cultures containing C57BL/6 BM cells and irradiated DBA/2J spleen cells were also shown to contain low levels of IL-2 activity and induced significant IFN production in fresh BM cells. Different IL-2 preparations were tested for their ability to induce IFN-alpha/beta production in mouse BM cells. Mouse BM cells cultured with recombinant human IL-2 or highly purified mouse IL-2 produced high levels of IFN-alpha/beta activity after 2-3 days of culture with significant IFN activity being detected as early as 24 hr of culture. IL-2-induced IFN-alpha/beta production was partially resistant to irradiation. In contrast, irradiated (2000 rad) bone marrow cells failed to produce any IFN when cultured with alloantigen in the absence of IL-2. T-cell-depleted BM cells or BM cells obtained from C57BL/10 nude mice produced high levels of IFN-alpha/beta following stimulation with IL-2. In addition, bone marrow cells depleted of Ia+, Qa 5+, or Asialo GM+1 cells produced IFN in response to IL-2. Thus, neither T cells nor NK cells are required for IL-2-induced IFN-alpha/beta production by BM cells. The action of IL-2 on bone marrow cells to induce IFN production was mediated by the classical IL-2 receptor, since monoclonal antibodies to the IL-2 receptor present on T cells blocked this response and since bone marrow cells depleted of IL-2 receptor-bearing cells failed to produce IFN when cultured with IL-2. These results suggest that non-T cells resident in the BM have receptors for IL-2 and can produce IFN-alpha/beta upon stimulation by IL-2. Since IFN has been shown to affect different aspects of hematopoiesis, the production of IFN by BM cells stimulated by IL-2 may be important in the control of hematopoiesis. In addition, IL-2-induced IFN production may play a role in graft-versus-host disease.     

Differentiation of NK1.1+, Ly49+ NK cells from flt3+ multipotent marrow progenitor cells.

To delineate factors involved in NK cell development, we established an in vitro system in which lineage marker (Lin)-, c-kit+, Sca2+ bone marrow cells differentiate into lytic NK1.1+ but Ly49- cells upon culture in IL-7, stem cell factor (SCF), and flt3 ligand (flt3L), followed by IL-15 alone. A comparison of the ability of IL-7, SCF, and flt3L to generate IL-15-responsive precursors suggested that NK progenitors express the receptor for flt3L. In support of this, when Lin-, c-kit+, flt3+ or Lin-, c-kit+, flt3- progenitors were utilized, 3-fold more NK cells arose from the flt3+ than from the flt3- progenitors. Furthermore, NK cells that arose from flt3- progenitors showed an immature NK1.1dim, CD2-, c-kit+ phenotype as compared with the more mature NK1.1bright, CD2+/-, c-kit- phenotype displayed by NK cells derived from flt3+ progenitors. Both progenitors, however, gave rise to NK cells that were Ly49 negative. To test the hypothesis that additional marrow-derived signals are necessary for Ly49 expression on developing NK cells, flt3+ progenitors were grown in IL-7, SCF, and flt3L followed by culture with IL-15 and a marrow-derived stromal cell line. Expression of Ly49 molecules, including those of which the MHC class I ligands were expressed on the stromal or progenitor cells, as well as others of which the known ligands were absent, was induced within 6-13 days. Thus, we have established an in vitro system in which Ly49 expression on developing NK cells can be analyzed and possibly experimentally manipulated.     

Lymphokine-activated killer (LAK) cells. II. Delineation of distinct murine LAK-precursor subpopulations

Lymphokine-activated killer (LAK) cells can lyse a number of tumor target cells regardless of whether the tumors are natural killer (NK) sensitive or resistant. LAK can also lyse autologous lymphoblasts that have been modified with 2,4,6-trinitrobenzene sulfonic acid (TNBS). In this study, we examined the surface markers of murine LAK precursors. It was found that depletion of Thy 1- or Lyt 2-bearing precursor cells abolished the ability of spleen cells to generate LAK against TNBS-self, but had no effect on the generation of LAK against tumor cells. Depletion of asialo-GM1 (AGM1)-bearing precursors abolished the generation of LAK against all target cells tested. Normal spleen cells were fractionated on a Percoll density gradient and two fractions were examined: fraction (Fxn) 3, which is enriched for NK activity but depleted of the ability to generate cytotoxic T lymphocytes (CTL), and Fxn 5, which had no NK activity but was enriched for the ability to generate CTL. Both fractions were capable of generating LAK, although Fxn 5 required a relatively larger amount of interleukin 2 (IL 2). Upon examination of the surface markers of LAK precursors in these fractions it was found that the precursors in Fxn 3 giving rise to LAK against tumors were Thy-1-, Lyt-2-, AGM1+, whereas the precursors in Fxn 5 were Thy-1+, Lyt-2+, AGM1+. The precursors generating LAK against TNBS-self were Thy-1+, Lyt-2+, AGM1+ in both fractions. The time kinetics of LAK generation in both fractions were different, with Fxn 3 showing much earlier kinetics. These data delineate at least two different LAK precursors defined by their buoyant density, by their surface markers, and by their susceptible target cells. These data also may resolve the confusion in the literature regarding the phenotype of LAK precursors.     

Differential sensitivity of cytotoxic T lymphocytes and lymphokine-activated killer cells to inhibition by L-ornithine

The selective inhibition of murine cytotoxic T lymphocyte (CTL) differentiation in C57B1/6 (B6) anti-DBA/2 mixed leukocyte cultures (MLC) by the amino acid L-ornithine (Orn) could not be reversed by addition of up to 1000 U/ml IL-2. Analysis of the effects of Orn on induction of lymphokine-activated killer (LAK cells), using dosages of IL-2 from 10-1000 U/ml and measuring cytolytic activity against two tumor targets (P815 and YAC-1) over the course of 5 days, indicated that LAK cells were not suppressed by Orn. LAK precursors and effector cells were CD8- and ASGM1+, indicating that they were derived from natural killer (NK) cells. We also found that the growth and maintenance of cloned CTL lines were not sensitive to inhibition by Orn; nor was their acquisition of nonspecific cytolytic activity in the presence of high lymphokine concentrations. Thus, induction of naive CTL shows differential susceptibility to Orn inhibition relative to LAK and LAK-like activities by NK and cloned CTL lines in response to IL-2.     

Characterization of interleukin 2-expanded human peripheral blood lymphocytes: not only NKH-1+-NK cells but also NKH-1+ and NKH-1- T cells are LAK effectors

In vitro culture of human peripheral blood mononuclear cells (PBMC) with interleukin 2 (IL-2) results in the expansion of lymphocytes including lymphokine-activated killer (LAK) cells. Using flow cytometry, studies were undertaken to determine the phenotype and LAK activity of each subset of lymphocytes expanded in vitro as a result of incubation for 2 weeks with 2500 U/ml of recombinant IL-2. Such expanded PBMC, when examined by two-color staining with various combinations of anti-CD3, 4, 8, 16, and NKH-1 monoclonal antibodies, consisted of the following six subgroups of cells: (1) CD3+4+8-, (2) CD3+4-8+, (3) CD3+4-8-, (4) CD3-16+NKH-1+, (5) CD3-16-NKH-1+, and (6) CD3-16-NKH-1-. Of the six subgroups, all five subgroups that could be tested, i.e., CD3+ T cells (CD3+4+8-, CD3+4-8+, CD3+4-8-), CD16+ natural killer (NK) cells (CD3-16+NKH-1+), and CD3-16-NKH-1- non-T non-NK cells, possessed LAK activity. Both NKH-1- as well as NKH-1+ T and non-T cells possessed LAK activity.     

Differential roles for IL-15R alpha-chain in NK cell development and Ly-49 induction

IL-15Ralpha-deficient (IL-15Ralpha(-/-)) mice lack NK cells. However, when bone marrow (BM) progenitors from IL-15Ralpha(-/-) mice were cultured with IL-7, stem cell factor and flt3 ligand, followed by IL-15, they were able to differentiate into functional NK cells, indicating that IL-15Ralpha is not critical for NK cell development. Whereas NK cells generated in vitro from IL-15Ralpha(-/-) BM progenitors expressed CD94/NKG2, they failed to express Ly-49 receptors. In keeping with this, when IL-15Ralpha(-/-) BM cells were transferred into wild type recipients, they gave rise to NK cells in vivo, but with greatly reduced expression of Ly-49 receptors. Furthermore, the small numbers of NK cells found in IL-15(-/-) as well as IL-15Ralpha(-/-) but not flt3 ligand(-/-) mice expressed much lower levels of Ly-49 receptors than those from wild type mice. These results indicate a novel role for IL-15Ralpha-chain in Ly-49 induction on developing NK cells.     

Physiology of natural killer cells. In vivo regulation of progenitors by interleukin 3

Adoptive transfer of bone marrow cells to syngeneic lethally irradiated C57BL/6 mice was used to study the maturation of natural killer (NK) cells from their progenitors. The NK progenitor cell was found to be asialomonoganglioside-negative, (aGM1-) Thy-1-, NK-1-, Ly-1-, Ly-2-, and L3T4-. The NK cells emerging from the bone marrow grafts were aGM1+, NK-1+, Thy-1+/-, Ly-1-, Ly-2-, and L3T4- and to have a target specter similar to that of NK cells isolated from the spleen of normal mice. The regulatory role of interleukin 2 (IL-2) and interleukin 3 (IL-3) for the maturation of NK cells was examined by exposure of the bone marrow cells to the lymphokines in vitro before bone marrow grafting or by treatment of bone marrow-grafted mice with lymphokines through s.c. implanted miniosmotic pumps. IL-3 antagonized the IL-2-induced maturation of NK cells in vitro and strongly inhibited the generation of NK cells after adoptive transfer of bone marrow cells in vivo. The suppressive effect of IL-3 was evident throughout the treatment period (8 or 16 days) but was apparently reversible because NK activity returned to control levels within 8 days after cessation of treatment. The inhibition of cytotoxic activity was accompanied by a reduced appearance of cells with the NK phenotypic markers aGM1 or NK-1, indicating that not only the cytotoxic activity of NK cells but also their actual formation was inhibited. Concomitantly, a moderate increase in cells expressing the T cell marker L3T4 and an increased proliferative response to the T cell mitogen concanavalin A was observed. A direct estimate of the effect of IL-3 on the frequency of NK cell progenitors was obtained by limiting dilution analysis of bone marrow cells at day 8 after bone marrow transplantation. The estimated minimal frequency of NK cell progenitors was reduced from 1/11,800 in control to 1/41,900 in IL-3-exposed mice. IL-3 may take part in the homeostasis of NK cells by the down-regulation of their progenitors.     

Characterization of cytotoxic cells generated from bone marrow culture

Bone marrow (BM) harbors precursors (Pre-NK) to NK cells. Recently, we devised an in vitro culture system that induces differentiation of the presumptive BM Pre-NK cells into cytotoxic cells to YAC in the presence of rat concanavalin A (Con A) conditioned medium. We have now analyzed the antigenic phenotype of the effector cells, precursor cells, and the target specificity of these cytotoxic cells. The cytotoxic cells had antigenic profiles similar to endogenous NK cells with the exception of Lyt-2 antigen. They are strongly positive for Qa-5, Thy-1, and partially positive for NK-1, Ly-5, Ly-6, Ly-10, and AsGm-1 and Lyt-2 antigens. The Pre-NK or accessory cells are positive for Qa-5, Ly-10, and Ly-20 and partially positive for NK-1, Thy-1, and AsGm-1 antigens. These Qa-5+ NK cells do not exhibit cytotoxic activity to WEHI or P815. They could also be generated from BM of nude mice as well as beige mice. We concluded from these studies that rat Con A-conditioned medium contained factors that could differentiate Pre-NK cells to mature NK cells and that these cells are heterogeneous. This in vitro culture system is useful in delineating the ontogeny of NK cells.