In vitro migration of rat large granular lymphocytes

Rat peripheral blood large granular lymphocytes (LGL) were isolated by fractionation on discontinuous Percoll gradients. LGL migration was studied using nitrocellulose filters. Rat LGLs migrated into nitrocellulose filters in response to N-formyl-methionyl-leucyl-phenylalanine (f-MLP), casein, and serum components. Percoll-enriched high-density lymphocytes had small, but significant, migratory capacity in response to stimuli under these conditions. Removal of OX-19+ contaminating cells by panning confirmed the migratory capability of rat LGL/NK cells under these conditions. Checkerboard analysis of the LGL response to chemoattractants revealed that induction of migration involved chemokinesis although a chemotactic component was also discernible. The prompt migration of rat LGL in response to different stimuli is consistent with the hypothesis that these cells may represent one of the first easily mobilizable lines of resistance against noxious agents. In the rat combined in vitro/in vivo studies may provide a better understanding of the regulation of LGL recruitment and extravasation.     

Modulation of the locomotory capacity of human large granular lymphocytes

The regulation of the migratory capacity of Percoll-purified large granular lymphocytes (LGL) into nitrocellulose filters was studied in a 2-hr assay with the use of modified Boyden chambers. Compounds that stimulate the natural killer cytotoxic function of LGL, such as interferons (natural beta, recombinant alpha A, recombinant hybrid alpha A/D, recombinant gamma), recombinant interleukin-2, and inactivated streptococci (OK 432), augmented the capacity of LGL to penetrate into filters spontaneously in the absence of chemoattractants in the lower compartment of the chamber. These compounds did not increase the LGL responsiveness to chemoattractants. Phorbol 12-myristate 13-acetate did not appreciably affect the locomotory capacity of LGL but augmented their cytotoxic activity. Thus the cytotoxic function and locomotion of LGL in response to biological response modifiers can be dissociated.     

Lysis of fresh human tumour cells by autologous tumour-associated lymphocytes: Two distinct types of autologous tumour killer cells induced by co-culture with autologous tumour

Summary The specific and natural killer (NK)-restricted nature of auto-tumour cytotoxicity of tumour-associated lymphocytes was studied in cancer patients with malignant pleural effusions. Large granular lymphocytes (LGL) and small T lymphocytes were isolated from carcinomatous pleural effusions by centrifugation on discontinuous Percoll gradients. Tumour cells freshly isolated from pleural effusions were classified according to their susceptibility to lysis by Percoll-purified LGL from the blood of normal donors in a 4-h ⁵¹Cr release assay. Of 12 NK-sensitive tumour samples, 11 were killed by autologous fresh effusion LGL, whereas only 2 were lysed by autologous T cells. Neither LGL nor T cells were cytotoxic to NK-resistant autologous tumour cells. T cells and LGL were each cultured in vitro with autologous tumour cells for 6 days. Effusion LGL maintained their auto-tumour killing activity in 10 of 12 autologous mixed lymphocyte-tumour cultures (MLTC) with NK-sensitive tumour, while LGL lost the activity when cultured alone. Removal of high-affinity sheep erythrocyte-rosetting cells from Percoll-purified LGL enriched effector cells. Autologous MLTC-derived LGL could also kill NK-sensitive allogeneic effusion tumour cells and K562 cells, as did fresh LGL. In autologous MLTC LGL failed to acquire lytic function to NK-resistant autologous tumour cells. In contrast, in vitro activation of effusion T cells with autologous tumour cells induced auto-tumour killer cells in 9 of 12 NK-sensitive tumour samples and 3 of 6 NK-resistant tumour cases. However, cultured T cells were incapable of killing allogeneic tumour cells and K562 cells. In the autologous MLTC effusion T cells proliferated vigorously in response to autologous tumour cells, whereas LGL showed no proliferation. The enrichment of blasts from cultured T cells on discontinuous Percoll gradients resulted in an enhancement of auto-tumour cytotoxicity, with no reactions recorded in blast-depleted, small, resting T cells. These results indicate that two distinct types of auto-tumour-recognising lymphocytes, LGL and T cells, are present in carcinomatous pleural effusions of cancer patients and that each effector type recognises different membrane moieties of autologous effusion tumour cells.     

Large granular lymphocytes provide an accessory function in the in vitro development of influenza A virus-specific cytotoxic T cells

We report that large granular lymphocytes (LGL) have an accessory function in the development of cytotoxic T cells (Tc) through the production of soluble factor(s). LGL and T cells were separated on Percoll gradients and the ability of the separated and of the recombined LGL and T cells to generate influenza A virus-specific Tc activity was measured. When stimulated by virus-infected, irradiated, adherent cells, neither LGL nor T cells cultured separately produced Tc activity. When they were co-cultured, however, even if separated by a 0.22-micron pore size membrane, Tc responses were readily generated from the small T cell precursors and natural killer activity was maintained in the LGL. Thus, LGL were required as accessory cells for Tc responses to occur and the effect was mediated by a soluble factor(s). alpha-Interferon (IFN) was produced in cultures containing LGL and/or stimulating adherent cells, whereas gamma-IFN was only produced in cultures containing both LGL and T cells. Therefore, neither alpha- nor gamma-IFN appeared to be the LGL produced soluble factor that mediated the accessory effect of LGL on Tc responses.     

NK-leukocyte chemotactic factor (NK-LCF): a large granular lymphocyte (LGL) granule-associated chemotactic factor

A chemotactic factor was identified in the supernatants of human large granular lymphocytes (LGL) activated by a glutaraldehyde-fixed NK-sensitive tumor, K562. The factor stimulated migration of human LGL, rat alveolar macrophage (RAM), and human monocytes and neutrophils (PMN). The locomotor response was chemotactic and chemokinetic on the basis of unidirectional migration in concentration gradients. The cell producing the factor was detected exclusively in LGL-rich Percoll fraction coincident with the peak of NK lytic activity and HNK-1+ cells. The monoclonal phenotype of the cell was HNK-1+, partially OKT-11+, OKM-1-, OKT-3-, OKT-4-, and OKT-8-. The factor was released by LGL within 20 min of incubation with Sr++, a cation that is able to induce LGL degranulation. A powerful chemoattractant was also detected in the granules of the rat LGL leukemia, RNK. Chemotactic activity coincided with granule enzyme beta-glucuronidase and cytolysin after RNK nitrogen cavitation and Percoll fractionation of subcellular constituents. The RNK granule chemoattractant induced unidirectional migration of human LGL and was also active against rat alveolar macrophages and human PMN. Anti-RNK granule antibody conjugated to Sepharose 4B was able to deplete the chemotactic activity from both K562-induced LGL supernatants and solubilized RNK granules. These observations indicate that a leukocyte chemotactic factor (NK-LCF) is present in NK cell granules and is probably released after tumor-induced granule exocytosis.     

Chemotaxis of large granular lymphocytes

The hypothesis that large granular lymphocytes (LGL) are capable of directed locomotion (chemotaxis) was tested. A population of LGL isolated from discontinuous Percoll gradients migrated along concentration gradients of N-formyl-methionyl-leucyl-phenylalanine (f-MLP), casein, and C5a, well known chemoattractants for polymorphonuclear leukocytes and monocytes, as well as interferon-beta and colony-stimulating factor. Interleukin 2, tuftsin, platelet-derived growth factor, and fibronectin were inactive. Migratory responses were greater in Percoll fractions with the highest lytic activity and HNK-1+ cells. The chemotactic response to f-MLP, casein, and C5a was always greater when the chemoattractant was present in greater concentration in the lower compartment of the Boyden chamber. Optimum chemotaxis was observed after a 1 hr incubation that made use of 12 micron nitrocellulose filters. LGL exhibited a high degree of nondirected locomotion when allowed to migrate for longer periods (greater than 2 hr), and when cultured in vitro for 24 to 72 hr in the presence or absence of IL 2 containing phytohemagluttinin-conditioned medium. The chemotactic LGL was HNK-1+, OKT11+ or HNK-1+, OKT11- on the basis of monoclonal antibody and complement depletion. They did not bear either T cell or monocyte cell surface markers, exhibiting an OKT3-, OKT4-, OKT8-, OKM1-, and MO2- phenotype, and did not form E rosettes at 29 degrees C, which is characteristic of lytic NK cells in contrast to T cells. Furthermore, a rat LGL leukemia (RNK) exhibited a chemotactic response to both f-MLP and casein. LGL chemotaxis to f-MLP could be inhibited in a dose-dependent manner by the inactive structural analog CBZ-phe-met, and the RNK tumor line specifically bound f-ML[3H]P, suggesting that LGL bear receptors for the chemotactic peptide.     

Effects of natural and recombinant IL 2 on regulation of IFN gamma production and natural killer activity: lack of involvement of the Tac antigen for these immunoregulatory effects

Highly enriched populations of human large granular lymphocytes (LGL), natural killer (NK) cells, and T cells were obtained from low and high density fractions, respectively, of discontinuous Percoll gradients. The NK cells were composed of 75 to 90% LGL, with the majority of the contaminating cells being monocytes. The T cells were greater than 95% OKT3+. The proliferative and cytotoxic progenitors in both fractions were examined by using a limiting dilution assay with interleukin 2 (IL 2) from four sources: 1) crude supernatant of a gibbon lymphoma (MLA-144), 2) purified (150,000-fold) MLA-144 IL 2, 3) partially purified human IL 2, and 4) purified recombinant human IL 2. The proliferative capacity was measured at day 7 by [3H]thymidine incorporation, whereas the progenitors of cells with NK-like activity were evaluated by assessing cytotoxic activity against K562 cells at day 8 in a 4-hr 51Cr-release assay. The frequency of proliferative progenitors among T cells was approximately 1/5 and was approximately 1/60 with LGL. Titration of the highly purified IL 2 preparation demonstrated that LGL proliferated with as little as 2 U of IL 2. The frequency of detectable cytotoxic progenitors in the LGL population, however, fell sharply when less than 40 U of IL 2 were employed. The T cells failed to demonstrate cytotoxic activity against the NK-susceptible target cells at any concentration of IL 2 tested. The IL 2 preparations also were examined for their ability to directly and rapidly enhance the cytotoxic activity of highly purified NK cells. All four preparations of IL 2 enhanced the cytotoxic activity of LGL without any detectable accessory requirement after incubation for as little as 6 hr, even though the MLA-144 IL 2 preparations were devoid of detectable interferons (IFN). These data indicate that IL 2 has dual effects on NK cells, regulating their activity was well as promoting their proliferation. Collectively, these results demonstrate that highly purified IL 2, devoid of other detectable lymphokines, is capable of supporting the growth of human NK cells and augmenting their in vitro activity. In parallel experiments, these same IL 2 preparations were quite active in causing the proliferation of T lymphocytes, clearly demonstrating a role of IL 2 in promoting the proliferation of NK cells as well as T cells. The mechanism of IL 2 boosting appears to be a direct interaction with LGL, resulting in the production of IFN gamma.(ABSTRACT TRUNCATED AT 400 WORDS)     

beta-Endorphin augments the cytolytic activity and interferon production of natural killer cells

We have investigated the in vitro effects of the neurohormone beta-endorphin (b-end) on natural killer (NK) activity and interferon (IFN) production mediated by large granular lymphocytes (LGL). LGL-enriched fractions from peripheral blood mononuclear cells (PBMC) from normal human volunteers were obtained by fractionation over discontinuous Percoll gradients. LGL were preincubated with or without various concentrations of b-end or the closely related peptides alpha-endorphin (a-end), gamma-endorphin (g-end), or D-ALA2-beta-endorphin (D-ALA2-b-end), a synthetic b-end analogue. NK activity was assayed on 51Cr-labeled K562 target cells. Preincubation of LGL effectors (but not K562 targets) for 2 to 18 hr with concentrations of b-end between 10(-7) M and 10(-10) M produced significant augmentation of NK cytolytic activity (mean percentage increase: 63%). The classic opiate antagonist naloxone blocked the enhancing effect when used at a 100-fold molar excess relative to b-end. Neither a-end nor g-end could augment NK activity, whereas D-ALA2-b-end produced an enhancement comparable with that produced by b-end. In addition, incubation of LGL with b-end in the presence of phytohemagglutinin or poly I:C significantly augmented IFN production. These findings demonstrate that b-end enhances NK activity and IFN production of purified LGL, and suggests that b-end might bind to an opioid receptor on LGL that can be blocked by naloxone. These results lend support to the concepts of regulation of the immune response by neurohormones and the functional relationship between the nervous and immune systems.     

Modulation of adhesion molecules on human large granular lymphocytes by interleukin-2 in vivo and in vitro.

The modulation of adhesion molecules on human large granular lymphocytes (LGL) by interleukin (IL)-2 was investigated both in vivo and in vitro. Intercellular adhesion molecule-1 (ICAM-1; CD54) expression increased on LGL of cancer patients receiving IL-2 adoptive immunotherapy. ICAM-1 expression on LGL isolated by Percoll gradient centrifugation, LGL purified, and expanded by adherence to plastic surfaces and LGL identified by Leu 19 (CD56) monoclonal antibody were increased significantly in response to IL-2 in vitro. Exposure of LGL to IL-1, interferon (IFN)-gamma, and tumor necrosis factor (TNF) in vitro did not induce ICAM-1. The expression of LFA-1 (CD11a/CD18), a receptor for ICAM-1, and other leukocyte adhesion molecules, including Mac-1 (CD11b/CD18) and p150,95 (CD11c/CD18), was only maintained by IL-2. IL-2 induction of ICAM-1 and the maintenance of CD18 complex expression on small lymphocytes separated by Percoll gradients were similar to that on LGL. We conclude that IL-2 enhances the expression of ICAM-1 on multiple human lymphocyte populations including LGL effectors. Expression of the CD18 complex on LGL does not appear to be highly regulated by IL-2. These findings may have implications relevant to the role of these adhesion molecules in the activities of LGL modulated by IL-2.     

Optimization of the Wound Scratch Assay to Detect Changes in Murine Mesenchymal Stromal Cell Migration After Damage by Soluble Cigarette Smoke Extract

Cell migration is vital to many physiological and pathological processes including tissue development, repair, and regeneration, cancer metastasis, and inflammatory responses. Given the current interest in the role of mesenchymal stromal cells in mediating tissue repair, we are interested in quantifying the migratory capacity of these cells, and understanding how migratory capacity may be altered after damage. Optimization of a rigorously quantitative migration assay that is both easy to customize and cost-effective to perform is key to answering questions concerning alterations in cell migration in response to various stimuli. Current methods for quantifying cell migration, including scratch assays, trans-well migration assays (Boyden chambers), micropillar arrays, and cell exclusion zone assays, possess a range of limitations in reproducibility, customizability, quantification, and cost-effectiveness. Despite its prominent use, the scratch assay is confounded by issues with reproducibility related to damage of the cell microenvironment, impediments to cell migration, influence of neighboring senescent cells, and cell proliferation, as well as lack of rigorous quantification. The optimized scratch assay described here demonstrates robust outcomes, quantifiable and image-based analysis capabilities, cost-effectiveness, and adaptability to other applications.     

Changes in number and density of large granular lymphocytes upon in vivo augmentation of mouse natural killer activity

NK activity of mice as well as humans and rats has been clearly associated with large granular lymphocytes (LGL). To better understand the effects of interferon (IFN) and IFN inducers on natural killer (NK) cells, we have compared the LGL in the spleens of normal and boosted mice. Cells were fractionated by centrifugation on discontinuous Percoll density gradients, and each fraction was tested for NK activity against YAC-1 targets and for the presence of LGL. In vivo treatment with C. parvum (0.7 mg/mouse, i.p., day-3), MVE-2 (25 mg/kg, i.p., day-3), poly I:C (4 mg/kg, i.p., day-3), or IFN (10(5) U/mouse, i.p., day-1) resulted in a marked augmentation and a change of distribution of cytotoxic activity. Most of the NK activity of boosted spleen cells was associated with lower density fractions 1 and 2, whereas active normal spleen cells had somewhat higher density (fractions 2 and 3). In parallel to their increased reactivity, the boosted spleens had a marked increase in the percentage of LGL, particularly in fractions 1 and 2. The augmented activity appeared to be mediated by the LGL, because treatment with anti-asialo GM1 or anti-Thy-1.2 plus complement reduced NK as well as the number of LGL. These results indicate that IFN-mediated boosting of NK activity in the spleen is due to an increase in the lower density LGL, as well as to an increase in the function of preexisting NK cells.     

Proliferation of human peripheral blood lymphocytes induced by recombinant human interleukin 2: contribution of large granular lymphocytes and T lymphocytes

Recombinant human interleukin 2 (rH IL-2) in the presence or absence of additional stimuli, was found to be able to induce and support the proliferation of human peripheral blood lymphocytes (PBLs). These proliferative effects were observed at low doses (less than or equal to 10 U/ml) of interleukin 2 (IL-2) only when additional signals (antigen, mitogen) were provided. However, higher doses (greater than or equal to 100 U/ml) of rH IL-2 significantly stimulated the proliferation of PBL even in the absence of exogenous lectin, antigen, or allogeneic serum. The subpopulation of lymphocytes most responsive to these higher doses of rH IL-2 was the large granular lymphocyte (LGL), the morphologic homologue of natural killer activity. After the separation of human PBLs on discontinuous Percoll gradients, cells from fraction 2 (greater than 90% LGLs) responded in a dose-dependent manner to rH IL-2 alone, whereas cells from fraction 6 (greater than 90% T cells) were only slightly responsive to rH IL-2 alone. A portion of the proliferation of cells from fraction 2 was dependent on the expression of the TAC receptor, because the prior removal of TAC-positive cells significantly reduced IL-2-induced lymphocyte proliferation. These results demonstrate that human LGL that have not been exogenously stimulated can proliferate in direct response to IL-2, and suggest that LGL are the major cellular phenotype in the proliferative response that has been observed clinically.     

The recognition specificity of a murine helper T cell for hemagglutinin of influenza virus A/PR/8/34

Human large granular lymphocytes (LGL), which are known to be responsible for natural killer (NK) cell activity, also produced a variety of lymphokines including interleukin 2 (IL 2), colony stimulating factor (CSF), and interferon (IFN) in response to phytohemagglutinin (PHA) or concanavalin A (Con A). Human peripheral blood LGL, which were purified by removal of monocytes adhering to plastic flasks and nylon columns, followed by separation on a discontinuous Percoll gradient, and additional treatment with anti-OKT3 and Leu-M1 plus complement, were more potent producers of these lymphokines than unseparated mononuclear cells (MNC), nylon column-eluted cells, or purified T lymphocytes. Moreover, IL 2 production by LGL could be further distinguished in that it was not enhanced by the addition of macrophages or macrophage-derived factor, i.e., IL 1, whereas addition of macrophages did potentiate IL 2 production by T lymphocytes. Further analysis of cells in the LGL population using various monoclonal antibodies revealed that removal of cells with OKT11 or AF-10, a monoclonal antibody against human HLA-DR antigen, decreased IL 2 production, whereas removal of OKT8+, OKM1+, Leu-M1+, or Leu-7+ cells led to enhanced IL 2 production. The LGL population is therefore heterogeneous and includes at least three functionally and phenotypically distinct subsets. An atypical T cell subset (OKT3-, Leu-1-, OKT11+) rather than the myeloid subset of LGL (Leu-M1+ or OKMI+) was the source of LGL-derived IL 2, whereas the latter subset and/or another subset of OKT8+ cells appear to regulate this IL 2 production. In addition to performing NK activity, LGL on a per cell basis seem to be more effective than T lymphocytes in producing lymphokines, namely, IL2, CSF, and IFN.     

Natural killer cell activity in the rat. V. The circulation patterns and tissue localization of peripheral blood large granular lymphocytes (LGL)

Large granular lymphocytes (LGL) and T cells were separated from blood by centrifugation on discontinuous gradients of Percoll, were labeled with [3H]uridine or [111In]oxine, and were injected i.v. into syngeneic euthymic or athymic nude rats. The tissue distribution of these labeled cells was monitored for up to 24 hr after transfer by scintillation counting of tissue homogenates and autoradiography of tissue sections. In normal euthymic rats, the main sites of LGL localization were the alveolar walls of the lungs and spleen red pulp; however, they were not detectable in the major traffic areas of T lymphocyte recirculation, the spleen white pulp, and lymph nodes. Furthermore, the density of labeled LGL was very low in the small intestine, thymus, kidney, and liver, although on a per-organ basis, about 10% of the injected radioactivity was found in the liver by 24 hr post-injection. When 111In-labeled LGL were injected i.v. into rats with an indwelling thoracic duct cannula, they completely failed to enter the thoracic duct lymphocyte (TDL) population over an observation period of 6 days. This finding was markedly different from the results obtained with T cells and was consistent with the lack of natural killer and antibody-dependent cellular cytotoxicity activity observed among TDL, even in rats pretreated with the biological response modifier, poly I:C. LGL in athymic nude rats also failed to recirculate between blood and lymph. However, in contrast to normal euthymic animals, a significant increase in the localization of radiolabeled LGL to lymph nodes was observed in nude rats between 30 min and 24 hr. Taken as a whole, these findings define the areas within the lungs and spleen in which blood LGL normally localize, and clearly demonstrate that LGL do not normally recirculate between blood and lymph.     

Natural killer activity in the rat. IV. Distribution of large granular lymphocytes (LGL) following intravenous and intraperitoneal transfer

Highly enriched populations of rat large granular lymphocytes (LGL) and T lymphocytes were prepared on discontinuous density gradients of Percoll, labeled with either 111In-oxine or 51Cr and injected either intravenously (iv) or intraperitoneally (ip) into normal syngeneic recipients. Following iv inoculation of labeled LGL or T cells into normal recipients, a large proportion of radioactivity (18 to 33%) was recovered within minutes in the lungs. By 2 to 4 hr following transfer, significantly more LGL (13.5%) than T cells (6.4%) remained in the lungs. This difference persisted through 48 hr (5.4 vs 0.8%). Decreasing levels of radioactivity in the lungs were accompanied by corresponding increases in counts in the spleen and liver. At early time points, a significantly higher proportion of T cells was found to distribute to the spleen, while labeled LGL persisted for longer periods in the blood as well as in the lungs. Following ip inoculation into normal recipients, there was a slow clearance of radiolabeled LGL and T cells from the peritoneal cavity, with less than 20% of the radiolabel found in peripheral organs by 24 hr. These results demonstrate a distribution pattern for LGL and T cells that resembles the previously reported proportions of these cells in various organs. In addition, these studies provide a firm basis for the formulation of further experiments to examine the usefulness of adoptive immunotherapy with LGL or immune T cells.     

Sequential metabolic events and morphological changes during in vivo large granular lymphocyte activation and proliferation

Interferon (IFN) and IFN inducers are known to boost natural killer (NK) activity in vivo and in vitro. In vivo enhancement of NK activity results from activation of preexisting NK cells as well as from an increased number of large granular lymphocytes (LGL), with a portion of them undergoing cell division. Our study was addressed to analyze the sequence of metabolic events occurring within the LGL population of Fischer rats treated with poly(I:C), as an IFN inducer. The increase in cytotoxic activity and LGL number in the peripheral blood already reached maximal levels by 12 hr after poly(I:C) injection, remained on a plateau 24 to 48 hr later, then slightly decreased on Day 4, and returned to control levels by Day 6. A similar kinetics was observed for RNA synthesis. In contrast DNA synthesis first increased at 24 hr, peaked at 48 hr, then decreased on Day 4, and was not detectable on Day 6. Percoll fractionation resulted in 92-97% of LGL in fraction 1, and cells in this fraction accounted for the increase of cytotoxicity as well as for newly synthesized RNA and DNA. However, LGL recovered on Day 1 or 2 after poly(I:C) stimulation displayed quite heterogeneous morphology, and a number of mitotic configurations were seen on Day 2 within the LGL population. Our results indicate that the boosting of NK activity by poly(I:C) is always associated with an increase in LGL numbers, the enhanced lytic capacity is associated in vivo with new RNA synthesis by the NK cells, and only in a later phase NK cell proliferation may account for the increase in LGL numbers.     

Natural killer cell-mediated antitumor reactivity of rhesus monkeys

We have analyzed natural killer (NK) cell-mediated antitumor activity or peripheral blood mononuclear cells of rhesus monkeys. All monkeys displayed significant NK cell cytolytic activity against the human tumor cell lines K-562, Daudi and CEM in a short-term (3 h) 51Cr-release assay. Similar to NK cells described in other species, the cytotoxic cells of monkeys were relatively nonadherent to nylon wool columns, exhibited low density after separation on discontinuous Percoll density gradients, and displayed large granular lymphocyte (LGL) morphology. Analysis of the mechanism of NK cell cytotoxicity of rhesus monkeys demonstrated that on the average, 7.1% (range: 3.1-13.2%) of lymphocytes bound to K-562 tumor, and that approximately 14.8% (range: 7.9-26.3%) of these tumor-binding cells (TBC) were cytolytically active. Examination of TBC on cytocentrifuge slides indicated that the majority of binders displayed LGL morphology. The cytotoxic reaction mediated by monkey NK cells exhibited Michaelis-Menten kinetics pattern; the maximum rate of lysis (Vmax) of K-562 was found to be 1-2 X 10(4) following 3 h of incubation. Using similar culture conditions, the recycling capacity of NK cells of this species was estimated at 2-6 times. Finally, it was observed that the NK cell activity of most monkeys could be potentiated following in vitro exposure to the biological response modifier, interleukin-2.     

Activation of rat and human alveolar macrophage intracellular microbicidal activity by a preformed LGL cytokine

An alveolar macrophage-activating factor was released from Percoll fractionated large granular lymphocytes (LGL) within minutes of contact with either the natural killer (NK)-sensitive K562 tumor or heat-killed Staphylococcus aureus. The factor enhanced the intracellular killing of S. aureus without altering the rate of phagocytosis. Factor release was blocked by treatment of LGL with monensin, a carboxylic ionophore that inhibits vesicular traffic, but was unaffected by actinomycin D and cycloheximide pretreatment, suggesting that the cytokine was performed. The cell producing the factor was found only in Percoll fractions containing high concentrations of lytic NK cells and LGL, and the phenotypes of the LGL were HNK-1+ and E rosette-. The macrophage activating factor was a small protein of 10,000 to 20,000 daltons, as determined by gel fractionation, and was sensitive to proteolytic enzymes and heat and pH labile. Active supernatants were devoid of antiviral (interferon; IFN) or interleukin 2 (IL 2) activity, and IFN-beta, IFN-gamma, IL 2, and interleukin 1 were unable to activate staphylococcidal activity, suggesting that the LGL macrophage activating factor was distinguishable from these cytokines.     

Natural cytotoxicity of lymphocytes from lymph nodes draining breast carcinoma and its augmentation by interferon and OK432

Summary Lymphocytes isolated from axillary lymph nodes draining breast carcinoma were tested for natural killer (NK) activity against K562 in a 4-h ⁵¹Cr-release assay, and the in vitro effects of interferon (IFN) and OK432 (a streptococcal preparation) on their cytotoxicity were examined in comparison with NK activity of autologous peripheral blood lymphocytes (PBL). The levels of NK activity were lower in lymph node lymphocytes (LNL) than in PBL of the same patients. Significant levels of LNL-mediated lysis were recorded in 14 of 42 (33%) lymph node samples and in nine of 14 (64%) patients. Purification of large granular lymphocytes (LGL) from lymph node cells by discontinuous Percoll density gradient centrifugation resulted in an induction or enhancement of cytotoxic activity, with no reactivity in LGL-depleted, small T-lymphocyte populations. Positive reactions were observed with 10 of 13 (77%) LGL samples. The low reactivity of LNL was not attributable to coexistent suppressor cells for NK function, since lymph node cells failed to suppress NK activity of normal PBL. Partially purified human IFN and OK432 augmented NK activity of patients' PBL in approximately 70% and 90% of the cases, respectively, while LNL-mediated lysis was augmented in only 7% and 36% of the lymph node samples by IFN and OK432, respectively. These results indicate that K562-reactive NK cells and/or their precursors may frequently be present at subthreshold levels in the lymph nodes draining breast carcinoma, and that the augmentation of LNL-mediated cytotoxicity by OK432 might provide a local potentiation of natural immune function at the host-tumor interface rather than IFN.     

Identification and purification of NK cells with lysosomotropic vital stains: correlation of lysosome content with NK activity

The lysosome content of lymphocytes has been analyzed with lysosomotropic vital stains and the fluorescence-activated cell sorter (FACS). Large granular lymphocytes (LGL), which account for virtually all natural killing activity in peripheral blood, are quantitatively different from small lymphocytes (SL) in this respect. LGL obtained by Percoll gradient density centrifugation accumulate more of the lysosomotropic vital dyes than SL do, staining with either neutral red or mepacrine (quinacrine). Furthermore among the LGL-rich, low density lymphocyte population highly, granulated cells can be separated from less granulated ones by mepacrine staining and FACS. Thus, separated highly granulated LGL express very high natural killing, whereas the less granulated low density large lymphocytes do not kill.