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.     

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.     

In vitro migration of human large granular lymphocytes

Large granular lymphocyte (LGL)-enriched peripheral blood mononuclear cells were prepared on discontinuous gradients of Percoll. Migration into nitrocellulose filters was studied in a 2-hr assay with the use of modified Boyden chambers. LGL migrated into filters in response to casein or C5a. Migration depended on the presence of a concentration gradient of chemoattractant between the lower and upper compartment of the chambers. Percoll-purified high density small lymphocytes had little or no migratory capacity under these conditions, requiring a longer incubation time (4 hr) for consistent migration. Migratory capacity in response to stimuli correlated with the frequency of LGL in the various fractions of Percoll gradients. Fractionation of LGL-enriched Percoll preparations with monoclonal antibodies and immunoadsorbent columns or a cell sorter revealed that cells with migratory capacity in response to stimuli were B73.1+ and OKT3-, thus confirming that migrating cells were LGL. LGL preincubated with interferon (IFN) showed enhanced spontaneous motility but no increased responsiveness to chemoattractants. IFN did not modify the migratory capacity of small lymphocytes. The prompt migration of LGL in response to stimuli is consistent with the hypothesis that these cells may serve as one of the first easily mobilizable lines of resistance against infectious agents and tumors. The migration assay described here may offer a better insight into the functions and regulation of LGL.     

Accumulation and chemotaxis of natural killer/large granular lymphocytes at sites of virus replication

A model for monitoring the accumulation of natural killer cell/large granular lymphocytes (NK/LGL) at a site of virus replication was studied by using mice infected i.p. with either lymphocytic choriomeningitis virus (LCMV), murine cytomegalovirus (MCMV), mouse hepatitis virus (MHV), Pichinde virus, or vaccinia virus. An i.p. but not i.v. infection resulted in a localized increase in NK/LGL cell number (a fourfold to greater than 20-fold increase) and augmentation (a 10- to 20-fold increase) of NK cell activity associated with virus-induced peritoneal exudate cell (PEC) populations. An increase in NK/LGL cell number was detected as early as 12 hr postinfection (p.i.) and peaked at 3 days p.i. with MHV. The initial LGL recruited into the peritoneal cavity at 1 to 3 days p.i. were nonadherent to plastic and were demonstrated to have an NK cell phenotype: asialo GM1+, Thy-1.2 +/-, Lyt-2.2-, and J11d-. The peak number of LGL appeared at 7 days after infection with the NK cell-resistant virus, LCMV. This LGL population had been previously demonstrated to contain cytotoxic T lymphocyte/LGL (CTL/LGL) as well as NK/LGL. During an MHV infection the number of LGL decreased between days 3 and 7 p.i., suggesting that the second wave of CTL/LGL was absent. These findings may explain the absence of a good MHV-CTL model. Virus-induced, activated NK/LGL responded to chemotactic signals by migrating in a unidirectional manner across two 5-microns pore size polycarbonate filters during 7 hr in vitro chemotaxis assays. Wash-out fluid obtained from the peritoneal cavity contained chemotactic activity for NK/LGL as well as for other cell types. We conclude that production and/or release of chemotactic factors at sites of virus replication are at least partially responsible for the accumulation of NK/LGL at these sites.     

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.     

Characterization of human large granular lymphocyte subpopulations: comparison of the phenotype of NK cells and of interleukin 2-dependent progenitors of cytolytic effector cells

Antigenically different subpopulations of human large granular lymphocytes (LGL) were identified according to their reactivity with monoclonal antibodies (MoAb). Antigen-positive and -negative subsets were isolated by immunoaffinity columns using a Sepharose 4B gel coupled with F(a')2 goat anti-mouse IgG or by flow cytometry cell sorting. The distinct LGL subsets were tested for natural killer (NK) activity against a panel of tumor targets: K562, Daudi, Alab; and for antibody-dependent cellular cytotoxicity (ADCC) against antibody-coated RL male 1 cells. LGL positively selected for any of the following phenotypic markers: B73.1+, OKM1+, OKT11+, and OKT10+ were highly cytotoxic, while B73.1- and OKM1- cells were completely devoid of NK activity. The OKT10- and OKT11- LGL subsets were occasionally cytotoxic, with low levels of reactivity. LGL subpopulations were also tested in a limiting dilution assay (LDA) for their capacity to proliferate in medium supplemented with interleukin 2 (IL-2) and to develop NK-like cytotoxic activity. The majority of proliferative progenitors have the following phenotype: OKT11+, OKM1-, B73.1-, and OKT10-, while the majority of progenitors for cytotoxic cells were OKT11+, OKM1+/-, OKT10+, and B73.1-. Results indicate that although B73.1+ cells can grow, the mature B73.1+ NK cells seem to be primarily derived in vitro from a small subset of less differentiated B73.1 pre-NK progenitors in the peripheral blood lymphocytes.     

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.     

Subsets of human large granular lymphocytes (LGL) exhibit accessory cell functions

The present study shows that human large granular lymphocytes (LGL) depleted of OKT3 (T lymphocytes) and Leu-M1-positive (monocytes) cells exhibit accessory cell function for the T lymphoproliferative responses to the soluble stimulants Staphylococcus protein A (SpA) or Streptolysin O (SLO), as well as to surface antigens in the autologous and allogeneic mixed leukocyte reaction (MLR). Fractionation of LGL into subsets according to their reactivity with alpha OKT11, alpha DR, and alpha OKM1 MoAb led to the identification of the subset(s) of LGL with OKT11+, DR+, OKM1+ phenotype as the antigen-presenting cell (APC), whereas the DR-, OKM1- subset(s) of LGL was completely ineffective. Furthermore, virtually all the natural killer (NK) activity of LGL was associated with OKT11+ and OKM1+, DR+ LGL that exerted the observed APC function, suggesting that NK-active cells may also act as effective APC for T lymphocyte activation. These results indicate that human LGL with NK activity may exert other noncytotoxic functions and may play a major role in immunoregulation.     

A subpopulation analysis of f-MLP stimulated granulocytes migrating in filters

Leukocyte migration in vitro has been studied extensively during many years without providing satisfactory theoretical models for the different migratory behaviors (chemotaxis and chemokinesis) of leukocyte populations. The present study utilized the fluid gradient chamber, which is a new method to study leukocyte migration in filters. Human neutrophils were applied between two stacked filters and migrated in all directions under the influence of constant concentrations or chemotactic gradients of f-MLP, maintained in fluid phase density gradients. The distributions of the granulocytes over filter depth were fitted to theoretical functions composed by 1–3 Gaussian distributions, representing subpopulations. The results showed that the neutrophils migrated as two discrete subpopulations during chemokinetic stimulation (a constant concentration of f-MLP). One of the subpopulations showed less active and passive (slow sedimentation under the influence of gravity) translocation. The most mobile subpopulation was divided into two new subpopulations when exposed to chemotactic stimulation (concentration gradient of f-MLP), one of which responded chemotactically and one of which migrated in random directions. The properties of the different subpopulations where characterized in terms of diffusion coefficient (random migration), convection velocity (chemotactic migration) and sedimentation coefficient (passive translocation).     

Noncytotoxic functions of natural killer (NK) cells: large granular lymphocytes (LGL) produce a B cell growth factor (BCGF)

Highly purified human large granular (LGL), depleted of any detectable contaminant T and B cells or monocytes, were found to be potent producers in vitro of a soluble B cell growth factor (BCGF) able to sustain proliferation of B cells activated by anti-mu. Activation by lectins (phytohemagglutinin, PHA, concanavalin A, Con A; and pokeweed mitogen, PWM) was required to induce the production of high levels of this BCGF from cultured LGL. Production of BCGF was also detected after the binding of LGL with natural killer (NK)-sensitive (K562) but not with NK-resistant (RL male 1) target cells. In contrast to T cells, LGL did not need the additional presence of accessory cells to reach optimal production of BCGF by 72 hr of culture. The subpopulation of LGL responsible for the production of BCGF had phenotypic characteristics associated with NK cells (3G8+, HNK1+/OKT11+, DR-, OKT3-, Leu-M1-), and separated cells with these markers exerted high levels of NK activity. Selective production of BCGF also was obtained from cytotoxic clones derived from LGL. A partial characterization of the LGL-derived BCGF was performed by gel filtration. BCGF activity was detected in fractions with estimated m.w. of 20,000 and 45,000. The LGL-derived BCGF activity was resistant to reduction with 2-mercaptoethanol and was stable at -20 degrees C for months. Conversely, heating (56 degrees C for 1 hr) or digestion with trypsin greatly reduced the LGL-derived BCGF activity. These findings strongly suggest that LGL including those with NK activity can play an important positive role in the early events of the B cell-mediated immune response.     

Ultrastructure of large granule-containing lymphocytes possessing natural killer activity

By means of light and electron microscopy, ultrastructural cytochemistry and immune cytochemistry methods, contents and ultrastructure of large granule-containing lymphocytes (LGL) have been studied in human blood--this is cell population possessing natural killer and, partly, antibody-depending cytotoxicity. The LGL concentrates are isolated from blood applying successive physical-chemical methods, differential centrifugation in the density gradient of pack-phycoll and percoll included. Separate LGL populations are marked by means of rosette-forming reaction with sheep erythrocytes and monoclonal antibodies OKT4 and OKT8. Relative and absolute amount of the LGL in 1 1 of blood is 5.4 +/- 0.5% and 0.319 +/- 0.28 X 10(9), respectively. The LGL ultrastructure is characterized with a low nuclear-cytoplasmic ratio, with presence of osmiophilic (azurophilic) granules in cytoplasm and specific parallel-tubular structures, with a well developed Golgi complex, an essential number of mitochondria, vesicles with smooth wall and vacuoles, as well as multivesicular bodies and Gallo bodies. The LGL subpopulations, expressing various membrane antigens (E+, E-, OKT8+, OKT8-) differ in their ultrastructure, that is evidently stipulated by the degree of their differentiation and their function.     

Morphologic and phenotypic analysis of canine natural killer cells: evidence for T-cell lineage

Canine natural killer (NK) activity and antibody-dependent cell-mediated cytotoxicity were studied utilizing a canine thyroid adenocarcinoma cell line and a lymphoblastoid cell line (CT-45S), respectively, as cell targets. Fractionation of peripheral blood mononuclear cells by Percoll discontinuous-gradient centrifugation resulted in a six- to sevenfold enrichment in large granular lymphocytes (LGL) in parallel with a twofold increase in NK activity (%specific lysis) in low-density fractions. Further enrichment in LGL (78 +/- 6%) and NK activity (threefold increase) was obtained by lytic treatment of low-density fractions 2 and 3 with monoclonal antibody WIG4. By means of cytolytic treatment with additional monoclonal antibodies the phenotype of canine NK cells was determined as Dly-1+, Dly-6+, 1A1+, E-11+, DT-2-, WIG4-. Some NK cells were also Ia+. NK activity was relatively radioresistant with 40% specific lysis even after irradiation with 40 Gy. Among the populations examined, the highest NK activity was found in peripheral blood mononuclear cells, followed by splenic mononuclear cells and bone marrow mononuclear cells. These results indicate that canine NK cells have the morphology of LGL, are relatively radioresistant, and express cell surface antigens suggesting a T-cell lineage.     

Production of B cell growth factor by a Leu-7+, OKM1+ non-T cell with the features of large granular lymphocytes (LGL)

The present study reports the characterization of a non-T cell from human peripheral blood which is capable of releasing BCGF. This BCGF-producing non-T cell had a T3-, T8-, Leu-7+, OKM1+, HLA-DR-, Leu-11- surface phenotype and was likely to belong to the so-called large granular lymphocyte (LGL) subset because: after fractionation of non-T cells according to the expression of Leu-7 or HLA-DR markers, it was found in the Leu-7+, HLA-DR- fractions that were particularly enriched in LGL; it co-purified with LGL on Percoll density gradients; and it expressed Leu-7 and OKM1 markers that are shared by a large fraction of LGL. Although co-purified with cells with potent NK capacities, the BCGF-producing cell was not cytotoxic, because treatment of Leu-7+ cells with Leu-11 monoclonal antibody and complement abolished the NK activity but left the BCGF activity unaltered. The factor released by this LGL subset was not IL 1 or IL 2 mistakenly interpreted as BCGF, because: a) cell supernatants particularly rich in BCGF activity contained very little or no IL 1 or IL 2; b) BCGF-induced B cell proliferation was not inhibitable by anti-Tac antibodies (this in spite of the expression of IL 2 receptor by a proportion of activated B cells); and c) BCGF activity was absorbed by B but not T blasts.     

Interferon-alpha induction of lymphocytes containing parallel tubular structures

The induction by IFN-alpha in peripheral blood lymphocytes of parallel tubular structures (PTS) and/or electron-dense granules occurring in a minority of peripheral blood lymphocytes was examined. IFN reportedly augments natural killer (NK) cell activity of large granular lymphocytes (LGL); these cells contain PTS and/or electron-dense granules. Normal peripheral blood mononuclear cells were incubated with IFN-alpha and surface antigen expression was measured by means of indirect immunofluorescence and, at the ultrastructural level, using gold labelled monoclonal antibodies. Surface antigen reactivity with the monoclonal antibodies OKT 3, 4, 8 and Anti-Leu-7 (HNK-1) showed no difference between the IFN-alpha incubation and non-IFN-alpha groups. However, electron microscope investigation revealed significant absolute increases in the percentage of OKT 8+ and Anti-Leu-7+ cells which were PTS-positive after IFN-alpha treatment compared with the control groups. The cytotoxicity assay using the K562 cell line showed enhanced lytic activity. Our results suggest that cells coexpressing the OKT 8 and Leu-7 antigens may be responsible for a minor proportion of the increase in PTS but that IFN-alpha mainly induces PTS and/or associated structures in cells which express the OKT 8+ antigen. These PTS+/OKT 8+ cells may contribute to enhanced cell cytotoxicity.     

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.     

Exposure of human neutrophils to chemotactic factors potentiates activation of the respiratory burst enzyme

NADPH oxidase activity in particulate fractions from human neutrophils stimulated with phorbol myristate acetate (PMA) or opsonized zymosan was enhanced by prior exposure of the neutrophils to chemotactic factors. Enhanced activity was seen measuring both NADPH-dependent chemiluminescence and superoxide anion production. Enhancement was observed to be both time and dose dependent with several chemotactic stimuli, including casein, N-formyl-methionyl-leucyl-phenylalanine (f-MLP), and C5a. F-MLP and C5a showed similar patterns, with peak enhancement occurring within 2 to 15 min of preincubation and lasting up to 1 hr. In contrast, enhancement of PMA-stimulated oxidase activity by casein was more gradual and sustained, lasting up to 2 hr. Fractions from cells treated only with chemotactic factors and not stimulated with PMA showed no oxidase activity. Kinetic studies of this enhanced activity show that chemotactic factors induce increases in Vmax values but do not significantly alter Km values for the oxidase. Further experiments using agents that modulate degranulation suggest that enzyme release is not involved in this enhancement. These data suggest that pretreatment with chemotactic factors results in an increase in the amount of activated oxidase in membrane fractions obtained from PMA-stimulated neutrophils. This alteration of NADPH oxidase activity provides a subcellular basis for the enhanced bactericidal activity and increased oxidative metabolism seen in neutrophils treated with chemotactic factors.     

A visual analysis of chemotactic and chemokinetic locomotion of human neutrophil leucocytes. Use of a new chemotaxis assay with Candida albicans as gradient source.

The locomotion of human blood neutrophil leucocytes was observed and analysed by time-lapse cinematography (1) under conditions where chemokinetic locomotion was stimulated, i.e. in a uniform concentration of casein; (2) in response to chemotactic gradients generated at a point-like source, namely blastospores of the pathogenic yeast Candida albicans in normal human plasma, and (3) in response to soluble chemotactic factors diffusing from Sephadex beads. Neutrophils moving in purely chemokinetic conditions tended to persist in straight paths and showed a preference for narrow angles of turn suggesting a “persistent random walk” type of locomotion rather than a pure random walk. Cells responding to Candida spores showed near straight-line locomotion to the gradient source over short distances (ca 50 μm) and brief time periods. They phagocytosed the spores on arrival and were usually immediately able to respond to a new gradient. Colchicine treatment caused the cells to turn through wider angles, but they were still able to home onto and phagocytose the spores. Colchicine-treated cells showed bizarre and fluctuating shapes but were nonetheless usually polarized towards the gradient source. Gradients from large sources, such as Sephadex beads containing soluble chemotactic factors, were more easily disturbed than those from Candida spores and directional locomotion of cells towards the beads was only seen in certain sectors. The angles of turn made by moving cells under these conditions were an important determinant of chemotaxis since paths of those cells reaching beads showed longer straight segments and narrower angles of turn than those which failed to show a directional response.     

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.     

Purification and properties of cytoplasmic granules from cytotoxic rat LGL tumors

To evaluate the role of NK cell granules in the lytic activity of NK cells, cytoplasmic granules of rat NK tumors were purified by centrifugation of the cell homogenates in a Percoll gradient. Analysis of such gradients showed a band of light-scattering material near the bottom of the tube; assay of gradient fractions for lytic activity against SRBC showed a potent lytic activity giving a sharp peak in this region. Complete lysis of SRBC was achieved with less than 1 microgram/ml protein of the most active fractions. Examination in the electron microscope showed that a pool of fractions containing lytic activity consisted of pure cytoplasmic granules showing similar morphology to those found in the LGL tumors. The lytic band was associated with a peak in the activity of four different lysosomal enzymes. Analysis of Percoll gradient fractions showed that marker enzymes for mitochondria, plasma membrane, and cytosol were well separated from this activity peak. Analysis of the Percoll gradient fractions by SDS gel electrophoresis showed that this granule fraction was free of contamination of proteins from other parts of the gradient. The granules contained major protein bands of 62, 58, 30, 29, and 28 kilodaltons. In addition to protein, the purified granule fractions contain hexose and uronic acid, but no nucleic acids or phospholipids were detected in chemical assays. Major amounts of chymotryptic, tryptic, and elastase activities were not present, nor were peroxidase or lysozyme activities detectable in substantial amounts. These data show that NK tumor cell cytoplasmic granules contain a potent lytic activity and have biochemical properties that distinguish them from granules present in granulocytes and mast cells.     

Leishmania major and Leishmania donovani: effect of LPG-containing and LPG-deficient strains on monocyte chemotaxis and chemiluminescence.

Lipophosphoglycan (LPG) is a major glycolipid present on the membrane of Leishmania promastigotes and amastigotes. We have previously shown that preincubation of peripheral blood monocytes with purified LPG inhibits IL-1 production, chemotactic locomotion, and luminol-dependent chemiluminescence (LDCL). In the present study we tested the effect of LPG present on live parasites on monocyte activity. For this purpose, we used two mutant strains deficient in LPG and two LPG-containing strains. One pair was Leishmania major and the other Leishmania donovani. Monocytes in suspension were infected with the different parasite strains and tested for chemotactic locomotion and LDCL at different times between 1 and 72 hr after infection. In parallel, the percentage of infected monocytes was measured in stained cytospin preparations. The results obtained showed that at 1 hr of incubation only the LPG-containing strains inhibited chemotaxis, while the mutant strains showed a normal response. From 4 hr of incubation onwards, the mutant strains also inhibited monocyte chemotactic locomotion. LDCL was only slightly inhibited by the LPG-containing strains after 1 hr, because of a high level of spontaneous stimulation, probably due to phagocytosis. At 24 and 72 hr all strains inhibited LDCL. These results suggest that LPG is responsible for early inhibition of macrophage activity, but that other factors are responsible for inhibition at later stages of in vitro infection. The model described here might represent a useful tool to further analyze the mechanisms involved in immune evasion of Leishmania parasites.