Inhibition of activity of human NK and K cells by simple sugars: discrimination between binding and postbinding events

The Mannose Receptor Mediates Induction of IFN-α in Peripheral Blood Dendritic Cells by Enveloped RNA and DNA Viruses

Peripheral blood dendritic cells (DC) produce IFN-α in response to challenge by many enveloped viruses including herpes simplex virus (HSV) and HIV, whereas Sendai virus predominantly stimulates IFN-α production by monocytes. Glycosylated viral envelope proteins are known to be important for the induction of IFN-α. In this study we demonstrate that stimulation of IFN-α synthesis by HSV is inhibited by a number of monosaccharides, including fucose, N-acetylglucosamine, and N-acetylgalactosamine as well as the yeast polysaccharide mannan, supporting a role for lectin(s) in the IFN-α stimulation pathway. Furthermore, antiserum to the mannose receptor (MR) also inhibited HSV, vesicular stomatitis virus, and HIV-induced IFN-α production, but failed to inhibit the IFN-α induced by Sendai virus. We further demonstrated that freshly isolated blood DC and IFN-α-producing cells responding to HSV stimulation express the MR. This study therefore implicates the MR as an important receptor for the nonspecific recognition of enveloped viruses by DC and the subsequent stimulation of IFN-α production by these viruses. Thus, the MR probably serves as a critical link between innate and adaptive immunity to viruses, especially given the role of the MR in Ag capture by DC and the importance of IFN-α in shaping immunity.

The effects of carcinogenic methylcholanthrene on carbohydrate residues of NK cells

The present study examines the effect of methylcholanthrene (MCA), a a carcinogenic polycyclic hydrocarbon, on the carbohydrate receptor determinants (RD) on natural killer (NK) cell surface using the bead-coupled lectin assay. Murine NK cells exhibited different degrees of preferential binding to the specific lectins tested. Of the ten lectins tested, five exhibited a positive binding affinity while the remaining five exhibited no or insignificant binding. NK cells bind to beads derivatized with mannose specific lectins: Concanavalin A (Con A), Lens culinaris, and Pisum sativum. NK cells also bind to other lectin beads such as Triticum vulgaris (GalNac) and Vicia villosa (D-GlcNAc). All these lectin beads exhibited greater than 90% adhesion. The underivatized control beads exhibited no NK binding. The NK cells that were exposed to MCA for 2 h demonstrated a significant decrease in lectin bead-cell coupling in a dose dependent manner. MCA (10 micrograms/mL) caused a 17.8%, 40% and 4.7% decrease in binding affinity when introduced to the mannose specific lectins; Con A, L. culinaris and P. sativum beads, respectively. The binding of T. vulgaris and V. villosa to NK cells was inhibited (23.4% and 28%) by MCA treatment. An increase in the dose to 20 micrograms/mL resulted in a greater inhibition in binding affinity towards lectin beads. Con A, 35.3%, L. culinaris, 62.6%, P. sativum, 30.9%, T. vulgaris, 44.2% and V. villosa, 46.2%. The effect of MCA activation and cytotoxic response. Hydrolysis of PI metabolites (PIP and PIP2) cause generation of secondary messenger: inositol-1,4,5-triphosphate and diacylglycerol, both of which elicit an immune response through their products (Ca2+ and PKC) respectively. Identification of the relationship between receptor level, induction of second messenger and cytotoxic activity may resolve the molecular basis of suppression of NK cytotoxicity by MCA and other PAH compounds.

Inhibition of human natural killer cell activity by platelet-derived growth factor (PDGF). III. Membrane binding studies and differential biological effect of recombinant PDGF isoforms

We have previously reported that platelet-derived growth factor (PDGF) substantially inhibits human natural killer (NK) cell cytotoxicity, and that NK cells possess high-affinity surface binding sites for the PDGF-AB isoform. In this communication, we present direct evidence for the presence of A-type (alpha) PDGF receptors on human NK cells by demonstrating that human NK cells have approximately 150,000 high-affinity, surface binding sites for recombinant (r)PDGF-AA and approximately 300,000 high-affinity, surface binding sites for rPDGF-BB. This was determined by the competitive binding of 125I-labelled rPDGF-AA or 125I-labelled rPDGF-BB and homologous unlabelled rPDGF-AA or rPDGF-BB to FACS-sorted, CD16+ lymphoid (NK) cells, and Scatchard analysis of these data. In addition, we also demonstrate that the various isoforms of PDGF have differential effects on NK-cell cytotoxicity. Physiological quantities (100 ng/ml) of rPDGF-BB homodimers, highly purified PDGF-AB heterodimers from outdated platelets, and rPDGF-AB heterodimers substantially inhibited NK-cell cytotoxicity in both a dose- and time-dependent manner. In contrast, pretreatment of NK cells with equivalent nanogram amounts of rPDGF-AA homodimers resulted in a significantly weaker inhibitory effect on NK-cell cytotoxicity as compared with the PDGF-BB and PDGF-AB isoforms. The implications of these findings are discussed.

Alterations in cell-surface carbohydrates of rat large granular lymphocytes associated with interleukin-2 activation

The activation of large granular lymphocytes (LGLs)/natural killer (NK) cells with interleukin-2 (IL-2) has been shown to increase the ability of these cells to lyse NK-resistant tumor target cells. Activated LGLs, termed LAK (lymphokine-activated killer) cells, have been demonstrated to be of therapeutic value in vivo against metastatic tumors. The mechanism by which IL-2 induces broadened cytolytic capability, as well as the molecular basis of target recognition and killing by the activated cells has not yet been elucidated. Since carbohydrate moieties have been demonstrated to be of possible significance in the cytolytic cascade of a variety of effector cells, the current study was undertaken to determine if the activation of LGLs with IL-2 is accompanied by an alteration of cell-surface carbohydrates. Two-color flow cytometry was performed to identify LGL/NK cells in populations of nylon wool-nonadherent splenic mononuclear cells and to assess the binding of various lectins to activated as well as nonactivated LGLs. Increases were observed in the binding of four lectins to LGLs after IL-2 activation; Triticum vulgaris (wheat germ agglutinin), Phytolacca americana (pokeweed mitogen), Lycopersicon esculentum (tomato lectin), and Griffonia simplicifolia I-B4 (GSI-B4). The wheat germ, pokeweed, and tomato lectins recognize complex carbohydrates structure consisting of GlcNAc(Bl,4GlcNAc)n while GSI-B4 recognizes alpha-D-galactose terminal end groups. Lectin binding to the activated LGLs was homogenous (i.e., flow cytometry revealed only a single population of fluorescent cells). Lectin binding to LGLs prior to activation was more heterogeneous, however, the tomato lectin uniquely revealed a bimodal distribution of receptors. These data indicate that LGL/NK cells from the rat are heterogeneous in their ability to bind specific lectins, and that IL-2 activation of these cells results in altered expression of specific cell-surface carbohydrates.

Biology of natural killer cells

Studies of cytotoxicity by human lymphocytes revealed not only that both allogeneic and syngeneic tumor cells were lysed in a non-MHC-restricted fashion, but also that lymphocytes from normal donors were often cytotoxic. Lymphocytes from any healthy donor, as well as peripheral blood and spleen lymphocytes from several experimental animals, in the absence of known or deliberate sensitization, were found to be spontaneously cytotoxic in vitro for some normal fresh cells, most cultured cell lines, immature hematopoietic cells, and tumor cells. This type of nonadaptive, non-MHC-restricted cellmediated cytotoxicity was defined as “natural” cytotoxicity, and the effector cells mediating natural cytotoxicity were functionally defined as natural killer (NK) cells. The existence of NK cells has prompted a reinterpretation of both the studies of specific cytotoxicity against spontaneous human tumors and the theory of immune surveillance, at least in its most restrictive interpretation. Unlike cytotoxic T cells, NK cells cannot be demonstrated to have clonally distributed specificity, restriction for MHC products at the target cell surface, or immunological memory. NK cells cannot yet be formally assigned to a single lineage based on the definitive identification of a stem cell, a distinct anatomical location of maturation, or unique genotypic rearrangements.

Inhibition of cytolysin activity in large granular lymphocyte granules by lipids: evidence for a membrane insertion mechanism of lysis

The ability of various compounds to inhibit the lytic activity of purified cytoplasmic granules from LGL tumors was tested. The lytic activity of granule cytolysin was modestly inhibited by inorganic phosphate, and various monophosphoesters, with I50 values in the range of 8-20 mM. Among monophosphoesters, choline phosphate was exceptionally potent, with an I50 of 1.4 mM. In contrast to the inhibition by phosphate esters, the parent compounds such as neutral sugars, glycerol, and choline, showed no detectable inhibition at 50 mM. A lysolipid bearing a short aliphatic chain and some detergents were inhibitory with I50 values in the range of 1 mM. Lysolipids with longer aliphatic chains, phospholipids as liposomes, and related lipid compounds were found to display potent inhibition of the hemolytic activity of LGL granule cytolysin, with I50 values in the range of 0.2-30 microM. Soluble globular proteins inhibited LGL granule cytolysin hemolytic activity with I50 of 0.07-0.4 mg/ml. However, lipoproteins were 2-3 orders of magnitude more potent inhibitors, with L50 values of less than 1 microgram/ml. The observed potent inhibition by lipid compounds lends support to a model of the lytic action of granule cytolysin in which soluble cytolysin molecules insert into the membrane lipid bilayer during the course of the lytic event.

Carbohydrate interference of complement-dependent cell lysis

The antibody-mediated cytotoxicity of three autoreactive sera, an allogeneic hyperimmune serum and a xenogeneic hyperimmune serum was abrogated by the presence of either glucosamine, galactosamine, lactulose or lactose. This inhibition could be overcome in a dose-dependent fashion by increasing the amount of complement in the cytotoxicity assay, but not by increasing the amount of antibody. Furthermore, the inhibition was specific for these sugars in that isomers and N-acetylated derivatives were not inhibitory. The results suggest that these sugars directly blocked events of the complement cascade.

Inhibition of natural killing and antibody-dependent cell-mediated cytotoxicity by the plasma protease inhibitor alpha 2-macroglobulin (alpha 2M) and alpha 2M protease complexes

Over the past few years increasing attention has been given to the relationship between the immune response and proteases. The aim of our present study was to examine the dose-response effect of purified alpha 2-macroglobulin (alpha 2M) with varying degrees of protease (trypsin) saturation on natural killing (NK) and antibody-dependent cell-mediated cytotoxicity (ADCC). The results demonstrated that alpha 2M with 50% trypsin saturation (fast alpha 2M) was more inhibitory in both assays than alpha 2M with no bound protease (slow alpha 2M).

Human seminal plasma is a potent inhibitor of natural killer cell activity in vitro

The effect of human seminal plasma on the natural killer (NK) activity of human peripheral blood leukocytes in vitro has been investigated. Small concentrations (as low as 0.01% v/v) of seminal plasma were found to inhibit the ability of human peripheral blood leukocytes to lyse K562 target cells. These inhibitory effects were observed with seminal plasma donations from normal and infertile individuals, including those who had been vasectomised. The inhibition noted appeared to be independent of the presence of antisperm antibodies which could conceivably cross-react with NK cells. Furthermore, the factors responsible survived boiling for 15 min and could not be absorbed out with K562 target cells. These profound inhibitory effects might be relevant to malignancy of the urogenital tract and the defence against sexually transmitted disease.

Studies of human natural killer cytotoxic factor (NKCF): characterization and analysis of its mode of action

Soluble natural killer cytotoxic factors (NKCF) have been detected in the supernatant of normal mouse, rat, and human lymphocytes stimulated in vitro for 1 to 3 days in serum-free medium. Stimulation of large granular lymphocytes (LGL) with NK-sensitive targets or mitogens has resulted in high levels of NKCF production. Previous studies in the mouse and human systems have analyzed the cells responsible for production, specificity, and general characteristics of NKCF. In the present study, using human NKCF as a model for cytolysis by LGL, we have analyzed a variety of agents previously demonstrated to inhibit NK activity. These have included: (i) phosphorylated sugars; (ii) protease inhibitors; (iii) antibodies to rat LGL granules; (iv) Ca++, and Mg++; (v) lipomodulin; (vi) nucleotides; (vii) prostaglandins; and (viii) inhibitors of lysosomal enzymes. All inhibitors were tested for their effects on production of NKCF after target cell interaction, binding of NKCF to target cells, and target cell lysis (after 6-hour NKCF absorption and washing of targets). Phosphorylated sugars and antibodies to rat LGL granules were found to inhibit the lysis of targets by NKCF, whereas the other agents tested had no detectable effect (ATP, cyclic AMP, protease inhibitors, prostaglandin E2). In regard to the production of NKCF, the data indicated that (i) the absence of calcium and magnesium, (ii) prostaglandin E2, and (iii) ATP inhibited production, whereas phosphorylated sugars did not. Studies with these types of agents will now enable us to dissect the sites at which these agents function within the lytic process. In addition to the above studies, purification studies were performed using tritiated arginine to label NKCF to begin biochemical characterization of human NKCF. The results indicated that radiolabeled NKCF has an apparent molecular weight between 20,000 and 40,000. This material demonstrated a pattern of binding to target cells which was similar to the pattern of lysis by NKCF. In addition, the binding of this material was competitively inhibited by unlabeled NKCF preparations. Such approaches with radiolabeled NKCF should be useful for the further study of the biochemical characteristics of human NKCF and of its mechanism of action.