Selective adsorption of immune lymphocytes, synthesizing DNA, on corresponding target cells]

Lymphocytes of inbred mice immunized with allogenic tumour cells were labelled in vitro or in vivo by 3H-thymidine, washed out and incubated with target cells in the presence of "cold" thymidine. A fraction of labelled small and medium lymphocytes was demonstrated by autoradiography to be absorbed rapidly and specifically onto the corresponding target cells. When the non-labelled immune lymphocytes were preincubated with target cells for 2 hours, and 3H-thymidine was added to the medium at various time periods, the percentage of labelled small and medium lymphocytes which adhered to the target cells appeared to be reduced in the course of the incubation, with the target reaching the initial value after an 8-hour contact. Small and medium immune lymphocytes which synthesize DNA are supposed to be the effector killer fraction which do not transform into blasts during the interaction with the target cells.     

Functional characteristics of T cell receptors during sensitization against histocompatibility antigens in vitro

Using the mixed leukocyte culture (MLC) reaction as a model system for the generation of cytotoxic effector lymphocytes, we have examined changes which occur in recognition-binding function during T cell sensitization. Properties of recognition-binding units on normal and immune T lymphocytes were assessed through the ability of T cells to bind to specific cellular immunoadsorbants at various stages of in vitro sensitization. While antigen-specific recognition-binding function was readily detected on fully cytotoxic effector cells, we were unable to detect functionally specific binding of unsensitized lymphocytes to cellular immunoadsorbants. The ability of cells undergoing sensitization in MLC to bind specifically to target cell monolayers appeared congruent in time with cytotoxic function. These results suggest that a fundamental membrane-associated change occurring during T cell sensitization may be the development of a strong and specific target-cell binding function.     

Activity of acid phosphatase and succinate and dehydroorotate dehydrogenases during the interaction of allogeneic lymphocytes and target cells in tissue culture]

A study was made of the activity of acid phosphatase in interaction of lymphocytes and target cells; it was shown that in the lymphocytes its greatest increase occurred in the 1- and sometimes in the 3-hour cultures; sometimes the activity of the enzyme in the L-cells increased by the 3rd-6th hour. The initial activity of acid phosphatase was greater in the immune lymphocytes; later, on their addition to the L-cell culture, there was no significant difference in the changes in the activity of the enzyme in the immune and normal lymphocytes. In the L-cells the activity of acid phosphatase was lower on addition of normal lymphocytes in comparison with the immune ones. The activity of dehydrogenases in the lymphocytes increased by the 3rd hour of the incubation period and was greater in the immune lymphocytes than in the normal ones. The activity of the succininc- and dehydroorotic dehydrogenases altered practically at the same periods in the L-cells as in the lymphocytes. The intensification of the activity of the redox enzymes and of the acid phosphatase during the first hours of contact pointed to the rapid activation of the effector lymphocytes.     

Cell-mediated cytotoxicity of lymphocytes from chickens inoculated with herpesvirus of turkey against a Marek's disease lymphoma cell line (MSB-1).

Using a new device which increases the sensitivity of detection of specific immune lysis of target cells by labeling them with [35S]-methionine, the in vitro cell-mediated cytotoxic response of spleen lymphocytes and peripheral blood lymphocytes from chickens vaccinated with herpesvirus of turkey (HVT), O1 strain, against MSB-1 line cells was clearly demonstrated. The cytotoxic activity was clearly inhibited by pretreatment of effector lymphocytes with anti-T lymphocyte serum and complement. The activity was greater using T cells purified from spleen lymphocytes and peripheral blood lymphocytes than with the unfractionated cells, indicating that T lymphocytes play the main role in effector activity. Using sera from HVG-vaccinated chickens, no significant cytotoxic effects were detected in the complement-dependent antibody cytotoxicity test against MSB-1 cells. These results suggest that cellular immunity against the surface antigen of Marek's disease (MD) lymphoma cells is mainly related to the preventive mechanism against MD incidence by HVT vaccination.     

Feline cytotoxic immune mechanisms against virus-associated leukemia and fibrosarcoma

Humoral and cellular cytotoxic immune mechanisms of cats were compared against feline leukemia virus (FeLV)- and feline sarcoma virus (FeSV)-transformed cells. The groups of animals studied were nonexposed control cats; FeLV-infected immune or viremic tumor-bearing cats; FeSV-inoculated tumor progressor or regressor cats, and cats immunized with FeSV-transformed autochthonous fibroblasts (ATF). Sera containing complement-dependent antibodies (CDA), which lysed FeLV-producer lymphoma lines, had no cytotoxic effects when tested against FeLV-producer FeSV-transformed fibroblasts. Sera with lytic CDA activity were also tested for antibody-dependent cellular cytotoxic (ADCC) effects with peripheral blood lymphocytes (PBL) from nonimmune cats. No ADCC activity was detected against either lymphoid or fibroblast target lines. To demonstrate that cat PBL contained ADCC effector cells, antibody-coated murine target cells were employed and positive results obtained. Natural killer (NK) assays were performed using PBL from normal and tumor-bearing cats. Cytotoxic effects were only detectable to FeLV-producer lymphomas, and comparable levels of NK activity were found in normal and lymphoid tumor-bearing animals. In cats immunized with ATF, a population of effector cells was found in peripheral blood which had functional characteristics of cytotoxic T lymphocytes (CTL). The killing of ATF by CTL-like cells was not inhibited by FeLV/FeSV immune sera or by sera from autochthonous immune cats. The comparative importance of humoral and cellular cytotoxic mechanisms against FeLV- and FeSV-induced tumors is discussed.     

Potentiation of cell-mediated lysis of xenogemeic tumor cells: the role of antiserum and effector cells.

The development of the immune response to xenogeneic tumor cells and the mechanism of potentiation of cell-mediated cytotoxicity (CMC) by xenoantiserum were investigated. The kinetics of potentiation of CMC resembled, both qualitatively and quantitatively, the kinetics of antibody-dependent cellular cytotoxicity (ADCC) of target cells treated with the same xenoantisera. Varying proportions of immune and nonimmune effector cells did not influence the amount of lysis of antibody-treated tumor cells. It would appear, therefore, that spleens from immunized animals contained cell populations that were capable of mediating both CMC and ADCC. Potentiation of CMC would appear to result from the preferential expression of ADCC effector cells; interaction of CMC effector cells was apparently hindered by the presence of antibody on the tumor cell surface. Immune complexes formed in antibody excess may also modify ADCC and the potentiation of CMC.     

The mononuclear cell in human blood which mediates antibody-dependent cellular cytotoxicity to virus-infected target cells. II. Identification as a K cell.

Studies were carried out to determine whether the mononuclear cell in human blood which mediates antibody-dependent cellular cytotoxicity (ADCC) to herpes simplex virus (HSV)-infected target cells has surface Fc receptors which participate in the reaction. The F (ab')2 fragment of human IgG antibody was inactive both in ADCC and in complement-mediated cytolysis, but retained the capacity to neutralize infectious virus, to agglutinate erythrocytes coated with viral antigens, and to bind to the surface of virus-infected cells. Treatment of sensitized virus-infected target cells with staphylococcus protein A, which has affinity for the Fc epitope of IgG, strongly reduced their susceptibility to lysis by ADCC in a dose-dependent relationship. These findings indicate that the Fc portion of IgG antibody to the virus is necessary for cytotoxicity. Treatment of blood mononuclear cells with either heat-aggregated gamma-globulin or HSV immune complexes inhibited effector cell activity. The presence of "third party" cellular immune complexes also strongly inhibited ADCC. Adsorption of mononuclear cells to plastic surfaces coated with soluble third party immune complexes resulted in a significant reduction in effector cell activity. These findings demonstrate that the ADCC effector cell possesses surface Fc receptors which are utilized in the ADCC reaction. The presence of Fc receptors on the surface of the effector cell indicates that it is a K cell rather than a null cell.     

Human monocyte-macrophage-mediated antibody-dependent cytotoxicity to herpes simplex virus-infected cells.

Human peripheral blood mononuclear cells which mediate antibody-dependent cellular cytotoxicity (ADCC) against herpes simplex virus- (HSV) infected target cells consist of both adherent (MA) and nonadherent (MNA) effector cell populations. These two cell populations can be distinguished by their different phagocytic properties and morphologic appearance, their requirement for antibody in the ADCC reaction, and the rapidity with which they lyse target cells in the presence of immune serum. The MA cells are predominantly phagocytic and have the morphologic characteristics of monocyte-macrophages, whereas the MNA cells are nonphagocytic and appear to be small to medium-sized lymphocytes. Optimal expression of ADCC by MA cells requires higher concentrations of immune serum than does MNA cell-mediated ADCC. MA-mediated cell killing is first detectable by 8 hr and reaches completion after 24 hr of incubation. In contrast, MNA-mediated ADCC produces target cell damage by 2 hr and reaches completion at 8 hr of incubation. Unlike MNA effector cells, the MA effector cells are profoundly inhibited after preincubation with either latex or silica particles. The HSV immune status of the donor had no effect on the ability of either cell population to mediate ADCC. These data demonstrate the participation of both nonadherent mononuclear cells, presumably K cells, and monocyte-macrophages, in ADCC directed against HSV-infected target cells.     

Regulatory role for the immune complex in modulation of phagocytosis by 3-deazaadenosine

The S-adenosyl-L-homocysteine hydrolase inhibitor 3-deazaadenosine (3-DAA) modulates antibody-dependent cellular cytotoxicity (ADCC) and antibody-dependent phagocytosis (AD phi) by mouse spleen effector cells and antibody-coated erythrocyte target cells. Concentrations of this compound inhibiting ADCC caused augmentation of phagocytosis. In a modified version of these assays referred to as complement-independent cellular cytotoxicity (CICC) and complement-independent phagocytosis (CI phi), specifically immune spleen cells were the source of effector cells and antitarget antibodies. CICC and CI phi were assayed with antiserum-untreated erythrocyte target cells. Although CICC was inhibited, 3-DAA failed to induce augmentation of phagocytosis in CI phi assays. Augmentation was restored by the presence of antibody-coated targets. If 3-DAA was present before the initiation of the assay by the addition of antibody-coated targets, it also failed to augment conventional AD phi. Varying dilutions of the antiserum, used for the preparation of antibody-coated target cells, induced differential effects of 3-DAA on phagocytosis. A regulatory interaction between the target cell antigen-antibody complex and the action of 3-DAA on phagocytosis has been suggested.     

Antibody-mediated cell cytotoxicity in a defined system: regulation by antigen, antibody, and complement.

The use of a serum-free environment and target cells carrying defined amounts of radiolabeled antigen allowed a quantitative study of the role of antigen, antibody, and complement on antibody-mediated cell cytotoxicity (AbMC). For lysis to occure, a minimum number of antigen molecules must be present on the target cell. 51Cr release from target cells with lower antigen density requires larger concentration of effector cells and antibodies. Target cell-bound complement, itself unable to mediate cytotoxicity, reduces the number of IgG molecules required for lysis. The antibody and complement, however, have to be bound to the same target cell. Bystander complement-coated erythrocytes, present in the same reaction mixture with IgG-coated targets, are not lysed. Blocking of AbMC is effected only by antigen, either soluble or in immune complexes prepared in antigen excess. Antigen competes at the level of the target cell. Blocking at the level of the effector cell, by use of immune complexes prepared at equivalence or in antibody excess, is difficult to achieve. The large number of cells with Fc receptors contained in mouse spleens may explain this finding. Arming of effector cells by passive binding of immune complexes is poorly effective as a means of obtaining lysis of the target cells. In all situations, the outcome of the reaction is determined by the presence of free antibody-combining sites, alone, or in immune complexes, that are able to combine with the target cell membrane antigen. The requirements for lysis are rather stringent.     

Identification of five human lymphocyte subpopulations by their differential binding of various strains of bacteria.

The ability of human peripheral blood lymphocytes to kill antibody-coated Chang liver cells in antibody-dependent cell-mediated cytotoxicity (ADCC) can be blocked with aggregated IgG (agg-IgG) or by soluble immune complexes. Dissociation of aggregates of IgG or immune complexes from the cell surface, however, resulted in partial recovery of the ability both to bind agg-IgG and to kill in the ADCC assay. Our results indicate that “unblocking” of effector cells could occur in vivo when the concentration of circulating immune complexes is lowered.     

Generation of cytotoxic lymphocytes in the autologous mixed lymphocyte culture.

We have studied the ability of purified B lymphocytes to generate cytotoxic T lymphocytes in autologous mixed leukocyte cultures (MLC). Cytotoxic lymphocytes were produced but only autologous mononuclear cells stimulated by lipopolysaccharide (LPS) were susceptible target cells. Unstimulated mononuclear cells and purified B cells were not susceptible to killing by cytotoxic cells generated in the autologous MLC. This suggests that the target antigen may be expressed on stimulated or dividing B lymphocytes in a way that renders the cells more susceptible to cytolysis. Autologously stimulated cytotoxic effector cells were found to exhibit specificity. Cy totoxicity for autologous LPS-stimulated target cells occurred but not for an allogeneic, B cell, histiocytic lymphoma cell line. It is postulated that cytotoxic T cells generated in the autologous MLC may play a role in immune surveillance or in regulation of the immune system.     

Inhibition of human natural killer (NK) activity and antibody dependent cellular cytotoxicity (ADCC) by lipomodulin, a phospholipase inhibitory protein

A highly purified preparation of lipomodulin, a phospholipase-inhibitory protein from rabbit neutrophils treated with glucocorticoids, inhibited NK and antibody-dependent cellular cytotoxicity (ADCC) activities of human peripheral blood lymphocytes in a dose-dependent manner. The presence of lipomodulin during the early period of the cytotoxicity assay was necessary to obtain maximal inhibition. The inhibition of NK or ADCC activity by lipomodulin was greater when effector cells were treated with lipomodulin than when target cells were incubated with lipomodulin. As lipomodulin did not block binding of effector cells to target cells, our results suggest that lipomodulin inhibits the cytolytic phase of NK and ADCC activities after binding to target cells, and imply that phospholipase(s) may be involved in NK and ADCC activities.     

Ultrastructure of antibody dependent cellular cytotoxicity in HSV 1 infected and uninfected Chang liver cells

The binding and ultrastructural features of antibody dependent cellular cytotoxicity (ADCC) mediated by human peripheral blood lymphocytes were studied in herpes simplex virus type I (HSV-1) infected Chang liver (CL) cells plus human anti-HSV-1 serum, and in uninfected CL cells plus guinea pig anti-CL antiserum. Non-cytolytic controls included target cells treated with normal serum in place of sensitized targets and heat shocked lymphocytes instead of normal lymphocytes. By transmission electron microscopy, target cell membranes were either broadly indented by effector cells or locally invaginated by means of effector cell filopodia. In neither case did the indentation appear to break the plasma membrane of the target. Control preparations showed only non-indented areas of simple membrane contact. By scanning electron microscopy, the effector lymphocytes in both the active ADCC and normal serum control preparations had a sparse distribution of short microvilli over their surfaces. The majority of heat shock control lymphocytes appeared normal, but 12-20% demonstrated surface patches devoid of microvilli. The hypothesis that ADCC may involve a three-step process is discussed.     

Lymphocyte-mediated cytotoxicity to autologous cells infected with measles virus. II. Specificity of the cytotoxic reaction and characterization of the effector cells involved.

The mechanism of lymphocyte-mediated cytotoxicity to cells infected with measles virus was investigated. Cytotoxicity was measured in a direct assay, immediately after the isolation of lymphocytes from human peripheral blood; mononuclear leukocytes, infected with measles virus in vitro, served as autologous target cells. Virus-specific cytotoxicity required the presence of both IgG antibodies against measles virus and of effector lymphocytes. The effector lymphocytes had Fc receptors and were mainly present in a fraction of non-T lymphocytes. Monocytes were not cytotoxic but rather inhibitory. These results indicate that lysis of virus-infected cells in this direct assay is due to antibody-dependent cellular cytotoxicity (ADCC), caused by K cells. Control experiments showed that the virus-infected target cells were sensitive to incubation with human serum or IgG, resulting in a nonspecific increase of ⁵¹Cr release; however, this did not affect the results of K-cell cytotoxicity. Maximal virus-specific lysis by ADCC did not reach the level obtained by complement-dependent cytotoxicity. Possible explanations for this difference are discussed.     

Immunoproteomics: Mass spectrometry-based methods to study the targets of the immune response

The mammalian immune system has evolved to display fragments of protein antigens derived from microbial pathogens to immune effector cells. These fragments are typically peptides liberated from the intact antigens through distinct proteolytic mechanisms that are subsequently transported to the cell surface bound to chaperone-like receptors known as major histocompatibility complex (MHC) molecules. These complexes are then scrutinized by effector T cells that express clonally distributed T cell receptors with specificity for specific MHC-peptide complexes. In normal uninfected cells, this process of antigen processing and presentation occurs continuously, with the resultant array of self-antigen-derived peptides displayed on the surface of these cells. Changes in this peptide landscape of cells act to alert immune effector cells to changes in the intracellular environment that may be associated with infection, malignant transformation, or other abnormal cellular processes, resulting in a cascade of events that result in their elimination. Because peptides play such a crucial role in informing the immune system of infection with viral or microbial pathogens and the transformation of cells in malignancy, the tools of proteomics, in particular mass spectrometry, are ideally suited to study these immune responses at a molecular level. Here we review recent advances in the studies of immune responses that have utilized mass spectrometry and associated technologies, with specific examples from collaboration between our laboratories.     

Antibodies to human immunodeficiency virus in human sera induce cell-mediated lysis of human immunodeficiency virus-infected cells

The capacity of human immunodeficiency virus (HIV) antibody-positive sera from homosexually active men without acquired immune deficiency syndrome to lyse the HIV-infected T cell lines MOLT-4f and CCRF-CEM (CEM) in cooperation with lymphocytes from normal donors was investigated. Twenty-seven HIV antibody-positive sera, most of which enhanced the killing of HIV-infected MOLT-4f and CEM target cells by normal mononuclear cells were studied in detail. HIV antibody-positive sera resulted in lysis at dilutions as high as 1/10,000. HIV antibody-negative sera did not augment lysis of infected target cells. In addition, lysis of uninfected targets was not enhanced in the presence of HIV antibody-positive sera. Because fractionation of the HIV antibody-positive sera on a protein A affinity column resulted in recovery of the activity from the IgG fraction, the extra cytotoxic activity mediated by nonimmune cells in the presence of immune sera appears to be antibody-dependent. Furthermore, the cytotoxic effector cells were in the nonrosetting fraction of lymphocytes and expressed Leu-11 (cluster designation (CD)15) antigens, which is characteristic of cells participating in antibody-dependent cellular cytotoxicity reactions. The antibody specificity of the sera, determined by radioimmunoprecipitation, provides evidence that antibody-dependent cellular cytotoxicity can occur even when there are no detectable antibodies directed against gag proteins. Sera which lacked detectable antibodies to the envelope protein gp120 by radioimmunoprecipitation did not mediate antibody-dependent cellular cytotoxicity.     

Studies on the specificity of in vitro induced lymphocytotoxicity to SV40-transformed fibroblasts.

Cytotoxic effector lymphocytes were induced by in vitro immunization of lymph node and spleen cells from AKR-mice (H-2k) and from BALB/c-mice (H-2d) to syngeneic SV40-transformed fibroblasts. The T cell-dependent cytotoxicity was specific for target cells expressing the same H2-specificity as the immunizing cells. Nontransformed fibroblasts as stimulator cells did not induce efficient cytotoxicity to transformed or nontransformed target cells. Incubation with phytohemagglutinin during the sensitization period modified the specificity of the T cell-mediated lysis of syngeneic SV40-transformed fibroblasts: allogeneic as well as syngeneic target cells were destroyed by these effector cells. However, the polyclonal stimulant activates preferentially cytotoxicity to H2-matched target cells. The in vitro generation of cytotoxic effector cells was restricted to living SV40-transformed fibroblasts as immunizing cells; it was not possible to immunize lymphocytes in the presence of membrane proteins prepared from the SV40-transformed cells. The cytotoxicity of the in vitro immunized lymphocytes was inhibited by incubation with membrane protein preparations from syngeneic or allogeneic SV40-transformed fibroblasts.     

Inhibition of human antibody-dependent cellular cytotoxicity, cell-mediated cytotoxicity, and natural killing by a xenogeneic antiserum prepared against "activated" alloimmune human lymphocytes

Xenogeneic antiserum (RH1) was prepared in Lewis rats by hyperimmunization with concanavalin A- (Con A) activated alloimmune human lymphocytes. The antiserum RH1 effectively inhibited human antibody-dependent cellular cytotoxicity (ADCC), cell-mediated cytotoxicity (CMC), and natural killing (NK) in the absence of complement (C). Inhibition by RH1 was dependent on the dilution of antiserum employed and the number of cytotoxic lymphocytes present during cytolysis. Pretreatment of lymphocytes with RH1 or the presence of RH1 in culture did not inhibit lymphocyte proliferation stimulated by Con A, phytohemagglutinin, or allogeneic cells; lymphokine production as measured by leukocyte-inhibiting factor production; antibody-dependent C lysis; or CMC mediated by murine cytotoxic T lymphocytes. Analysis of the mechanism of inhibition of cytotoxicity by RH1 revealed that 1) RH1 was not cytotoxic for human lymphocytes at 37 degrees C in the absence of C; 2) purified F(ab')2 fragments were equally inhibitory as whole serum; 3) pretreatment of lymphocytes with RH1 effectively inhibited their capacity to mediate ADCC, CMC, or NK, and this effect was reversible by culturing the cells overnight at 37 degrees C; 4) RH1 did not inhibit target cell binding by K cells, effector cells of ADCC, or alloimmune T cells, but did inhibit binding by NK cells; and finally, 5) the addition of RH1 to preformed lymphocyte-target conjugates in a single cell cytotoxicity assay inhibited killing of the bound target cells in all three systems without disrupting the conjugates. Collectively, these findings suggest that RH1 antiserum interacts with structures present on the surfaces of cytotoxic lymphocytes that are involved in the activation of the lytic mechanism(s) or with the actual lytic molecule or molecules themselves. Furthermore, the ability of RH1 to inhibit ADCC, CMC, and NK during the post-binding cytolytic phase of these reactions indicates that binding and cytolysis are distinct and separate events in all types of cell-mediated cytolysis.     

Characteristics of cytotoxic t-lymphocytes eluted from allogenic target cells]

Gain in the specific cytotoxic effect of immune lymphocytes after their absorption on the corresponding target cells (TC) and subsequent elution with pronase was caused not by the increase of the cytotoxic activity of individual cells, but by the quantitative enrichment of the population with the effector T-cells. Eluted and the initial immune lymphocytes failed to differ by the kinetics of absorption on the TC. The eluted lymphocyte fraction was characterized by a two fold increase in the T-cell content and a 4-5-fold increase in the number of DNA-synthesizing cells on account of an increase in the content of medium and large lymphocytes.