Nicotinamide protects target cells from cell-mediated cytolysis

Nicotinamide in concentrations of 5 mM and greater protected fibroblast target cells from lysis by lymphokine-activated killer cells (LAK cells). Protection was concentration dependent and was exerted at the level of the target cell. Nicotinamide did not interfere with effector-target cell conjugate formation or with the calcium dependent triggering step of the lytic process. Target cell lysis in cultures without nicotinamide was accompanied by fragmentation of target cell DNA. The DNA of target cells cultured with LAK cells in the presence of nicotinamide remained intact. 3-Aminobenzamide which, like nicotinamide, inhibits poly(ADP-ribose) synthetase but is not a precursor of NAD, was an effective inhibitor of target cell lysis while nicotinic acid, an alternative precursor of NAD in cells, was not. The data point to a central role for poly(ADP-ribose) synthetase in the events leading up to DNA fragmentation and the release of 51Cr from target cells damaged by lymphokine-activated killer cells.     

Direct tumor lysis by NK cells uses a Ras-independent mitogen-activated protein kinase signal pathway

Destruction of tumor cells is a key function of lymphocytes, but the molecular processes driving it are unclear. Analysis of signal molecules indicated that mitogen-activated protein kinase (MAPK)/extracellular regulated kinase 2 critically controlled lytic function in human NK cells. We now have evidence to indicate that target ligation triggers a Ras-independent MAPK pathway that is required for lysis of the ligated tumor cell. Target engagement caused NK cells to rapidly activate MAPK within 5 min, and PD098059 effectively blocked both MAPK activation and tumoricidal function in NK cells. Target engagement also rapidly activated Ras, detected as active Ras-GTP bound to GST-Raf-RBD, a GST fusion protein linked to the Raf protein fragment containing the Ras-GTP binding domain. However, Ras inactivation by pharmacological disruption with the farnesyl transferase inhibitor, FTI-277, had no adverse effect on the ability of NK cells to lyse tumor cells or to express MAPK activation upon target conjugation. Notably, MAPK inactivation with PD098059, but not Ras inactivation with FTI-277, could interfere with perforin and granzyme B polarization within NK cells toward the contacted target cell. Using vaccinia delivery of N17 Ras into NK cells, we demonstrated that IL-2 activated a Ras-dependent MAPK pathway, while target ligation used a Ras-independent MAPK pathway to trigger lysis in NK cells.     

In vitro generation of human activated lymphocyte killer cells. II. N-acetyl-D-galactosamine inhibits a distinct subpopulation of human activated lymphocyte killer cells generated in mixed lymphocyte culture

A range of monosaccharides was tested for its ability to inhibit the generation of cytotoxic cells during mixed lymphocyte culture. The most discriminatory effect was produced by N-acetyl-D-galactosamine (NADG). The presence of this sugar at the initiation of the coculture significantly inhibited in a dose-dependent manner the induction of a subset of nonspecific activated lymphocyte (ALK) cells preferentially able to lyse the K562 target cell (natural killer, NK-like cells) but had no effect on the generation of either specific cytotoxic T lymphocytes or another separate subset of ALK cells mediating lysis of an NK-insensitive melanoma cell line. The addition of conditioned medium containing interleukin 2 and interferon (IFN) at the start of culture reversed the inhibitory effect of the sugar. Under conditions of limiting dilution, the frequency of NK-like precursors ranged from 1/50 to 1/1200 with different mononuclear cells (MNC) and in all cases the presence of NADG from Day 0 of culture selectively decreased the frequency of these precursors. At the concentrations used NADG had no effect on NK-like cell cytolysis once generated. The addition of recombinant gamma-IFN did not abrogate the inhibitory effect of NADG and in MLC of some individuals decreased the frequencies of ALK cell precursors. These data provide further evidence for the heterogeneity of ALK cells and indicate that what is usually referred to as NK-like cell activity in in vitro culture is mediated by a subpopulation of MNC which are activated and induced to differentiate along a pathway independent of that of other ALK subsets.     

Spatial Heterogeneity and Peptide Availability Determine CTL Killing Efficiency In Vivo

The rate at which a cytotoxic T lymphocyte (CTL) can survey for infected cells is a key ingredient of models of vertebrate immune responses to intracellular pathogens. Estimates have been obtained using in vivo cytotoxicity assays in which peptide-pulsed splenocytes are killed by CTL in the spleens of immunised mice. However the spleen is a heterogeneous environment and splenocytes comprise multiple cell types. Are some cell types intrinsically more susceptible to lysis than others? Quantitatively, what impacts are made by the spatial distribution of targets and effectors, and the level of peptide-MHC on the target cell surface? To address these questions we revisited the splenocyte killing assay, using CTL specific for an epitope of influenza virus. We found that at the cell population level T cell targets were killed more rapidly than B cells. Using modeling, quantitative imaging and in vitro killing assays we conclude that this difference in vivo likely reflects different migratory patterns of targets within the spleen and a heterogeneous distribution of CTL, with no detectable difference in the intrinsic susceptibilities of the two populations to lysis. Modeling of the stages involved in the detection and killing of peptide-pulsed targets in vitro revealed that peptide dose influenced the ability of CTL to form conjugates with targets but had no detectable effect on the probability that conjugation resulted in lysis, and that T cell targets took longer to lyse than B cells. We also infer that incomplete killing in vivo of cells pulsed with low doses of peptide may be due to a combination of heterogeneity in peptide uptake and the dissociation, but not internalisation, of peptide-MHC complexes. Our analyses demonstrate how population-averaged parameters in models of immune responses can be dissected to account for both spatial and cellular heterogeneity.     

Kinetics of cytolytic T lymphocyte binding to target cells in suspension

Cytolytic T lymphocytes (CTL) were able to specifically bind and lyse allogeneic P815 tumor cells and LPS blast cells in suspension. An assay was developed to measure the rate of target cell binding in suspension independent of the rate of lysis. Target cell binding was found to plateau within 3 hr in suspension. The presence of free, functional CTL and targets at these plateaus was demonstrated, indicating that target cell binding was an equilibrium process. Scatchard plots were used to derive values for Kd (apparent affinity) and bmax (maximum binding). Target cell binding in suspension could not be blocked by purified plasma membranes. Target cell binding was compared for CTL generated by secondary in vitro stimulation with intact cells or with purified membranes. These 2 CTL populations yielded distinct values for Kd and bmax. Implications of this kinetic difference for CTL recognition of purified plasma membranes are discussed.     

Cellular origin of cytotoxic effectors and secondary educated lymphocytes in human mixed leukocyte reaction

Human lymphocytes sensitized in vitro during a mixed leucocyte reaction (MLR) against an allogeneic-stimulating cell respond by blast transformation and generation of specific cytotoxic effector cells. Both proliferation and cytotoxicity are maximum on Days 6 and 7 of culture. On Day 14, no more dividing cells or cytotoxic cells are detected in such primary cultures. Restimulation by the specific priming cell triggers a secondary proliferative response and rapid reappearance of specific cytotoxic effector cells. The velocity sedimentation cell separation method which separates cells according to their size was applied to human lymphocytes sensitized in vitro during an MLR on Day 7 of culture. Blast cells were separated from nondividing small lymphocytes. It was shown that: (1) cytotoxic effectors generated at the peak of a primary response are exclusively present in the isolated blast population; (2) highly cytotoxic secondary effector cells are induced to reappear mainly from the blast-derived population upon restimulation; and (3) secondary educated proliferative cells mainly derive from the blast population. Conversely, the blast-depleted small lymphocyte population is operationally depleted of cells able to respond by proliferation to the priming cell while responding normally against third party control cells. HLA-D region specificity of the secondary proliferative response is suggested.     

Effects of sodium periodate modification of lymphocytes on the sensitization and lytic phases of T cell-mediated lympholysis.

Sensitization of mouse splenic lymphocytes in vitro with sodium borohydride, suggesting that the biologic effects of sodium periodate are-treated autologous spleen cells stimulated a one-way mixed lymphocyte reaction and led to the generation of thymus-derived cytotoxic effector cells. These effectors were capable of lysing in 4 hr periodate-treated syngeneic and, to a lesser extent, periodate-treated allogeneic target cells. These results suggest that sensitization by periodate-treated autologous cells could result either from a specific reaction to modified self components or from a nonspecific mitogenic stimulation. Effector cells generated by allogeneic sensitization were detected on periodate-modified targets, irrespective of the H-2 antigens expressed by the targets. The effects of periodate modification on both stimulator and target cells were reversible by sodium periodate are dependent on the formation of a free aldehyde group on cell surface glycoproteins. Pretreatment of stimulator cells with neuroaminidase prevented the effect of periodate treatment, suggesting that the sensitization involves oxidized sialic acid residues. During the 4-hour 51Cr-release assay periodate-treated targets could be used to detect cytotoxic effector cells of any specificity. Fresh spleen cells and lymphocytes cultured for 5 days without antigen or in the presence of lipopolysaccharide did not lyse periodate-treated targets. An increasing level of cytotoxicity was detected on periodate-treated targets when the effector cells were generated, respectively, by stimulation with concanavalin A, by sensitization with periodate-modified autologous cells. Although the lysis of periodate-treated targets is itself nonspecific, effector cell specificity could be determined by selective blocking of the lytic phase with cells syngeneic to the stimulators. These results indicate that a nonspecific interaction can occur between lymphocytes and periodate-treated target cells, but that this interaction leads to lysis only when the lymphocytes were activated to become cytotoxic effectors.     

Target cell recognition structures in LDCC and ODCC

Cytotoxic T lymphocyte effector cells specific for a defined class I antigen can kill target cells displaying a wide range of different class I proteins in the presence of certain lectins and oxidizing agents. However, optimal lysis of the target cell (TC) still requires interaction of the CTL with the TC class I proteins. This raises the question of how the lectin or oxidizing agent alters the system in such a way that an "inappropriate" CTL-TC interaction takes place, in a class I-dependent manner. In this study we show that if papain-sensitive molecules are cleared from the TC surface and are allowed to regenerate in the presence of tunicamycin, the cells still serve as targets in direct, class I antigen-specific CTL killing, but not in LDCC or ODCC. Target cells treated in this way display N-linked carbohydrate-less class I proteins, and presumably other N-linked carbohydrate-less, papain-sensitive molecules as well. We present data showing that both types of molecules are important in nonspecific lytic reactions.     

The role of Ca2+ in activation of mature cytotoxic T lymphocytes for lysis

We carried out a detailed analysis of the requirement for Ca2+ in the lysis of target cells by cloned cytotoxic T lymphocytes (CTL). In direct, antigen-specific lysis we always observed an influx of Ca2+ into the CTL concomitant with target cell binding. However, we never observed an increase in CTL Ca2+ content during lectin-mediated lysis, or nonspecific lysis by phorbol myristate acetate-induced CTL. We found that in all three types of lysis (direct, lectin-mediated lysis, C or phorbol myristate acetate-induced) the requirement for Ca2+ in lysis was dictated by the target cell used; the same CTL can kill one target cell in the absence of detectable Ca2+, and absolutely require Ca2+ for the lysis of another target cell. Target cell killing, when it occurred in the absence of Ca2+, was accompanied by microtubule organizing center reorientation in the CTL, showing that this function is not uniformly Ca2+ dependent. These results provide further evidence that Ca2+ is not always required for activation of the lytic pathway in CTL, although Ca2+ may be absolutely required for other CTL functions such as interleukin production or expression of the interleukin 2 receptor.     

Design Parameters for Granzyme-Mediated Cytotoxic Lymphocyte Target-Cell Killing and Specificity

Cytotoxic lymphocytes are key elements of the immune system that are primarily responsible for targeting cells infected with intracellular pathogens, or cells that have become malignantly transformed. Target cells are killed mainly via lymphocyte exocytosis of specialized lysosomes containing perforin, a pore-forming protein, and granzymes, which are proteases that induce apoptosis. Due to its central role in lymphocyte biology, as well as its implication in a host of pathologies from cancer to autoimmunity, the granzyme-perforin pathway has been the subject of extensive investigation. Nevertheless, the details of exactly how granzyme and perforin cooperate to induce target-cell death remain controversial. To further investigate this system, we developed a biophysical model of the immunological synapse between a cytotoxic lymphocyte and a target cell using a spatial stochastic simulation algorithm. We used this model to calculate the spatiotemporal evolution of granzyme B and perforin from the time of their exocytosis to granzyme internalization by the target cell. We used a metric of granzyme internalization to delineate which biological processes were critical for successful target-cell lysis. We found that the high aspect ratio of the immunological synapse was insufficient in this regard, and that molecular crowding within the synapse is critical to preserve sufficient concentrations of perforin and granzyme for consistent pore formation and granzyme transfer to target cells. However, even when pore formation occurs in our model, a large amount of both granzyme and perforin still escape from the synapse. We argue that a tight seal between the cytotoxic lymphocyte and its target cell is not required to avoid bystander killing. Instead, we propose that the requirement for spatiotemporal colocalization of granzyme and perforin acts as an effective bimolecular filter to ensure target specificity.     

Tumor cell killing by macrophages activated in vitro with lymphocyte mediators: I. Development of a short term in vitro microcytotoxicity assay

We describe a short term in vitro microcytotoxicity assay to study the killing by macrophages of adhering tumor cells prelabeled with [³H]proline. With this assay, killing of line 1 hepatoma cells can be demonstrated within 6 hr of cocultivation with normal macrophages activated in vitro with the lymphocyte mediator macrophage activating factor (MAF).The data show that the decrease in residual adhering radioactivity, on which the calculations of percent kill are based, results from the lysis as well as from the detachment of tumor cells. However, detached tumor cells fail to exclude trypan blue and are no longer capable of DNA and protein synthesis. This suggests that the detachment of intact but nonviable tumor cells precedes actual target cell lysis in this system.     

Studies on the specificity of in vitro-induced lymphocytotoxicity to methylcholanthrene-induced fibrosarcoma cell lines

Cytotoxic effector lymphocytes were induced by in vitro immunization of lymph node and spleen cells from CS7B16(H2^b) and Balb/c(H2^d) mice to syngeneic or allogeneic methylcholanthrene-induced fibrosarcoma (MCAF) cell lines. The T cell-dependent cytotoxicity was specific to target cell lines to which the lymphocytes were immunized in vitro. Normal fibroblasts as stimulator cells did not induce lymphocytotoxicity to syngeneic MCAF cells or to normal syngeneic fibroblasts. The results indicate that the in vitro-immunized lymphocytes recognize individual specific tumor-associated antigens of the MCAF cells. In experiments in which the lymphocytes were immunized in vitro to allogeneic MCAF cells, cytotoxic reactions to alloantigens, but not to tumor-associated antigens, were detected. Incubation with phytohemagglutinin (PHA) during the sensitization period modified the specificity of the cell-mediated lysis of MCAF cells: Allogeneic as well as syngeneic target cells were destroyed by these effector cells. PHA induced a nonspecific cytotoxic effect which increased the specific lysis of target cells. The cytotoxicity of the in vitro-immunized lymphocytes was inhibited by incubation with membrane protein preparations from the syngeneic MCAF cell lines. In contrast to the specificity of the cytotoxic effect to the different syngeneic cell lines, the membrane extract of one individual syngeneic MCAF cell line was able to inhibit the lymphocytotoxicity to all other syngeneic cell lines. Membrane protein preparations from allogeneic MCAF cells or from normal syngeneic fibroblasts were not inhibitory. The in vitro-immunized cytotoxic lymphocytes did not impair the tumor growth in vivo as could be demonstrated by passive transfer of the lymphocytes in a Winn assay.     

THE MECHANISM OF LYMPHOCYTE-MEDIATED CYTOTOXICITY

1. Three classes of cytotoxic lymphocyte are discussed: thymus-derived T cells, antibody-dependent K cells and NK (natural killer) cells. Each of these cytotoxic lymphocytes has receptors allowing the formation of adhesions (contact) with a target cell (the cell to be killed). The type of receptor and the corresponding ligand on the target cell is different in each class. Cytotoxic T cells (and probably NK cells) react with a target cell antigen, in a manner rather like antibody-antigen reactions (although not involving classical serum antibody). K cells have a receptor for the Fc part of immunoglobulin (IgG) and hence can make contact with antibody-coated target cells. 2. It seems likely that all three classes of cytotoxic lymphocyte have a similar basic mechanism of killing, which is different from the membrane leakage occurring in complement-mediated lysis. Much more information is available on cytotoxic T cells than on the other types of cell. 3. Cytotoxic T cell killing can be divided into two phases. A reversible phase in which the T cell is in contact with the target cell, but causes no apparent damage. This phase can vary from a few minutes up to several hours, when a single T cell interacts with a single target cell. If the T cell detaches or is inactivated the target cell survives. The second phase is irreversible, once the lethal event has occurred, and the target cell will progress to eventual lysis in the absence of the Tc cells. 4. The lethal event initiates a period of zeiosis (membrane blebbing) in the target cell, which is accompanied by increased effiux of ⁸⁶rubidium. Cell lysis occurs at a variable time after the initiation of zeiosis, when the soluble contents of the cytoplasm burst out of the target cell. The fact that both these phases are of variable length leads to the accumulation of cytoplasmic markers (such as ⁵¹chromium) in the medium in an approximately linear fashion. 5. The nature of the lethal event is unknown, but it is suggested that it involves changes inside the target cell rather than at the target cell membrane. Remarkable long projections from the T cell (and also seen from K cells and NK cells), apparently arising as a result of the receptor-ligand interaction, may be involved in the delivery of the lethal event.     

In situ effector pathways of allograft destruction. 1. Generation of the "cellular" effector response in the graft and the graft recipient

Inflammatory leukocytes of DA-to-WF rat renal allografts displayed significant cytolytic activity to natural killer (NK) target cells on Day 2 after transplantation. The NK activity, which was associated with large granular lymphocytes in discontinuous Percoll gradients, peaked on Day 4 and disappeared rapidly thereafter. Coincident with the presence of NK activity in the graft, a decrease in NK activity in the recipient spleen was observed. Low NK activity was also recorded in WF-to-WF autografts. The cells displaying direct cytotoxic activity to donor (but not to recipient) strain peritoneal exudate target cells (PEC) were associated with the T suppressor/killer lymphocytes in affinity chromatography. They appeared in the graft between Days 2 and 4, peaked between Days 6 and 8 and disappeared slowly thereafter. In the spleen the cytotoxic T lymphocyte (CTL) activity appeared later and it reached a maximum between Days 16 and 20 before decreasing. In the blood distinct CTL activity was seen only from Days 16-20 onwards, after the graft had been rejected. No CTL activity was recorded in the graft, blood, or spleen of an autograft recipient. Addition of donor-directed post-transplantation antibody (antibody-dependent cellular cytotoxicity, ADCC) had a slight enhancing effect on the cytotoxic activity of inflammatory leukocytes up to Day 5. After this time, added antibody had a blocking effect on direct CTL activity. No ADCC activity was recorded in the inflammatory population of an autograft. On the contrary, high levels of ADCC activity to donor strain PEC were recorded in the spleens of both autograft and allograft recipients throughout the period of follow-up. The results demonstrate that at least three cellular effector pathways exist in an allograft: a strong natural killer cell component, a strong cytotoxic T lymphocyte component, and (possibly) a weak cell component participating in an ADCC type of cytotoxicity.     

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.     

Natural killer cell-mediated lysis involves an hydroxyl radical-dependent step

The role of oxygen radicals in lysis of K562 target cells by human natural killer (NK) cells was determined by addition of scavengers of these free radicals. Lysis was greatly reduced under hypoxic conditions. Superoxide dismutase and cytochrome c, scavengers of superoxide anions, and catalase and scavengers of hypochlorite had no effect on lysis. Of 15 hydroxyl radical scavengers tested, 13 inhibited lysis. These were not toxic, because cell morphology and spontaneous chromium release were not affected and preculture with scavengers was not inhibitory. These scavengers differed widely in structure, but degree of inhibition of lysis correlated with their rate constants (k) for reaction with hydroxyl radical (k vs log inhibitor concentration required to decrease lysis by 50%: r = -0.9202, p less than 0.001), showing that inhibition was due to inactivation of the hydroxyl radical. Target cell binding was not reduced at concentrations that inhibited lysis. Inhibitors of the lipoxygenase pathway also decreased lysis, suggesting this pathway to be the source of hydroxyl radicals. In view of the reported requirements for hydroxyl radical-mediated lipid peroxidation for optimal secretory activity in a number of cell types, it appears that the generation of hydroxyl radicals by NK cells is required for delivery of cytotoxic factors.     

Cell-mediated and glucocorticoid-mediated target cell lysis do not appear to share common pathways

Target cell lysis by cytolyic lymphocytes follows a sequence of events that culminate in osmotic destruction of the target. Although it is clear that killer cell derived components play a crucial role in target cell lysis it is not clear to what extent the target itself is involved in its destruction. Recent observations have pointed to the possibility that glucocorticoid mediated and cell mediated lysis may utilize common pathways of cell lysis. In analyzing this question we found that cell lines that have nonfunctional glucocorticoid receptors like S49-78 and S49-88 are good targets for both NK and thymus-derived killer (TK) cells. Cell lines that are glucocorticoid sensitive such as Q1(4)6 are sensitive to NK-mediated lysis as its derivative HL4-6-3 which contains glucocorticoid receptors but is glucocorticoid resistant. An intriguing exception to this is the glucocorticoid-resistant mutant S49-4RD which is relatively resistant to both NK and TK lysis compared with parent S49. The resistance of S49-4RD to cell-mediated lysis we show here is most likely due to a defect in the target which results in its failure to trigger the cytolytic machinery in the killer cell rather than in its resistance to lysis per se. In support of this we demonstrate that lysis of S49-4RD by cytolytic granules from TK cells is normal. Moreover TK cells lyse S49-4RD as efficiently as its parent in the presence of the lectin Con A. The conclusion that S49-4RD has a defect in its ability to induce killer cells to initiate the cytolytic reaction is also in agreement with the finding that TK-S49-4RD conjugates show inefficient reorientation of the Golgi apparatus in the effector.     

Immunologic monitoring studies in advanced cancer patients treated with recombinant human gamma interferon (IFN-gamma 4A)

Thirty-nine patients with a variety of advanced malignancies were treated with recombinant IFN-gamma 4A (AMGen, specific activity 1 to 5 x 10(7) U/mg protein). IFN-gamma 4A was administered at a dose of 10-2,000 micrograms/m2/d. Following a 2-week rest, a maintenance phase was continued with injections 3 d/wk. Immunologic monitoring studies were performed on patients' peripheral blood cells before administration of IFN-gamma 4A, then on Days 15 and 90. Flow cytometric analysis was used to determine the absolute number of CD 3+, CD 4+, CD 8+, CD 19+, and CD 16+ cells using a panel of monoclonal antibodies. Natural killer (NK) cell function was assayed by monitoring lysis of the K562 cell line in the Cr51 release assay. Changes from baseline were observed on Days 15 and 90 in all parameters studied, although the ratio of helper to suppressor cells seemed to remain within the normal range. Whereas there were no substantial changes in CD 3+ and CD 4+ cells on Day 15, IFN-gamma 4A had an enhancing effect on CD 8+, CD 19+, and CD 16+ cells. This trend continued at Day 90 only for CD 19+ and CD 16+ cells at the higher dose levels. An increase in functional NK cell activity at Day 15 was less noted on Day 90. Comparison of intravenous (IV) to intramuscular-subcutaneous (IM-SC) administration showed differences in the effect on lymphocyte subpopulations at 450 and 1,000 micrograms. The effect of IFN-gamma 4A on the equilibrium among lymphocyte subpopulations and the possibility of its role in combination therapy with other biologic response modifiers are discussed.     

Transmembrane chloride flux is required for target cell lysis but not for Golgi reorientation in cloned cytolytic effector cells. Golgi reorientation, N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester serine esterase release, and delivery of the lethal hit are separable events in target cell lysis

Cell-mediated cytotoxicity can be inhibited by the replacement of chloride with ions that are incapable of passing through chloride channels or by the presence of stilbene disulfonate derivatives known to interfere with chloride flux. We show that the stilbene disulfonate (4,4-diisothiocyano-2,2'-disulfonic acid stilbene (DIDS) inhibits lysis of YAC-1 targets by the cloned cell line NKB61A2. Inhibition of lysis occurs on the level of the effector cell inasmuch as preincubation of effectors but not of targets interferes with subsequent lysis. Moreover, inhibition of chloride flux in the target does not interfere with target cell lysis by cytotoxic granules isolated from killer cells. Target cell binding takes place in the presence of DIDS or absence of external chloride, suggesting that events that follow target cell binding require chloride flux. We show that reorientation of the Golgi apparatus, which occurs subsequent to target cell binding in the effector cell, occurs under conditions that interfere with chloride flux. It is therefore suggested that events in the effector cell taking place subsequent to the Golgi apparatus reorientation reaction are inhibited and that delivery of the lethal hit is a stimulus-induced secretory event that requires transmembrane chloride flux. Delivery of the lethal hit is shown to be independent of the release of N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester (BLT) serine esterase, suggesting that cytolytic components and BLT serine esterase are likely packaged in different vesicles.     

The degree of CTL-induced DNA solubilization is not determined by the human vs mouse origin of the target cell

CTL-mediated lysis is unique among lytic mechanisms in inducing rapid, prelytic nuclear disintegration. Target cell DNA can be solubilized within minutes as a result of degradation, which can proceed to the nucleosomal level, presumably mediated by endonucleases that are either endogenous or injected by the CTL. Nuclear disintegration has been reported for mouse lymphoid target cells by several groups. However, previous studies in which human target cells were studied saw little or no DNA solubilization. We here report rapid, extensive CTL-induced solubilization of DNA in human lymphoid target cells; on the other hand, we found that three mouse cell lines exhibit little or no nuclear disintegration. We conclude that the degree of nuclear disintegration depends on the nature of the target cell, but is not determined by the species of origin of the target cell.