Extracellular ATP as a trigger for apoptosis or programmed cell death

Extracellular ATP is shown here to induce programmed cell death (or apoptosis) in thymocytes and certain tumor cell lines. EM studies indicate that the ATP-induced death of thymocytes and susceptible tumor cells follows morphological changes usually associated with glucocorticoid-induced apoptosis of thymocytes. These changes include condensation of chromatin, blebbing of the cell surface, and breakdown of the nucleus. Cytotoxicity assays using double-labeled cells show that ATP-mediated cell lysis is accompanied by fragmentation of the target cell DNA. DNA fragmentation can be set off by ATP but not the nonhydrolysable analogue ATP gamma S nor other nucleoside-5'-triphosphates. ATP-induced DNA fragmentation but not ATP-induced 51Cr release can be blocked in cells pretreated with inhibitors of protein or RNA synthesis or the endonuclease inhibitor, zinc; whereas pretreatment with calmidazolium, a potent calmodulin antagonist, blocks both DNA fragmentation and 51Cr release. The biochemical and morphological changes caused by ATP are preceded by a rapid increase in the cytoplasmic calcium of the susceptible cell. Calcium fluxes by themselves, however, are not sufficient to cause apoptosis, as the pore-forming protein, perforin, causes cell lysis without DNA fragmentation or the morphological changes associated with apoptosis. Taken together, these results indicate that ATP can cause cell death through two independent mechanisms, one of which, requiring an active participation on the part of the cell, takes place through apoptosis.     

Distinct pathways of CD4 and CD8 cells induce rapid target DNA fragmentation.

When activated with either Con A, a CD3-specific mAb, or Ag-pulsed B lymphoma (LK35.2) cells, CD4 (Th1) clones quickly induce DNA fragmentation in target cells followed by release of 51Cr-labeled intracellular materials. Both activated CD4 clones and CD8 (CTL) cells fragment target DNA into electrophoretically identical "ladder" pattern made of approximately 200 bp. The effect of various metabolic inhibitors on the ability of CD4 and CD8 cells to induce target DNA fragmentation was studied. Little effect was observed with the DNA synthesis inhibitor, mitomycin C. The RNA synthesis inhibitor, actinomycin D, and the protein synthesis inhibitor, cycloheximide, strongly inhibited the ability of CD4 cells, but not CD8 cells, to induce target DNA fragmentation. In contrast, target DNA fragmentation by CD8 cells, but not by CD4 cells, was inhibited by cholera toxin. Although cyclosporin A inhibited CD4 cells to fragment target DNA during the early phase (90 min) of E:T interaction, this inhibition was not sustained in the later phase (210 min) of the assay. Zinc ions inhibited the ability of both CD4 and CD8 cells to fragment target DNA. Treatment of effectors and targets with these inhibitors, followed by washings, demonstrated that the action of these inhibitors on effector cells alone is sufficient to inhibit target DNA fragmentation. The strong correlation among these parameters of DNA fragmentation and Cr-release assays supports the hypothesis of programed cell death. Although distinct cytolytic pathways are used by CD4 and CD8 cells to kill targets, both pathways deliver a signal that activates endonuclease(s), fragments target DNA, causes Cr-release, and lyses target cells. Taken together with our previous studies, the present findings demonstrate that activated cytolytic CD4 clones do not use perforin, serine proteases, and TNF as mediators for resistant target DNA fragmentation.     

Fas/FasL-independent activation-induced cell death of T lymphocytes from HIV-infected individuals occurs without DNA fragmentation

We assessed the effects of activation with phorbol myrystic acetate (PMA) and ionomycin on peripheral blood mononuclear cells (PBMC) from HIV-infected individuals by (51)Cr release, propidium iodide (PI) uptake, electron microscopy, and DNA analysis. Up to 70% (51)Cr release was induced from PBMC of HIV-infected individuals, versus up to 26% (51)Cr release from PBMC of non-HIV-infected volunteers. Flow cytometry identified mostly T cells undergoing activation-induced cell death (AICD). The kinetics of (51)Cr release and the effects of cold target inhibitors were consistent with cell-mediated cytotoxicity. Certain anti-CD3 antibodies or extracellular Ca(2+) chelation prevented AICD, but antagonistic anti-Fas antibodies, caspase inhibitors, and cycloheximide had no effect. The antioxidants thiourea and N-acetylcysteine reduced AICD, indicating a role for oxidative stress. Electron microscopy revealed plasma membrane disruption with nuclear integrity, while DNA analysis showed intact chromosomal DNA. This form of T cell AICD triggered by PMA and ionomycin differs from classical apoptosis in the absence of either caspase involvement or DNA fragmentation.     

Cell death mediated by alloreactive cytotoxic T cells via the granule exocytosis or the Fas pathway is independent of p34cdc2 kinase: Fas dependent killing of cells arrested in the cell cycle

Inappropriate activation of p34cdc2 kinase has been shown to occur during apoptosis induced by cytotoxic T-cell derived perforin and fragmentin. We analysed the effect of two inhibitors of p34cdc2 kinase on alloreactive Tc-cell-mediated lysis and DNA fragmentation of P815 and L1210 target cells. Olomoucine, a specific inhibitor of cyclin dependent kinases, did not affect DNA fragmentation in the target cells. Lysis of olomoucine-treated target cells as assessed by 51Cr release over a typical 8-h period was also unaffected. We also examined the effects of thapsigargin on target cell death. This toxin causes increased intracellular calcium rises that then result in irreversible inhibition of cyclin dependent kinases, including p34cdc2 kinase. The same extent of specific cell lysis was induced by cytotoxic T cells from perforin(-/-), granzyme B(-/-), granzyme A(-/-), perforin(-/-) X granzymeB(-/-) X granzymeA(-/-) KO mice or normal mice in untreated target cells or target cells treated with either olomoucine or thapsigargin. Similarly DNA fragmentation measured by release of tritiated DNA was also unaffected. Thus inhibition of p34cdc2 kinase affects neither the Fas nor the perforin/granzyme pathways of alloreactive cytotoxic T-cell killing as measured by DNA fragmentation or chromium release. P815 cells treated with olomoucine were arrested in the cell cycle after 12-16 h exposure to the toxin. After cell cycle arrest, target cells now showed enhanced 51Cr release induced by effector cytotoxic T cells (CTL) derived from perforin(-/-) mice compared to untreated cells. This lysis was accompanied by an increase in cell surface Fas expression. Olomoucine induced cell cycle arrest and expression of Fas was reversible and when cells re-entered the cell cycle, surface expression of Fas was lost.     

Differences in target cell DNA fragmentation induced by mouse cytotoxic T lymphocytes and natural killer cells

Fragmentation of YAC-1 target cell DNA during cytolysis mediated by mouse natural killer (NK) cells and cytotoxic T lymphocytes (CTL) was compared. Cleavage of nuclear chromatin was always an extensive and early event in CTL-mediated cytolysis, whereas with NK cell-mediated killing the degree of DNA fragmentation showed an unexpected relationship to the effector:target (E:T) ratio. At low NK:YAC-1 ratios, DNA fragmentation and 51Cr release were equivalent and increased proportionately until a ratio of about 50:1 was reached; at higher ratios, 51Cr release increased as expected but DNA fragmentation decreased dramatically. Comparison of time course data at E:T ratios producing similar rates of 51Cr release showed that the target cell DNA fragmentation observed in NK killing was not nearly as rapid nor as extensive as that observed with CTL effectors. These results suggest that NK cells induce target cell injury via two different mechanisms. One mechanism would involve lysis mediated by cell-to-cell contact, while the other may induce DNA fragmentation via a soluble mediator. In support of this notion, cell-free culture supernatants containing NK cytotoxic factor (NKCF) induced DNA fragmentation in YAC-1 cells. The DNA fragments induced by NK cells and NKCF-containing supernatants consisted of oligonucleosomes indistinguishable from those induced by CTL. The results presented here show distinct differences in target cell DNA fragmentation induced by CTL and NK cells, and suggest that these two effectors use different mechanisms to achieve the same end. CTL seem to induce DNA fragmentation in their targets by direct signaling, whereas NK cells may do so by means of a soluble factor.     

Responses of mouse lymphocytes to extracellular ATP. II. Extracellular ATP causes cell type-dependent lysis and DNA fragmentation

Extracellular ATP (ATPo) caused dose-dependent lysis of YAC-1 and P-815 mouse tumor cells. This event, assessed by 51Cr release, was accompanied by sustained depolarization of the plasma membrane potential and Ca2+ influx. Plasma membrane depolarization and Ca2+ influx occurred within a few seconds of ATPo addition to both cell types, whereas 51Cr was released without apparent lag in YAC-1 cells and after 2 h in P-815 cells. Furthermore, a rise in [Ca2+]i was required for ATPo-dependent lysis of YAC-1 but not P-815 cells. In P-815 cells, ATPo caused an early and [Ca2+]i-independent DNA fragmentation that occurred at lower nucleotide concentrations than those required to trigger 51Cr release. Instead in YAC-1 cells very low concentrations of ATPo caused early lysis (ED50 for lysis about 200 microM) accompanied by only barely detectable DNA fragmentation. Previous studies disclosed that lymphokine-activated killer cells are fully resistant to the membrane-perturbing effects of ATPo. We show that lymphokine-activated killer cells also do not undergo DNA fragmentation even in the presence of high ATPo concentrations. This study complements previous observations on the lytic effects of ATPo and shows that this nucleotide can also cause DNA fragmentation, one of the earliest target cell alterations observed during CTL-mediated lysis.     

DNA Fragmentation Induced by Cytotoxic T Lymphocytes Can Result in Target Cell Death

Cytotoxic T lymphocyte (CTL)-mediated lysis is accompanied by fragmentation of target cell DNA into an oligonucleosome ladder, a hallmark of apoptosis. Is this a fortuitous coincidence, or could CTL be inducing lysis by activation of the suicide signal? In this report we demonstrate that CTL-mediated target cell death can be blocked with the drug aurintricarboxylic acid (ATA). The abrogation of death correlates with the inhibition of DNA fragmentation. While ATA prevented DNA fragmentation, it failed to significantly alter protein, RNA, or DNA synthesis in the cell lines over the dose range used. In addition, there was no inhibition of cell-cell interaction or granule exocytosis during CTL-mediated killing. ATA also significantly inhibited the cytolysis and DNA fragmentation mediated by isolated cytolytic granules, as well as the granular protein fragmentin. We developed an assay in which target cells could be separated from CTL after binding and programming for lysis. Once they had received the "kiss of death," target cells could be rescued from lysis (as indicated by inhibition of DNA fragmentation and increased target cell viability) by treatment with ATA. These results suggest that ATA blocks target cell death by inhibition of DNA fragmentation, and further, that chromatin degradation is a cause rather than a result of cell death in CTL-mediated lysis.     

NSAIDs induce both necrosis and apoptosis in guinea pig gastric mucosal cells in primary culture

A major clinical problem encountered with the use of nonsteroidal anti-inflammatory drugs (NSAIDs) such as indomethacin is gastropathy. In this study, we examined, using guinea pig gastric mucosal cells in primary culture, how NSAIDs damage gastric mucosal cells. The short-term treatment of cells with high concentrations of indomethacin decreased cell viability in the absence of apoptotic DNA fragmentation, chromatin condensation, or caspase activation. Cells lost membrane integrity with this short-term indomethacin treatment, suggesting that indomethacin induced necrosis under these conditions. In contrast, the long-term treatment of cells with low concentrations of indomethacin decreased cell viability and was accompanied by apoptotic DNA fragmentation, chromatin condensation, and caspase activation. Pretreatment of cells with inhibitors of caspases or protein synthesis suppressed cell death caused by long-term indomethacin treatment, suggesting that apoptosis was induced when the inhibitors were not present. These results imply that NSAIDs cause gastric mucosal damage through both necrosis and apoptosis of gastric mucosal cells.     

Apoptosis and DNA fragmentation precede TNF-induced cytolysis in U937 cells.

The hypothesis that activation of apoptosis and DNA fragmentation is involved in TNF-mediated cytolysis of U937 tumor cells was investigated. Morphological, biochemical, and kinetic criteria established that TNF activates apoptosis as opposed to necrosis. Within 2-3 h of exposure to TNF, U937 underwent the morphological alterations characteristic of apoptosis. This was accompanied by cleavage of DNA into multiples of nucleosome size fragments. Both of these events occurred 1-2 h prior to cell death as defined by trypan blue exclusion or 51Cr release. DNA fragmentation was not a non-specific result of cell death since U937 cells lysed under hypotonic conditions did not release DNA fragments. The percentage of cells undergoing apoptosis depended on the concentration of TNF and was augmented by the addition of cycloheximide. A TNF-resistant variant derived from U937 did not undergo apoptosis in response to TNF, even in the presence of cycloheximide. Furthermore, TNF could still activate NFkB in this variant, suggesting that this pathway is not involved in TNF-mediated cytotoxicity. Two agents known to inhibit TNF-mediated cytotoxicity, ZnSO4 and 3-aminobenzamide, were shown to inhibit TNF-induced apoptosis. Taken altogether, these data support the hypothesis that activation of apoptosis is at least one essential step in the TNF lytic pathway in the U937 model system.     

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.     

Neuronal death is an active, caspase-dependent process after moderate but not severe DNA damage

Mild insults to neurons caused by ischemia or glutamate induce apoptosis, whereas severe insults induce non apoptotic death, such as necrosis. The molecular targets that are damaged by these insults and ultimately induce cell death are not fully established. To determine if DNA damage can induce apoptotic or non apoptotic death depending on the severity, neurons were treated with up to 128 Gy of ionizing radiation. Such treatment induced a dose-related increase in DNA single-strand breaks but no immediate membrane disruption or lipid peroxidation. Following moderate doses of < or = 32 Gy, neuronal death had many characteristics of apoptosis including nuclear fragmentation and DNA laddering. Nuclear fragmentation and membrane breakdown after moderate DNA damage could be blocked by inhibition of active protein synthesis with cycloheximide and by inhibition of caspases. In contrast, cell death after doses of > 32 Gy was not blocked by cycloheximide or caspase inhibitors, and membrane breakdown occurred relatively early in the cell death process. These data suggest that cell death after high dose irradiation and severe DNA damage can occur by non apoptotic mechanisms and that blocking apoptotic pathways may not prevent death after severe damage.     

Oxidative Stress Induces a Form of Programmed Cell Death with Characteristics of Both Apoptosis and Necrosis in Neuronal Cells

Abstract: Oxidative stress is implicated in a number of neurological disorders including stroke, Parkinson's disease, and Alzheimer's disease. To study the effects of oxidative stress on neuronal cells, we have used an immortalized mouse hippocampal cell line (HT-22) that is particularly sensitive to glutamate. In these cells, glutamate competes for cystine uptake, leading to a reduction in glutathione and, ultimately, cell death. As it has been reported that protein kinase C activation inhibits glutamate toxicity in these cells and is also associated with the inhibition of apoptosis in other cell types, we asked if glutamate toxicity was via apoptosis. Morphologically, glutamate-treated cells underwent plasma membrane blebbing and cell shrinkage, but no DNA fragmentation was observed. At the ultrastructural level, there was damage to mitochondria and other organelles although the nuclei remained intact. Protein and RNA synthesis inhibitors as well as certain protease inhibitors protected the cells from glutamate toxicity. Both the macromolecular synthesis inhibitors and the protease inhibitors had to be added relatively soon after the addition of glutamate, suggesting that protein synthesis and protease activation are early and distinct steps in the cell death pathway. Thus, the oxidative stress brought about by treatment with glutamate initiates a series of events that lead to a form of cell death distinct from either necrosis or apoptosis.     

Filamin (280-kDa actin-binding protein) is a caspase substrate and is also cleaved directly by the cytotoxic T lymphocyte protease granzyme B during apoptosis

We used yeast two-hybrid screening to identify the cytoskeletal protein filamin as a ligand for the proapoptotic protease granzyme B, produced by cytotoxic T lymphocytes. Filamin was directly cleaved by granzyme B when target cells were exposed to granzyme B and the lytic protein perforin, but it was also cleaved in a caspase-dependent manner following the ligation of Fas receptors. A similar pattern of filamin cleavage to polypeptides of approximately 110 and 95 kDa was observed in Jurkat cells killed by either mechanism. However, filamin cleavage in response to granzyme B was not inhibited by the caspase inhibitor z-Val-Ala-Asp-fluoromethylketone at concentrations that abolished DNA fragmentation. Filamin staining was redistributed from the cell membrane into the cytoplasm of Jurkat cells exposed to granzyme B and perforin and following ligation of Fas receptors, coincident with the morphological changes of apoptosis. Filamin-deficient human melanoma cells were significantly (although not completely) protected from granzyme B-mediated death compared with isogenic filamin-expressing cells, both in clonogenic survival and (51)Cr release assays, whereas death from multiple other stimuli was not affected by filamin deficiency. Thus, filamin is a functionally important substrate for granzyme B, as its cleavage may account at least partly for caspase-independent cell death mediated by the granzyme.     

Tumor necrosis factor induced DNA fragmentation of HL-60 cells

Tumor necrosis factor (TNF) induces differentiation of HL-60 cells, with only slight effects upon proliferation and little or no cytotoxicity. TNF induced cytotoxicity of other target cell lines has been associated with DNA fragmentation. To assess whether TNF-induced DNA fragmentation might also contribute to HL-60 differentiation, studies were performed using a [3H]-dThd release assay. Between 1 and 2 hours of culture, significant [3H]-dThd release was induced by TNF at concentrations of 10 U/ml and greater. This response was blocked by inhibiting energy metabolism, but not by several inhibitors of cell surface signal transduction, protein or RNA synthesis, or free radical scavengers. DNA electrophoresis of the released DNA disclosed a wide range of low molecular weight fragments. It is possible that TNF-induced DNA fragmentation contributes to HL-60 differentiation.     

Sensitization to death receptor cytotoxicity by inhibition of fas-associated death domain protein (FADD)/caspase signaling. Requirement of cell cycle progression

Upon binding of their ligands, death receptors belonging to the tumor necrosis factor (TNF) receptor family initiate a signaling pathway leading to the activation of caspases and ultimately apoptosis. TNF, however, in parallel elicits survival signals, protecting many cell types from cell death that can only be induced by combined treatment with TNF and inhibitors of protein synthesis. Here, we report that in NIH3T3 cells, apoptosis in response TNF and cycloheximide is not inhibited by the broad spectrum caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp-fluoromethyl ketone (zVAD. fmk). Moreover, treatment with zVAD.fmk sensitizes the cells to the cytotoxic action of TNF. Sensitization was also achieved by overexpression of a dominant-negative mutant of Fas-associated death domain protein and, to a lesser extent, by specific inhibition of caspase-8. A similar, but weaker sensitization of zVAD.fmk to treatment with the TNF-related apoptosis-inducing ligand (TRAIL) or anti-CD95 antibody was demonstrated. The unexpected cell death in response to TNF and caspase inhibition occurs despite the activation of nuclear factor kappaB and c-Jun N-terminal kinases. The mode of cell death shows several signs of apoptosis including DNA fragmentation, although activation of caspase-3 was excluded. TNF/zVAD.fmk-induced cell death is preceded by an accumulation of cells in the G(2)/M phase of the cell cycle, indicating an important role of cell cycle progression. This hypothesis is further strengthened by the observation that arresting the cells in the G(1) phase of the cell cycle inhibited TNF/zVAD.fmk-induced cell death, whereas blocking them in the G(2)/M phase augmented it.     

Apoptosis is induced in cells with cytolytic potential by L-leucyl-L-leucine methyl ester.

Previous studies have demonstrated that the selective toxicity of leucyl-leucine methyl ester (Leu-Leu-OMe) for cytotoxic lymphocytes and myeloid cells is dependent on intracellular conversion to membranolytic metabolites by the acyl transferase activity of the granule enzyme dipeptidyl peptidase I (DPPI) that is enriched in these cells. The mechanism of cell death remained unclear, however, and was the subject of the experiments reported here. When human U937, HL60, or THP-1 myeloid tumor cell lines or murine CTLL-2 cells were treated with Leu-Leu-OMe, early release of both cytosolic 51Cr and soluble [3H]TdR labeled DNA fragments was observed, whereas antibody + C treatment of these cells caused only 51Cr release. Killing of U937 or THP-1 cells by incubation with the lysosomotropic amino acid methyl ester, Phe-OMe also induced only 51Cr release without evidence of DNA fragmentation. Preincubation with Zn2+, a known inhibitor of endonuclease activity prevented Leu-Leu-OMe-induced 51Cr or [3H]TdR release from these cell lines, but had no effect on antibody + C or Phe-OMe-induced 51Cr release. Zn2+ also prevented Leu-Leu-OMe-mediated killing of normal human CD16+ NK cells. Zn2+ had no inhibitory effect on Leu-Leu-OMe uptake or intracellular conversion to (Leu-Leu)n-OMe metabolites by these cell lines. Moreover, Zn2+ did not inhibit 51Cr release from nonnucleated E or nucleated U937 targets induced by extracellular production of DPPI-generated metabolites of Leu-Leu-OMe. Thus, killing of cytotoxic lymphocytes and myeloid cells by Leu-Leu-OMe appears to be dependent on generation of metabolites with membranolytic properties, but cell death induced by this process does not involve simple lysis of the plasma membrane. Rather, intracellular production of DPPI generated (Leu-Leu)n-OMe metabolites appears to trigger, an additional Zn(2+)-sensitive process that is associated with induction of apoptosis in cells with cytolytic potential.     

Mechanisms involved in natural killer cell mediated target cell death leading to spontaneous tumour regression

We have studied the mechanisms involved in the spontaneous regression of a rat histiocytoma in syngeneic hosts and tumour cell death processes. In addition to the natural killer (NK) cells which act through antibody dependent cellular cytotoxicity (ADCC), TNF-α also participates in the induction of necrosis in tumours. We have shown that the tumour cell is killed by necrosis which is perforce mediated, and apoptosis leading to target cell DNA fragmentation. A prior activation of the effector cells is essential before it can kill the target cell, as naive effector cells are ineffective. Activation of effector cells is mediated by Thl type of cytokines in viro andin vivo. IFN-γ seems to play an important role in tumour regression as injection of antibodies to IFN-γin vivo inhibited tumour rejection.     

Primary cultured murine hepatocytes but not hepatoma cells regulate the cell number through density-dependent cell death

The mechanisms by which hepatocytes regulate their cell numbers in culture have been examined. We found that when murine hepatocytes were cultured at an overconfluent stage, the number of viable cells were reduced to that of the confluent stage 48 h later by cell death. Cell death was accompanied by LDH release, and it was observed only in primary cultured hepatocytes but not in hepatoma cells. Genomic DNA analysis using electrophoresis showed that DNA fragmentation, a biochemical hallmark of apoptosis, was induced in superconfluent cultures of hepatocytes in a cell-density-dependent fashion, but not in pre-confluent cells. DNA fragmentation was rapidly induced 2 h after the beginning of the in vitro culture and continued up to 24 h later. Flow cytometry analysis demonstrated that the nuclei from the hepatocytes in a high density culture were condensed and that the DNA content was reduced. These data suggest that the mechanism of cell death is apoptosis. The DNA fragmentation seen in the high density hepatocyte culture was not observed in hepatoma cell lines. Moreover, apoptosis was induced in hepatocytes of MRL/lpr mice, suggesting that the Fas antigen was not involved in the apoptotic process. Apoptosis was inhibited by a protein synthesis inhibitor, cycloheximide, and by a calmodulin antagonist, W-7. Taken together, the results indicate that high density culture of murine hepatocytes though not hepatoma cells regulate their cell numbers by an apoptotic mechanism. The apoptosis is dependent on de novo protein synthesis and intracellular calcium metabolism.     

DNA fragmentation induced in macrophages by gliotoxin does not require protein synthesis and is preceded by raised inositol triphosphate levels.

We have shown that the immunomodulating agent gliotoxin induces DNA fragmentation in macrophages characteristic of programmed cell death or apoptosis (Waring, P., Eichner, R. D., Mullbacher, A., and Sjaarda, A. (1988) J. Biol. Chem, 263, 18493-18499). In addition, morphological changes and DNA fragmentation characteristic of apoptosis are induced in 48 h concanavalin A-stimulated T blasts by gliotoxin and these changes are inhibited by Zn2+ (Waring, P., Egan, M., Braithwaite, A., Mullbacher, A., and Sjaarda, A. (1990) Int. J. Immunopharmacol., in press). We have studied the effects of actinomycin D and the protein synthesis inhibitor cycloheximide on apoptosis induced by gliotoxin in these cells, and these studies demonstrate no effect on apoptosis induced by gliotoxin. Cycloheximide and actinomycin D alone induce DNA fragmentation in these cells. Gliotoxin itself proved to be a potent inhibitor of protein synthesis. The fragmentation caused by cycloheximide correlated with the extent of protein synthesis inhibition. The toxin ricin also induced DNA fragmentation in T blasts characteristic of apoptosis. These results indicate that protein synthesis is not required for induction of apoptosis in macrophages or T blasts by gliotoxin. Gliotoxin caused elevated levels of inositol triphosphate in treated macrophages which may be related to mobilization of Ca2+ levels during apoptosis.