Nuclear events of apoptosis in vitro in cell-free mitotic extracts: a model system for analysis of the active phase of apoptosis

Proteolytic specificity of caspases is required to signal the appearance of apoptotic morphology

The caspase family of cysteine proteases is essential for implementation of physiological cell death. Since a wide variety of cellular proteins is cleaved by caspases during apoptosis, it has been predicted that digestion of proteins crucial to maintaining the life of a cell is central to apoptosis. To assess the role of the proteolytic destruction during apoptosis, we introduced the non-specific protease proteinase K into intact cells. This introduction led to extensive digestion of cellular proteins, including physiological caspase-substrates. Caspase-3-like activity was induced rapidly, followed by morphological signs of apoptosis such as membrane blebbing and nuclear condensation. The caspase inhibitor Z-VAD-fmk inhibited the appearance of these morphological changes without reducing the extent of intracellular proteolysis by proteinase K. Loss of integrity of the cell membrane, however, was not blocked by Z-VAD-fmk. This system thus generated conditions of extensive destruction of caspase substrates by proteinase K in the absence of apoptotic morphology. Taken together, these experiments suggest that caspases implement cell death not by protein destruction but by proteolytic activation of specific downstream effector molecules.

Caspase-mediated cleavage of APC results in an amino-terminal fragment with an intact armadillo repeat domain

During the effector phase of apoptosis, caspase activation appears to be responsible for the distinctive structural changes of apoptosis and perhaps for some of the changes in function of the doomed cells. There is therefore interest in identifying caspase substrates and the details of the cleavage events. Here we define precisely the event responsible for generation of a stable 90 kDa fragment from the oncosuppressor protein adenomatous polyposis coli (APC). Using synthetic radiolabeled APC peptides as substrate, we demonstrate cleavage by cytosolic extracts from preapoptotic cells. This cleavage was reproduced by recombinant caspase-3 and blocked by a tetrapeptide inhibitor Ac-DEVD-CHO, which is specific for caspase-3 family members. Inhibitors specific for caspase-1 and -8 however, were less effective in blocking APC cleavage. Mutation of a candidate DNID caspase-3 target site completely abolished cleavage. This cleavage may be of biological importance since the 90 kDa fragment consists of a sequence that is highly conserved in the human, rat, mouse, Xenopus, and Drosophila APC, although wide sequence divergence is observed in Drosophila immediately carboxy-terminal to the DNID site. Furthermore, cleavage at this site separates two significant functional domains: an amino-terminal armadillo repeat and an adjacent series of beta-catenin binding sites. Further circumstantial evidence for the significance of APC-related pathways in apoptosis is provided by the observation that apoptosis also induces cleavage of beta-catenin itself, a protein known to accumulate in cells depleted in functional APC and that appears to link cell-cell signaling to changes in transcription and cell movement.

Extent and limitation of the control of nuclear apoptosis by DNA-fragmenting factor

During apoptosis, changes to the nucleus of the dying cell include DNA degradation and structural collapse. These changes are accomplished by caspase-mediated cleavage of DNA-fragmenting factor DFF45, an inhibitor of the effector molecule DFF40. DFF45 and, more efficiently, a mutant lacking one caspase-cleavage site (DFF45m) inhibited nuclear changes in a cell-free system when apoptosis was initiated by adding caspase-3 to cell extracts. In primary tissues from several mammalian species, human caspase-3 activated and human DFF45m blocked nuclear apoptosis demonstrating evolutionary conservation of this step. However, DFF45m did not significantly inhibit DNA-fragmenting activity in extracts from staurosporine-treated cells from the human cell line Jurkat. In extracts from normal Jurkat cells, DFF45m blocked caspase-triggered DNA cleavage efficiently only if added within a short time of the addition of the caspase. At later time points, this inhibition by DFF45m was strongly reduced in efficiency while Zn2+ still completely blocked DNA fragmentation. These results demonstrate the evolutionary conservation of a linear pathway in apoptosis and suggest the existence of more complex events as final effector machinery.

Induction of Bax protein and degradation of lamin A during p53-dependent apoptosis induced by chemotherapeutic agents in human cancer cell lines

In this study, subcellular fractionation analysis was performed to investigate the intracellular localization of Bax protein. We demonstrated that Bax protein is localized primarily in the nuclear and heavy membrane fractions. The expression of Bax protein in the nuclear membrane was induced in wild-type p53 human cancer cells (COLO 205 and Hep G2) by a wide variety of cancer chemotherapeutic agents in order to scrutinize further the biologic function of the Bax protein in the nuclear membrane. We found that lamin A and poly-(ADP ribose) polymerase (PARP) protein degradation coincided when the Bax protein level was elevated in the nuclear membrane of cells affected by drug stimuli. By using anti-sense oligodeoxynucleotides specific to human Bax mRNA, we further demonstrated that inhibition of Bax expression could specifically block lamin A but not PARP cleavage in apoptotic cancer cells.

Tributyltin triggers apoptosis in trout hepatocytes: the role of Ca2+, protein kinase C and proteases

The purpose of the present study was to study the mechanisms involved in the induction of apoptosis and by tributyltin (TBT) in rainbow trout hepatocytes, and to examine the role of intracellular Ca2+, protein kinase C (PKC) and proteases in the apoptotic process. The intracellular Ca2+ chelator BAPTA-AM has a suppressive effect on TBT-mediated apoptosis. However, exposure to the ionophore A23187 is not sufficient to induce apoptosis in trout hepatocytes. The results obtained also show that TBT stimulates PKC gamma and delta translocation from cytosol to the plasma membrane in trout hepatocytes after 30 min of exposure. However, PKC gamma translocation is down-regulated after 90 min of treatment. The addition of protein kinase inhibitors (staurosporine and H-7) not only fails to inhibit apoptosis induced by TBT, but also leads to enhancement of DNA fragmentation. These inhibitors also afford a remarkable protection against the loss of plasma membrane integrity caused by TBT exposure. PMA, a direct activator of PKC, fails to stimulate DNA fragmentation. In addition, Z-VAD.FMK is an extremely potent inhibitor of TBT-induced apoptosis in trout hepatocytes, indicating that the activation of ICE-like proteases is a key event in this process. The cysteine protease inhibitor N-ethylmaleimide also prevented TBT-induced DNA fragmentation. Taken together, these data allow for the first time to suggest a mechanistic model of TBT-induced apoptosis. We propose that TBT could trigger apoptosis through a step involving Ca2+ efflux from the endoplasmic reticulum or other intracellular pools and by mechanisms involving cysteine proteases, such as calpains, as well as the phosphorylation status of apoptotic proteins such as Bcl-2 homologues.

Mitochondrial DNA mutations and age

Apopotic cell death is reported to be prominent in the stable tissues of the failing heart, in cardiomyopathies (CM), in the sinus node of complete heart block, in B cells of diabetes mellitus, and in neurodegenerative diseases. Recently, mitochondrial (mt) control of nuclear apoptosis was demonstrated in the cell-free system. The mt bioenergetic crisis induced by exogenously added factors such as respiratory inhibitors leads to the collapse of mt transmembrane potential, to the opening of the inner membrane pore, to the release of the apoptotic protease activating factors into cytosol, and subsequently to nuclear DNA fragmentation. However, the endogenous factor for the mt bioenegertic crisis in naturally occurring cell death under the physiological conditions without vascular involvement has remained unknown. Recently devised, the total detection system for deletion demonstrates the extreme fragmentation of mtDNA in the cardiac myocytes of senescence, and mt CM harboring maternally inherited point mutations in mtDNA and on the cultured cell line with or without mtDNA disclosed that mtDNA is unexpectedly fragile to hydroxyl radial damage and hence to oxygen stress. The great majority of wild-type mtDNA fragmented into over two hundreds types of deleted mtDNA related to oxidative damage, resulting in pleioplasmic defects in the mt energy transducing system. The mtDNA fragmentation to this level is demonstrated in cardiac myocytes of normal subjects over age 80, of an mtCM patient who died at age 20 and one who died at age 19, of a recipient of heart transplantation at age 7 with severe mtCM, and in mtDNA of a cultured cell line under hyperbaric oxygen stress for two days, leading a majority of cells to apoptotic death on the third day. The extreme fragility of mtDNA could be the missing link in the apoptosis cascade that is the physiological basis of aging and geriatrics of such stable tissues as nerve and muscle.

The identification of two Drosophila K homology domain proteins. Kep1 and SAM are members of the Sam68 family of GSG domain proteins

Sam68 is a member of a growing family of RNA-binding proteins that contains an extended K homology (KH) domain embedded in a larger domain called the GSG (GRP33, Sam68, GLD1) domain. To identify GSG domain family members, we searched data bases for expressed sequence tags encoding related portions of the Sam68 KH domain. Here we report the identification of two novel Drosophila KH domain proteins, which we termed KEP1 (KH encompassing protein) and SAM. SAM bears sequence identity with mammalian Sam68 and may be the Drosophila Sam68 homolog. We demonstrate that SAM, KEP1, and the recently identified Drosophila Who/How are RNA-binding proteins that are able to self-associate into homomultimers. The GSG domain of KEP1 and SAM was necessary to mediate the RNA binding and self-association. To elucidate the cellular roles of these proteins, SAM, KEP1, and Who/How were expressed in mammalian and Drosophila S2 cells. KEP1 and Who/How were nuclear and SAM was cytoplasmic. The expression of KEP1 and SAM, but not Who/How, activated apoptotic pathways in Drosophila S2 cells. The identification of KEP1 and SAM implies that a large GSG domain protein family exists and helps redefine the boundaries of the GSG domain. Taken together, our data suggest that KEP1 and SAM may play a role in the activation or regulation of apoptosis and further implicate the GSG domain in RNA binding and oligomerization.

Atractyloside-induced release of cathepsin B, a protease with caspase-processing activity

Recent data show that a strong relation exists in certain cells between mitochondria and caspase activation in apoptosis. We further investigated this relation and tested whether treatment with the permeability transition (PT)-inducing agent atractyloside of Percoll-purified mitochondria released a caspase-processing activity. Following detection of procaspase-11 processing, we further purified this caspase-processing protease and identified it as cathepsin B. The purified cathepsin B, however, was found to be derived from lysosomes which were present as minor contaminants in the mitochondrial preparation. Besides procaspase-11, caspase-1 is also readily processed by cathepsin B. Procaspase-2, -6, -7, -14 are weak substrates and procaspase-3 is a very poor substrate, while procaspase-12 is no substrate at all for cathepsin B. In addition, cathepsin B induces nuclear apoptosis in digitonin-permeabilized cells as well as in isolated nuclei. All newly described activities of cathepsin B, namely processing of caspase zymogens and induction of nuclear apoptosis, are inhibited by the synthetic peptide caspase inhibitors z-VAD.fmk, z-DEVD.fmk and to a lesser extent by Ac-YVAD.cmk.

Phosphorylated Forms of Activated Caspases Are Present in Cytosol From HL-60 Cells During Etoposide-Induced Apoptosis

Treatment of HL-60 human leukemia cells with etoposide induces apoptotic cell death and activation of at least 18 electrophoretically distinct cysteine-dependent aspartate-directed protease (caspase) isoforms, several of which differ only in their isoelectric points. The purpose of the present study was to determine whether activated caspases are phosphorylated. Phosphatase treatment of cytosolic extracts containing active caspases followed by affinity labeling with N-(N-benzyloxycarbonylglutamyl-N-biotinyllysyl)aspartic acid [(2,6-dimethylbenzoyl)oxy] methyl ketone (Z-EK(bio)D-aomk) showed a mobility shift in several of the labeled species, suggesting that phosphorylated forms of these enzymes are present in the extracts. Metabolic labeling with 32P followed by etoposide treatment and subsequent affinity purification of affinity-labeled caspases confirmed that at least three caspase species were phosphorylated. To detect effects of the phosphorylation on enzymatic activity, caspase-mediated cleavage of aspartylglutamylvalinylaspartyl-7-amino-4-trifluoromethylcoumarin (DEVD-AFC) and poly(ADP-ribose) polymerase (PARP) by phosphorylated and dephosphorylated extracts was measured. No significant changes in Km or vmax were detected using DEVD-AFC. In contrast, a slight, but significant enhancement of PARP cleavage was observed in dephosphorylated extracts, suggesting that phosphorylation of active caspases could have an inhibitory effect on enzyme activity. These observations, which provide the first evidence that caspases are phosphoproteins, suggest that caspases may be targets for some of the growing list of protein kinases that are involved in apoptotic events.

© 1998 by The American Society of Hematology.

Dephosphorylation, proteolysis, and reduced activity of poly(A) polymerase associated with U937 cell apoptosis

The apoptotic trend of the widely used cell lines HL-60, U937, HeLa, Molt-3, and K562 has been found to be accompanied and reversibly related with Poly(A) polymerase (PAP; EC 2.7.7.19) activity levels. Moreover, variations in the pattern of multiple enzyme forms are revealed, being most prominent in apoptosis-prone cell lines, HL-60 and U937. Furthermore, in heat-shocked or nutrient-deprived apoptotic U937 Percoll-fractionated subpopulations, PAP lower mobility phosphorylated forms of 106 and 100 kDa as well as enzyme activity were progressively reduced along with the appearance of higher than 80 kDa mobility species. The kinetics of these alterations (dephosphorylation, proteolysis, and activity) coincided with the appearance of DNA fragmentation. In fact, PAP dephosphorylation appears to precede the appearance of DNA fragmentation. In addition, inhibition of PAP dephosphorylation, proteolysis, and decrease in its activity were tightly coupled with the concomitant prevention of apoptosis. This novel finding yields information on a possible involvement of PAP in cell commitment and execution to apoptosis.

Cancer cell necrosis by autoschizis: synergism of antitumor activity of vitamin C: vitamin K3 on human bladder carcinoma T24 cells

Scanning and transmission electron microscopy and fluorescence light microscopy were employed to characterize the cytotoxic effects of vitamin C (VitC), vitamin K3 (VitK3) or a VitC:VK3 combination on a human bladder carcinoma cell line (T24) following 1-h and 2-h vitamin treatment. T24 cells exposed to VitC alone exhibited membranous damage (blebs and endoplasmic extrusions, elongated microvilli). VitK3-treated cells displayed greater membrane damage and enucleation than those treated with VitC as well as cytoplasmic defects characteristic of cytoskeletal damage. VitC:VitK3-treated cells showed exaggerated membrane damage and an enucleation process in which the perikarya separate from the main cytoplasmic cell body by self-excision. Self-excisions continued for perikarya which contained an intact nucleus surrounded by damaged organelles. After further excisions of cytoplasm, the nuclei exhibited nucleolar segregation and chromatin decondensation followed by nuclear karryorhexis and karyolysis. This process of cell death induced by oxidative stress was named autoschizis because it showed both apoptotic and necrotic morphologic characteristics.

Inactivation of DNA-dependent protein kinase by protein kinase Cdelta: implications for apoptosis

Protein kinase Cdelta (PKCdelta) is proteolytically cleaved and activated at the onset of apoptosis induced by DNA-damaging agents, tumor necrosis factor, and anti-Fas antibody. A role for PKCdelta in apoptosis is supported by the finding that overexpression of the catalytic fragment of PKCdelta (PKCdelta CF) in cells is associated with the appearance of certain characteristics of apoptosis. However, the functional relationship between PKCdelta cleavage and induction of apoptosis is unknown. The present studies demonstrate that PKCdelta associates constitutively with the DNA-dependent protein kinase catalytic subunit (DNA-PKcs). The results show that PKCdelta CF phosphorylates DNA-PKcs in vitro. Interaction of DNA-PKcs with PKCdelta CF inhibits the function of DNA-PKcs to form complexes with DNA and to phosphorylate its downstream target, p53. The results also demonstrate that cells deficient in DNA-PK are resistant to apoptosis induced by overexpressing PKCdelta CF. These findings support the hypothesis that functional interactions between PKCdelta and DNA-PK contribute to DNA damage-induced apoptosis.

Phosphorylated Forms of Activated Caspases Are Present in Cytosol From HL-60 Cells During Etoposide-Induced Apoptosis

Treatment of HL-60 human leukemia cells with etoposide induces apoptotic cell death and activation of at least 18 electrophoretically distinct cysteine-dependent aspartate-directed protease (caspase) isoforms, several of which differ only in their isoelectric points. The purpose of the present study was to determine whether activated caspases are phosphorylated. Phosphatase treatment of cytosolic extracts containing active caspases followed by affinity labeling with N-(N-benzyloxycarbonylglutamyl-N-biotinyllysyl)aspartic acid [(2,6-dimethylbenzoyl)oxy] methyl ketone (Z-EK(bio)D-aomk) showed a mobility shift in several of the labeled species, suggesting that phosphorylated forms of these enzymes are present in the extracts. Metabolic labeling with 32P followed by etoposide treatment and subsequent affinity purification of affinity-labeled caspases confirmed that at least three caspase species were phosphorylated. To detect effects of the phosphorylation on enzymatic activity, caspase-mediated cleavage of aspartylglutamylvalinylaspartyl-7-amino-4-trifluoromethylcoumarin (DEVD-AFC) and poly(ADP-ribose) polymerase (PARP) by phosphorylated and dephosphorylated extracts was measured. No significant changes in Km or vmax were detected using DEVD-AFC. In contrast, a slight, but significant enhancement of PARP cleavage was observed in dephosphorylated extracts, suggesting that phosphorylation of active caspases could have an inhibitory effect on enzyme activity. These observations, which provide the first evidence that caspases are phosphoproteins, suggest that caspases may be targets for some of the growing list of protein kinases that are involved in apoptotic events.

© 1998 by The American Society of Hematology.

UV-C radiation induces apoptotic-like changes in Arabidopsis thaliana

With a view to studying programmed cell death in plants at the molecular level, we report here for the first time that apoptotic-like changes are induced by UV radiation in plant nuclei. In Arabidopsis thaliana seedlings a UV-C dose of 10-50 kJ/m2 induces an oligonucleosomal DNA fragmentation which is reminiscent of the apoptotic DNA ladder described in animal cells. This DNA fragmentation was also detected in situ in protoplast nuclei as soon as 2 h after UV-C treatment. Moreover, UV-C induced a nuclear morphology characteristic of animal apoptotic nuclei. We propose that UV-C induction constitutes a powerful tool to compare the cellular response to irreversible UV damage in plants to that in animals and to study programmed cell death in A. thaliana.

Transition from caspase-dependent to caspase-independent mechanisms at the onset of apoptotic execution

We have compared cytoplasmic extracts from chicken DU249 cells at various stages along the apoptotic pathway. Extracts from morphologically normal "committed stage" cells induce apoptotic morphology and DNA cleavage in substrate nuclei but require ongoing caspase activity to do so. In contrast, extracts from frankly apoptotic cells induce apoptotic events in added nuclei in a caspase-independent manner. Biochemical fractionation of these extracts reveals that a column fraction enriched in endogenous active caspases is unable to induce DNA fragmentation or chromatin condensation in substrate nuclei, whereas a caspase-depleted fraction induces both changes. Further characterization of the "execution phase" extracts revealed the presence of an ICAD/DFF45 (inhibitor of caspase-activated DNase/DNA fragmentation factor)- inhibitable nuclease resembling CAD, plus another activity that was required for the apoptotic chromatin condensation. Despite the presence of active caspases, committed stage extracts lacked these downstream activities, suggesting that the caspases and downstream factors are segregated from one another in vivo during the latent phase. These observations not only indicate that caspases act in an executive fashion, serving to activate downstream factors that disassemble the nucleus rather than disassembling it themselves, but they also suggest that activation of the downstream factors (rather than the caspases) is the critical event that occurs at the transition from the latent to active phase of apoptosis.

Cell death induced by topoisomerase-targeted drugs: more questions than answers

Chemotherapeutic agents that target topoisomerase I and II set into motion a series of biochemical changes that culminate in cell death, but only under some conditions. The realization that stabilization of covalent topoisomerase-DNA complexes is not sufficient to insure cell death has prompted investigators to examine various aspects of the drug-induced death process itself. Several discrete steps along this pathway have been identified, including (a) the processing of stabilized cleavage complexes into frank DNA strand breaks; (b) sensing of the DNA damage, leading to activation of stress-associated signaling pathways and cell cycle arrest; and (c) activation of a preexisting group of enzymes and enzyme precursors, typified by the cysteine-dependent aspartate-directed proteases (caspases), that catalyze the relatively orderly biochemical cascade of terminal events known as apoptosis. The present review discusses the evidence that these steps occur after treatment with etoposide or camptothecin, the two prototypic topoisomerase poisons that are commonly studied. As in any emerging area, a large number of questions remain to be answered about the process of cell death induced by topoisomerase-directed drugs.

Development of Non-invasive Methods to Study Cell Death

A novel non-invasive marker to monitor apoptosis in the living cell is presented. A human neuroblastoma cell line expressing an integral nuclear pore membrane protein tagged with GFP (green fluorescent protein) has been established, which enables monitoring of the nuclear envelope dynamics in intact cell cultures by fluorescence microscopy. During apoptosis, but not during necrosis, the GFP fluorescence around the nuclear rim disappears at a stage preceding nucleosomal DNA fragmentation. This phenomenon can thus be used as an early and convenient marker to specifically diagnose apoptotic development in cell cultures.

Elevation of cytoplasmic cytochrome c in radiation-induced apoptosis

The signal transduction pathway involved in radiation-induced apoptosis remains unclear, especially as regards the site at which the primary effect of radiation occurs. In this study, we demonstrate that cytochrome c may be released from mitochondria into the cytosol after irradiation, but that direct irradiation of isolated mitochondria induces no elevation of cytochrome c release. These observations suggest that cytochrome c and mitochondria may be involved in the radiation-induced apoptotic pathway, but mitochondria might not be a target of radiation, and that a signal transduction pathway from an unknown target might exist upstream of mitochondria during radiation-induced apoptosis.

Chromatin condensation is not associated with apoptosis

Apoptosis plays an important role in the survival of an organism, and substantial work has been done to understand the signaling pathways that regulate this process. Characteristic changes in chromatin organization accompany apoptosis and are routinely used as markers for cell death. We have examined the organization of chromatin in apoptotic PC12 and HeLa cells by indirect immunofluorescence and electron spectroscopic imaging. Our results indicate that de novo chromatin condensation normally seen during mitosis does not occur when cells undergo apoptosis. Instead, the condensed chromatin typically observed results from aggregation of the heterochromatin. We present evidence that, early in apoptosis, there is a rapid degradation of the nuclease-hypersensitive euchromatin that contains hyperacetylated histones. This occurs coincident with the loss of nuclear integrity due to degradation of lamins and reorganization of intranuclear protein matrix. These events lead to collapse of the nucleus and aggregation of heterochromatin to produce the appearance of condensed apoptotic chromatin. This heterochromatin aggregate is then digested by nucleases to produce the oligonucleosomal DNA ladder that is a hallmark of late apoptosis. Unlike mitosis, we have not seen any evidence for the requirement of phosphorylated histones H1 and H3 to maintain the chromatin in the condensed state.

Bruton's tyrosine kinase (BTK) as a dual-function regulator of apoptosis

Multiple counterregulatory mechanisms have been identified in B-cell precursors that operate to regulate cell survival and growth, thereby ensuring the orderly development and differentiation of B-cells. Inappropriate apoptosis may underlie the pathogenesis of immunodeficiencies, as well as pathogenesis and drug/radiation resistance of human leukemias and lymphomas, which makes control of apoptosis an important potential target for therapeutic interventions. Therefore, identification of the molecular regulators of apoptosis is an area of intense investigation. Bruton's tyrosine kinase (BTK) is the first tyrosine kinase to be identified as a dual-function regulator of apoptosis, which promotes radiation-induced apoptosis but inhibits Fas-activated apoptosis in B-cells. BTK functions in a pro-apoptotic manner when B-cells are exposed to reactive oxygen intermediates, at least in part, by down-regulating the anti-apoptotic activity of STAT-3 transcription factor. In contrast, BTK associates with the death receptor Fas and impairs its interaction with Fas-associated protein with death domain (FADD), which is essential for the recruitment and activation of FLICE by Fas during the apoptotic signal, thereby preventing the assembly of a pro-apoptotic death inducing signaling complex (DISC) after Fas-ligation. The identification of BTK as a dual-function regulator of apoptosis will significantly increase our understanding of both the biological processes involved in programmed cell death and the diseases associated with dysregulation of apoptosis. New agents with BTK-modulatory activity may have clinical potential in the treatment of B-cell malignancies (in particular acute lymphoblastic leukemia, the most common form of childhood cancer), as well as B-cell immunodeficiencies.

Resistance to etoposide-induced apoptosis in a Burkitt's lymphoma cell line

Burkitt's lymphoma cells that vary in their phenotypic characteristics show significantly different degrees of susceptibility to radiation-induced apoptosis. Propensity to undergo apoptosis is reflected in the degradation of substrates such as DNA-dependent protein kinase but the status of bcl-2, c-myc and p53 has been uninformative. In this study, we have focused on 2 Epstein-Barr virus (EBV)-associated Burkitt's cell lines, one (WW2) susceptible and the other (BL29) resistant to etoposide-induced apoptosis. Differences in expression of BHRF1, an EBV gene that is homologous to the Bcl-2 proto-oncogene and known to inhibit apoptosis, or changes in apoptosis inhibitory proteins (IAPs), did not appear to account for the difference in susceptibility in the 2 cell lines. Cytoplasmic extracts from etoposide-treated WW2 cells caused apoptotic changes in nuclei isolated from either BL29 or WW2 cells, whereas extracts from BL29 cells failed to do so. In addition, extracts from etoposide-treated WW2 cells degraded the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs), an important indicator of apoptosis, but this protein was resistant to degradation by BL29 extracts. It appears likely that caspase 3 (CPP32) is involved in this degradation since it was activated only in the apoptosis susceptible cells and the pattern of cleavage of DNA-PKcs was similar to that reported previously with recombinant caspase 3. As observed previously, addition of caspase 3 to nuclei failed to induce morphological changes indicative of apoptosis, but addition of caspase 3 to nuclei in the presence of extract from the resistant cells led to apoptotic changes. We conclude that resistance to apoptosis in BL29 cells is due to a failure of etoposide to activate upstream effectors of caspase activity.

Apparent caspase independence of programmed cell death in Dictyostelium

During normal development, cell elimination [1,2] occurs by programmed cell death (PCD) [3], of which apoptosis [4] is the best known morphological type. Activation of cysteine proteases termed caspases [5] is required in many instances of animal PCD [6-9], but its role outside the animal kingdom is as yet unknown. PCD occurs during developmental stages in the slime mold Dictyostelium discoideum [10,11]. Under favorable conditions, Dictyostelium multiplies as a unicellular organism. Upon starvation, a pathway involving aggregation, differentiation and morphogenesis induces the formation of a multicellular fungus-like structure called a sorocarp [12], consisting mainly of spores and stalk cells, the latter being a result of cell death. Dictyostelium cell death is similar to classical apoptosis in that some cytoplasmic and chromatin condensation occurs but differs from apoptosis because it involves massive vacuolisation and, interestingly, lacks DNA fragmentation [11]. We examined whether caspase activity is required for Dictyostelium cell death. We found that caspase inhibitors did not affect cell death, although some caspase inhibitors that did not inhibit cell death impaired other stages in development and could block affinity-labelling of soluble extracts of Dictyostelium cells with an activated caspase-specific reagent. The simplest interpretation of these results is that in Dictyostelium, whether or not caspase-like molecules exist and are required for some developmental steps, caspase activation is not required for cell death itself.

Ultrastructural distribution of the death-domain-containing MyD88 protein in HeLa cells

MyD88, a protein implicated in interleukin-1 signaling, was localized in HeLa cells transiently transfected with an epitope-tagged (flag) version of MyD88. Overexpression of MyD88 can induce apoptosis. We have analyzed the fine structural intracellular distribution of MyD88 using immunoelectron microscopy. MyD88 is localized to the nucleus and to the cytoplasm as revealed by immunofluorescence visualization. Ultrastructural immunocytochemistry shows that, in the cytoplasm, this protein is associated with fibrillar aggregates containing beta-actin. In the nucleus, MyD88 was found in fibrillar domains present only in cells not yet displaying morphological signs of apoptosis. These domains are not derived from nucleoli and do not constitute an accumulation site of splicing factors. We suggest that such structures could be involved in the formation of the apoptotic bodies and/or in the modification of the nuclear structure and of nucleocytoplasmic trafficking during apoptosis.

Apoptotic changes preceding necrosis in lipopolysaccharide-treated macrophages in the presence of cycloheximide

Apoptotic changes occurred specifically in a macrophage-like cell line, J774.1, treated with lipopolysaccharide (LPS) and cycloheximide (CHX) prior to the release of lactate dehydrogenase (LDH). The addition of 100 ng/ml LPS and 10 microg/ml CHX induced both the formation of DNA nicks and elevation of caspase-3-like activity (DEVDase) after 75 min, and then the cleavage of poly(ADP-ribose) polymerase (PARP) into 28-kDa fragments, formation of apoptotic bodies, and DNA ladder formation. These apoptotic changes were reversible until 60 min, however, later than 75 min after LPS and CHX addition, the apoptosis proceeded normally even on extensive washing of the macrophages, which removed the LPS and CHX. These results suggest that there is a "point of no return" in the apoptotic processes in macrophages induced by LPS and CHX and that DNA nicks and activation of DEVDase are critical for these processes.

Activation of caspases in pig kidney cells infected with wild-type and CrmA/SPI-2 mutants of cowpox and rabbitpox viruses

The cowpox virus (CPV) CrmA and the equivalent rabbitpox virus (RPV) SPI-2 proteins have anti-inflammatory and antiapoptosis activity by virtue of their ability to inhibit caspases, including the interleukin-1beta-converting enzyme (ICE; caspase-1). Infection of LLC-PK1 pig kidney cells with a CPV CrmA mutant, but not with wild-type (wt) CPV, results in the induction of many of the morphological features of apoptosis (C. A. Ray and D. J. Pickup, Virology 217:384-391, 1996). In our study, LLC-PK1 cells infected with CPV delta crmA, but not those infected with wt CPV, showed induction of poly(ADP-ribose) polymerase (PARP)- and lamin A-cleaving activities and processing of the CPP32 (caspase-3) precursor to a mature 18-kDa form. Surprisingly, infection of LLC-PK1 cells with either wt RPV (despite the presence of the SPI-2 protein) or RPV delta SPI-2 resulted in cleavage activity against PARP and lamin A and the appearance of the mature subunit of CPP32/caspase-3. The biotinylated specific peptide inhibitor Ac-Tyr-Val-Lys(biotinyl)-Asp-2,6-dimethylbenzoyloxymethylketone [AcYV(bio)KD-aomk] labeled active caspase subunits of 18, 19, and 21 kDa in extracts from LLC-PK1 cells infected with CPV delta crmA, wt RPV, or RPV delta SPI-2 but not wt CPV. Mixed infection of LLC-PK1 cells with wt RPV and wt CPV gave no PARP-cleaving activity, and all PARP cleavage mediated by SPI-2 and CrmA mutants of RPV and CPV, respectively, could be eliminated by coinfection with wt CPV. These results suggest that the RPV SPI-2 and CPV CrmA proteins are not functionally equivalent and that CrmA, but not SPI-2 protein, can completely prevent apoptosis in LLC-PK1 cells under these conditions.

Alkyl hydroperoxide reductase subunit C (AhpC) protects bacterial and human cells against reactive nitrogen intermediates

In Salmonella typhimurium, ahpC encodes subunit C of alkyl hydroperoxide reductase, an enzyme that reduces organic peroxides. Here, we asked if ahpC could protect cells from reactive nitrogen intermediates (RNI). Salmonella disrupted in ahpC became hypersusceptible to RNI. ahpC from either Mycobacterium tuberculosis or S. typhimurium fully complemented the defect. Unlike protection against cumene hydroperoxide, protection afforded by ahpC against RNI was independent of the reducing flavoprotein, AhpF. Mycobacterial ahpC protected human cells from necrosis and apoptosis caused by RNI delivered exogenously or produced endogenously by transfected nitric oxide synthase. Resistance to RNI appears to be a physiologic function of ahpC. ahpC is the most widely distributed gene known that protects cells directly from RNI, and provides an enzymatic defense against an element of antitubercular immunity.

LBR, a chromatin and lamin binding protein from the inner nuclear membrane, is proteolyzed at late stages of apoptosis

Chromatin condensation and apposition to the nuclear envelope is an important feature of the execution phase of apoptosis. During this process, lamin proteins that are located between the inner nuclear membrane and heterochromatin are proteolyzed by the apoptosis-specific protease caspase 6. We have investigated the fate of nuclear membranes during apoptosis by studying the lamin B receptor (LBR), a transmembrane protein of the inner nuclear membrane. LBR interacts through its nucleoplasmic amino-terminal domain with both heterochromatin and B-type lamins, and is phosphorylated throughout the cell cycle, but on different sites in interphase and mitosis. We report here that: (i) the amino-terminal domain of LBR is specifically cleaved during apoptosis to generate an approximately 20 kDa soluble fragment; (ii) the cleavage of LBR is a late event of apoptosis and occurs subsequent to lamin B cleavage; (iii) the phosphorylation of LBR during apoptosis is similar to that occurring in interphase. As the association of condensed chromatin with the inner nuclear membrane persists until the late stages of apoptosis, we suggest that the chromatin binding protein LBR plays a major role in maintaining this association.

Proteolytic activities that mediate apoptosis

Since the discovery that cells can activate their own suicide program, investigators have attempted to determine whether the events that are associated with this form of cell death are genetically determined. The discovery that the ced-3 gene of Caenorhabditis elegans encodes a cysteine protease essential for developmentally regulated apoptosis ignited interest in this area of research. As a result, we now know that cell death is specified by a number of genes and that this biologic process contributes significantly to development, tumorigenesis, and autoimmune disease. In this review I summarize what is currently known about signaling pathways involved in apoptosis, with particular emphasis on the function of the cysteine proteases known as caspases. However, there is also evidence that protease-independent cell death pathways exist. Is there a relationship between these two distinct mechanisms? If so, how do they communicate? Finally, even though the involvement of tumor necrosis factor/nerve growth factor family of receptors and cysteine proteases has been elegantly established as a component of many apoptotic signaling pathways, what happens downstream of these initial events? Why are only a selected group of cellular proteins--many nuclear--the targets of these proteases? Are nuclear events essential for apoptosis in vivo? Are the cellular genes that encode products involved in apoptotic signaling frequent targets of mutation/alteration during tumorigenesis? These are only a few questions that may be answered in the next ten years.

The PITSLRE protein kinase family

A family of p34Cdc2 related protein kinases, the PITSLRE kinases, is generated by alternative splicing and promoter utilization from three duplicated and tandemly linked genes on human chromosome 1p36.3, which is frequently deleted during the late stages of tumorigenesis. PITSLRE mRNA, protein, and enzyme activity are induced during Fas receptor- and glucocorticoid-mediated apoptosis of human T cells. Several PITSLRE isoforms are specific targets of proteolysis during apoptosis, generating an enzymatically active 50 kDa isoform. Inhibition of this protease activity blocks PITSLRE processing and enzyme activation, as well as apoptosis. Thus, PITSLRE kinases may be integral downstream components of apoptotic signal transduction pathway(s). Furthermore, PITSLRE genes, and their products, are physically altered in human neuroblastoma tumors, suggesting that they may be tumor suppressors.

Chemical inhibitors of cyclin-dependent kinases

The eukaryotic cell division cycle is regulated by a family of protein kinases, the cyclin-dependent kinases (cdk's), constituted of at least two subunits, a catalytic subunit (cdk1-7) associated with a regulatory subunit (cyclin A-H). Transient activation of cdk's is responsible for transition through the different phases of the cell cycle. Major abnormalities of cdk's expression and regulation have been described in human tumours. Enzymatic screening is starting to uncover chemical inhibitors of cdk's with anti-mitotic activities. This review summarizes our knowledge of these first inhibitors, their mechanism of action, their effects on the cell cycle, and discusses the potential of such type of inhibitors as anti-tumour agents.

Bcl-xL modulates apoptosis induced by anticancer drugs and delays DEVDase and DNA fragmentation-promoting activities

Using an episomal eucaryotic expression vector, we derived three stable transfected human leukemic U-937 variant lines showing differential expression of the Bcl-xL protein. Preventive effect of Bcl-xL on cell death induced by various concentrations of camptothecin (DNA topoisomerase I inhibitor; CPT) was observed in the three lines with most pronounced effect in cells containing the highest level of Bcl-xL expression. These results show that increased cell death protection by Bcl-xL is correlated with its level of expression. The extent of DNA strand break formation and DNA synthesis inhibition following CPT treatments was similar in control and transfected U-937 cells, suggesting that Bcl-xL acts downstream of CPT-DNA topoisomerase I-mediated DNA strand breaks. Modulation of cell death by Bcl-xL was also observed in cells treated with etoposide, vinblastine, paclitaxel, and cisplatinum (II) diammine dichloride. To define whether Bcl-xL functions downstream or upstream of apoptogenic proteolytic cascade activation, we compared kinetics of DNA fragmentation in treated cells with kinetics of caspase 1-like, caspase 3-like, and N-tosyl-L-phenylalanylchloromethyl ketone (TPCK)-sensitive activities. In CPT-treated U-937 cells, caspase 3-like and TPCK-sensitive activities promoting DNA fragmentation in a cell-free system were detected much more rapidly in extracts obtained from CPT-treated U-937 cells compared to those obtained from CPT-treated U-937-Bcl-xL variant cells. These results suggest that Bcl-xL delays their activation that correlates with the occurrence of DNA fragmentation. Addition of recombinant Bcl-xL in extracts containing DEVDase and TPCK-sensitive activities did not inhibit these activities, suggesting that Bcl-xL acts primarily upstream of their activation in the apoptotic process. Taken together, these results suggest that Bcl-xL is a primary checkpoint that can block or delay transmission of cell death signals emerging from DNA damage and prevents activation of an apoptogenic proteolytic cascade.

The short Sendai virus leader region controls induction of programmed cell death

The replication of nonsegmented minus-strand RNA genomes, like that of Sendai paramyxovirus (SeV), are controlled by the short leader regions present at each end of the linear genomes and antigenomes; the left and right promoters (PL and PR), respectively. Wild-type SeV is highly cytopathic in cell culture, because it induces programmed cell death (PCD). We have found that a recombinant SeV (rSeVGP42), in which the first 42 nt of le+ sequences at PL were replaced with the equivalent sequences of PR, and which produces infectious virus in amounts comparable to wild type, does not kill cells. Further, the increasing replacement of the terminal le+ sequences at PL with le- sequences led to a decreasing fraction of infected cells being apoptotic. This property (PCD-), moreover, is dominant in cells co-infected with SeVwt and rSeVGP42, and the mutant virus therefore appears to have gained a function which prevents PCD induced by SeVwt. Even though this virus has not been selected for naturally, it excludes SeVwt during co-infections of cultured cells or embryonated chicken eggs. The noncytopathic nature of cells infected or co-infected with rSeVGP42 leads automatically to stable, persistent infections. The mutation in rSeVGP42 is not in the protein coding regions of the viral genome, but in the 55-nt-long leader region which controls antigenome synthesis from genome templates. The SeV leader regions, which are expressed as short RNAs, thus appear to control the induction of PCD.

Dual mechanisms of apoptosis induction by cytotoxic lymphocytes

Cytotoxic T lymphocytes and natural killer cells together comprise the means by which the immune system detects and rids higher organisms of virus-infected or transformed cells. Although differing considerably in the way they detect foreign or mutated antigens, these cells utilize highly analogous mechanisms for inducing target cell death. Both types of effector lymphocytes utilize two principal contact-dependent cytolytic mechanisms. The first of these, the granule exocytosis mechanism, depends on the synergy of a calcium-dependent pore-forming protein, perforin, and a battery of proteases (granzymes), and it results in penetration by effector molecules into the target cell cytoplasm and nucleus. The second, which requires binding of FasL (CD95L) on the effector cell with trimeric Fas (CD95) molecules on receptive target cells, is calcium independent and functions by generating a death signal at the inner leaflet of the target cell membrane. Exciting recent developments have indicated that both cytolytic mechanisms impinge on an endogenous signaling pathway that is strongly conserved in species as diverse as helminths and humans and dictates the death or survival of all cells.

Inhibition by dexamethasone of transforming growth factor beta1-induced apoptosis in rat hepatoma cells: a possible association with Bcl-xL induction

The authors previously reported that transforming growth factor beta1 (TGF-beta1) induces apoptosis in McA-RH7777 (7777) and McA-RH8994 (8994) rat hepatoma cell lines. Although these cell lines exhibit different responses to glucocorticoid treatment in various cellular functions and gene expression, dexamethasone (DEX) inhibited spontaneous and TGF-beta1-induced apoptosis in both. Analysis of analogous hormones in TGF-beta1-induced apoptosis in 8994 cells suggested the inhibitory effect to be glucocorticoid-specific. By cell-cycle analysis and DNA fragmentation assay using sodium butyrate, a G1-arrest-inducing reagent, regulation of apoptosis by TGF-beta1 and DEX was shown independent of the cell cycle. For elucidation of the mechanisms of anti-apoptotic action of DEX, the effects of various chemical probes on this apoptosis model were examined, and various reagents known to exhibit anti-apoptotic activity in other experimental systems were found to be ineffective. The effect of TGF-beta1 and DEX on cellular amounts of several apoptosis-related proteins, members of the Bcl-2 family, Bcl-2, Bcl-xL, Bcl-xS, Bad, and Bax was also examined. DEX drastically increased Bcl-xL in both cell lines irrespective of the presence of TGF-beta1. Bcl-2 and Bcl-xS proteins were not detected, and Bax and Bad content did not change by treatment with TGF-beta1 or DEX. Progesterone (Prog), a partial antagonist for glucocorticoid receptor, inhibited the effects of DEX on apoptosis and Bcl-xL expression in 8994 cells. Thus, Bcl-xL induction by DEX would appear closely associated with its inhibitory effect on spontaneous and TGF-beta1-induced apoptosis in the hepatoma cell lines.

Suppression of Fas/APO-1-Mediated Apoptosis by Mitogen-Activated Kinase Signaling

Jurkat T cells undergo rapid apoptosis upon stimulation of the Fas/APO-1 (CD95) receptor. We examined the role of the mitogen-activated protein kinase (MAPK) cascade as a negative regulator of Fas-mediated apoptosis. To this end, we used both physiologic and artificial activators of MAPK, all of which activate MAPK by distinct routes. MAPK activity could be efficiently elevated by two T cell mitogens, the lectin PHA and an agonistic Ab to the T cell receptor complex as well as by the type 1 and 2A phosphatase inhibitor, calyculin A, and the protein kinase C-activating phorbol ester, tetradecanoyl phorbol acetate. All these treatments were effective in preventing the characteristic early and late features of Fas-mediated apoptosis, including activation of caspases. Our results indicate that the elevated MAPK activities intervene upstream of caspase activation. The degree of MAPK activation by the different stimuli used in our study corresponds well to their potency to inhibit apoptosis, indicating that MAPK activation serves as an efficient modulator of Fas-mediated apoptosis. The role of MAPK in modulation of Fas-mediated apoptosis was further corroborated by transient transfection with constitutively active MAPK kinase, resulting in complete inhibition of the Fas response, whereas transfection with a dominant negative form of MAPK kinase had no effect. Furthermore, the apoptosis inhibitory effect of the MAPK activators could be abolished by the specific MAPK kinase inhibitor PD 098059. Modulation of Fas responses by MAPK signaling may determine the persistence of an immune response and may explain the insensitivity of recently activated T cells to Fas receptor stimulation.

Mechanism of UV-induced apoptosis in human leukemia cells: roles of Ca2+/Mg(2+)-dependent endonuclease, caspase-3, and stress-activated protein kinases

Ultraviolet light (UV) induced rapid apoptosis of U937 leukemia cells, concurrent with DNA fragmentation and cleavage of poly(ADP-ribose)polymerase (PARP) by activated caspase-3. The in vitro reconstitution of intact HeLa S3 nuclei and apoptotic U937 cytosolic extract (CE) revealed that (i) Ca2+/Mg(2+)-dependent, Zn(2+)-sensitive endonuclease activated in the apoptotic CE induced DNA ladder in HeLa nuclei at pH 6.8-7.4, (ii) activated caspase-3 cleaved PARP in HeLa nuclei, and (iii) when the apoptotic CE was treated with the caspase-3 inhibitor (1 microM Ac-DEVD-CHO) or the caspase-1 inhibitor (10 microM Ac-YVAD-CHO), the former, but not the latter, caused a 50% inhibition of DNA fragmentation and the complete inhibition of PARP cleavage in HeLa nuclei. Similarly, Ac-DEVD-CHO (100 microM) inhibited apoptosis and DNA ladder by 50% and PARP cleavage completely in UV-irradiated U937 cells, but Ac-YVAD-CHO (100 microM) did not. Thus, UV-induced apoptosis of U937 cells involves the Ca2+/Mg(2+)-dependent endonuclease pathway and the caspase-3-PARP cleavage-Ca2+/Mg(2+)-dependent endonuclease pathway. The former pathway produced directly 50% of apoptotic DNA ladder, and the latter involved activated caspase-3 and PARP cleavage, followed by formation of the remaining 50% DNA ladder by the activated endonuclease. In UV-irradiated B-cell lines, further, p53-dependent increase of Bax resulted in a greater caspase-3 activation compared to its absence. However, UV-induced activation of JNK1 and p38 was not affected by the caspase-1 and -3 inhibitors in U937 cells, so that caspases-1 and -3 do not function upstream of JNK1 and p38.

Micromolar zinc affects endonucleolytic activity in hydrogen peroxide-mediated apoptosis

When damaged by hydrogen peroxide, peripheral blood lymphocytes undergo cell death by apoptosis in the absence of internucleosomal DNA cleavage, while, in the same cells, other apoptosis-inducing treatments bring DNA cleavage to completion. However, the formation of internucleosomal DNA fragments is readily obtained if cells are pretreated with a divalent metal chelator, TPEN, at micromolar concentrations. Since the coadministration of equimolar zinc concentrations abrogates the formation of the ladder, a zinc-inhibitable endonucleolytic activity is accounted for the effect. Most notably, subtraction of zinc ions does not increase the percentage of cells undergoing apoptosis, but rather results in a rescue from death.

Activation of caspase-3-like enzymes in non-apoptotic T cells

The activation of the caspase family of cysteine proteases is a key step in the implementation of apoptotic cell death leading to further downstream effects such as DNA fragmentation. In cultured tumor cells, caspase activity appears only when cells are undergoing apoptosis. Here we show that human and murine T lymphocytes acquire high intracellular activities of cell death-specific caspases upon activation by mitogens and IL-2 without evidence that apoptosis is proceeding. The highest activity is seen when cells are mitogen activated for 3 days. On a per cell basis, caspase activity in activated T cells is much higher than in tumor cells induced to undergo apoptosis. In the presence of exogenously added IL-2 cells stay alive and maintain a high level of caspase activity while IL-2 withdrawal results in cell death and decline of caspase activity. Caspase activity can also be measured in extracts from spleen and lymph nodes from mice injected with superantigen. While in tumor cell lines caspase activity correlates with cleavage of poly(ADP)-ribose polymerase (PARP) and DNA fragmentation, in activated T cells cleavage products of cellular PARP can be detected whereas DNA fragmenting activity appears only upon IL-2 withdrawal which coincides with cell death. These data show that caspase activation in intact cells does not necessarily lead to cell death and argue for a checkpoint in the apoptotic pathway downstream of caspases. Furthermore, they provide a molecular correlate for the high susceptibility of activated T cells for apoptosis.

Activation of a PP2A-like phosphatase and dephosphorylation of tau protein characterize onset of the execution phase of apoptosis

The execution phase is an evolutionarily conserved stage of apoptosis that occurs with remarkable temporal and morphological uniformity in most if not all cell types regardless of the condition used to induce death. Characteristic features of apoptosis such as membrane blebbing, DNA fragmentation, chromatin condensation, and cell shrinkage occur during the execution phase; therefore, there is considerable interest in defining biochemical changes and signaling events early in the execution phase. Since onset of the execution phase is asynchronous across a population with only a small fraction of cells in this stage at any given time, characterizing underlying biochemical changes is difficult. An additional complication is recent evidence suggesting that the execution phase occurs after cells commit to die; thus, agents that modulate events in the execution phase may alter the morphological progression of apoptosis but will not affect the time-course of death. In the present study, we use a single cell approach to study and temporally order biochemical and cytoskeletal events that occur specifically in the execution phase. Microtubules de-acetylate and disassemble as terminally differentiated PC12 cells enter the execution phase following removal of nerve growth factor. Using phosphorylation sensitive antibodies to tau, we show that this microtubule-stabilizing protein becomes dephosphorylated near the onset of the execution phase. Low concentrations of okadaic acid inhibit dephosphorylation suggesting a PP2A-like phosphatase is responsible. Transfecting (tau) into CHO cells to act as a ‘reporter’ protein shows a similar dephosphorylation of (tau) by a PP2A-like phosphatase during the execution phase following induction of apoptosis with UV irradiation. Therefore, activation of PP2A phosphatase occurs at the onset of the execution phase in two very different cell types following different initiators of apoptosis which is consistent with activation of PP2A phosphatase being a common feature of the execution phase of apoptosis. Experiments using either taxol to inhibit microtubule disassembly or okadaic acid to inhibit tau dephosphorylation suggest that microtubule disassembly is necessary for tau dephosphorylation to occur. Thus, we propose that an early step in the execution phase (soon after a cell commits to die) is microtubule disassembly which frees or activates PP2A to dephosphorylate tau as well as other substrates.

Induction of the mitochondrial permeability transition causes release of the apoptogenic factor cytochrome c

It was recently reported that the mitochondrial protein cytochrome c is required for the induction of apoptosis, and that the overexpression of Bcl-2 caused increased retention of this apoptogenic factor by mitochondria. Several cellular toxins, including H2O2, tBOOH and Ca++, induce the Mitochondrial Permeability Transition (MPT); we tested the possibility that MPT is an intracellular sensor of toxicity that results in the release of cytochrome c. We observe that the release of cytochrome c from purified mitochondria is stimulated by the classical inducers of MPT, and is inhibited by the classical inhibitor of MPT, cyclosporin A (CsA). After induction of MPT, mitochondrial supernatants gained the activity to induce cleavage of caspase 3 (CPP32) in cytosolic extracts, and this gain of activity was inhibited by CsA pretreatment of mitochondria, and was cancelled by immunodepletion of cytochrome c from the supernatants. After induction of MPT, mitochondrial supernatants mixed with or without cytosolic extract gained the activity to ladder nuclei, and this gain of activity was inhibited by CsA pretreatment of mitochondria, and cancelled by immunodepletion of cytochrome c from the supernatants. These results demonstrate that the induction of MPT causes release of cytochrome c from mitochondria, which is required for the hallmarks of cytosolic and nuclear apoptosis, caspase 3 activation and nuclear laddering, and identify the MPT as a potential intracellular sensor of oxidants and other toxins, and as a target for the pharmacological inhibition of apoptosis.

Caspases are activated in a branched protease cascade and control distinct downstream processes in Fas-induced apoptosis

Two novel synthetic tetrapeptides, VEID-CHO and DMQD-CHO, could selectively inhibit caspase-6 and caspase-3, respectively. We used these inhibitors to dissect the pathway of caspase activation in Fas-stimulated Jurkat cells and identify the roles of each active caspase in apoptotic processes. Affinity labeling techniques revealed a branched protease cascade in which caspase-8 activates caspase-3 and -7, and caspase-3, in turn, activates caspase-6. Both caspase-6 and -3 have major roles in nuclear apoptosis. Caspase-6 cleaves nuclear mitotic apparatus protein (NuMA) and mediates the shrinkage and fragmentation of nuclei. Caspase-3 cleaves NuMA at sites distinct from caspase-6, and mediates DNA fragmentation and chromatin condensation. It is also involved in extranuclear apoptotic events: cleavage of PAK2, formation of apoptotic bodies, and exposure of phosphatidylserine on the cell surface. In contrast, a caspase(s) distinct from caspase-3 or -6 mediates the disruption of mitochondrial membrane potential (permeability transition) and the shrinkage of cytoplasm. These findings demonstrate that caspases are organized in a protease cascade, and that each activated caspase plays a distinct role(s) in the execution of Fas-induced cell death.

Temporal and Spatial Distribution of DNA Topoisomerase II Alters During Proliferation, Differentiation, and Apoptosis in HL-60 Cells

We related cellular content of DNA topoisomerase (topo) IIα and IIβ with the cell cycle position in proliferating, differentiated, and apoptotic HL-60 cells using two-dimensional flow cytometry. In logarithmically growing HL-60 cells, topo IIα increased especially in late S to G2/M phases, although the topo IIβ level was almost constant throughout the cell cycle. Induction of differentiation by all-trans retinoic acid dramatically reduced the topo IIα but not the topo IIβ level. A new G2/M population containing virtually no topo IIα appeared during differentiation and was supposed to be alive and noncycling. Two-dimensional flow cytometry of topo IIα or IIβ staining and terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling assay showed that one topo IIβ epitope situated at the C-terminal end decreased specifically in apoptotic HL-60 cells treated with Ara-C, etoposide, and vincristine. The amounts of a topo IIα epitope and another topo IIβ epitope located at a more central portion were almost equal between apoptotic and nonapoptotic cells. Western blot analysis confirmed that topo IIβ protein was completely degraded into smaller fragments and lost its C-terminal end during apoptosis. On the contrary, a large portion of topo IIα remained of its original size, although both topo IIα and IIβ left from the nuclear fraction in apoptotic cells. Confocal laser microscopy showed nuclear localization of topo IIα and IIβ in growing HL-60 cells. Although topo IIα and IIβ were distributed throughout the cell during mitosis, only topo IIα was densely concentrated in the mitotic chromosomes. Both enzymes were dissociated from the genomic DNA even at an early phase of apoptosis and completely separated from the propidium iodide signal of DNA in the advanced stage. Chromatin condensation process in apoptosis is therefore completely topo II-independent and obviously differs from the mitotic one.

Cytosolic nuclease activated by caspase-3 and inhibited by DFF-45

To study the intracellular apoptotic signaling pathways, we have established a cell-free system, in which DNA fragmentation of the isolated mouse liver nuclei was induced with lysates from the Fas-activated cells. We have found that the inactive nuclease present in the intact cell cytosol is activated by a caspase-3-like protease and the activated nuclease induces the nucleosomal DNA fragmentation. We attempted the purification of the inactive nuclease from bovine liver cytosol. The partially purified nuclease was activated by recombinant caspase-3, and to a lesser extent by caspase-6. The activated nuclease was able to digest plasmid DNA in addition to induce the DNA fragmentation of nuclei. DFF-45, which is a subunit of heterodimeric protein leading to DNA fragmentation upon its digestion by caspase-3, is found to inhibit the activity of the activated nuclease. These results suggest that the inactive nuclease in cytoplasm is converted to the active form by caspases, and the activated nuclease enters into nucleus to induce the DNA fragmentation. It is suggested that DFF-45 may function as an inhibitory factor of the caspase-sensitive nuclease in vivo.

Asynchrony and commitment to die during apoptosis

Time lapse video microscopy is used to study the chronology of morphological changes and commitment to die in individual PC12 cells after induction of apoptosis. Cell death is highly asynchronous occurring over a 2- to 3-day period following serum removal; however, all cells go through three characteristic morphological phases irrespective of the time they die following serum removal. During phase 1, which lasts from 2 to 44 h, cells maintain normal morphology. Phase 2 is characterized by plasma membrane bubbling which lasts from 10 min to 40 h. Phase 3 represents the active or execution phase of apoptosis and involves dynamic whole cell body blebbing. Phase 3/execution phase has a restricted duration, lasting 96 +/- 5 min. At the end of the execution phase of apoptosis, cells die. The inherently asynchronous nature of cell death is still present in cells that are synchronized following mitosis. Daughter cells enter phase 2 synchronously but remain in phase 2 for varying periods and die at different times. Addition of serum 24-48 h after initiating apoptosis blocks death of 89% of cells in phase 1, 79% in phase 2, and 0% in phase 3. Serum rescue experiments are consistent with cells committing to die about 2-3 h prior to the onset of phase 3 (execution phase of apoptosis). These studies indicate that although apoptosis is an asynchronous process it can be defined in terms of reproducible morphological changes that can be used to place other events, such as the commitment to die, in a temporal sequence.

Apoptosis and Fas expression in human fetal membranes

Apoptosis (i.e. programmed cell death) plays a key role in maintaining reproductive function in the ovary, mammary and prostate glands, uterus, and testis. The purpose of the present report was to determine, based on biochemical and morphological parameters, whether cells in human fetal membranes undergo apoptosis and express Fas (CD95), a cell surface receptor that mediates apoptosis. Using the terminal deoxynucleotidyl transferase deoxy-UTP-nick end labeling immunohistochemical technique, apoptotic nuclei were identified in amnion epithelial, chorionic trophoblast, and decidua parietalis cell layers of human fetal membranes at term. Electron microscopy of fetal membranes revealed ultrastructural characteristics in amnion epithelium and chorion trophoblast cell layers consistent with apoptosis, including condensation of chromatin along the periphery of the nucleus and nuclear shrinkage. The apoptotic index (percentage of terminal deoxynucleotidyl transferase deoxy-UTP-nick end labeling-positive nuclei of the total nuclei) ranged from 8-29% in amnion epithelial, chorionic trophoblast, and decidual cell layers from women at 23-30, 31-36, and 37-42 weeks gestation. The apoptotic index was statistically greater in the 37-42 week group than in the 23-30 week group in chorionic trophoblast (P < 0.05) and decidual cell (P < 0.01) layers. In contrast, the apoptotic index in the amnion epithelial cell layer was statistically greater (P < 0.05) in the 23-30 week group than in the 31-36 week group, suggesting that apoptosis may be independently regulated in amnion epithelial, chorionic trophoblast, and decidual cell types. Based on the importance of Fas in mediating apoptosis, we investigated whether Fas was expressed by human fetal membrane cells. Immunohistochemical staining of fetal membranes with anti-Fas antibody localized Fas in amnion epithelial, chorionic trophoblast, and decidua parietalis cell layers. A 266-bp band corresponding to the cytoplasmic domain of Fas was detected in samples of amnion, chorion, decidua, and placenta by RT-PCR. Northern blotting revealed a molecular weight of approximately 1.9 kilobases for Fas messenger ribonucleic acid in amniotic tissue. These data suggest that apoptosis and Fas signaling may play a role in remodeling of fetal membrane architecture across gestation.