Activation of the CED3/ICE-Related Protease CPP32 in Cerebellar Granule Neurons Undergoing Apoptosis But Not Necrosis (original) (raw)

J Neurosci. 1997 Jan 15; 17(2): 553–562.

Robert C. Armstrong

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Teresa J. Aja

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Kim D. Hoang

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Smita Gaur

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Xu Bai

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Emad S. Alnemri

2Jefferson Cancer Institute, Thomas Jefferson University, Philadelphia, Pennsylvania 19107

Gerald Litwack

2Jefferson Cancer Institute, Thomas Jefferson University, Philadelphia, Pennsylvania 19107

Donald S. Karanewsky

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Lawrence C. Fritz

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

Kevin J. Tomaselli

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

1IDUN Pharmaceuticals, Inc., La Jolla, California 92037, and

2Jefferson Cancer Institute, Thomas Jefferson University, Philadelphia, Pennsylvania 19107

Received 1996 Sep 4; Revised 1996 Oct 17; Accepted 1996 Oct 23.

Abstract

Neuronal apoptosis occurs during nervous system development and after pathological insults to the adult nervous system. Inhibition of CED3/ICE-related proteases has been shown to inhibit neuronal apoptosis_in vitro_ and in vivo, indicating a role for these cysteine proteases in neuronal apoptosis. We have studied the activation of the CED3/ICE-related protease CPP32 in two in vitro models of mouse cerebellar granule neuronal cell death: K+/serum deprivation-induced apoptosis and glutamate-induced necrosis. Pretreatment of granule neurons with a selective, irreversible inhibitor of CED3/ICE family proteases, ZVAD-fluoromethylketone, specifically inhibited granule neuron apoptosis but not necrosis, indicating a selective role for CED3/ICE proteases in granule neuron apoptosis. Extracts prepared from apoptotic, but not necrotic, granule neurons contained a protease activity that cleaved the CPP32 substrate Ac-DEVD-aminomethylcoumarin. Induction of the protease activity was prevented by inhibitors of RNA or protein synthesis or by the CED3/ICE protease inhibitor. Affinity labeling of the protease activity with an irreversible CED3/ICE protease inhibitor, ZVK(biotin)D-fluoromethylketone, identified two putative protease subunits, p20 and p18, that were present in apoptotic but not necrotic granule neuron extracts. Western blotting with antibodies to the C terminus of the large subunit of mouse CPP32 (anti-CPP32) identified p20 and p18 as processed subunits of the CPP32 proenzyme. Anti-CPP32 specifically inhibited the DEVD-amc cleaving activity, verifying the presence of active CPP32 protease in the apoptotic granule neuron extracts. Western blotting demonstrated that the CPP32 proenzyme was expressed in granule neurons before induction of apoptosis. These results demonstrate that the CED3/ICE homolog CPP32 is processed and activated during cerebellar granule neuron apoptosis. CPP32 activation requires macromolecular synthesis and CED3/ICE protease activity. The lack of CPP32 activation during granule neuron necrosis suggests that proteolytic processing and activation of CED3/ICE proteases are specific biochemical markers of apoptosis.

Keywords: apoptosis, necrosis, cerebellar neurons, CED3/ICE proteases, CPP32, Caspase

Cell death is a prominent feature of the developing nervous system. In both neuronal and glial populations, as many as 70% of the cells that are generated die during a period of naturally occurring cell death (for review, see Oppenheim, 1991; Raff et al., 1993). Many naturally occurring neuronal cell deaths are apoptotic in nature (Oppenheim et al., 1990; Wood et al., 1993;Blaschke et al., 1996) and can be modeled in vitro by trophic factor deprivation. For example, developing superior cervical ganglion neurons undergo apoptosis when deprived of nerve growth factor_in vitro_ (Martin et al., 1988; Deckwerth and Johnson, 1993). Similarly, spinal motoneurons undergo apoptosis in culture when deprived of muscle-derived survival factors (Milligan et al., 1994). Neuronal cell death induced by trophic factor deprivation is blocked, in some instances, by expression of the anti-apoptotic human proto-oncogene bcl-2 (Allsopp et al., 1993).

In the adult nervous system, neuronal cell death occurs in response to ischemia. Recent studies provide evidence for both apoptotic and necrotic neuronal cell death after ischemia (for review, see Bredesen, 1995). For example, inhibition of macromolecular synthesis or transgenic overexpression of Bcl-2 protein in neurons reduces infarct size in rodent models of brain ischemia (Linnik et al., 1993; Martinou et al., 1994). Thus, in addition to programmed neuronal cell death during development, neuronal apoptosis occurs in the adult nervous system in response to injury.

Genetic studies in the roundworm _Caenorhabditis elegans_identified the ced3 gene, whose function is required for all of the developmentally programmed deaths in the hermaphrodite (Yuan et al., 1993). CED3 is a cysteine protease that cleaves proteins at Asp-X peptide bonds (Xue and Horvitz, 1995; Hugunin et al., 1996; Xue et al., 1996). There are currently ten human homologs of CED3 comprising the CED3/ICE family of cysteine proteases (Ceretti et al., 1992; Thornberry et al., 1992; Kumar et al., 1993; Fernandes-Alnemri et al., 1994, 1995a,b, 1996; Wang et al., 1994; Faucheu et al., 1995; Kamens et al., 1995; Munday et al., 1995; Boldin et al., 1996; Duan et al., 1996;Muzio et al., 1996; Srinivasula et al., 1996). As with CED3, all of the mammalian CED3/ICE proteases identified to date are cysteine proteases with Asp cleavage specificities. Several studies have implicated CED3/ICE proteases in neuronal apoptosis. First, neuronal apoptosis can be blocked by expression of either of two viral anti-apoptotic genes,CrmA or p35 (Rabizabeh et al., 1993; Gagliardini et al., 1994), whose protein products are potent inhibitors of CED3/ICE proteases (Ray et al., 1992; Komiyama et al., 1994; Bump et al., 1995;Xue and Horvitz, 1995; Bertin et al., 1996). Second, selective peptide inhibitors of CED3/ICE proteases block apoptosis of lumbar spinal motoneurons, both in vitro and in vivo (Milligan et al., 1995). Because the viral and peptidyl inhibitors inhibit multiple CED3/ICE family members (Bump et al., 1995; Bertin et al., 1996), the protease targets of these inhibitors in neuronal cells are currently unknown. Although mRNAs encoding CED3/ICE proteases have been detected in brain (Kumar et al., 1993; Wang et al., 1994;Fernandes-Alnemri et al., 1995b; 1996), no studies have addressed the functions of specific family members in neuronal apoptosis.

Recent evidence has implicated the CED3/ICE-related protease CPP32 in the effector pathway of apoptosis in non-neuronal cells (Darmon et al., 1995; Nicholson et al., 1995; Tewari et al., 1995). Consistent with such a role, CPP32 and a closely related homolog, MCH3/ICELAP3, are cleaved from their proenzyme forms and activated early during apoptosis by treatment with Fas antibody or staurosporine (Armstrong et al., 1996; Chinnaiyan et al., 1996; Duan et al., 1996; Schlegel et al., 1996). In the present study, we sought evidence of activation of CED3/ICE proteases in an in vitro model of cerebellar granule neuronal apoptosis (D’Mello et al., 1993; Yan et al., 1994;Galli et al., 1995). We demonstrate that CPP32 is cleaved and activated early during cerebellar granule neuron apoptosis. CPP32 activation was prevented when apoptosis was blocked by inhibitors of RNA or protein synthesis, or by a selective inhibitor of CED3/ICE proteases. In addition, CPP32 activation seemed to be specific for apoptosis, because it was not observed when cerebellar granule neurons underwent necrotic cell death.

MATERIALS AND METHODS

Neuronal cell culture. Cerebellar granule neurons were isolated from 3- to 4-d-old C57Black6 mice (Harlan Sprague Dawley, Indianapolis, IN) and were purified by density sedimentation. Briefly, cerebella were removed and dissociated with 0.25% trypsin (Worthington, Freehold, NJ) in calcium- and magnesium-free HBSS (BioWhittaker, Walkersville, MD) for 25 min at 37°C. Trypsin was inactivated with an equal volume of Eagle’s basal media (BME; Life Technologies, Gaithersburg, MD) containing 10% fetal bovine serum (Hyclone, Logan, UT) and 0.4% DNase (Worthington) before dissociation by trituration using a Pasteur pipette. Dissociated cells were centrifuged for 10 min at 3000 rpm through a discontinuous percoll gradient (35%/60%). The granule neurons were harvested from the 35%/60% interface and washed with calcium- and magnesium-free DPBS (BioWhittaker). The neurons were plated on poly-d-lysine-coated (Becton Dickinson, Bedford, MA) 96-well plates, 60 mm dishes, or eight-well chamber slides in BME supplemented with 10% fetal bovine serum, 25 mmKCl, and 50 μg/ml gentamicin sulfate at a density of 312,500 cells/cm2. After the addition of 5 μm AraC on the second day, the cultures were maintained at 37°C/5% CO2 for 7 d without a change in medium.

Viability studies. After 7 d, apoptosis was induced (D’Mello et al., 1993) by switching to a medium containing reduced potassium and no serum. The medium change involved three sequential 5:1 dilutions with BME supplemented only with 5 mm KCl. To induce necrosis (Ankarcrona et al., 1995), cultures were exposed to 300 μm or 3.0 mm glutamate for 30 min in Locke solution (134 mm NaCl, 25 mm KCl, 4 mm NaHCO3, 5 mm HEPES, 2.3 mm CaCl2, and 5 mm glucose) in the presence of 10 μm glycine. At the end of 30 min, the cultures were washed in BME and returned to the original conditioned medium. Alternatively, necrosis was induced by a single media change to BME containing fresh serum. Exposure of 7 d cultured cerebellar granule neurons to fresh serum has been reported to induce an acute, NMDA receptor-dependent cell death (Schramm et al., 1990). The addition of inhibitors or other compounds was carried out concomitantly with treatment. Viability was measured in triplicate in 96-well plates by either monitoring the conversion of Alamar blue to a fluorescent product or by quantitative colorimetric assay with 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT). Viability was expressed as the ratio of the signal obtained from treated cultures and the signal from untouched control cultures multiplied by 100 (percentage control).

Assessment of nuclear morphology. Eight-well chamber slides were treated as described above. Cells were labeled with Hoechst 33342 (5 μg/ml) for 15 min, washed in PBS, and fixed in 10% formalin. Fixed cells were washed and mounted under glass coverslips with citifluor and viewed on a Nikon Diaphot microscope with illumination at 430 nm ultraviolet light.

DEVD-amc cleavage studies. Cells in 96-well plates were treated as described above. At the appropriate time, medium was aspirated, and the neurons were lysed in 50 μl of buffer A (10 mm HEPES, pH 7.4, 42 mm KCl, 5 mmMgCl2, 1 mm PMSF, 0.1 mm EDTA, 0.1 mm EGTA, 1 mm DTT, 1 μg/ml pepstatin A, 1 μg/ml leupeptin, 5 μg/ml aprotinin, 0.5% CHAPS). DEVD-amc was added to a final concentration of 10 μm in 150 μl of buffer B (25 mm HEPES, 1 mm EDTA, 0.1% CHAPS, 10% sucrose, 3 mm DTT, pH 7.5). Fluorescent amc production was measured at excitation 360 nm, emission 460 nm, using a Cytofluor II fluorescent plate reader (Millipore, Bedford, MA). Experiments were performed in triplicate, and the activity was expressed as change in fluorescence units per hour per 100,000 cells. For experiments examining the ability of ZVAD-fmk to inhibit the induction of DEVD-amc cleaving activity, neurons were washed four times with 200 μl PBS to remove residual inhibitor before cell lysis. To ensure that excess inhibitor was removed by this washing protocol, recombinant human CPP32 was added to control cell lysates that either had been exposed or not been exposed to ZVAD-fmk, and added CPP32 activity was compared with CPP32 alone.

Titration experiments using Ac-DEVD-aldehyde and anti-CPP32 antibody were performed against neuronal extracts derived from 60 mmplates 8 hr after K+ switching. For these experiments, plates with 5 × 106 neurons were harvested by scraping in PBS and centrifuging at 5000 × g for 15 min. Cells were lysed in 40 μl of buffer A, and extracts were assayed for DEVD-amc cleaving activity. Equivalent units of neuronal extract, recombinant human CPP32, and mouse ICE proteases were then used to titrate the activity of the anti-CPP32. Recombinant CPP32 and ICE were expressed in Escherichia coli as described previously (Armstrong et al., 1996). The 8 hr granule neuronal extract and CPP32 were tested with DEVD-amc as the substrate, whereas ICE was assayed with YVAD-amc as substrate. Experiments were performed in duplicate, and the results were expressed as the amount of residual activity when compared with the reaction with no inhibitor (percentage control).

SDS-PAGE and Western blotting. SDS-PAGE was performed with precast gels from NOVEX (San Diego, CA) according to their specifications. Neuronal extracts were prepared by lysis in buffer A (40 μl/5 × 106 cells). Twenty micrograms of extract were run in each lane and then transferred to nitrocellulose. Blots were blocked with 3% BSA in TBST (50 mm Tris, pH 7.5, 150 mm NaCl, 0.05% Tween 20) and probed with 1:1000 dilutions of the anti-CPP32 antibodies in TBST/1% BSA. Immunoreactive species were visualized with goat-anti-rabbit alkaline phosphatase-conjugated secondary antibody (Jackson Labs, Bar Harbor, ME). An antiserum (anti-CPP32p20Pep) was raised to a 13 amino acid peptide (CRGTELDCGIETD) corresponding to the C terminus of the p20 subunit of human and mouse CPP32. The peptide was coupled via cysteine to KLH. The antiserum was affinity-purified against the peptide coupled to Sepharose 4B (Pharmacia, Piscataway, NJ). The purified antiserum was shown by Western blotting to recognize the processed p20 subunit of recombinant, active mouse CPP32. A second antiserum (anti-CPP32RP) was raised against the large subunit of recombinant human CPP32 purified from E. coli lysates by affinity chromotography (Srinivasula et al., 1996).

Affinity labeling with ZVK(biotin)D-fmk was achieved by incubation of 20 μg of neuronal extract with 0.1 μm ZVK(biotin)D-fmk at 4°C for 20 hr, a time at which all of the DEVD-amc cleaving activity was inhibited. Labeled extracts were separated by SDS-PAGE and transferred to PVDF membrane, and biotinylated species were visualized with streptavidin-conjugated alkaline phosphatase using a Tropix ECL kit (Bedford, MA).

Substrate and inhibitor synthesis. Ac-AspGluValAsp-amc (Ac-DEVD-amc) was prepared by coupling Ac-Asp(OBut)-OH to H-Glu(OBut) ValAsp(OBut)ValAsp(OBut)-amc followed by deprotection with 50% TFA in CH2Cl2. The requisite amine was prepared by coupling CBZX-Glu(OBut)Val-OH to H-Asp(OBut)-amc followed by catalytic hydrogenation over Pd-C.

CBZ-ValLys(biotin)Asp-CH2 F [ZVK(biotin)D-fmk] was prepared via a modified Pfitzer-Moffatt oxidation of CBZ-ValLys(biotin)NHCH(CH2CO2But)CH(OH)CH2 F with EDAC and pyridinium trifluoroacetate in DMSO-CH2 Cl2 followed by deprotection with 35% TFA in CH2 Cl2/anisole. The requisite alcohol was prepared by coupling CBZ-ValLys(biotin)-OH to H2NCH(CH2CO2But)CH(OH)CH2F (Revesz et al., 1994) with EDAC-HOBt in DMF. CBZ-ValLys(biotin)-OH was prepared in three steps from CBZ-ValLys(Boc)-OMe by successive reactions with (1) 25% TFA in CH2Cl2, (2)d-biotin-OSu in CH2Cl2-DMF, and (3) 1.0 N NaOH in MeOH20 (4:1).

Benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone (ZVAD-fmk) was synthesized as described in Armstrong et al. (1996). BenzyloxycarbonylPhe-Ala-fluoromethylketone (ZFA-fmk) was purchased from Enzyme Systems Products (Dublin, CA). Ac-Tyr-Val-Ala-Asp-amc (YVAD-amc) was purchased from Bachem (King of Prussia, PA).

RESULTS

Induction of apoptosis and necrosis in cerebellar granule neurons

Purified mouse cerebellar granule neurons were cultured for 7 d in depolarizing levels of K+ (25 mm) in the presence of serum. Simultaneous lowering of the K+concentration to 5 mm and removal of serum (K+/serum withdrawal) led to a loss of neuronal viability. Morphologically, most of the neurons remained normal in appearance for 2–4 hr after K+/serum withdrawal, after which they progressively underwent cytoplasmic and nuclear condensation typical of apoptosis, as has been observed previously (D’Mello et al., 1993). As assessed by the ability of the neurons to metabolize MTT, a small loss of viability was observed by 4 hr after K+/serum withdrawal. At 8 hr the viability was reduced to 40% of untreated control cultures, and by 24 hr viability was reduced to 80% (Fig.​1A). Nuclear staining with Hoechst 33342 confirmed that the loss of viability was attributable to apoptosis. Nuclear condensation was observed in a small percentage of neurons as early as 2 hr after K+/serum withdrawal. By 8 hr, the majority of the neurons contained condensed nuclei, with some showing margination of the chromatin and nuclear fragmentation (Fig.​2D). Of note, however, and in agreement with the MTT data, some of the neurons appeared to be resistant to the apoptotic stimulus, showing no evidence of nuclear condensation even at 24 hr (data not shown). Cerebellar granule neuron apoptosis was blocked significantly by treatment with either 10 μg/ml cycloheximide (Figs. ​1B, ​2G) or 1 μg/ml actinomycin D (Fig. ​2H). The need for macromolecular synthesis to activate apoptosis in cerebellar granule neurons has been observed previously (D’Mello et al., 1993; Galli et al., 1995).

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Cerebellar granule neuron cell death induced by withdrawal of K+/serum or exposure to glutamate.A, Time course of loss of viability of granule neurons after K+/serum deprivation (open diamonds) or exposure to 300 μm glutamate (open squares). B, Viability of granule neurons 24 hr after K+/serum deprivation (5 mm_K+_/No Serum) without or with cycloheximide (Cycloheximide) (10 μg/ml), ZVAD-fmk (ZVAD-FMK) (50 μm), or ZFA-fmk (ZFA-FMK) (50 μm).C, Viability of granule neurons 2 hr after exposure to glutamate (300 μm) without or with cycloheximide (10 μg/ml), ZVAD-fmk (50 μm), or ZFA-fmk (50 μm). Cell viability was measured using MTT. Values represent the mean ± SEM of triplicate cultures run in parallel and are expressed as percentage of untreated control cultures.

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Phase-contrast (A, C, E) and Hoechst 33342 immunofluorescence (B, D, F–J) microscopy of cerebellar granule neurons after K+/serum withdrawal (A–H) or exposure to 300 μm glutamate (I, J). Phase-contrast of control untreated neurons (A) or neurons 24 hr after high K+/serum withdrawal in the absence (C) or presence (E) of 50 μm ZVAD-fmk. Note highly refractile, condensed cell bodies (∼2–3 μm diameter) of apoptotic neurons in_C_ and the relative reduction in their proportion in_E_. Hoechst-labeled nuclei of control, untreated granule neurons (B), or neurons after 8 hr of K+/serum withdrawal in the absence (D) or presence (F) of 50 μm ZVAD-fmk.Arrow in D marks a highly condensed, apoptotic nucleus. Arrow in F marks a nucleus that is less well protected by ZVAD-fmk than the surrounding nuclei. Hoechst-labeled nuclei of cells 24 hr after K+/serum withdrawal in the presence of either 10 μg/ml cycloheximide (G) or 1 μg/ml actinomycin D (H). Note normal size and morphology of nuclei in_G_ and H. Hoechst-labeled nuclei in cells 2 (I) or 8 hr (J) after exposure to 300 μm glutamate. Note that nuclei in_I_ look normal in size and appearance of nucleoli.Arrow in J marks a nucleus that appears slightly shrunken compared with the normal-sized nucleus indicated by the arrowhead. Scale bars: A, 25 μm; B, 10 μm.

To induce necrotic cell death, cerebellar neurons were exposed to high concentrations of glutamate that were shown previously to induce an acute, nonapoptotic cell death (Ankarcrona et al., 1995). Thirty minutes of exposure of the neurons to 0.3–3.0 mm glutamate in the presence of 10 μm glycine led to a loss of viability that differed both kinetically and morphologically from that induced by K+/serum deprivation. Treatment with either 300 μm or 3 mm glutamate led to a more rapid loss of viability: at the earliest time point studied (2 hr) after glutamate treatment, neuronal viability had reached its nadir of 20% of untreated control (Fig. ​1A). Morphologically, these neurons displayed none of the typical signs of apoptosis. Most of the neurons appeared swollen or ruptured by phase-contrast microscopy, with nuclei that appeared similar to control after staining with the Hoechst dye (Fig. ​2I). Exposure to fresh serum, which acutely kills cerebellar granule neurons through a glutamate-like mechanism (Schramm et al., 1990), produced similar results (data not shown). On prolonged incubation after glutamate exposure (8–24 hr), some of the nuclei appeared condensed (Fig. ​2J). These may represent a population of neurons that undergo delayed apoptotic death as reported previously (Ankarcrona et al., 1995). In contrast to the apoptotic death induced by K+/serum withdrawal, glutamate-induced cell death was not inhibited significantly by either cycloheximide (Fig. ​1C) or actinomycin D (data not shown). These observations are in agreement with previous reports demonstrating that exposure to high-dose glutamate leads to acute, necrotic death of cerebellar granule neurons (Ankarcrona et al., 1995).

Involvement of CED3/ICE protease(s) in apoptotic granule neuron death

Peptide inhibitors of CED3/ICE proteases have been shown to inhibit trophic factor deprivation-induced apoptosis of motoneurons (Milligan et al., 1995) and cerebellar granule neurons (Schulz et al., 1996). We tested the ability of ZVAD-fmk, a selective, irreversible inhibitor of CED3/ICE proteases, to inhibit cerebellar granule neuron apoptosis. ZVAD-fmk inhibits recombinant ICE and CPP32 proteases ∼10,000-fold and 500-fold faster, respectively, than it does the cysteine protease calpain 1 and has no observable inhibitory activity against the Asp-X-directed serine protease granzyme B (Armstrong et al., 1996). ZVAD-fmk (50 μm) significantly inhibited the loss of viability observed after K+/serum deprivation (Figs. ​1B, ​2C). The inhibition by ZVAD-fmk at 24 hr was not complete, with maximal inhibition ranging from ∼30% to 80% in different experiments. Inhibition by ZVAD-fmk was dose-dependent (data not shown) and specific, because a control cysteine protease inhibitor, ZFA-fmk, which lacks the Asp in the P1 position, had no anti-apoptotic activity (Fig. ​1B). ZVAD-fmk treatment also dramatically reduced the nuclear condensation observed after K+/serum deprivation (Fig.​2D). In contrast to its anti-apoptotic effects, ZVAD-fmk failed to inhibit the necrotic death of cerebellar neurons induced by exposure to either 0.3 mm (Fig. ​1C) or 3 mm glutamate (data not shown). These results demonstrate a role for CED3/ICE proteases in apoptotic, but not necrotic, death of cerebellar granule neurons.

CED3/ICE family proteases are activated during cerebellar granule neuron apoptosis

Having established a role for CED3/ICE proteases in cerebellar granule neuron apoptosis, we analyzed the process of protease activation in this model. Detergent extracts prepared from neurons at various times after K+/serum withdrawal were tested for Ac-DEVD-amc cleaving activity. Ac-DEVD-amc is a fluorogenic, tetrapeptide substrate that is cleaved by CED3/ICE proteases (Nicholson et al., 1995; Armstrong et al., 1996). By 2 hr after K+/serum withdrawal, a small increase in DEVD-amc cleavage activity was observed, and by 8 hr protease activity had increased almost 14-fold over control extracts from untreated cells, decreasing by 24 hr (Fig. ​3A). In contrast, no increase in DEVD-amc cleaving activity was observed at any time during glutamate-induced cell death (Fig. ​3A). Even as early as 15–60 min after glutamate exposure, no DEVD-amc cleaving activity was observed (data not shown). Induction of the CED3/ICE-like protease activity was prevented in neurons treated with 1 μg/ml actinomycin D, 10 μg/ml cycloheximide, or 50 μm ZVAD-fmk (Fig.​3B), each of which inhibited apoptosis induced by K+/serum withdrawal (Figs. ​1, ​2). Inhibition of DEVD-amc cleaving activity by ZVAD-fmk was not attributable to inhibition by residual inhibitor that was present post-lysis, because control experiments in which recombinant human CPP32 was added to cells treated with ZVAD-fmk before cell lysis demonstrated that residual inhibitor was not present after washing (data not shown). Thus, activation of the CED3/ICE protease activity in apoptotic granule neurons requires both macromolecular synthesis and the action of CED3/ICE-like proteases.

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Induction of a Ac-DEVD-amc cleaving protease activity after K+/serum deprivation but not after exposure to glutamate. A, Time course of induction of Ac-DEVD-amc cleaving activity in extracts of granule neurons after K+/serum withdrawal (open squares) or exposure to 3 mm glutamate (open diamonds).B, Time course of induction of Ac-DEVD-amc cleaving activity in extracts of granule neurons after K+/serum deprivation in the absence (open squares with dotted line; data replotted from A) or in the presence of cycloheximide (10 μg/ml; open diamonds), actinomycin D (1 μg/ml; open circles), or ZVAD-fmk (50 μm; open triangle). Values represent the mean ± SEM of triplicate reactions run in parallel and are expressed as the change in fluorescence units per hour per 105 cells.

The Ac-DEVD-amc cleaving activity induced after K+/serum withdrawal was inhibited by Ac-DEVD-aldehyde, a potent, reversible inhibitor of several CED3/ICE proteases (Nicholson et al., 1995; Fernandes-Alnemri et al., 1995a,b, 1996). The IC50 of Ac-DEVD-aldehyde inhibition of the protease activity from an 8 hr apoptotic granule neuron extract was 0.65 nm, similar to that for inhibition of recombinant human CPP32 (IC50 0.5 nm; Fig.​4A). The granule neuron protease activity was also inhibited completely by an affinity-purified, function-blocking polyclonal antibody to the C terminus of the mouse CPP32 p20 subunit (Fig. ​4B). The anti-CPP32p20Pep specifically inhibited CPP32 protease activity, because it did not inhibit mouse ICE protease activity (Fig. ​4B). The anti-CPP32p20Pep IC50 of 217 μg/ml against the granule neuron apoptotic protease activity was nearly identical to that for inhibition of recombinant human CPP32 (228 μg/ml; Fig.​4B). These data demonstrate that the CED3/ICE-like protease activity induced in granule neurons undergoing apoptosis is biochemically and immunologically similar to CPP32.

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Inhibition by Ac-DEVD-aldehyde (A) and affinity-purified anti-CPP32 p20 (B) of the Ac-DEVD-amc cleaving activity present in extracts of granule neurons 8 hr after K+/serum deprivation. A, Dose–response of inhibition by Ac-DEVD-aldehyde of granule neuron protease activity (open squares) or recombinant human CPP32 protease (open diamonds). B, Dose–response of inhibition by anti-CPP32p20Pep of granule neuron protease activity (open squares), recombinant human CPP32 protease (open diamonds), or recombinant mouse ICE protease (open circles). Values represent the mean ± SEM of triplicate reactions run in parallel and are expressed as percentage of activity in uninhibited, control reactions.

CPP32 is processed after K+/serum withdrawal

CED3/ICE proteases activated during cerebellar neuron apoptosis were identified by affinity labeling with an irreversible inhibitor of ICE family proteases, ZVK (Biotin)D-fmk. ZVK(Biotin)D-fmk covalently modifies the active site cysteine of the processed “p20” subunits of several recombinant, active ICE family proteases, including human CPP32 and mouse ICE (data not shown). Untreated control or 8 hr apoptotic extracts were incubated for 20 hr with 0.1 μmZVK(biotin)D-fmk, sufficient time to inhibit all of the Ac-DEVD-amc cleaving activity present in the apoptotic extract. Detection of covalently labeled proteins by Western blotting using streptavidin/alkaline phosphatase identified two protease subunits of ∼20 and 18 kDa present only in the apoptotic extracts (Fig.​5A). Western blotting of the apoptotic extracts with antibodies to the C terminus of the large subunit of CPP32 identified two proteins, p20 and p18, that co-migrated with those recognized by the affinity label (Fig. ​5B). The p20 protein co-migrated with recombinant mouse CPP32 p20 expressed in bacteria (Fig. ​5B). The same two immunoreactive bands were observed with two additional independently derived CPP32 p20 antisera (Fig.​5B and data not shown). Neither of the CPP32 immunoreactive proteins was detected in extracts prepared from cells treated with glutamate for either 2 or 8 hr (Fig. ​5B). Thus, CPP32 is processed proteolytically to produce p20 and p18 subunits during cerebellar granule neuron apoptosis but not during necrosis. Incubation of cells with ZVAD-fmk prevented processing of pro-CPP32 to p20 and p18 subunits (Fig. ​5B). Thus, CPP32 processing is inhibited by a selective inhibitor of CED3/ICE family proteases.

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The CPP32 proenzyme is cleaved to generate p20/p18 subunits. A, Affinity labeling with ZVK(biotin)D-fmk of protease subunits in extracts of granule neurons before (lanes 1 and 2) or 8 hr after (_lanes 3_and 4) K+/serum withdrawal either in the presence (lanes 2 and 4) or absence (lanes 1 and 3) of ZVK(biotin)D-fmk. Two proteins of _M_r 20 and 18 kDa are labeled in the 8 hr apoptotic extract. B, Western blotting with affinity-purified anti-CPP32p20Pep (lanes 1–3, 5–7) or with the anti-CPP32RP antiserum (lane 4). Lane 1: recombinant mouse CPP32; lane 2: extracts of unstimulated granule neurons; lanes 3 and 4: extracts of granule neurons 8 hr after K+/serum deprivation;lane 5: extracts of granule neurons 8 hr after K+/serum deprivation in the presence of 50 μmZVAD-fmk; lanes 6 and 7: extracts of granule neurons 2 hr (lane 6) or 8 hr (lane 7) after exposure to 300 μmglutamate. C, Time course of disappearance of p32 proenzyme and appearance of p20 subunits before (lane 1) and at 2 hr (lane 2), 4 hr (lane 3), 6 hr (lane 4), and 8 hr (lane 5) after K+/serum withdrawal. Top panel was blotted with the anti-CPP32RP antiserum; bottom panel was blotted with the affinity-purified anti-CPP32p20Pep.

A time course study in apoptotic neurons revealed that the 32 kDa CPP32 proenzyme was expressed in unstimulated cells and was processed proteolytically within the first 8 hr of apoptosis. The anti-CPP32RP recognized the p32 proenzyme form of CPP32 in resting, unstimulated extracts, the levels of which declined substantially by 8 hr (Fig.​5C). Coincident with the disappearance of the CPP32 proenzyme, the processed p20 and p18 subunits recognized by anti-CPP32p20Pep accumulated (Fig. ​5C).

DISCUSSION

This study demonstrates for the first time the proteolytic processing and activation of a CED3/ICE protease, CPP32, in a model of neuronal apoptosis: K+/serum deprivation-induced cerebellar granule neuron apoptosis. By enzymological and biochemical criteria, CPP32 was proteolytically cleaved and activated early during apoptosis. CPP32 activation was not observed when apoptosis was inhibited by treatment with a selective inhibitor of CED3/ICE proteases or with inhibitors of RNA or protein synthesis. CPP32 activation was also not observed when the neurons were induced to die by necrosis after exposure to high levels of glutamate. Thus, CPP32 activation is an early biochemical marker of apoptosis in this neuronal cell type.

The CPP32 protease is processed and activated in neurons undergoing apoptosis but not during necrosis. CPP32 activation may thus be a useful marker for distinguishing apoptotic neurons from necrotic neurons in vitro and in vivo during neural development and after pathological brain insult. To compare CPP32 activation in apoptosis and necrosis, we chose two well characterized_in vitro_ cerebellar granule neuron cell death models. Cultured neonatal rodent cerebellar granule neurons grown for 7 d under depolarizing conditions in high (25 mm) potassium undergo classical apoptotic changes on simultaneous lowering of potassium (to 5 mm) and serum withdrawal (D’Mello et al., 1993; Yan et al., 1994). These changes include cell shrinkage, nuclear condensation and fragmentation, and DNA cleavage into oligonucleosomal-sized fragments (D’Mello et al., 1993). Cerebellar granule apoptosis, like trophic factor deprivation-induced apoptosis (Deckwerth and Johnson, 1993; Milligan et al., 1994, 1995), is blocked by inhibitors of macromolecular synthesis (D’Mello et al., 1993; Galli et al., 1995) (Fig. ​2). The apoptotic death of granule neurons observed using our culture conditions recapitulated the apoptotic changes observed previously by others (Figs. ​1, ​2). In contrast, granule neurons exposed to fresh serum or to high concentrations (0.3–3.0 mm) of glutamate undergo a more rapid, nonapoptotic form of cell death in which there is little cell shrinkage, the nuclei remain intact, and nuclear DNA is cleaved neither to the large (50–300 kb) nor the small oligonucleosomal fragments normally observed during apoptosis (Ankarcrona et al., 1995) (Fig. ​2). In addition to the kinetic and morphological differences, these two forms of cerebellar granule neuron cell death are distinguished biochemically by the presence or absence of endonuclease activity (Ankarcrona et al., 1995) and by their sensitivity to inhibition by (1) inhibitors of macromolecular synthesis (D’Mello et al., 1993) (Figs.​1, ​2) and (2) a selective inhibitor of CED3/ICE proteases, ZVAD-fmk (Figs. ​1, ​2). Our inability to detect either Ac-DEVD-amc cleaving activity or CPP32 processing after acute glutamate-induced necrosis further distinguishes granule neuron apoptosis from necrosis biochemically and suggests a selective role for the CPP32 protease in granule neuron apoptosis.

Ankarcrona et al. (1995) showed previously that after the acute, necrotic death of cerebellar granule neurons exposed to 300 μm or 3 mm glutamate, the remaining neurons undergo a delayed, apoptotic death beginning at ∼8-12 hr. Although our study was not designed to examine this delayed form of apoptosis, it is interesting that we failed to detect CPP32 activation as late as 24 hr after exposure to glutamate. There are several possible explanations for this. First, the amount of CPP32 activated in the remaining neurons after the acute phase of necrotic cell death may be below the limits of detection of our biochemical assays. Alternatively, CPP32 may not be activated in delayed glutamate-induced apoptosis in these neurons. Experiments are in progress to examine these and other possibilities.

Our studies demonstrate clearly that the CPP32 proenzyme is cleaved from its 32 kDa precursor form to an active form as early as 4 hr after induction of apoptosis. CPP32 enzymatic activity (defined as anti-CPP32 inhibitable, Ac-DEVD-amc cleaving activity) was elevated >10-fold within 8 hr of the apoptotic stimulus. Pro-CPP32, like all members of the CED3/ICE family, is cleaved at Asp-X peptide bonds to generate an active protease containing a large (∼20 kDa) and a small (∼12 kDa) subunit (Nicholson et al., 1995). Our antibodies to the C terminus of the large subunit of mouse CPP32 (anti-CPP32p20Pep) recognized two proteins of 20 and 18 kDa, one of which co-migrated with the large subunit of active, recombinant mouse CPP32. As expected for processed large subunits of active CPP32, the p20 and p18 proteins accumulated coincidentally with the increase in Ac-DEVD-amc cleaving activity and were specifically labeled with an irreversible CED3/ICE inhibitor that covalently modifies the active site cysteine contained in the large subunits of active CPP32 and other ICE proteases. Based on the ability of three different anti-CPP32 p20 antisera to recognize both p20 and p18 proteins, we believe it to be likely that both immunoreactive proteins are subunits of active mouse CPP32; however, we cannot exclude the possibility that the CPP32 antibodies used also recognize closely related homologs of mouse CPP32. Biochemical (Nicholson et al., 1995) and site-directed mutagenesis (Fernandes-Alnemri et al., 1996) studies of human CPP32 indicate that in addition to the cleavage site between the large and small subunits (Asp 175), pro-CPP32 is processed proteolytically at two sites (Asp9 and Asp28) in the N terminus of the p20 subunit. Comparison of the cleavage sites in human and mouse CPP32 show that although the Asp 9 cleavage site is relatively well conserved (NSVD vs TSVD), the Asp 28 cleavage site has a charge reversal in the P4 position (ESMD vs KSVD) that could decrease processing at Asp 28. Although we have not yet sequenced the CPP32 p20 and p18 immunoreactive proteins, we consider it likely that the p20 and p18 proteins represent large subunits of CPP32 that are differentially processed at their amino termini.

The consequences of CPP32 activation in cerebellar granule neurons are unknown. CPP32 has been implicated in the cleavage of several proteins that function in cellular metabolism and homeostasis, including poly-(ADP-ribose)-polymerase (PARP), a nuclear protein involved in DNA repair that is cleaved in many models of apoptosis (Nicholson et al., 1995; Tewari et al., 1995; Armstrong et al., 1996). It seems likely that PARP is also cleaved during neuronal apoptosis. Unfortunately, our attempts to detect PARP cleavage in the cerebellar granule neurons were unsuccessful because of the species-specificity of the PARP monoclonal antibody that we used (R. Armstrong, unpublished observations). A recent study (Schulz et al., 1996) showed that the production of reactive oxygen species in cerebellar granule neurons undergoing apoptosis is downstream of the activation of an unidentified CED3/ICE protease activity. Our data, together with those of Schulz et al. (1996), suggest that CPP32 may lie on a pathway leading to production of reactive oxygen species.

The mechanism by which the CPP32 protease becomes activated is unknown but does not seem to require de novo CPP32 expression. Western blot data (Fig. ​5) indicate that the CPP32 proenzyme is expressed in resting, unstimulated cultures. Inhibitors of macromolecular synthesis, however, do prevent apoptosis and the proteolytic processing and activation of CPP32, indicating that the transcription/translation-dependent step in cerebellar granule apoptosis is upstream of CPP32 activation (also see Schulz et al., 1996). One possible site of action of these gene products is regulation of the protease(s) that cleave pro-CPP32. ZVAD-fmk blocked CPP32 processing, indicating that a protease(s) with substrate specificity similar to CPP32 cleaves pro-CPP32. This could be either active CPP32 itself or an upstream-activated CED3/ICE protease (Fernandes-Alnemri et al., 1996; Liu et al., 1996; Orth et al., 1996). The expression or function of this unidentified protease could be modified in a transcription- or translation-dependent manner. Neuronal apoptosis requires new gene expression in a number of model systems in vitro (Deckwerth and Johnson, 1993; Milligan et al., 1994) and_in vivo_ (Oppenheim et al., 1990; Linnik et al., 1993). For example, c-Jun is upregulated early and is required for neurotrophin withdrawal-induced apoptosis in sympathetic neurons (Estus et al., 1994; Ham et al., 1995). Our data suggest a model in which components of the cell death effector machinery, including CPP32, are already expressed in neuronal cells, and their activity is regulated, directly or indirectly, by factors that require new gene expression to exert their action(s). Recent studies demonstrating that staurosporin induces apoptosis in many cell types, including postmitotic cardiac myocytes, in the absence of new protein synthesis (Weil et al., 1996) is consistent with this view.

In summary, we have shown that the CED3/ICE protease CPP32 is processed and activated in cerebellar granule neurons undergoing apoptosis but not necrosis. CPP32 activation requires continued macromolecular synthesis and CED3/ICE protease activity. Although these data indicate a role for CPP32 in the effector pathway of neuronal apoptosis, whether the CPP32 protease plays a necessary role will require inhibition of CPP32 with selective protease inhibitors. Although initially described as a CPP32-selective inhibitor (Nicholson et al., 1995), the tetrapeptide Ac-DEVD-aldehyde inhibits several members of the CED3-ICE protease family nearly as potently as CPP32 (Fernandes-Alnemri et al., 1995b; 1996). In the absence of selective protease inhibitors, the role of CPP32 in neuronal apoptosis could be examined through inducible, targeted inactivation of the CPP32 gene.

Footnotes

We thank Drs. Anu Srinivasan and Yan Wang for helpful discussions and Lisa Trout for administrative assistance.

Correspondence should be addressed to Kevin J. Tomaselli, Cell Biology, IDUN Pharmaceuticals, Inc., 11085 North Torrey Pines Road, Suite 300, La Jolla, CA 92037.

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