p53 Expression Induces Apoptosis in Hippocampal Pyramidal Neuron Cultures

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Volume 17, Number 4, Issue of February 15, 1997 pp. 1397-1405
Copyright ©1997 Society for Neuroscience

p53 Expression Induces Apoptosis in Hippocampal Pyramidal Neuron Cultures

Joaquín Jordán¹, María F. Galindo¹, Jochen H. M. Prehn¹, Ralph R. Weichselbaum², Michael Beckett², Ghanashyam D. Ghadge³, Raymond P. Roos³, Jeffrey M. Leiden⁴, and Richard J. Miller¹
Departments of ¹ Pharmacological and Physiological Sciences, ² Radiation and Cell Oncology, ³ Neurology, and ⁴ Medicine, The University of Chicago, Chicago, Illinois 60637

ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The tumor suppressor gene p53 has been implicated in the induction of apoptosis in dividing cells. We now show that overexpressionof p53 using an adenoviral vector in cultured rat hippocampalpyramidal neurons causes widespread neuronal death with featurestypical of apoptosis. p53 overexpression did not induce p21, bax,or mdm2 in neurons. X-irradiation of hippocampal neurons inducedp53 immunoreactivity and cell death associated with features typicalof apoptosis. Overexpression of a constitutively active nonphosphorylatableform of the retinoblastoma gene product blocked x-irradiation-inducedneuronal death. However, overexpression of the cyclin-dependentkinase inhibitor p21 did not. Treatment of neurons with transforminggrowth factor- $beta$ 1 protected them from x-irradiation. These resultsare consistent with a role for p53 in nerve cell death that isdistinct from its actions relating to cell cycle arrest.
Key words: adenovirus; irradiation; retinoblastoma; tumor suppressor genes; overexpression; p21; transforming growth factor- $beta$ 1

INTRODUCTION

The death of populations of neurons occurs naturally by programmed cell death or apoptosis during the development of the nervoussystem (Oppenheim, 1991; Driscoll and Chalfie, 1992; Truman etal., 1992). In certain diseases, including stroke (Linnik et al.,1993; Charriaut-Marlangue et al., 1996a,b; Du et al., 1996), Alzheimer'sdisease (La Ferla et al., 1995; Prehn et al., 1996), and AIDS-associateddementia (Charriaut-Marlangue et al., 1996b; Meucci and Miller,1996), the death of neurons may also involve events related toor identical to those occurring during development. Evidence suggeststhat the death of neurons after stroke, trauma, and seizure activityis attributable to "excitotoxicity," a process involving the overactivationof neuronal glutamate receptors (Choi, 1988). The molecular eventsthat underlie excitotoxic neuronal death are believed to includelarge increases in [Ca]i and toxic free radicals (Choi, 1988;Bindokas and Miller, 1995; Bindokas et al., 1996). It was originallybelieved that neurons died by necrosis under excitotoxic conditions.However, more recent evidence suggests that many cells may alsodie by apoptosis (Linnik et al., 1993; Crumrine et al., 1994;Sakhi et al., 1994; Rink et al., 1995; Morrison et al., 1996),depending on the severity of the stimulus (Bonfoco et al., 1995).It is clearly important to understand the molecular basis of apoptosisin neurons and how these events can be manipulated.

Studies on a variety of cells have started to define the steps that are involved in apoptosis under different conditions (Kroemeret al., 1995). The final common pathway that produces programmedcell death is believed to operate in the cytoplasm and is probablycommon to most, if not all, cells (Jacobson et al., 1994; Kroemeret al., 1995). These events can be triggered by a variety of factorsand modulated by several classes of proteins. Prominent amongthese proteins are a group of "tumor suppressors" that includethe p53 gene product, the retinoblastoma gene product (pRb), andseveral inhibitors of the cyclin-dependent kinases, particularlythe p21^WAF1/CIP1 protein (p21) (Cox and Lane, 1995; Katayose et al., 1995; Kouzarides,1995). The p53 protein plays a central role in the cellular responseto DNA damage (Elledge and Lee, 1995; Enoch and Norbury, 1995).p53 expression leads to arrest of the cell cycle so that DNA repaircan occur or can activate apoptotic pathways when repair seemsimpossible (Lane et al., 1994). Consistent with this idea areobservations that increases in p53 after x-irradiation (Clarkeet al., 1993; Lowe et al., 1993) or DNA-damaging ("genotoxic")drugs (Wood and Youle, 1995) or p53 overexpression (Wu and Levine,1994) cause cell cycle arrest and/or apoptosis in a variety ofcell types. In addition, excitotoxic stimulation has been shownto stimulate p53 production by neurons, suggesting that p53 mayalso be responsible for triggering apoptosis under these circumstances(Sakhi et al., 1994). Although this seems to be an interestingpossibility, it should be noted that virtually all studies onthe role of tumor suppressor genes in apoptosis have been carriedout on dividing cells. It is not known whether p53 actually causeshighly differentiated, postmitotic cells such as neurons to dieand if so, precisely how this process is manifest in such cells(but see Sadoul et al., 1996) (Eizenberg et al., 1996). The presentseries of studies explores the role of p53 in neuronal apoptosis.Our studies provide support for a potential role for p53 in neurodegenerativedisease.

MATERIALS AND METHODS
Materials. Recombinant human TGF- $beta$ 1 was obtained from R & D systems (Minneapolis, MN) and was prepared as a 1000 ng/ml stockin PBS containing 1 mg/ml ovalbumin and 4 mM HCl.

Hippocampal pyramidal neuron culture. Pyramidal neurons were prepared from the hippocampi of fetal rats at 17 d of gestation(E17) as described by Scholz and Palfrey (1991). These neuronsare highly differentiated and establish functional synaptic connections(Scholz and Miller, 1995, 1996). Hippocampi were dissected inCa²⁺/Mg²⁺-free HBSS (Cellgro) and incubated in 0.1% trypsin (Worthington)for 15 min. The hippocampi were triturated by aspirating 7 to10 times using a normal-bore Pasteur pipette with a flame-narrowedPasteur pipette. Cells were plated in DMEM (Life Technologies,Grand Island, NY) plus 10% horse serum (Life Technologies) onpoly-L-lysine- (Sigma, St. Louis, MO; 0.5 mg/ml in borate buffer,pH 8.0) coated 15 mm round glass coverslips and allowed to adherefor 2-4 hr. The coverslips were then transferred to 60 mm dishescontaining supporting astrocytes attached to the bottom of theculture dish. Astrocytes were prepared from the cerebral hemispheresof newborn rats.

For biochemistry experiments, the layer of glial and neuronal cells were inverted. After 4 d in culture, glial cells wereremoved from the dishes with trypsin and plated on 30 mm Thermanoxecoverslips equipped with paraplast feet. Neurons were plated inDMEM (Life Technologies) plus 10% horse serum (Life Technologies)on poly-L-lysine- (Sigma; 0.5 mg/ml in borate buffer, pH 8.0)coated 35 mm tissue culture dishes at 3.5 10⁵ cell/Petri dish. After 2-4 hr, the medium was replaced with aserum-free defined medium (N2), and the coverslips containingthe feeder glial cells were placed on top of each dish of pyramidalneurons. Cytosine- $beta$ -D-arabinofuranoside (5 µM) was added to eachplate 2 d later to inhibit non-neuronal cell proliferation.

X-irradiation protocol. X-Irradiation was performed using a GE Maxitron 250 X-Ray Generator operating at 250 kV and 26 mAwith a dose rate of 114 cGy/min. Cells received a single doseof 200, 500, or 1000 cGy at 22-25°C. Control dishes were sham-irradiatedunder identical conditions.

Cell viability assay. Cell death was determined using fluorescein diacetate/propidium iodide double-staining procedure (Favaronet al., 1988). The cells were incubated for 45 sec at 22-25°Cwith 15 µg/ml fluorescein diacetate (Sigma) and 4.6 µg/ml propidiumiodide (Molecular Probes, Eugene, OR) in PBS, pH 7.4. The stainedcells were examined immediately with a standard epi-illuminationfluorescence microscope (Olympus, 450 excitation, 520 barrier).Cells stained with propidium iodide represent dead cells, whereascells stained with fluorescein represent live cells. A total of~300-400 cells (viable plus nonviable) were counted in randomfields of each coverslip, and the percentage of cells survivingwas then determined above the total cell number. The percentageof neurons surviving was determined on three or four coverslipsfor each condition in each experiment and normalized to controlsexamined in parallel under the same conditions. The average relativepercent survival from at least three separate experiments foreach condition is expressed in the text and figures as the mean± SEM.

Analysis of DNA fragmentation. For evaluation of cellular DNA fragmentation, both the TUNEL (Gavrieli et al., 1992) and Hoechst33342 (Earnshaw, 1995) stains were used. For the TUNEL method,we used the Apoptag kit (Oncor, Gaithersburg, MD). Briefly, cultureswere fixed in Bouin's solution (Sigma) at room temperature for20 min. After rinsing three times using PBS, cultures were incubatedwith terminal deoxynucleotidyl transferase and digoxigenin-dUTPat 37°C for 1 hr. After labeling, the DNA breaks were visualizedwith an anti-digoxigenin antibody coupled to peroxidase. diaminobenzidine(Sigma) and hydrogen peroxide were used to develop the stain.

For staining with Hoechst 33342, cultures were rinsed three times using PBS, fixed with 4% paraformaldehyde for 10 min at37°C, permeabilized in ethanol/acetic acid (19:1 v/v) for 15 minat $-$ 20°C, washed three times in PBS, and then incubated with 1ng/ml Hoechst 33342 (Molecular Probes) for 20 min at room temperature.After two rinses with PBS, the cell staining was analyzed usinga fluorescent microscope.

Immunoblotting. Pyramidal neuron cultures were washed with cold PBS twice and then collected by mechanical scraping with 100µl of PBS per tissue culture dish. Phenylmethylsulfonyl fluoride(10 µM) was added to halt further protease activity. The proteinsuspension was centrifuged at 12,000-14,000 rpm for 5 min. Thesupernatant was discarded, and the protein pellet brought up in40 µl of sample buffer. The protein from each condition was quantifiedspectophotometrically (Micro BCA Protein Reagent Kit, Pierce,Rockford, IL), and an equal amount of protein (~30 µg) was loadedonto each lane of the SDS-PAGE (7.5% SDS-PAGE for p53, 12.5% SDS-PAGEfor p21, and 10% SDS-PAGE for H $Delta$ pRb), which was then run at 30mA. After electrophoresis, proteins were transferred to ImmobilonPVDF membranes overnight at 110 mA. Nonspecific protein bindingwas blocked with Blotto [4% w/v nonfat dried milk, 4% bovine serumalbumin (Sigma) and 0.1% Tween 20 (Calbiochem-Novabiochem, LaJolla, CA)] in PBS for 1 hr. The membranes were incubated withone of the following antibodies for 1 hr: anti-p53(Ab-1) and anti-mdm-2(1:100 and 1:1000 dilution of mouse monoclonal, Oncogene Science);anti-p21 (1:1000 dilution of rabbit serum, PharMingen); anti-hemagglutininprotein of human influenza virus (1:1000 dilution of mouse monoclonalantibody HA-(12CA5), Boehringer Mannheim Corporation); anti-bax(N-20)(1:200 dilution of rabbit serum, Santa Cruz). After washing withBlotto, the membranes were incubated with a secondary antibody(1:5000 dilution of peroxidase-labeled anti-mouse or goat anti-rabbitIgG, Promega, Madison, WI) in Blotto. The signal was detectedusing an enhanced chemiluminescence detection kit (Amersham ECLRPN 2106 Kit). Immunoblots were developed by exposure to x-rayfilm (Eastman-Kodak, Rochester, NY).

Construction of replication-defective adenoviruses and infection protocol. The different viruses were constructed as describedpreviously. Adp53 recombinant adenovirus (Wills et al., 1994)is based on Ad 5 with a deletion of E1 region of nucleotides 360-3325replaced with a 1.4 kb full-length p53 cDNA driven by the CMV(A/M/53) promoter followed by Ad 2 tripartite leader cDNA. Adp21and AdH $Delta$ pRb are described in Chang et al. (1995a,b), and AdBacLacZ(Barr et al., 1994) was used as a control virus vector. The enzymaticactivity and high efficiency of AdBacLacZ have been shown previously.Under our conditions, AdBacLacZ was observed in >90% of culturedcells (Chard et al., 1995; Jordán et al., 1995). Similar resultshave been obtained with other viruses (Chard et al., 1995; Jordánet al., 1995; Prehn et al., 1996).

Cultured rat hippocampal neurons were infected using methods described previously (Chard et al., 1995). In brief, the coverslipswere removed from the astrocyte feeder layer and placed in a 60mm tissue dish in astrocyte-conditioned, N2.1 supplemented MEMculture medium. An aliquot of high-titer virus was then addedto the culture medium to give a multiplicity of infection (MOI)of 100. The dish was agitated gently and placed in an incubatorfor 2 hr. The coverslips were then returned to the original tissueculture dish containing the astrocyte feeder layer. In each toxicityexperiment, successful expression of the respective proteins wasverified by immunocytochemistry (one coverslip per experimentalcondition).

Immunocytochemistry. Cultures were fixed by incubating at 37°C for 15 min with 4% paraformaldehyde in culture medium. Afterwashing three times in 0.1 M PBS, pH 7.4, cells were permeabilizedusing 0.1% Triton X-100 (Eastman Kodak) in PBS, for 2.5 min. Thecoverslips were then incubated for 1 hr in blocking media [0.1%Tween 20 (Sigma), 4% BSA (Sigma), in 0.1 M PBS] at room temperature.Incubations with primary antibodies were performed overnight at4°C using monoclonal mouse antibodies for anti- $beta$ -galactosidase(1:1000, Sigma), p53 (Ab-4, Oncogene Science, 1:100) diluted inblocking media. Monoclonal antibodies were detected using eitherCy3-conjugated streptadivin or anti-mouse IgG (Jackson ImmunoResearchLab, West Grove, PA) diluted 1:200 in blocking solution. The latterfollowed by Vectastain ABC Kit (Vector Labs, Burlingame, CA).The peroxidase was visualized using 3,3 $'$ -diaminobenzidine (Sigma)as a chromogenic substrate. Cultures were mounted in 90% glycerolwith 0.1 phosphate buffer and 0.01% NaN₃.

RESULTS

Overexpression of p53 induces apoptosis in hippocampal pyramidal neurons
Previous investigations on dividing cells, including neuronal precursors, have demonstrated the importance of p53 in mediatingapoptosis caused by x-irradiation or genotoxic agents (Kameyamaand Inouye, 1994; Wood and Youle, 1995). Therefore, we investigatedthe effects of p53 on hippocampal pyramidal neurons in cultureby using an adenovirus that expresses p53 (Adp53) (Wills et al.,1994). The neurons used in these studies are postmitotic and exhibitextensive functional synaptic connections (Scholz and Miller,1995, 1996). p53 protein was undetectable in these neurons undercontrol conditions. However, 48 hr after infection of the neuronswith Adp53, expression of human p53 protein was detectable usingWestern blot analysis (Fig. 1A). Approximately half of the neurons(43%, n = 4) was clearly immunoreactive for human p53 at the sametime. Neuronal death increased greatly during the 72 hr periodafter infection, with the death of ~75% of the neurons after 3d. Neurons dying after the expression of p53 displayed many ofthe features typical of apoptosis, including cell shrinkage, nuclearcondensation, and membrane blebbing. We observed that cells stainingfor p53 also invariably exhibited chromatin condensation as shownusing Hoechst 33342 (Fig. 1C,D, n > 200 cells). p53 expressionalso produced a large increase in TUNEL staining, indicative ofdouble stranded DNA breaks (Fig. 1E,F). After Adp53 infection(48 hr), ~80% of the neurons were positive for TUNEL staining,whereas <5% were positive in cultures infected with a $beta$ -galactosidase-expressingcontrol adenovirus. These results indicate that p53 expressioncauses postmitotic neurons to undergo apoptosis, consistent withits effects in a variety of dividing cells.
Fig. 1. Overexpression of p53 induces neurotoxicity in rat hippocampal pyramidal neurons. Hippocampal cultures were infected at 7DIV, using 100 MOI of each virus. A, Western blots showing overexpressionof p53, p21, and H $Delta$ pRb after 48 hr of infection. Hippocampal cultureswere infected on 7 DIV, using 100 MOI of each virus. Similar resultswere found in three separate experiments. B, Time course plotof cell viability after Adp53, Adp21, Ad $beta$ gal, or AdH $Delta$ pRb infectionof hippocampal pyramidal neuron cultures. Results represent themean ± SEM of 12 coverslips. ***p < 0.001 versus control conditions(no virus); ANOVA and Tukey's test. C, D, Pictures showing colocalizationof human p53 expression (C) and chromatin fragmentation measuredusing Hoechst 33342 (D, n > 200 cells). E, F, Cultures stainedusing the TUNEL technique illustrating the degree of double-strandedDNA breaks in control cultures (E) and 48 hr after Adp53 infection(F). Scale bar, 20 µm.
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We also examined the effects of expressing two other tumor suppressor genes, the cyclin kinase inhibitor p21 and a constitutivelyactive nonphosphorylatable form of the retinoblastoma gene productcarrying an N-terminal epitope tag taken from the influenza hemagglutininmolecule (H $Delta$ pRb) (Chang et al., 1995b). The expression of p21is of interest owing to the fact that many of the effects of p53,particularly those on the cell cycle, have been shown to be mediatedby p21 (Cox and Lane, 1995; Kouzarides, 1995). In addition, pRbhas also been shown to impact p53-mediated events in several circumstances(Kouzarides, 1995). A Western blot confirmed expression of boththe p21 and H $Delta$ pRb proteins 48 hr after infection with adenovirusesthat contained the respective cDNAs (Adp21, AdH $Delta$ pRb) (Chang etal., 1995 a,b) (Fig. 1A). Only a small increase in cell deathwas noted 72 hr after infection after expression of these twoproteins (Fig. 1B). This small decrease in viability was comparablewith that seen after overexpression of $beta$ -galactosidase (Fig. 1B)(Chard et al., 1995).

p53-Induced neuronal cell death uses a different pathway from that used after cell cycle arrest
The above studies demonstrate that p53 overexpression was able to induce apoptosis in postmitotic neurons. To characterizethe pathway involved in this process, we compared the effectsof infection with Adp53 on gene expression in two different celltypes: hippocampal neurons and PC-3, a prostate carcinoma cell,(a mitotic cell line) (Kaighn et al., 1979). These latter cellsdo not expresses p53 normally (Isaacs et al., 1991). The levelsof bax, mdm2, and p21 proteins were measured at 8, 12, and 24hr after infection of the two cell types, using a Western blottechnique. In addition, we measured bax at 48 hr in neuronal cultures.Figure 2 shows that neuronal cultures failed to show any increasein the proteins assayed at 12 hr (Fig. 2A) or at other time points(data not shown). mdm2 was undetectable before and after treatment.In contrast, PC-3 cells showed an increase in both p21 and mdm2,although not of bax, after p53 expression (Fig. 2B).
Fig. 2. p53-Induced gene expression. Hippocampal pyramidal neurons (7 DIV) (A) or PC-3 cells (B) were infected with Adp53 at 100 MOI.Later (8, 12, or 24 hr), the cells were harvested. Result shownillustrate effects at 12 hr, but similar patterns were seen atother time points. Similar results were found in three separateexperiments. In addition, no increase in bax was observed at a48 hr time point in hippocampal cultures. C, No changes in levelsof the proteins were found in extracts from x-irradiated hippocampalneurons (500 cGy; immunoblots show the 24 hr time point).
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Effect of x-irradiation on hippocampal neurons in culture
X-irradiation is a commonly used mechanism for triggering the death of dividing cells by apoptosis. These effects are frequently,but not always, mediated by p53 (Strasser et al., 1996). Althoughit has been shown that x-irradiation can kill neuronal precursorcells, including those in the hippocampus and the external granulelayer of the cerebellum (Kameyana and Inouye, 1994; Wood and Youle,1995), little is known about the effect of x-irradiation on postmitoticneurons. Therefore, we examined the effects of x-irradiation onhippocampal pyramidal neurons in culture. Cultures at 11 d invitro (11 DIV) were exposed to different doses of x-irradiation(200, 500, or 1000 cGy), and cell viability was subsequently measuredat different time points (Fig. 3). There was a marked increasein cell death 6-48 hr after x-irradiation. The rate at which thisoccurred depended on the dose of x-irradiation used. However,75-80% of the cells died 48 hr after x-irradiation, irrespectiveof dose (Fig. 3).
Fig. 3. Time course plot of cell viability after exposure of the hippocampal pyramidal neuron cultures to 200, 500, and 1000 cGy totaldoses of x-irradiation. Cultures were irradiated at 11 DIV. Eachpoint represents the mean ± SEM of 9 coverslips. **p < 0.01; ***p< 0.001 versus non-x-irradiated control conditions; ANOVA andTukey's test.
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Dying neurons showed many of the hallmarks of apoptosis, including shrunken, irregularly shaped cell bodies and nuclear condensation.Double-stranded DNA breaks, measured by the TUNEL staining method,increased greatly after x-irradiation (Fig. 4C), with >80% ofcells staining 24 hr after x-irradiation. Staining with the fluorescentdyes Hoechst 33342 and propidium iodide showed changes in thestate of the chromatin, with many cells exhibiting chromatin condensationand nuclear fragmentation (Fig. 4D). Immunostaining for p53 wasclearly observed in a small number of cells 5 hr after x-irradiation( $-$ 5%) (Fig. 4F), although staining was never observed in controlcells (Fig. 4E). A correlation between p53 expression and morphologicalfeatures typical of apoptosis was found in all of the p53 positivecells (Fig. 4F, arrows; n > 200). Nevertheless, and in agreementwith that reported recently by Arai et al. (1996), p53 proteinwas not detected in the fragmented nuclei of most apoptotic cellsof bodies. These observations show that x-irradiation kills hippocampalpyramidal neurons by apoptosis.
Fig. 4. Apoptosis after x-irradiation of hippocampal pyramidal neuron cultures. The cultures were exposed to a 500 cGy dose of x-irradiationat 11 DIV and analyzed 24 hr later. A, Nomarski picture showingmorphological changes (n = 8). B, Propidium iodide and fluoresceindiacetate staining (n = 8). C, TUNEL staining illustrating thedegree of double-stranded DNA breaks (n = 3). D, Chromatin ofhippocampal nuclei from x-irradiated cultures stained with Hoechst33342. Arrows in A-D illustrate examples of nuclei with condensedchromatin. E, F, Control (E) and 500 cGy irradiated hippocampalcultures (F) stained for p53 5 hr after x-irradiation (n = 2).Scale bar, 20 µm.
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Effect of tumor suppressor genes on neuronal apoptosis
We investigated the possibility that p21 or H $Delta$ pRb expression could modify apoptosis induced by either x-irradiation or p53overexpression. Cultures were infected 3 d before x-irradiationor Adp53 infection to allow sufficient time for maximal H $Delta$ pRbor p21 expression to occur. Overexpression of H $Delta$ pRb protectedneurons from x-irradiation-induced damage (Fig. 5B). H $Delta$ pRb expression,however, was unable to prevent death induced by the expressionof p53 when we reinfected the cultures with Adp53 (Fig. 5A). Deathof neurons under these circumstances was not attributable to thefact that we infected them with viruses twice. For example, ifthe same experiment was performed with AdH $Delta$ Rb followed by Adp21,significant death did not occur (Fig. 5B). The overexpressionof p21 was unable to protect cells from death caused by x-irradiation(Fig. 5B). Protein immunoblots performed with extracts from irradiatedneuronal cultures did not show any increase in the levels of p21,bax, or mdm2, 8, 12 (data not shown), or 24 hr after 500 cGy (Fig.2C).
Fig. 5. Effects of the overexpression of H $Delta$ pRb on p53- and x-irradiation-induced cell death. Cultures were infected with 100 MOI AdH $Delta$ pRbat DIV 7, and 3 d later were again infected with Adp53 or exposedto x-irradiation. Cell viability was analyzed 48 hr (Adp53) or24 hr (X-irradiation) later. A, Overexpression of H $Delta$ pRb failedto protect the cultures against cell death induced by p53 expression(AdH $Delta$ pRb/Adp53). B, Overexpression of H $Delta$ pRb was able to blockx-irradiation-induced death of hippocampal neurons (AdH $Delta$ pRb),whereas p21 overexpression did not (Adp21). Data represent mean± SEM of 9 coverslips. ***p < 0.01, versus Adp53 or irradiatedcontrol conditions; ANOVA and Tukey's test.
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Effect of TGF- $beta$ 1 on x-irradiation-induced apoptosis
We have demonstrated previously that the multifunctional cytokine transforming growth factor- $beta$ 1 (TGF- $beta$ 1) can protect neuronsfrom a variety of insults. In hippocampal pyramidal neurons, theseeffects are associated with the ability of this cytokine to upregulatethe synthesis of the proteins Bcl-2 and Bcl-xL, both of whichare known to oppose apoptotic death induced in many instances(Prehn et al., 1995, 1996). Treatment with TGF- $beta$ 1 protected neuronsagainst x-irradiation-induced cell death (Fig. 6B). However, TGF- $beta$ 1was ineffective in preventing death attributable to the overexpressionof p53 (Fig. 6A).
Fig. 6. Effect of TGF- $beta$ 1 (1 ng/ml) on neuronal death induced by either p53 overexpression or different doses of x-irradiation. A,24 Hr pretreatment with TGF- $beta$ 1 (Adp53/TGF $beta$ (1X)) failed to protectthe cultures 48 hr after 100 MOI Adp53 infection. Even the dailyaddition of the TGF- $beta$ 1 for 3 consecutive days (Adp53/TGF $beta$ (3X))did not protect neurons 48 hr after Adp53 infection. Cultureswere infected at 100 MOI, at 7 DIV. B, The 4 hr previous additionto the culture media of TGF- $beta$ 1 (1 ng/ml) protected hippocampalpyramidal neuronal cultures against x-irradiation-induced neurotoxicity.Data represent mean ± SEM of 9 coverslips. **p < 0.01 versus Adp53or irradiated control conditions; ANOVA and Tukey's test.
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DISCUSSION
It is well established that the p53 protein plays a central role in the death of many types of cells in response to DNA damage(Cox and Lane, 1995). The protein has frequently been shown tobe induced in response to x-irradiation and genotoxic drugs andto produce either cell cycle arrest or apoptosis, depending onthe situation (Lowe et al., 1993; Elledge and Lee, 1995; Enochand Norbury, 1995). Both of these events can be viewed as waysof protecting cells from the consequences of faulty DNA replication.

p53-Induced cell cycle arrest and apoptosis are probably mediated by different pathways (Rowan et al., 1996). The arrest ofthe cell cycle appears to involve the ability of p53 to enhancethe synthesis of the cyclin kinase inhibitor p21, leading to inhibitionof cyclin-dependent kinases (Cox and Lane, 1995; Haffner and Oren,1995; Kouzarides, 1995; Macleod et al., 1995). The mechanism bywhich p53 induces apoptosis has remained more elusive. Our datademonstrate that p53-induced apoptosis, in postmitotic neurons,does not involve p21 or require induction of the same set of targetgenes as those seen after cell cycle arrest, indicating that atleast portions of these pathways are distinct. p53-Induced apoptosishas also been observed to occur in mice that are deficient inp21 (Brugarolas et al., 1995; Kouzarides, 1995; Attardi et al.,1996). On the other hand, we found that p53 overexpression andx-irradiation were unable to induce other proteins such as bax,which have been widely shown to induce apoptosis in many celltypes (Miyashita and Reed, 1995). This implies that p53-inducedneuronal apoptosis is independent of bax, although correspondingchanges in other key proteins such as bcl-2 or bcl_X could maskits effects. Notably, however, it has been reported that p53 caninduce apoptosis without the transactivation of transcription(Caelles et al., 1994; Wagner et al., 1994). An important questionis whether the function of p53 in the apoptosis of postmitoticcells, such as neurons, is similar to its functions on non-neuronalcells. It may be that p53 acts to ensure the fidelity of genetranscription in postmitotic cells, rather than to function asa response to replication errors as in mitotic cells.

The levels of p53 are known to increase in some neurons after a number of insults that can lead to neuronal death. These includeischemia (Chopp et al., 1992; Li et al., 1994), seizure activity(Sakhi et al., 1994; Morrison et al., 1996) and the death of dentategranule cells after adrenalectomy (Schreiber et al., 1994). p53is also induced in replicating cells after hypoxia (Graeber etal., 1995, 1996). Because neuronal damage after ischemia or seizuresis thought to involve a significant component of apoptotic death(Bonfoco et al., 1995; Charriaut-Marlangue et al., 1996a,b; Duet al., 1996), and glutamate-mediated excitotoxicity, a relationshipbetween p53 and excitotoxicity has been suggested (Sakhi et al.,1994; Morrison et al., 1996). This relationship is supported bythe observation that the AMPA/kainate receptor agonist kainicacid increases the level of p53 mRNA in certain neurons (Sakhiet al., 1994; Morrison et al., 1996). In addition, p53-deficientmice show reduced neuronal death after ischemia (Crumrine et al.,1994) and decreased neurotoxicity after kainate administration(Morrison et al., 1996). The hypothesis that p53 is active duringinsults to the brain such as those occurring during ischemia ortreatment with certain kinds of genotoxic drugs (Wood and Youle,1995; Enokido et al., 1996) depends on whether p53 actually producesapoptosis in postmitotic cells such as neurons. The results ofthe present series of experiments clearly show that this is thecase, as do recent data by Eizenberg et al. (1996) using a p53antagonist protein. Therefore, p53 may form an important linkbetween toxic stimuli of varying types and the death of neurons.

The ability of x-irradiation to induce p53 and to produce apoptosis in hippocampal pyramidal neurons, as demonstrated in ourstudies, is also consistent with a role for this protein in someforms of neuronal apoptosis. This result is similar to resultsfound in other studies that have demonstrated that x-irradiationinduces apoptosis and the induction of p53 (Lowe et al., 1993).It should be noted, however, that not all types of x-irradiation-inducedapoptosis involve p53 induction (Strasser et al., 1994). In addition,p53 is not involved in all forms of neuronal apoptosis. For example,the apoptosis of neurons after growth factor withdrawal or culturein low-K⁺ medium presumably is not related to p53, because these phenomenaoccur in cells from p53-deficient mice (Davies and Rosenthal,1994; Enokido et al., 1996). Furthermore, apoptosis during thedevelopment of cerebellar granule cells is normal in p53-deficientmice, even though these same neurons exhibit increased resistanceto the effects of x-irradiation and genotoxic drugs such as methylazoxymethanol(Wood and Youle, 1995).

In our experiments, overexpression of a constitutively active nonphosphorylatable form of pRb (Chang et al., 1995b) in hippocampalcultures was found to protect against x-irradiation. This protectiveeffect of H $Delta$ pRb is consistent with the idea that x-irradiation-inducedapoptosis is a p53-mediated event, because pRb has been shownto act as an inhibitor of p53-induced cell death in several instances,giving rise to the idea that pRb has a generally antiapoptoticfunction (Haupt et al., 1995; Kouzarides et al., 1995; Slack andMiller, 1996). pRb-Deficient mice are not viable and die in mid-to late gestation, exhibiting defects in the hematopoietic systemas well as the CNS and PNS. Massive amounts of cell death occurthroughout the CNS as early as E11.5 (Lee et al., 1992). Thiscell death is dependent on p53 and is ameliorated in p53-deficientmice (Morgenbesser et al., 1994). pRb can overcome p53-inducedapoptosis in cultured cells (Haupt et al., 1995). The mechanismby which pRb protects cells from apoptosis remains obscure. However,it may act though an interaction with other factors such as E2F1(Wu and Levine, 1994).

The effects of TGF- $beta$ 1 are consistent with a role for p53 in neuronal apoptosis. We have demonstrated previously that TGF- $beta$ 1upregulates the proteins Bcl-2 and Bcl-xL in hippocampal neuronalcultures (Prehn et al., 1995, 1996) and inhibits apoptosis inmany different circumstances, including growth factor withdrawal,hypoxia, excitotoxicity, $beta$ -amyloid, and gp120 (Prehn et al., 1993,1995, 1996; Jordán et al., 1995; Meucci and Miller, 1996). p53-Inducedapoptosis can be blocked by increases in the levels of Bcl2 (Chiouet al., 1994).

It should be noted that although treatment with TGF- $beta$ 1 or expression of H $Delta$ pRb effectively blocked apoptosis induced by x-irradiation,both agents were ineffective in blocking apoptosis induced bydirect expression of p53. The reason for these different effectsmay be relate to different levels and kinetics of p53 in thesetwo situations. Adenoviral expression of p53 produces continuousexpression of the protein, and its effects may not be easy toinhibit compared with the transient expression achieved with stimulisuch as x-irradiation. It is, of course, also possible that theeffects of x-irradiation do not involve a p53-linked pathway.

Interestingly, some populations of neurons, such as cerebellar Purkinje cells and sympathetic neurons, constitutively expressp53 at high levels (Wood and Youle, 1995; Sadoul et al., 1996).In sympathetic neurons and oligodendrocytes (Eizenberg et al.,1995), p53 is localized in the cytoplasm. Manipulations that causep53 to be translocated to the nuclei of these cells produce apoptosisor at least chromatin condensation (Eizenberg et al., 1995; Sadoulet al., 1996). The cytoplasmic localization of p53 in these cells,together with the fact that they are normally viable, suggestsadditional functions for p53 in the nervous system.

Our results support the idea that p53 may act as a mediator of the apoptotic death of neurons under some conditions. If thisis so, it is of interest to define the intracellular mechanismthat lead to p53 induction. Traditionally, p53 induction has beenassociated with DNA damage; however, is this always the case?What is the link between p53 induction and ischemia, for example(Graeber et al., 1994, 1995)? One possibility is that this relatesto changes in Ca²⁺ homeostasis. Indeed, large changes in Ca²⁺ homeostasis certainly occur under ischemic conditions and arebelieved to be important for cell death (Choi, 1988). Furthermore,Ca²⁺-sensitive processes are believed to be involved in many instancesof apoptosis, particularly those involving Ca²⁺-dependent breakdown of DNA and proteins (Kroemer et al., 1995).Recently, a Ca²⁺ binding protein has been identified as a key element in the "programmedcell death" pathway (Vito et al., 1996). Another possibility isthat some reactive oxygen radicals mediate p53-induced apoptosis;thus, increases in free radical production have been demonstratedafter ischemia (Siesjo, 1989) or excitotoxic stimulation (Bindokaset al., 1996). The results reported here suggest that proteinssuch as p53 and pRb may be important targets for novel therapeuticagents for combating neurodegenerative processes in several diseasestates.

FOOTNOTES

Received Oct. 1, 1996; revised Nov. 27, 1996; accepted Dec. 4, 1996.

This study was supported by U.S. Public Health Service Grants DA02121, DA02575, and MH40165 (R.J.M.) and A 42596-09 (R.R.W.);Amyotrophic Lateral Sclerosis Association (R.P.R.) and AR42885,DK48987 (J.M.L.); German Research Foundation Grant Pr 338/2-1(J.H.M.P.); and a grant from Ministerio de Educación y Cienciaof Spain (J.J.). We thank Dr. Ning-Sheng Wang for her technicalhelp. We are grateful to Dr. J. Kokontis for advice and generousgifts of PC-3 cell line and to Dr. J. Tang of Schering-PloughResearch Institute for providing Adp53.

Correspondence should be addressed to Prof. Richard J. Miller, Department of Pharmacological and Physiological Sciences, TheUniversity of Chicago, 947 East 58th Street (MC 0926), Chicago,IL 60637.

Dr. Prehn's present address: Institut für Pharmakologie und Toxikologie, Philipps-Universität, Ketzerbach 63, 35032 Marburg,Germany.

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