p75 Neurotrophin Receptor Expression Is Induced in Apoptotic Neurons After Seizure

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (106)

Citing Articles via Google Scholar

Google Scholar

Articles by Roux, P. P.

Articles by Kennedy, T. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Roux, P. P.

Articles by Kennedy, T. E.

Previous Article  |  Next Article

The Journal of Neuroscience, August 15, 1999, 19(16):6887-6896

p75 Neurotrophin Receptor Expression Is Induced in Apoptotic Neurons After Seizure
Philippe P. Roux, Michael A. Colicos, Philip A. Barker, and Timothy E. Kennedy
Centre for Neuronal Survival, Montreal Neurological Institute, McGill University, Montreal, Quebec, Canada H3A 2B4

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Seizure causes neuronal cell loss in both animal models and human epilepsy. To determine the contribution of apoptotic mechanismsto seizure-induced neuronal cell death, rat brains were examinedfor the occurrence of terminal deoxynucleotidyl transferase-mediatedUTP nick end labeling (TUNEL)-positive nuclei after pilocarpine-inducedseizure. Numerous TUNEL-positive cells were observed throughoutthe postseizure hippocampus, piriform cortex, and entorhinal cortex.Combined TUNEL/NeuN immunocytochemistry demonstrated that thevast majority of TUNEL-positive cells were neurons. To identifycomponents of the signal transduction cascade promoting postseizureapoptosis, the expression of the p75 neurotrophin receptor (p75NTR)was examined. Seizure-induced increases in p75NTR protein andmRNA were detected in hippocampus, piriform cortex, and entorhinalcortex. Immunohistochemical double labeling revealed almost completecorrespondence between TUNEL-positive and p75NTR-expressing cells,suggesting that seizure-induced neuronal loss within the CNS occursthrough apoptotic signaling cascades involvingp75NTR.

Key words: seizure; apoptosis; pilocarpine; p75NTR; piriform cortex; entorhinal cortex; hippocampus

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neurotrophins are a conserved family of proteins that play a critical role in the development and maintenance of the nervoussystem (for review, see Barde, 1989). Their cellular effects aremediated by two distinct classes of cell surface receptors. Thetrk receptors are a family of transmembrane receptor tyrosinekinases that selectively bind different members of the neurotrophinfamily, with trkA preferentially binding NGF, trkB preferringBDNF and neurotrophin (NT)-4/5, and trkC interacting with NT-3(for review, see Kaplan and Miller, 1997). The second class ofneurotrophin receptor contains a single family member, the p75neurotrophin receptor (p75NTR), that binds all the neurotrophins(for review, see Barker, 1998; Casaccia-Bonnefil et al., 1998).p75NTR is a member of the tumor necrosis factor (TNF) receptorsuperfamily that includes CD27, CD30, CD40, 4-1BB, OX40, the fasantigen, and the tumor necrosis factor receptors TNFR1 and TNFR2(Bazan, 1993). Two opposing functions have been proposed for p75NTR.When coexpressed with trkA, p75NTR enhances NGF-mediated survivalby increasing the amount of NGF that binds the trkA receptor (Barkerand Shooter, 1994; Mahadeo et al., 1994; Verdi et al., 1994).Conversely, in some systems, p75NTR appears to behave as a ligand-regulatedproapoptotic receptor (Frade et al., 1996; Casaccia-Bonnefil etal., 1996; Majdan et al., 1997; Bamji et al., 1998; Frade andBarde, 1998). The signaling cascades that allow p75NTR to promoteapoptosis remain unknown but may involve ceramide production throughactivation of sphingomyelinase (Dobrowsky et al., 1994, 1995),activation of c-Jun N-terminal kinase (JNK; Casaccia-Bonnefilet al., 1996; Yoon et al., 1998), and accumulation of p53 (Aloyzet al., 1998).

Neuronal cell death has been well documented in both human epilepsy and experimental seizure models (for review, see Represaet al., 1995; Morrison et al., 1996; Sloviter, 1996; Treiman,1996). Although the specific contribution of cell death to thepathophysiology of epilepsy remains unclear, multiple studiessuggest that damage produced by status epilepticus (SE) promotesthe development of the recurrent spontaneous seizures characteristicof epilepsy (Aicardi and Chevrie, 1983; Cavalheiro et al., 1991;Priel et al., 1996). Pilocarpine-induced SE in the rat resultsin damage in multiple brain regions (Turski et al., 1983; Olneyet al., 1986; Turski et al., 1987). Dystrophic neurons can bedetected as early as 20 min after induction of SE, and much ofthis cell damage is likely necrotic (Fujikawa, 1996). Apoptoticcell death has been reported in some seizure models (Pollard etal., 1994; Morrison et al., 1996; Bengzon et al., 1997), but thespecific contribution of apoptotic or necrotic death to seizure-inducedneuronal loss is not clear, and the cellular mechanisms leadingto the induction of apoptosis after seizure areunknown.

In addition to necrotic and apoptotic cell death, seizure also induces changes in gene expression, including marked alterationsin neurotrophin and trk receptor expression (Gall et al., 1991a;for review, see Gall, 1993). Neurotrophins have been suggestedto play a trophic role after seizure; however, the recent demonstrationof a proapoptotic role for the p75 neurotrophin receptor suggeststhat increased neurotrophin expression after seizure could potentiallypromote cell death via p75NTR-dependent apoptoticmechanisms.

In this study, we demonstrate that pilocarpine-induced seizure results in marked and persistent apoptosis within hippocampal,piriform, and entorhinal cortical neurons. We show that this region-specificincrease in neuronal apoptosis is accompanied by expression ofp75NTR mRNA and protein. Furthermore, we demonstrate that neuronsundergoing seizure-induced apoptosis invariably show strong inductionof p75NTR, suggesting that upregulation of p75NTR expression andactivation of p75NTR signaling cascades may facilitate neuronalapoptosis afterseizure.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Seizure induction. Adult male Sprague Dawley rats (200-300 gm; Charles River ) were used for all experiments and housed underenvironmentally controlled conditions. Status epilepticus (SE)was induced by the administration of pilocarpine (380 mg/kg, i.p.;ICN Biochemicals, Montréal, Québec, Canada). Thirty minutesbefore administering pilocarpine, animals received scopolaminemethyl-bromide (1 mg/kg, i.p.; Sigma) to reduce the peripheralcholinergic effects of pilocarpine. During SE, the animals exhibitedtwo to five stage 5 seizures, behaviorally similar to kindledstage 5 seizures (Racine, 1972). To reduce mortality caused byseizure, diazepam (10 mg/kg, i.p.; Hoffmann-La Roche) was injected1 hr after the onset of SE. Control animals were treated identicallyto the experimental group, except that they received saline insteadof pilocarpine. Animals were killed, and tissue was removed 1,3, 7, or 14 d after pilocarpineinjection.

Tissue preparation. For immunocytochemical and terminal deoxynucleotidyl transferase-mediated UTP nick end labeling (TUNEL)assays, animals were anesthetized by injection of sodium pentobarbital(50 mg/kg, i.p.; MTC Pharmaceuticals), and perfused intracardiallywith PBS plus heparin (5 µg/ml) followed by 4% paraformaldehyde,15% picric acid, in PBS at pH 8 and 37°C. After perfusion, brainswere removed, post-fixed for 3 d at room temperature (RT) andcryoprotected in 30% sucrose-containing fixative at RT for 48hr before sectioning. Frozen 40 µm cryostat serial sections werestored in cryoprotectant at $-$ 20°C (30% sucrose and 30% ethyleneglycol in PBS) and assayed within 3 months of sectioning. Forimmunoblot analysis, animals were euthanized with pentobarbitalas above, the brain was removed, the cortex (combined neocorticaland paleocortical tissue excluding hippocampus) and hippocampuswere rapidly dissected, and total protein was extracted usingTrizol (Life Technologies, Gaithersburg, MD), as suggested bythemanufacturer.

Immunoblotting. p75NTR immunoreactivity was detected using anti-p75NTR-B1, a rabbit polyclonal antibody directed against aglutathione S-transferase (GST)-fusion protein containing aminoacids 276-425 of the intracellular domain of rat p75NTR (Majdanet al., 1997). MC192 ascites fluid was produced as described previously(Barker and Shooter, 1994) and purified using an Immunopure column(Pierce, Rockford, IL). Protein content of brain tissue extractswas normalized using the BCA assay (Pierce). Twenty five microgramsof protein were then solubilized in sample buffer (Laemmli, 1970),separated on 10% SDS-PAGE and electroblotted to nitrocellulose.Blocking, primary antibody, and secondary antibody incubationsfor p75NTR immunoblots were all performed in 10 mM Tris, pH 7.4,150 mM NaCl, and 0.2% Tween 20 with 5% (w/v) dry skim milk powderusing anti-p75NTR-B1 (1:2000). HRP-conjugated donkey anti-rabbitIgG (Jackson ImmunoResearch, West Grove, PA) was used at a dilutionof 1:10,000. Immunoreactive bands were detected using enhancedchemiluminescence (ECL) according to the manufacturer's instructions(DuPont). The immunoreactive band detected in brain homogenatescomigrated with an immunoreactive band of the appropriate molecularweight present in cell homogenates derived from p75NTR-transfected293 cells, and immunoreactivity could be blocked by a 6XHis-fusionprotein corresponding to the intracellular domain of p75NTR (datanot shown). Densitometry and quantification of the relative levelof p75NTR protein was performed on scanned images of immunoblots(Epson ES 1200C) using NIH Image software (United States NationalInstitutes of Health). The mean densitometric value correspondingto p75NTR expression was calculated for each time point (n = 3per time point with the exception of the 1 d postseizure timepoint where n = 2), and the percent increase from controls determinedby direct comparison with samples on the sameimmunoblot.

Immunocytochemistry. After cryostat sectioning, brain sections were washed briefly in PBS, and endogenous peroxidase activitywas reduced by incubation in 75% methanol and 3% H₂O₂ for 30 minat RT. Blocking, primary, and secondary antibody incubations wereperformed in blocking solution (2% bovine serum albumin, 2% heat-inactivatednormal goat serum, and 0.2% Triton X-100). Anti-p75NTR-B1 wasused at a dilution of 1:500, and HRP-conjugated goat anti-rabbitIgG was used at a dilution of 1:1000 (Jackson ImmunoResearch).Immunocytochemistry for c-Jun expression was performed as describedfor p75NTR, using a monoclonal antibody against c-Jun at 1:2000(Transduction Laboratories, Lexington, KY), and an HRP-conjugatedgoat anti-mouse IgG at 1:1000 (Jackson ImmunoResearch). Antibodycomplexes were detected with diaminobenzidine (DAB) and H₂O₂ asdescribed (Vector Laboratories, Burlingame, CA). For p75NTR andTUNEL costaining, sections were directly blocked for 2 hr afterthe TUNEL reaction, followed by an overnight incubation with purifiedMC192 (3 µg/ml at 4°C), a monoclonal antibody that recognizesrat p75NTR (Chandler et al., 1984). Secondary antibody incubationwas performed at RT for 2 hr using Cy3-conjugated goat anti-mouseIgG (Jackson ImmunoResearch) at a dilution of 1:1000. NeuN/TUNELdouble labeling was performed as for p75NTR, using the NeuN mousemonoclonal antibody at a dilution of 1:25 (gift of Richard Mullen).During the washes, nuclei were stained using Hoechst 33258 asdescribed (Molecular Probes, Eugene, OR). Bright-field imagesof p75NTR and c-Jun immunoreactivity and TUNEL were photographedusing a Zeiss Axiophot microscope. Fluorescence was visualizedusing a Zeiss Axioscop microscope and photographed using a CCDcamera and Northern Eclipse software (EmpixImaging).

In situ hybridization. After intracardial perfusion with 100 ml of 37°C saline with 5 µg/ml heparin, brains were immediatelydissected, placed in ice-cold PBS, and frozen in isopentane (2-methylbutane) chilled in liquid nitrogen. Five micrometer cryostat sectionswere cut and fixed to slides (Superfrost/Plus; Fisher Scientific)with 4% paraformaldehyde and 15% picric acid in PBS. In situ hybridizationwas performed as described (Braissant and Wahli, 1998) using digoxigenin-labeledRNA probes, signal-amplified using the Tyramide Signal Amplificationkit (NEN, Boston, MA), and peroxidase/DAB detection. Probes weresense and antisense transcripts of a 300 bp fragment correspondingto nucleotides 400-700 of rat p75NTR cDNA (Radeke et al., 1987).

In situ detection of DNA cleavage. TUNEL was performed using an in situ cell death detection kit as per the manufacturer'sinstructions (Boehringer Mannheim). TUNEL-positive nuclei weredetected using DAB and H₂O₂ with an HRP-conjugated anti-fluoresceinantibody. For the colabeling studies described above, TUNEL-positivecells were identified directly using the FITC fluorescence ofthe incorporated dUTP. Positive cells in 12 fields sampled fromlayers II and III of the entorhinal cortex derived from two differentrats (six fields each) at 3 d after seizure were scored for p75NTRimmunoreactivity, TUNEL reactivity, and their colocalization.In separate experiments, coincidence of NeuN and TUNEL reactivitywas similarlydetermined.

DNA extraction and agarose gel electrophoresis. Samples of hippocampi as well as frontal and temporal lobe were dissectedfrom brains of control rats or from rats seized 1 or 3 d earlierand then immediately frozen in dry ice, and stored at $-$ 70°C. DNAwas purified as described in Sankar et al. (1998) with some modifications.Tissues were homogenized using a Dounce homogenizer with a loosepestle in five volumes of a buffer containing 15 mM HEPES, pH7.2, 0.25 M sucrose, 60 mM KCl, 10 mM NaCl, 1 mM EGTA, 5 mM EDTA,and 1 mM PMSF. Cells were then centrifuged at 2000 × g for 10min and incubated overnight in a buffer containing 50 mM NaCl,10 mM Tris, pH 8.0, 25 mM EDTA, 0.5% SDS, 0.5 mg/ml proteinaseK, and 0.1 mg/ml DNase-free RNase A at 55°C. The lysate was extractedtwice using equal proportions of phenol: chloroform (1:1), andthen the aqueous layer was incubated at 37°C with 0.1 mg/ml RNaseA for 90 min. The phenol:chloroform extraction was repeated, andDNA was precipitated overnight with 2.5 vol of ethanol and 1/10vol of sodium acetate at $-$ 20°C. Precipitated DNA was spun at 15,000× g for 30 min and washed three times with 70% ethanol. The DNApellet was then air-dried and resuspended in 0.5-1 ml of 10 mMTris and 1 mM EDTA. Spectrophotometry revealed A260/280 ratiosof 1.6-1.9, indicating relatively pure DNA in concentrations of0.8-1.3 mg/ml. Thirty micrograms of DNA was run on each lane ofa 1% agarose gel containing 0.5% ethidium bromide at 5 V/cm gellength. The gel was viewed under UV transillumination and photographedusing a Kohu CCDcamera.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Pilocarpine-induced seizure leads to apoptosis in the adult rat brain

Brains of rats subjected to pilocarpine-induced seizure were examined for evidence of cell death using TUNEL, a method thatdetects apoptotic cells in situ (Gavrieli et al., 1992; Sgoncet al., 1994). Induction of SE by injection of pilocarpine causedsevere generalized seizures (multiple class 5) that resulted innumerous TUNEL-positive nuclei in multiple brain regions. TUNEL-positivecells were clearly detected at both 1 and 3 d after seizure inpiriform cortex, entorhinal cortex, and hippocampus, but TUNEL-positivecells were not observed in brain sections of control animals (Fig.1). The incidence of TUNEL-positive cells was greater 1 d afterseizure in both the piriform and entorhinal cortices comparedto 3 d. However, in the hippocampus, TUNEL staining was maximalat 3 d after seizure (n > 4 for each time point). Although theincidence of TUNEL-positive nuclei peaked at 1 d in entorhinalcortex after seizure, they were still detected in layers II andIII of the entorhinal cortex 14 d after seizure (data not shown).In the hippocampus, most TUNEL-positive nuclei were concentratedin the CA1 region, with lower numbers in the granule cell layerof the dentate gyrus (Fig. 1I). Consistent with previous histochemicaldescriptions of the distribution of dystrophic cells producedby pilocarpine-induced seizure (Mello et al., 1993; Fujikawa,1996), the amygdala, the perirhinal cortex, and the lateral posteriorthalamic nucleus showed fewer but detectable TUNEL-positive nucleiafter seizure (data not shown). Incidence of TUNEL-positive cellsvaried somewhat between animals, but the regional distributionof TUNEL-positive cells was consistent.

View larger version (155K):
[in this window]
[in a new window]
Figure 1. TUNEL staining and expression of c-Jun after pilocarpine-induced seizure in the rat brain. Cells positive for TUNEL reactivity (A-J) and for c-Jun expression (K, L) were visualized using peroxidase/DAB in brain sections from control rats (A, D, G, K), 1 d (B, E, H, L), or 3 d after seizure (C, F, I) in the piriform cortex (A-C), entorhinal cortex (D-F, K, L), and hippocampus (G-I). J is a higher magnification of the tissue in E showing TUNEL-positive nuclei. Filled arrowheads identify the hippocampal CA1 pyramidal cell layer. Open arrowheads identify the upper blade of the dentate granule cell layer. Cortical layers are indicated. Cx, Cortex. Scale bars: F, 200 µm; I, 400 µm; J, 20 µm; L, 160 µm.

To confirm that TUNEL staining within seized brain reflects seizure-induced apoptosis, genomic DNA was extracted from brainsof control and seized rats and analyzed for oligosomal fragmentation,a biochemical hallmark of apoptosis. Figure 2 shows that DNA fragmentationwas undetectable in brains from control animals; however, DNAfragments with a periodicity of ~180 bp were present in extractsof temporal cortex from seized animals at both 1 and 3 d afterSE. DNA fragmentation was most prevalent in temporal cortex, consistentwith the high level of TUNEL reactivity observed in the piriformand entorhinal cortices, but was also clearly detected in extractsof hippocampus and the frontal cortex. Sections costained withTUNEL and Hoechst 33258 demonstrate that a subset of the TUNEL-positivenuclei are condensed in a manner characteristic of apoptotic celldeath (Fig. 7). Together, these data demonstrate the presenceof apoptotic cells within multiple CNS regions in the rat afterpilocarpine-induced seizure.

View larger version (68K):
[in this window]
[in a new window]
Figure 2. DNA fragmentation after pilocarpine-induced seizure. DNA extracted from control, 1 d, and 3 d postseizure tissue was analyzed by agarose gel electrophoresis. DNA laddering is visible in extracts of rat brain 1 and 3 d after pilocarpine-induced seizure. DNA was extracted from dissected samples of frontal cortex (F), temporal cortex (T), and hippocampus (H).

Signaling pathways that result in c-Jun expression and phosphorylation are involved in neuronal apoptosis (for review, seeDragunow and Preston, 1995; Herdegen et al., 1997), and we thereforeexamined whether c-Jun protein expression was induced after pilocarpine-inducedseizure. Consistent with previous results that showed inductionof immediate-early response genes in other seizure models (Dragunowet al., 1993; Herdegen et al., 1997), prominent c-Jun expressionwas detected throughout the brain 1 d after pilocarpine-inducedSE (Fig. 1L).

p75NTR protein expression increases after seizure

Neurotrophins promote neuronal survival by activating trk receptors, but recent studies also suggest that p75NTR may facilitateneuronal apoptosis. As an initial step toward identifying moleculesthat may promote neuronal apoptosis after seizure, levels of p75NTRprotein were assayed after pilocarpine-induced seizure. Immunoblotanalysis of tissue isolated from nonseized controls show thatthe level of p75NTR protein is low but detectable in protein extractedfrom hippocampal and cortical tissue. After seizure, p75NTR proteinexpression increased in a time-dependent manner (Fig. 3). In thehippocampus (Fig. 3B), p75NTR protein levels increased 1 d afterseizure and then persisted as a fourfold to sixfold increase forat least 7 d. Two weeks after seizure, the level of p75NTR proteinhad returned to that of sham-treated controls. In cortical lysates(Fig. 3A), the increase was delayed and more transient, with afivefold increase in p75NTR expression 3 d after seizure but sharplyreduced p75NTR levels by 7 d.

View larger version (32K):
[in this window]
[in a new window]
Figure 3. Increased p75NTR expression after seizure. Protein homogenates from the hippocampus and cortex (neocortical and paleocortical tissue) of control, 1, 3, 7, and 14 d after seizure. Representative immunoblots show the relative amount of p75NTR protein in cortex (A) and hippocampus (B). Each graph represents the normalized densitometric index of immunoblots from three animals per time point (± SD) except for the 1 d time point, at which two animals were analyzed.

To identify the cellular distribution of p75NTR protein, brain sections from seized and control rats were analyzed for p75NTRimmunoreactivity 1 and 3 d after pilocarpine treatment. In controlanimals, p75NTR immunoreactivity was restricted to basal forebrain,as previously described (Kiss et al., 1988; Lee et al., 1998)(data not shown). After pilocarpine-induced seizure, p75NTR immunoreactivitywas detected in the piriform cortex, entorhinal cortex, perirhinalcortex, and hippocampus (Fig. 4). Of these regions, entorhinalcortex showed the strongest p75NTR immunoreactivity, particularly3 d after seizure. At 1 d after seizure, a diffuse increase inimmunoreactivity was detected in entorhinal, piriform, and perirhinalcortices. By 3 d after seizure, strong p75NTR immunoreactivitywas concentrated in cortical layers II and III and was clearlyassociated with cell bodies and processes. Immunoreactivity decreasedgradually dorsal to perirhinal cortex. The immunoblotting studiesdid not reveal an increase in p75NTR protein in the cortex 1 dafter seizure (Fig. 3), consistent with the restricted corticalexpression observed by immunocytochemistry at this time point.In the hippocampus, increased p75NTR expression was observed inthe dentate granule cell layer, dentate hilus, and CA1 pyramidalcell layer, and was most prominent 3 d after seizure.

View larger version (151K):
[in this window]
[in a new window]
Figure 4. Cellular localization of p75NTR protein after seizure. p75NTR expression visualized with peroxidase/DAB in brain sections from control (A, D, G, J), 1 d (B, E, H), or 3 d after seizure (C, F, I, K). A-C show the piriform cortex, D-F the entorhinal cortex, G-I the perirhinal cortex, and J, K, the hippocampus. L is a higher magnification of the tissue in F showing specifically stained cell bodies and processes. Filled arrowheads identify the hippocampal CA1 pyramidal cell layer. Open arrowheads identify the upper blade of the dentate granule cell layer. Cortical layers are identified as indicated. Cx, Cortex. Scale bars: F, 160 µm; I, 250 µm; K, 400 µm; L, 20 µm.

p75NTR mRNA expression is increased in seized brain

To identify the cellular source of p75NTR expression after pilocarpine seizure, p75NTR mRNA distribution was determined byin situ hybridization in sections taken from pilocarpine-treatedanimals 1 and 3 d after seizure. Figure 5A shows that p75NTR mRNAwas readily detected in layers II and III of the entorhinal cortexusing an antisense p75NTR cRNA. Within the hippocampus, p75NTRmRNA was detected primarily in the CA1 pyramidal cell layer anddentate granule cell layer, but lower levels were present in thehilus (Fig. 5D). No specific hybridization was observed when acontrol sense probe was used in the entorhinal cortex or the hippocampus(Fig. 5B,E), and sense and antisense p75NTR probes produced nodetectable signal in sections of entorhinal cortex and hippocampusfrom control, nonseized animals (data not shown).

View larger version (86K):
[in this window]
[in a new window]
Figure 5. p75NTR mRNA expression after seizure. p75NTR mRNA was detected by in situ hybridization 1 d after seizure in the entorhinal cortex. A, p75NTR mRNA detected with an antisense probe in entorhinal cortex 1 d after seizure. B, No signal was detected using the corresponding sense probe on a adjacent section from the same brain. C, Higher magnification of the tissue in A, illustrating the cytoplasmic localization of the specific hybridization signal. D, p75NTR mRNA detected in the hippocampus 3 d after seizure using the antisense probe, and (E) no signal was detected using the sense probe on an adjacent section from the same brain. Filled arrowheads identify the hippocampal CA1 pyramidal cell layer. Open arrowheads identify the upper blade of the dentate granule cell layer. Cortical layers are indicated. Scale bars: A, 120 µm; C, 12 µm; D, 200 µm.

p75NTR expression is induced after seizure by neurons undergoing apoptosis

To determine if the p75NTR immunoreactive and TUNEL-positive cells were neurons, we first examined the coincidence of TUNELand NeuN, a neuron-specific epitope (Mullen et al., 1992). Doublelabel immunofluorescence showed that >90% of the TUNEL-positivecells in layers II and III of the entorhinal cortex 3 d afterseizure were NeuN-positive, identifying them as neurons (Fig.6).

View larger version (17K):
[in this window]
[in a new window]
Figure 6. Cells undergoing apoptosis are neurons. Triple immunofluorescence demonstrating colocalization of Hoechst 33258 (A), NeuN (B), and TUNEL (C) in entorhinal cortex 3 d after pilocarpine-induced seizure. NeuN is neuron-specific, but not a pan-neuronal marker (Mullen et al., 1992), suggesting that some proportion of NeuN-negative cells may also be neuronal. Scale bar, 20 µm.

To determine if p75NTR expression correlated with TUNEL labeling of individual cells, colabeling was performed on sectionsof entorhinal cortex derived from animals 3 d after pilocarpine-inducedSE. The mouse monoclonal antibody MC192 was used to detect p75NTRin these experiments because p75NTR-B1 antigenicity was incompatiblewith the TUNEL reaction. Control studies on serial sections demonstratedthat MC192 and p75NTR-B1 produce identical patterns of immunoreactivity(data not shown). Colabeling within the entorhinal cortex demonstratedthat most of the TUNEL-positive cells present in layers II andIII 3 d after seizure were also p75NTR-immunoreactive (Fig. 7A-G).An almost complete coincidence of TUNEL staining with p75NTR immunoreactivitywas also observed in the CA1 region of the hippocampus (Fig. 7H,I).Cell counts of layers II and III in the entorhinal cortex revealeda strong correlation between p75NTR immunoreactivity and TUNEL(n > 600; Table 1): >83% of the cells that were positive forp75NTR were also TUNEL-positive, and >85% of TUNEL-positive cellswere immunoreactive for p75NTR (Table 1). Therefore, there wasan almost complete overlap between p75NTR expression and the presenceof TUNEL-positive nuclei.

View larger version (53K):
[in this window]
[in a new window]
Figure 7. p75NTR expression is induced after seizure in neurons undergoing apoptosis. Triple-immunofluorescence of p75NTR (A, D, H), TUNEL (B, E, I), and Hoechst 33258 (C, F, J) in layer III of the entorhinal cortex (between bregma $-$ 7.04 and $-$ 7.30; A-F) and within hippocampus (H-J), 3 d after pilocarpine-induced seizure. G is a composite of D-F, with p75NTR immunoreactivity visualized in red (Cy3-conjugated secondary antibody), TUNEL reaction in green (FITC), and Hoechst-stained nuclei in blue. In H-J, the dashed line indicates the boundary of the hippocampal CA1 layer, and the white bars indicate cells containing pyknotic nuclei. Scale bars: C, J, 50 µm; G, 10 µm.


View this table:
[in this window]
[in a new window]
Table 1. Proportion of TUNEL and p75NTR colabeled cells in the entorhinal cortex 3 d after seizure

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study we demonstrate that pilocarpine-induced seizure produces a large increase in TUNEL-positive neurons in the hippocampal,entorhinal, and piriform cortices and a dramatic rise in cellularDNA cleavage, a hallmark of apoptosis. This regional damage isaccompanied by a large increase in levels of p75NTR mRNA and proteinin neurons within these same structures. The incidence of TUNELwithin individual neurons correlates tightly with p75NTR expression,with >85% of the cells with TUNEL-positive nuclei showing inducedp75NTR expression. TUNEL-positive cells are still observed manydays after pilocarpine administration, indicating that apoptoticmechanisms, potentially mediated by p75NTR, may contribute tolong-term cell loss after statusepilepticus.

The relative proportions of necrotic and apoptotic cell death are not known in any seizure model, but both necrosis and apoptoticcell death occur after kainic acid-induced seizure and duringkindling (Pollard et al., 1994; Morrison et al., 1996; Bengzonet al., 1997). Histochemical assays have shown that pilocarpine-inducedseizure induces cell damage in numerous sites throughout the brainthat include the hippocampal gyrus (CA1 and CA3 cell layers),the dentate gyrus (both granule cell and hilar layers), piriformcortex, and entorhinal cortex (Fujikawa, 1996). This pilocarpine-inducedcell loss can be inhibited by NMDA antagonists (Rice and DeLorenzo,1998), suggesting that much of it is triggered by excitotoxicmechanisms. We have found that pilocarpine-induced seizure resultsin a profound increase in TUNEL reactivity in neurons, particularlyin entorhinal and piriform cortices but also within thehippocampus.

Necrosis and apoptosis are defined on the basis of morphological criteria but in mechanistic terms, apoptosis refers to activeintracellular signaling that results in cellular suicide. In somesystems, dying cells can show morphological features of both necrosisand apoptosis; for example, cells showing morphological hallmarksof necrotic death can also be TUNEL-positive (Charriaut-Marlangueand Ben-Ari, 1995). Pyknotic nuclei, which are characteristicof apoptosis, become numerous after pilocarpine-induced seizureparadigm (Fig. 7) but to confirm that intracellular apoptoticsignaling cascades contribute to the cell death that occurs afterpilocarpine-induced SE, DNA extracted from various areas of seizedbrains was examined for the DNA cleavage pattern characteristicof intracellular apoptotic mechanisms. Our demonstration thatseizure induced by pilocarpine results in DNA fragmentation thatcorrelates with the region-specific increase in TUNEL stainingand pyknotic nuclei indicates that this seizure model resultsin widespread activation of intracellular apoptotic cascades.Kainate, which is widely used to induce seizure, results in damageprimarily to the hippocampus, particularly within CA1, CA3, thehilus, and the subiculum (Morrison et al., 1996); our data suggestthat pilocarpine-induced seizure results in a much more profoundapoptotic response within the CNS, ultimately resulting in morewidespread neuronaldamage.

The expression of neurotrophins and trk receptors is regulated by kindling and after chemically-induced seizure. A transientincrease in mRNA for NGF, BDNF, trkB, and trkC in the hippocampusand neocortex has been demonstrated during kindling (Ernfors etal., 1991; Bengzon et al., 1993; Merlio et al., 1993), and kainicacid or bicuculline-induced seizure results in increased expressionof NGF, BDNF, and trkB mRNA levels (Zafra et al., 1990; Ballarinet al., 1991; Gall et al., 1991b; Isackson et al., 1991; Dugich-Djordjevicet al., 1992, 1995; Humpel et al., 1993; Wetmore et al., 1994).Studies examining NT-3 expression have suggested either no change(Ballarin et al., 1991; Ernfors et al., 1991; Merlio et al., 1993)or a decrease in expression by hippocampal neurons after seizure(Bengzon et al., 1992; Gall, 1992; Rocamora et al., 1992), suggestingthat increases in neurotrophin expression are restricted to specificfamily members. In addition, trkA mRNA is unchanged by kindlingor pilocarpine-induced seizure (for review, see Gall, 1993; Perssonand Ibanez, 1993; Mudo et al., 1996). Traditionally, the injury-inducedincrease in neurotrophin expression has been thought to mediatecell survival or synaptic plasticity; however, the recently discoveredapoptotic function of p75NTR may require re-evaluation of thishypothesis.

The p75NTR is widely expressed in the nervous system during development, but in the adult CNS, p75NTR expression is limitedmainly to magnocellular neurons of the basal forebrain, cellswithin the caudate putamen, and cerebellar Purkinje cells (forreview, see Barker, 1998). The expression profile of p75NTR afterchemically-induced seizure has not been previously addressed,but p75NTR mRNA levels are unchanged by kindling (Merlio et al.,1993). p75NTR mRNA levels are increased in some forms of neuronalinjury such as in motoneurons after sciatic nerve crush (Ernforset al., 1989), in adult striatal cholinergic neurons after experimentallyinduced focal cerebral ischemia (Kokaia et al., 1998), and inPurkinje cells after axotomy (Armstrong et al., 1991; Dusart etal., 1994; Martinez-Murillo et al., 1998). The functional consequencesof these changes in p75NTR expression after neuronal trauma areuncertain since p75NTR can, on the one hand, facilitate trkA activationand increase survival effects of the neurotrophins (Barker andShooter, 1994; Verdi et al., 1994; Ryden et al., 1997) but alsoplay a proapoptotic role (Rabizadeh et al., 1993; Barrett andBartlett, 1994; Frade et al., 1996; Majdan et al., 1997; Bamjiet al., 1998). This contrast in p75NTR function is illustratedby comparing wild-type and p75 $-$ / $-$ sympathetic neurons under differentexperimental conditions. Sympathetic neurons derived from p75 $-$ / $-$ mice require increased amounts of NGF to maintain survival (Leeet al., 1994; Ryden et al., 1997), indicating that p75NTR normallyfacilitates trkA activity, yet p75 $-$ / $-$ neurons undergo apoptosisin response to neurotrophin withdrawal considerably more slowlythan their wild-type counterparts (Bamji et al., 1998), indicatingthat p75NTR also normally facilitates apoptosis. It now seemsvery likely that there is considerable cell and developmentalspecificity to p75NTR function in vivo, with p75NTR enhancingsurvival in some circumstances and facilitating apoptosis inothers.

We favor the hypothesis that p75NTR is induced after seizure through an activity-dependent mechanism and is then capable ofactivating apoptotic signaling cascades in response to bound neurotrophin.This model is consistent with findings that show that p75NTR expressionis increased by potassium chloride treatment of cultured Purkinjecells (Cohen-Cory et al., 1993), with the action of other relatedapoptotic receptors, in which regulated receptor expression isnecessary and sufficient for the initiation of an apoptotic cascade(Muller et al., 1998; Chan et al., 1999), and with findings thatshow that p75NTR activates apoptotic pathways in a ligand-dependentmanner (Casaccia-Bonnefil et al., 1996; Frade et al., 1996; Majdanet al., 1997; Bamji et al., 1998; Frade and Barde, 1998, 1999).

Signaling pathways activated by p75NTR remain poorly characterized, but likely candidates that may be involved in this cascadeinclude JNK and the p53 tumor suppressor. Mice lacking the genefor JNK3, an isoform of JNK enriched in the CNS, show reducedapoptosis in response to excitotoxic injury (Yang et al., 1997),and although p75NTR-mediated activation of JNK has not been reportedin central neurons, JNK is induced after p75NTR activation inoligodendrocytes and sympathetic neurons (Casaccia-Bonnefil etal., 1996; Bamji et al., 1998; Yoon et al., 1998). Our resultsshow that seizure resulted in increased c-Jun immunoreactivity,yet the distribution of both p75NTR and TUNEL staining was considerablymore restricted than the increase in c-Jun expression. It is possiblethat production of the c-Jun protein may be a necessary prerequisitefor seizure-induced neuronal apoptosis but is insufficient tomediate apoptosis on its own. Indeed, c-Jun may become phosphorylatedby JNK (and therefore active) only in those cells expressing p75NTR.It is noteworthy that after brain ischemia, c-Jun is widely expressedyet c-jun phosphorylation occurs only in a proportion of piriformcortical cells undergoing apoptosis (Herdegen et al., 1998). Severalfindings also indicate that p53 may be involved in neuronal apoptosisafter seizure. Morrison et al. (1996) have shown that hippocampalneurons that are normally lost after kainic acid-induced seizureare protected in mice lacking functional alleles for p53. Furthermore,p53 may be implicated in a p75NTR-dependent apoptotic pathwayinduced in sympathetic neurons withdrawn from NGF (Aloyz et al.,1998). Given the links between p75NTR, JNK activation, and p53,it will be interesting to test if p75NTR acts as an apoptoticreceptor that mediates JNK and/or p53 activation in adult neuronsand to determine if p75NTR expression constitutes the first stepof a death process triggered byseizure.

The roles of p75NTR in enhancing trk activity and mediating apoptosis are complex, and signaling events evoked by p75NTR arenot fully understood. There is a critical need for in vitro andin vivo models that will allow the elucidation of p75NTR function.Here, the concurrence of apoptosis and p75NTR expression observedin the CNS after pilocarpine-induced seizure indicates that analysisof the role of p75NTR in seizure-induced apoptosis will proveuseful for identifying both p75NTR signaling mechanisms and thepotential contribution of p75NTR to neuronal cell death in vivo.

  FOOTNOTES

Received Dec. 23, 1998; revised May 10, 1999; accepted May 26, 1999.

This work was supported by grants from the Medical Research Council of Canada (MRC), the Neuroscience Network (Canada), andthe Fond de la Recherche en Santé du Quebec. P.P.R. and M.A.C.were supported by a Jeanne Timmons Costello studentship and bya Savoy Foundation studentship, respectively. P.A.B. is a KillamFoundation Scholar and a Scholar of the MRC. T.E.K. is a Scholarof the MRC. We thank Drs. Dan McIntyre and Adriana Di Polo forcritically reading thismanuscript.
Correspondence should be addressed to Philip A. Barker or Timothy E. Kennedy, Centre for Neuronal Survival, Montreal NeurologicalInstitute, McGill University, 3801 University Avenue, Montreal,Quebec, Canada H3A2B4.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Aicardi J, Chevrie JJ (1983) Consequences of status epilepticus in infants and children. Adv Neurol 34:115-125[Medline].
Aloyz RS, Bamji SX, Pozniak CD, Toma JG, Atwal J, Kaplan DR, Miller FD (1998) p53 is essential for developmental neuron death as regulated by the TrkA and p75 neurotrophin receptors. J Cell Biol 143:1691-1703[Abstract/Free Full Text].
Armstrong DM, Brady R, Hersh LB, Hayes RC, Wiley RG (1991) Expression of choline acetyltransferase and nerve growth factor receptor within hypoglossal motoneurons following nerve injury. J Comp Neurol 304:596-607[ISI][Medline].
Ballarin M, Ernfors P, Lindefors N, Persson H (1991) Hippocampal damage and kainic acid injection induce a rapid increase in mRNA for BDNF and NGF in the rat brain. Exp Neurol 114:35-43[ISI][Medline].
Bamji SX, Majdan M, Pozniak CD, Belliveau DJ, Aloyz R, Kohn J, Causing CG, Miller FD (1998) The p75 neurotrophin receptor mediates neuronal apoptosis and is essential for naturally occurring sympathetic neuron death. J Cell Biol 140:911-923[Abstract/Free Full Text].
Barde YA (1989) Trophic factors and neuronal survival. Neuron 2:1525-1534[ISI][Medline].
Barker PA (1998) p75NTR: A study in contrasts. Cell Death Diff 5:346-356.[ISI][Medline]
Barker PA, Shooter EM (1994) Disruption of NGF binding to the low affinity neurotrophin receptor, p75LNTR, reduces NGF binding to trkA on PC12 cells. Neuron 13:203-215[ISI][Medline].
Barrett GL, Bartlett PF (1994) The p75 nerve growth factor receptor mediates survival or death depending on the stage of sensory neuron development. Proc Natl Acad Sci USA 91:6501-6505[Abstract/Free Full Text].
Bazan JF (1993) Emerging families of cytokines and receptors. Curr Biol 3:603-606[ISI][Medline].
Bengzon J, Soderstrom S, Kokaia Z, Kokaia M, Ernfors P, Persson H, Ebendal T, Lindvall O (1992) Widespread increase of nerve growth factor protein in the rat forebrain after kindling-induced seizures. Brain Res 587:338-342[ISI][Medline].
Bengzon J, Kokaia Z, Ernfors P, Kokaia M, Leanza G, Nilsson OG, Persson H, Lindvall O (1993) Regulation of neurotrophin and trkA, trkB and trkC tyrosine kinase receptor messenger RNA expression in kindling. Neuroscience 53:433-446[ISI][Medline].
Bengzon J, Kokaia Z, Elmer E, Nanobashvili A, Kokaia M, Lindvall O (1997) Apoptosis and proliferation of dentate gyrus neurons after single and intermittent limbic seizures. Proc Natl Acad Sci USA 94:10432-10437[Abstract/Free Full Text].
Braissant O, Wahli W (1998) A simplified in situ hybridization protocol using non-radioactively labeled probes to detect abundant and rare mRNAs on tissue sections. Roche Molecular Biochemicals, Biochemica 1:1016.
Casaccia-Bonnefil P, Carter BD, Dobrowsky RT, Chao MV (1996) Death of oligodendrocytes mediated by the interaction of nerve growth factor with its receptor p75. Nature 383:716-719[Medline].
Casaccia-Bonnefil P, Kong H, Chao MV (1998) Neurotrophins: the biological paradox of survival factors eliciting apoptosis. Cell Death Diff 5:357-364.[ISI][Medline]
Cavalheiro EA, Leite JP, Bortolotto ZA, Turski WA, Ikonomidou C, Turski L (1991) Long-term effects of pilocarpine in rats: structural damage of the brain triggers kindling and spontaneous recurrent seizures. Epilepsia 32:778-782[ISI][Medline].
Chan H, Bartos DP, Owen-Schaub LB (1999) Activation-dependent transcriptional regulation of the human Fas promoter requires NF- $kappa$ B p50-p65 recruitment. Mol Cell Biol 19:2098-2108[Abstract/Free Full Text].
Chandler CE, Parsons LM, Hosang M, Shooter EM (1984) A monoclonal antibody modulates the interaction of nerve growth factor with PC12 cells. J Biol Chem 259:6882-6889[Abstract/Free Full Text].
Charriaut-Marlangue C, Ben-Ari Y (1995) A cautionary note on the use of TUNEL stain to determine apoptosis. NeuroReport 7:61-64[ISI][Medline].
Cohen-Cory S, Elliott RC, Dreyfus CF, Black IB (1993) Depolarizing influences increase low-affinity NGF receptor gene expression in cultured Purkinje neurons. Exp Neurol 119:165-175[ISI][Medline].
Dobrowsky RT, Werner MH, Castellino AM, Chao MV, Hannun YA (1994) Activation of the sphingomyelin cycle through the low affinity neurotrophin receptor. Science 265:1596-1598[Abstract/Free Full Text].
Dobrowsky RT, Jenkins GM, Hannun YA (1995) Neurotrophins induce sphingomyelin hydrolysis - modulation by co-expression of p75(ntr) with trk receptors. J Biol Chem 270:22135-22142[Abstract/Free Full Text].
Dragunow M, Preston K (1995) The role of inducible transcription factors in apoptotic nerve cell death. Brain Res Rev 21:1-28[Medline].
Dragunow M, Young D, Hughes P, MacGibbon G, Lawlor P, Singleton K, Sirimanne E, Beilharz E, Gluckman P (1993) Is c-Jun involved in nerve cell death following status epilepticus and hypoxic-ischaemic brain injury? Mol Brain Res 18:347-352[Medline].
Dugich-Djordjevic MM, Tocco G, Willoughby DA, Najm I, Pasinetti G, Thompson RF, Baudry M, Lapchak PA, Hefti F (1992) BDNF mRNA expression in the developing rat brain following kainic acid-induced seizure activity. Neuron 8:1127-1138[ISI][Medline].
Dugich-Djordjevic MM, Ohsawa F, Okazaki T, Mori N, Day JR, Beck KD, Hefti F (1995) Differential regulation of catalytic and non-catalytic trkB messenger RNAs in the rat hippocampus following seizures induced by systemic administration of kainate. Neuroscience 66:861-877[ISI][Medline].
Dusart I, Morel MP, Sotelo C (1994) Parasagittal compartmentation of adult rat Purkinje cells expressing the low-affinity nerve growth factor receptor: changes of pattern expression after a traumatic lesion. Neuroscience 63:351-356[ISI][Medline].
Ernfors P, Henschen A, Olson L, Persson H (1989) Expression of nerve growth factor receptor mRNA is developmentally regulated and increased after axotomy in rat spinal cord motoneurons. Neuron 2:1605-1613[ISI][Medline].
Ernfors P, Bengzon J, Kokaia Z, Persson H, Lindvall O (1991) Increased levels of messenger RNAs for neurotrophic factors in the brain during kindling epileptogenesis. Neuron 7:165-176[ISI][Medline].
Frade JM, Barde YA (1998) Nerve growth factor: two receptors, multiple functions. Bioessays 20:137-145[ISI][Medline].
Frade JM, Barde YA (1999) Genetic evidence for cell death mediated by nerve growth factor and the neurotrophin receptor p75 in the developing mouse retina and spinal cord. Development 126:683-690[Abstract].
Frade JM, Rodriguez-Tebar A, Barde YA (1996) Induction of cell death by endogenous nerve growth factor through its p75 receptor. Nature 383:166-168[Medline].
Fujikawa DG (1996) The temporal evolution of neuronal damage from pilocarpine-induced status epilepticus. Brain Res 725:11-22[ISI][Medline].
Gall CM (1992) Regulation of brain neurotrophin by physiological activity. Trends Pharmacol Sci 13:401-403[Medline].
Gall CM (1993) Seizure-induced changes in neurotrophin expression: implications for epilepsy. Exp Neurol 124:150-166[ISI][Medline].
Gall C, Lauterborn J, Bundman M, Murray K, Isackson P (1991a) Seizures and the regulation of neurotrophic factor and neuropeptide gene expression in brain. Epilepsy Res [Suppl] 4:225-245[Medline].
Gall C, Murray K, Isackson PJ (1991b) Kainic acid-induced seizures stimulate increased expression of nerve growth factor mRNA in rat hippocampus. Mol Brain Res 9:113-123[Medline].
Gavrieli Y, Sherman Y, Ben-Sasson SA (1992) Identification of programmed cell death in situ via specific labeling of nuclear DNA fragmentation. J Cell Biol 119:493-501[Abstract/Free Full Text].
Herdegen T, Skene P, Bahr M (1997) The c-Jun transcription factor-bipotential mediator of neuronal death, survival and regeneration. Trends Neurosci 20:227-231[ISI][Medline].
Herdegen T, Claret FX, Kallunki T, Martin-Villalba A, Winter C, Hunter T, Karin M (1998) Lasting N-terminal phosphorylation of c-Jun and activation of c-Jun N-terminal kinases after neuronal injury. J Neurosci 18:5124-5135[Abstract/Free Full Text].
Humpel C, Wetmore C, Olson L (1993) Regulation of brain-derived neurotrophic factor messenger RNA and protein at the cellular level in pentylenetetrazol-induced epileptic seizures. Neuroscience 53:909-918[ISI][Medline].
Isackson PJ, Huntsman MM, Murray KD, Gall CM (1991) BDNF mRNA expression is increased in adult rat forebrain after limbic seizures: temporal patterns of induction distinct from NGF. Neuron 6:937-948[ISI][Medline].
Kaplan DR, Miller FD (1997) Signal transduction by the neurotrophin receptors. Curr Opin Cell Biol 9:213-221[ISI][Medline].
Kiss J, McGovern J, Patel AJ (1988) Immunohistochemical localization of cells containing nerve growth factor receptors in the different regions of the adult rat forebrain. Neuroscience 27:731-748[ISI][Medline].
Kokaia Z, Andsberg G, Martinez-Serrano A, Lindvall O (1998) Focal cerebral ischemia in rats induces expression of p75 neurotrophin receptor in resistant striatal cholinergic neurons. Neuroscience 84:1113-1125[ISI][Medline].
Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227:680-685[Medline].
Lee KF, Davies AM, Jaenisch R (1994) p75-deficient embryonic dorsal root sensory and neonatal sympathetic neurons display a decreased sensitivity to NGF. Development 120:1027-1033[Abstract].
Lee TH, Kato H, Pan LH, Ryu JH, Kogure K, Itoyama Y (1998) Localization of nerve growth factor, trkA and p75 immunoreactivity in the hippocampal formation and basal forebrain of adult rats. Neuroscience 83:335-349[ISI][Medline].
Mahadeo D, Kaplan L, Chao MV, Hempstead BL (1994) High affinity nerve growth factor binding displays a faster rate of association than p140trk binding. Implications for multi-subunit polypeptide receptors. J Biol Chem 269:6884-6891[Abstract/Free Full Text].
Majdan M, Lachance C, Gloster A, Aloyz R, Zeindler C, Bamji S, Bhakar A, Belliveau D, Fawcett J, Miller FD, Barker PA (1997) Transgenic mice expressing the intracellular domain of the p75 neurotrophin receptor undergo neuronal apoptosis. J Neurosci 17:6988-6998[Abstract/Free Full Text].
Martinez-Murillo R, Fernandez AP, Bentura ML, Rodrigo J (1998) Subcellular localization of low-affinity nerve growth factor receptor-immunoreactive protein in adult rat purkinje cells following traumatic injury. Exp Brain Res 119:47-57[ISI][Medline].
Mello LE, Cavalheiro EA, Tan AM, Kupfer WR, Pretorius JK, Babb TL, Finch DM (1993) Circuit mechanisms of seizures in the pilocarpine model of chronic epilepsy: cell loss and mossy fiber sprouting. Epilepsia 34:985-995[ISI][Medline].
Merlio JP, Ernfors P, Kokaia Z, Middlemas DS, Bengzon J, Kokaia M, Smith ML, Siesjo BK, Hunter T, Lindvall O, Persson H (1993) Increased production of the TrkB protein tyrosine kinase receptor after brain insults. Neuron 10:151-164[ISI][Medline].
Morrison RS, Wenzel HJ, Kinoshita Y, Robbins CA, Donehower LA, Schwartzkroin PA (1996) Loss of the p53 tumor suppressor gene protects neurons from kainate-induced cell death. J Neurosci 16:1337-1345[Abstract/Free Full Text].
Mudo G, Jiang XH, Timmusk T, Bindoni M, Belluardo N (1996) Change in neurotrophins and their receptor mRNAs in the rat forebrain after status epilepticus induced by pilocarpine. Epilepsia 37:198-207[ISI][Medline].
Mullen RJ, Buck CR, Smith AM (1992) NeuN, a neuronal specific nuclear protein in vertebrates. Development 116:201-211[Abstract].
Muller M, Wilder S, Bannasch D, Israeli D, Lehlbach K, Li-Weber M, Friedman SL, Galle PR, Stremmel W, Oren M, Krammer PH (1998) p53 activates the CD95 (APO-1/Fas) gene in response to DNA damage by anticancer drugs. J Exp Med 188:2033-2045[Abstract/Free Full Text].
Olney JW, Collins RC, Sloviter RS (1986) Excitotoxic mechanisms of epileptic brain damage. Adv Neurol 44:857-877[Medline].
Persson H, Ibanez CF (1993) Role and expression of neurotrophins and the trk family of tyrosine kinase receptors in neural growth and rescue after injury. Curr Opin Neurol Neurosurg 6:11-18[ISI][Medline].
Pollard H, Charriaut-Marlangue C, Cantagrel S, Represa A, Robain O, Moreau J, Ben-Ari Y (1994) Kainate-induced apoptotic cell death in hippocampal neurons. Neuroscience 63:7-18[ISI][Medline].
Priel MR, dos Santos NF, Cavalheiro EA (1996) Developmental aspects of the pilocarpine model of epilepsy. Epilepsy Res 26:115-121[ISI][Medline].
Rabizadeh S, Oh J, Zhong LT, Yang J, Bitler CM, Butcher LL, Bredesen DE (1993) Induction of apoptosis by the low-affinity NGF receptor. Science 261:345-248[Abstract/Free Full Text].
Racine RJ (1972) Modification of seizure activity by electrical stimulation. II. Motor seizure. Electroencephalogr Clin Neurophysiol 32:281-294[ISI][Medline].
Radeke MJ, Misko TP, Hsu C, Herzenberg LA, Shooter EM (1987) Gene transfer and molecular cloning of the rat nerve growth factor receptor. Nature 325:593-597[Medline].
Represa A, Niquet J, Pollard H, Ben-Ari Y (1995) Cell death, gliosis, and synaptic remodeling in the hippocampus of epileptic rats. J Neurobiol 26:413-425[ISI][Medline].
Rice AC, DeLorenzo RJ (1998) NMDA receptor activation during status epilepticus is required for the development of epilepsy. Brain Res 782:240-247[ISI][Medline].
Rocamora N, Palacios JM, Mengod G (1992) Limbic seizures induce a differential regulation of the expression of nerve growth factor, brain-derived neurotrophic factor and neurotrophin-3, in the rat hippocampus. Mol Brain Res 13:27-33[Medline].
Ryden M, Hempstead B, Ibanez CF (1997) Differential modulation of neuron survival during development by nerve growth factor binding to the p75 neurotrophin receptor. J Biol Chem 272:16322-16328[Abstract/Free Full Text].
Sankar R, Shin DH, Liu H, Mazarati A, de Vasconcelos AP, Wasterlain CG (1998) Patterns of status epilepticus-induced neuronal injury during development and long-term consequences. J Neurosci 18:8382-8393[Abstract/Free Full Text].
Sgonc R, Boeck G, Dietrich H, Gruber J, Recheis H, Wick G (1994) Simultaneous determination of cell surface antigens and apoptosis. Trends Genet 10:41-42[ISI][Medline].
Sloviter RS (1996) Hippocampal pathology and pathophysiology in temporal lobe epilepsy. Neurologia 11:29-32.
Treiman DM (1996) Status epilepticus. Baillieres Clin Neurol 5:821-839[ISI][Medline].
Turski WA, Cavalheiro EA, Schwarz M, Czuczwar SJ, Kleinrok Z, Turski L (1983) Limbic seizures produced by pilocarpine in rats: behavioural, electroencephalographic and neuropathological study. Behav Brain Res 9:315-335[ISI][Medline].
Turski L, Meldrum BS, Cavalheiro EA, Calderazzo-Filho LS, Bortolotto ZA, Ikonomidou-Turski C, Turski WA (1987) Paradoxical anticonvulsant activity of the excitatory amino acid N-methyl-D-aspartate in the rat caudate-putamen. Proc Natl Acad Sci USA 84:1689-1693[Abstract/Free Full Text].
Verdi JM, Birren SJ, Ibanez CF, Persson H, Kaplan DR, Benedetti M, Chao MV, Anderson DJ (1994) P75LNGFR regulates Trk signal transduction and NGF-induced neuronal differentiation in MAH cells. Neuron 12:733-745[ISI][Medline].
Wetmore C, Olson L, Bean AJ (1994) Regulation of brain-derived neurotrophic factor (BDNF) expression and release from hippocampal neurons is mediated by non-NMDA type glutamate receptors. J Neurosci 14:1688-1700[Abstract].
Yang DD, Kuan CY, Whitemarsh AJ, Rincon M, Zheng TS, Davis RJ, Rakic P, Flavell RA (1997) Absence of excitotoxicity-induced apoptosis in the hippocampus of mice lacking the jnk3 gene. Nature 389:865-870[Medline].
Yoon SO, Casaccia-Bonnefil P, Carter DB, Chao MV (1998) Competitive signaling between TrkA and p75 nerve growth factor receptors determines cell survival. J Neurosci 18:3273-3281[Abstract/Free Full Text].
Zafra F, Hengerer B, Leibrock J, Thoenen H, Lindholm D (1990) Activity dependent regulation of BDNF and NGF mRNAs in the rat hippocampus is mediated by non-NMDA glutamate receptors. EMBO J 9:3545-3550[ISI][Medline].

Copyright © 1999 Society for Neuroscience 0270-6474/99/19166887-10$05.00/0

This article has been cited by other articles:

M. C. Opazo, A. Gianini, F. Pancetti, G. Azkcona, L. Alarcon, R. Lizana, V. Noches, P. A. Gonzalez, M. Porto, S. Mora, et al.
Maternal Hypothyroxinemia Impairs Spatial Learning and Synaptic Nature and Function in the Offspring
Endocrinology, October 1, 2008; 149(10): 5097 - 5106.
[Abstract] [Full Text] [PDF]