Nonobligate Role of Early or Sustained Expression of Immediate-Early Gene Proteins c-Fos, c-Jun, and Zif/268 in Hippocampal Mossy Fiber Sprouting

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The Journal of Neuroscience, November 15, 1998, 18(22):9245-9255

Nonobligate Role of Early or Sustained Expression of Immediate-Early Gene Proteins c-Fos, c-Jun, and Zif/268 in Hippocampal Mossy Fiber Sprouting
Walter K. Nahm and Jeffrey L. Noebels
Developmental Neurogenetics Laboratory, Department of Neurology, and Division of Neuroscience, Baylor College of Medicine, Houston, Texas 77030

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Axon sprouting in dentate granule cells is an important model of structural plasticity in the hippocampus. Although the processcan be triggered by deafferentation, intense activation of glutamatereceptors, and other convulsant stimuli, the specific molecularsteps required to initiate and sustain mossy fiber (MF) reorganizationare unknown. The cellular immediate early genes (IEGs) c-fos,c-jun, and zif/268 are major candidates for the initial stepsof this plasticity, because they encode transcription factorsthat may trigger cascades of activity-dependent neuronal geneexpression and are strongly induced in all experimental modelsof MF sprouting. The mutant mouse stargazer offers an importantopportunity to test the specific role of IEGs, because it displaysgeneralized nonconvulsive epilepsy and intense MF sprouting inthe absence of regional cell injury. Here we report that stargazermice show no detectable elevations in c-Fos, c-Jun, or Zif/268immediate early gene proteins (IEGPs) before or during MF growth.Experimental results in stargazer, including (1) a strong IEGPresponse to kainate-induced convulsive seizures, (2) no IEGP responseafter prolongation of spike-wave synchronization, (3) no IEGPincrease at the developmental onset of seizures or after prolongedseizure suppression, and (4) unaltered levels of the intracellularCa²⁺-buffering proteins calbindin-D_28k or parvalbumin, exclude thepossibility that absence of an IEGP response in stargazer is eithergene-linked or suppressed by known refractory mechanisms. Thesedata demonstrate that increased levels of these IEGPs are notan obligatory step in MF-reactive sprouting and differentiatethe early downstream molecular cascades of two major seizuretypes.

Key words: spike-wave epilepsy; transcription factor; axon sprouting; hippocampus; plasticity; cell death

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Axonal sprouting and neosynaptogenesis play functional roles in reorganization and repair throughout the mammalian CNS (Cotmanet al., 1981; West and Dewey, 1984; Fitzgerald et al., 1990; Darian-Smithand Gilbert, 1994). These processes are associated with complexpatterns of activity and injury-dependent gene expression (Galland Isackson, 1989; Nedivi et al., 1993; Chen et al., 1995; Konopkaet al., 1995). The products of these plasticity-related genesare thought to be responsible for axonal outgrowth, guidance,and establishment of functional synapses. It is widely proposedthat immediate early genes (IEGs) encode the initial transcriptionfactors that modulate the expression of these genes (Sheng andGreenberg, 1990, Morgan and Curran, 1991a).

In the dentate gyrus, a well defined pattern of axon sprouting from the granule cell-mossy fiber (MF) system into the innermolecular layer has been found in several models of hypersynchronousactivation, including kainic acid (KA) (Tauck and Nadler, 1985),kindling (Cavazos et al., 1991), and pentylenetetrazole (PTZ)(Golarai et al., 1992). Several lines of evidence link IEG inductionwith this process. Elevation of the mRNAs for c-fos, c-jun, andzif/268 precedes that of other genes associated with MF sprouting.Recurrent sprouting and IEG induction occur in the same cells,with sprouting occurring several days after the induction of IEGs(Morgan and Curran, 1991b). Both c-fos expression and MF-sproutinginduction have roughly equivalent dose thresholds for PTZ (Dragunowand Robertson, 1987; Morgan et al., 1987). Drugs that preventkindling and the induction of c-fos block MF sprouting (Kiesslingand Gass, 1993). Finally, kindling-induced sprouting is impairedin c-fos null mutant mice (Watanabe et al., 1996).

Although the process of MF synaptic reorganization is highly correlated with IEG induction, all MF sprouting models describedso far are also associated with regional cellular injury, death,synaptic loss, and gliosis (Cavazos and Sutula, 1990; Houser etal., 1990; Wallace and Fredens, 1992). Because IEG induction isclosely associated with cell death (Curran and Morgan, 1995; Kasofet al., 1995), the presence of seizure-related injury obscuresthe actual stimulus for IEG expression, and it remains unclearwhether immediate early gene proteins (IEGPs) are necessary orsufficient for aberrant axonalgrowth.

An opportunity to dissociate the role of IEGPs in MF sprouting from seizure-related damage arose with the neurological mutantstargazer. This mutant exhibits a stereotyped pattern of brief(1-10 sec) generalized six per second spike-wave (SW) dischargesin the neocortex, hippocampus, and thalamus (Noebels et al., 1990).These hypersynchronous SW discharges occur frequently (one ortwo per minute) and precede by several weeks the progressive appearanceof MF axon sprouting. No evidence of hippocampal cell death, gliosis,or cellular injury at the onset of sprouting has been found (Qiaoand Noebels, 1993; Chafetz et al., 1995). To determine whetherthe hippocampal IEGP expression pattern is coupled to MF sproutingdespite the absence of cellular injury, we compared the neuronalstaining patterns of polyclonal antibodies to c-Fos, c-Jun, andZif/268 in stargazer with those expressed in a sprouting modelinduced by KA. We also examined relative IEGP activation thresholds,the potential involvement of refractory mechanisms inhibitingIEGP induction, and the role of two Ca²⁺-binding proteins, calbindin-D_28k andparvalbumin.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Mice. Homozygous stargazer (C3B6Fe+ stg/stg) and wild-type (C57Bl/6J +/+) mice were obtained from breeding colonies of TheJackson Laboratory (Bar Harbor, ME) and Baylor College of Medicine.Animals were housed under a 12 hr light/dark cycle with ad libitumaccess to food and water. Unless otherwise noted, mice used inexperiments were adults ranging from 2-6 monthsold.

Electrocorticographic recordings. Mice were anesthetized with Avertin (1.25% tribromoethanol/amyl alcohol) by intraperitonealinjection (0.02 ml/gm body weight). Teflon-coated silver wireelectrodes (0.005 inch diameter) soldered to a microminiatureconnector were implanted through burr holes (0.1 inch diameter)of the skull into the subdural space over the frontal and occipitalcortices (Noebels et al., 1990). The microminiature connectorwas affixed permanently to the midline surface of the skull withcyanoacrylate glue and dental cement. All experiments and electrocorticographic(ECoG) recordings commenced 1 week after surgery. ECoG activityin alert and unrestrained mice was recorded using a Grass model6electroencephalograph.

Convulsive seizure induction. Wild-type and stg/stg mice were injected with KA (30 mg/kg, i.p.), a convulsant known to induceseizures that precede MF synaptic reorganization in the hippocampus(Tauck and Nadler, 1985). By the first 20-30 min after injection,both genotypes exhibited typical class V limbic seizures (Racine,1972) consisting of episodes of motionless behavior, followedby myoclonic facial movements, forepaw tremor, rearing, and fallingwith loss of postural balance. In both stg/stg and +/+, statusepilepticus occurred 1.5-2 hr after injection, followed by generalizedtonic-clonic convulsions. Stargazer mice displayed on averagemore severe seizures and a quicker onset to seizures than didwild-type mice. Mice were killed for immunohistochemistry (IHC)2 hr after KA injection to assess regional c-Fos, c-Jun, and Zif/268expression in thebrain.

(±)-3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid treatment. Pilot experiments revealed that stg/stg mice injectedintraperitoneally with 40 µM/kg of the competitive NMDA receptorantagonist (±)-3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonicacid (CPP) displayed prolonged episodes of continuous SW ECoGactivity lasting 60 min or longer (Nahm and Noebels, 1995). Theproepileptic effect of this treatment, which had no discernableeffect on ECoG activity in +/+ mice and blocked SW activity inanother SW-MF sprouting model, tottering (Stanfield, 1989), wasused to experimentally enhance SW synchronization in stg/stg.One hour of ECoG recordings was first obtained in stg/stg mutantsto quantify baseline SW activity. Within thirty min of CPP injection,near-continuous SW synchronization appeared (individual dischargesincreased 10- to 100-fold in duration). These animals were killed2 hr after the onset of prolonged SW activity to examine regionalIEGP expression in thebrain.

Ethosuximide treatment. To produce a complete blockade of SW seizure activity for a period of 30 hr, an stg/stg mouse wasinjected intraperitoneally with 200 mg/kg of ethosuximide (ETX)(Heller et al., 1983; Marescaux et al., 1992) approximately every2 hr. Continuous ECoG monitoring was performed to determine doseintervals and to verify the absence of SW discharges. At the endof the seizure-free period, ETX injections were discontinued,and the mouse was killed for IHC 2 hr after the spontaneous SWseizure activityresumed.

Immunohistochemistry. Mice were deeply anesthetized with Avertin (0.02 ml/gm, i.p.) and perfused transcardially with 0.1 Mphosphate buffer (PB), pH 7.4, followed by 4% paraformaldehydein 0.1 M PB. The brains were removed, post-fixed for 24 hr, andimmersed in 30% sucrose in 0.1 M PB for 5 d. Horizontal sections(40 µm thickness) through the whole brain were cut on a freezingmicrotome and pretreated in 0.03% H₂O₂ in absolute methanol. Tissuesections were then immersed in 2% bovine serum albumin (BSA) in0.1 M PBS for 3 hr and processed using the free-floating methodwith thorough rinsing between steps. Sections were incubated at4°C with either: (1) 1:400 c-Fos sheep polyclonal antibody (CambridgeTechnologies, Watertown, MA) in 0.1 M PBS with 1% BSA for 24 hr;(2) 1:400 c-Jun rabbit polyclonal antibody (Oncogene Science)in 0.1 M PBS with 1% BSA for 24 hr; (3) 1:300 Zif/268 rabbit polyclonalantibody (Santa Cruz Biotechnology, Santa Cruz, CA) in 0.1 M PBSwith 1% BSA for 48 hr; (4) 1:200 calbindin-D_28k mouse monoclonalantibody (Sigma, St. Louis, MO) in 0.1 M PBS with 1% BSA for 24hr; or (5) 1:400 parvalbumin mouse monoclonal antibody (Sigma)in 0.1 M PBS with 1% BSA for 24 hr. Sections were then incubatedfor 60 min at room temperature with the appropriate biotinylatedsecondary antibody (Jackson ImmunoResearch, West Grove, PA) at1:100, and followed by an incubation in an avidin-biotin-horseradishperoxidase (HRP) complex (ABC kit; Vector Laboratories, Burlingame,CA) (Hsu et al., 1981). The bound peroxidase was localized byincubating sections in 0.1% 3,3'-diaminobenzidine (DAB) and 0.025%H₂O₂ at room temperature for 5-10 min, which generated the visiblesubstrate. Sections incubated without the primary antibody servedas controls. All the sections were examined and photomicrographedusing standard light microscopy (Leitz, Orthoplan 2 and VarioOrthomat 2). Because variation occurs along the septal-temporalgradient, all levels of the hippocampal formation were analyzedin all experiments. A 0-4⁺ rating scale was used to quantify visible substrate stainingintensity in cell nuclei using standard light microscopy. Allslides were scored by a single observer to ensure consistency.A score of 0 was assigned when staining was completely absent.A score of 1⁺ was assigned to minimal basal level staining, 2⁺ for moderate staining, and 3⁺ for high staining. The greatest score of 4⁺ was only assigned to maximal nuclear staining patterns usuallyobserved in the dentate gyrus under KAadministration.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Absence of elevated IEGP expression in stg/stg hippocampus

Regional expression patterns of c-Fos, c-Jun, and Zif/268 were assayed in 12 adult mutant mice (stg/stg) and compared withthose of 12 age-matched wild-type control (+/+) mice. All stg/stgand +/+ mice displayed a consistent lack of nuclear c-Fos stainingin the dentate granule cells and other neurons of the hippocampus(Fig. 1). In both genotypes, minimal basal levels of specificnuclear c-Fos staining were found sporadically in the neocortex,thalamus, and septum. Specific staining throughout the remainderof the mutant brain was negligible, and no significant genotypicdifferences in regional c-Fos nuclear staining was identified(Table 1).

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Figure 1. Stargazer mutants show no resting elevations in c-Fos, c-Jun, or Zif/268. Comparison of sprouting pattern, electrocortical activity, and IEG protein expression patterns in the hippocampus of adult stg/stg, +/+, and +/+-KA mice (2 hr after kainic acid-induced limbic seizures). Top, Stargazer and +/+-KA mice display strong mossy fiber sprouting in the inner molecular layer of dentate gyrus. Representative 8 sec samples of ECoG recordings display spontaneous six or seven per second spike-wave discharges in the mutant that are not present in the wild-type control, whereas the ECoG recordings during kainic acid convulsive seizures show continuous discharges associated with tonic neuronal depolarizations. Bottom, In temporal hippocampus, stg/stg mice are devoid of c-Fos and Zif/268 staining in a pattern identical to +/+ mice and show moderate antibody staining to c-Jun in dentate granule cells and the pyramidal cell layers. Wild-type mice with KA-induced seizures display a strong c-Fos, c-Jun, and Zif/268 response that is greatest in the DG. Moderate elevations of c-Fos and Zif/268 and lesser elevations of c-Jun were seen in CA1, CA2, and CA3 pyramidal regions. Scale bar, 100 µm.


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Table 1. Regional IEG protein antibody stain intensity in stg/stg, +/+, and +/+-KA hippocampus

In contrast to SW seizures found in the mutant, limbic seizures induced by KA produced clear increases in nuclear c-Fos expressionin six assayed adult wild-type (+/+) mice. c-Fos staining in theKA model (+/+-KA) was most intense in the dentate granule cells,and elevated in pyramidal neurons of all the hippocampal subregions(CA1, CA2, and CA3) (Fig. 1). c-Fos expression was also diffuselyelevated in neuronal nuclei of the entorhinal cortex, thalamus,basal ganglia, septum, and most layers of the neocortex (Table1).

The pattern of polyclonal antibody staining to c-Jun revealed moderate immunoreactivity in all hippocampal subregions of bothstg/stg and +/+ brains (Fig. 1). As in the c-Fos experiments,both genotypes displayed light or negligible c-Jun staining inthe neocortex and thalamus, and no consistent differences in thedensity of neuronal staining for c-Jun were observed between thetwo genotypes. KA-induced seizures produced large increases inc-Jun staining in the wild-type dentate gyrus and CA1 pyramidalneurons and elevated to a lesser degree c-Jun staining in thehippocampal CA3 subregion. However, no consistent c-Jun stainingabove basal levels was found after a KA seizure in any other brainarea (Table 1).

Both stg/stg and +/+ displayed identical patterns of Zif/268 antibody staining in the forebrain. In the septal hippocampusof both genotypes, there was light staining in the dentate gyrusand CA1 pyramidal cells. The temporal hippocampus, however, wasdevoid of Zif/268 staining in both genotypes. In stg/stg therewas moderate Zif/268 staining in neocortex, entorhinal cortex,and basal ganglia; this pattern of staining was identical to thatfound in +/+ mice. The pattern of Zif/268 expression in +/+ micetreated with KA showed extreme elevations in dentate granule cellsand CA1 pyramidal neurons (Fig. 1; Table 1). Zif/268 expressionwas slightly elevated in CA2 but conspicuously absent in CA3 neurons.KA-induced seizures also greatly raised the number of Zif/268-stainedneurons in the neocortex and entorhinal cortex, and diffuse, moderateelevations of Zif/268 staining were found in the thalamus, basalganglia, and septum (Table 1). These experiments demonstratethe presence of a striking difference in hippocampal IEGP expressionbetween two types of hypersynchronous seizure activity that inducesimilar patterns of MF sprouting (spike-wave seizures in stg/stgand convulsive seizures in +/+-KA).

To ensure that the absence of an IEGP response to SW discharge activity was not specific for the stargazer mutation, we analyzedan adult tottering mouse, a mutation on a different genetic backgroundthat also shows SW discharge and sprouting activity (Stanfield,1989). No abnormal c-Fos staining was observed, and c-Fos elevationwas not seen in the neocortex of an inbred rat strain with SWdischarges (Willoughby et al., 1993), suggesting that the SW patternitself may be ineffective in inducing IEGP activity regardlessof geneticbackground.

IEGP induction patterns in stargazer brain

The absence of IEGP induction above basal levels in stg/stg hippocampus, thalamus, and neocortex was unexpected, consideringthe frequent bursts of SW synchronization generated in these areasand the strong increase in IEGP levels that follow neuronal activationduring synchronous discharges in other seizure models. This findingraised the possibility that the SW pattern might synchronize neuronsby activating synaptic networks below the depolarization thresholdrequired to initiate a measurable IEGP response, suggesting thatthe intensity of this pattern of abnormal synchronization differedsignificantly from those found in other experimental epilepsymodels. Other factors, however, could potentially mask the inductionof a detectable c-Fos, c-Jun, and Zif/268 response in the mutantand mitigate this conclusion, namely: (1) a gene-linked defectin one or more steps of the stimulus transduction pathway of IEGPexpression in stg/stg neurons; (2) the brevity (1-10 sec) of individualSW episodes relative to seizures in other experimental models;(3) short-term inactivation of IEGP expression in cells engagedin SW bursting; (4) longer-term cellular refractory mechanismsfor sustained IEGP expression activated by chronic SW stimulation;and (5) increased buffering capacity of intracellular free Ca²⁺ in stg/stg neurons. These possibilities were evaluated in a seriesof control experiments (Figs. 2-6).

Robust stimulus-induced IEGP expression in stg/stg neurons
To test whether the lack of IEGP induction in stg/stg neurons during SW activity might be caused by a gene-linked neuronaldefect in the intervening steps of the transynaptic inductionpathway, six stg/stg mice were injected with KA 30 mg/kg intraperitoneally(stg/stg-KA), monitored for ECoG seizure activity for 2 hr, andkilled for IHC (Fig. 2A). Within the first 15 min after injection,mutant mice exhibited typical class I-II seizure activity. Thisactivity was soon followed by class V limbic seizures and generalizedtonic-clonic seizures. In a similar manner to wild-type mice,the seizures induced by KA produced clear increases in nuclearexpression of the IEGPs, c-Fos, c-Jun, and Zif/268, in stg/stg.In the stg/stg hippocampal formation, KA produced increases inexpression of c-Fos in nuclei of DG, CA1, CA2, and CA3 neurons(Fig. 2B). In addition, strong c-Fos staining was observed inneocortex, entorhinal cortex, thalamus, basal ganglia, and septum.Clear increases in c-Jun expression were found in the DG, andsmaller elevations were found in CA1, CA2, and CA3 regions (Fig.2B). No c-Jun staining above basal levels was found in any otherbrain area. KA-induced seizures produced a pattern of intenseZif/268 elevation in DG neurons and moderate elevations of Zif/268in the hippocampal pyramidal layer subregions (CA1, CA2, and CA3)in stg/stg (Fig. 2B). The mutant neocortex and entorhinal cortexalso displayed a strong elevation of Zif/268, whereas the thalamus,basal ganglia, and septum showed mild Zif/268 increases. Thesedata show that stg/stg neurons are capable of seizure-inducedIEGP expression. More precisely, these data demonstrate that thespecific population of dentate granule cells in the temporal hippocampusof stg/stg that are involved in recurrent MF sprouting can displaya robust induction of c-Fos, c-Jun, and Zif/268.

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Figure 2. Stargazer mice demonstrate a strong IEGP response after KA-induced seizures. A, ECoG recordings demonstrate that inherited spike-wave seizures were converted to tonic discharges after intraperitoneal administration of 30 mg/kg of KA. B, IEGP expression patterns in stg/stg examined 2 hr after KA treatment reveal strong inductions of c-Fos and Zif/268 in DG, CA1, CA2, and CA3. Strong c-Jun expression was found in the DG, and lesser elevations of c-Jun were detected in the pyramidal layers. Scale bar, 100 µm.

Prolongation of SW activity does not increase IEGP expression
Preliminary pharmacological survey revealed that the NMDA receptor glutamate-binding site antagonist CPP paradoxically increasesSW seizure activity in stargazer, in contrast to its antiepilepticeffects in other epilepsy models. To test the possibility thatspontaneous SW seizures in stg/stg were simply too brief (1-10sec) or infrequent (one or two per minute) to elevate IEGPs overbasal levels, IHC to c-Fos, c-Jun, and Zif/268 was performed onseven stg/stg mice injected (40 µg/kg, i.p.) with CPP (stg/stg-CPP).Within 30 min of treatment, the ECoG of these mice converted froma pattern of brief intermittent SW discharges to a nearly continuous(95% of elapsed time) pattern of typical six per second SW burstinglasting ~2 hr accompanied by behavioral immobility (Fig. 3A).Although the possibility exists that CPP, an NMDA receptor antagonist,might indirectly block IEGP induction, recent evidence shows thatother NMDA antagonists MK-801 (Dragunow and Faull, 1990; Sharpet al., 1990; Hughes et al., 1993) and ketamine (Nakao et al.,1993) allow distinct induction of IEGPs in the CNS, presumablythrough non-NMDA receptor Ca²⁺ signaling pathways (Lerea et al., 1992).

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Figure 3. Prolongation of SW activity with CPP does not induce c-Fos expression pattern in stg/stg. A, ECoG recordings in a stg/stg mutant demonstrate the conversion of spontaneous SW discharges to prolonged status-like SW activity after injection of CPP (40 µM/kg, i.p.). B, After 2 hr of CPP-induced prolonged SW activity, stg/stg hippocampus displays no change in c-Fos expression. c-Jun and Zif/268 levels were also unchanged (data not shown). Scale bar, 100 µm.

Sections from CPP-treated stg/stg mice killed after 2 hr of continuous SW activity showed a pattern of c-Fos, c-Jun, and Zif/268staining in the hippocampal formation identical to that seen inuntreated stg/stg mice (Fig. 3B). No increases in c-Fos over basallevels were detected throughout all other brain regions examined,and similar results were found with c-Jun and Zif/268 stainingpatterns. The low levels of hippocampal IEGP expression were identicalto the basal levels seen in untreated stg/stg mice (Fig. 1). Thesedata suggest that the brief duration of individual spontaneousSW discharges is not a critical factor in the lack of a sustainedIEGP response in the mutant, and that the amount of neuronal depolarizationduring this pattern of activity remains below the threshold forIEGPinduction.

Short-term refractory mechanisms are not responsible for the lack of IEGP induction in stg/stg mice
Seizures induced by an initial dose of the convulsant PTZ are followed by a short (up to 16 hr) period during which a seconddose of PTZ is unable to further induce c-fos (Morgan et al.,1987). A desensitization of this type to c-fos and zif/268 inductionin the brain is also found after acute administration of cocaine(Ennulat et al., 1994). This interval in which IEGs are persistentlysuppressed even in the presence of an effective stimulus is referredto as a short-term refractory period. To determine whether short-termrefractoriness may have contributed to the lack of IEGP responsein stg/stg mice, SW seizures were completely blocked for 30 hrwith repeated injections of ETX (Fig. 4A). At the end of thistime, ETX administration was discontinued, and seizure activitywas allowed to return for 2 hr. The stg/stg mouse brain was thenexamined for IEGP expression. No changes in c-Fos expression ingranule cells or other brain regions were found after the ETXtreatment in comparison to untreated stg/stg mice (Fig. 4B). Similarly,there were no apparent changes in c-Jun or Zif/268 expressionpatterns. These data imply that short-term refractory mechanismsdo not contribute to the lack of stg/stg IEGP induction duringSW seizures.

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Figure 4. Short-term refractory mechanisms do not account for lack of c-Fos expression in stg/stg mice with chronic SW seizures. A, Schematic diagram shows blockade of basal SW discharge activity in a mutant mouse for 30 hr with ethosuximide injections. SW seizures (approximately one per minute) were allowed to resume, and IHC for IEG proteins was performed 2 hr later. B, IHC of stg/stg hippocampus after seizure suppression treatment shown in A reveals no abnormal induction of c-Fos. c-Jun and Zif/268 patterns were also unchanged (data not shown). Scale bar, 100 µm.

Postnatal day 17 and 18 stg/stg mutants do not display IEGP elevations over basal levels
Winston et al. (1990) reported a second, longer lasting (>1 day) refractory period for c-fos and c-jun mRNA induction afterchronic electroconvulsive seizures. Unlike short-term inactivation,this inhibition was maximal after 8-10 d of daily stimulationand did not appear to be related to c-Fos autoregulation, becauseit occurred in the absence of increased c-Fos protein. To testwhether similar long-term refractory mechanisms maintained bychronic SW seizures might result in a persistent block of IEGPinduction, stg/stg brains were examined within 24 hr of the developmentalonset of SW seizures during the third postnatal week, postnataldays 17 and 18 (P17-P18) (Fig. 5A) (Qiao and Noebels, 1993). Becausethe capacity for c-fos induction is already well established atthis age (Schreiber et al., 1992; Jensen et al., 1993; Smeyneet al., 1993), the potential for IEGP induction by SW seizureactivity in P17-P18 stg/stg mice should not be masked by eithershort- or long-term IEGP expression refractorymechanisms.
As in the adult, hippocampal sections from P17-P18 stg/stg displayed no evidence of increased c-Fos staining relative to thewild type (Fig. 5B). Similar results were found with c-Jun andZif/268 antibodies. In other brain regions, the only significantfindings among the three IEGP expression patterns were slightelevations in Zif/268 staining present diffusely in neocortex,entorhinal cortex, and basal ganglia in the young mutants comparedwith the adults.

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Figure 5. Long-term refractory mechanisms do not account for absence of c-Fos induction in stargazer mice. A, Schematic diagram illustrates the experimental time point for IEGP analysis, performed within 1 d of the developmental onset (P17-P18) of spike-wave seizures in stg/stg mutants. B, IHC of P17-P18 stg/stg hippocampus reveals the absence of c-Fos expression after spike-wave seizure onset. No c-Jun or Zif/268 changes in this tissue were seen (data not shown). Scale bar, 100 µm.

These data indicate that neither type of refractory mechanism is likely to account for the lack of c-Fos, c-Jun, and Zif/268induction in stargazer mutants. The previous finding that KA-inducedseizures in adult stg/stg caused marked c-Fos, c-Jun, and Zif/268induction also supports this conclusion. If refractory mechanismshad been recruited by chronic SW activity, the IEGP response afterKA administration in stg/stg mice would have been diminished relativeto that in KA-treated +/+mice.

stg/stg neurons show no increases in the Ca²⁺-buffering proteins calbindin-D_28k and parvalbumin
Several studies show that increases in intracellular Ca²⁺ are required for depolarization or seizure-induced expression of IEGs(Morgan and Curran, 1986; Lerea and McNamara, 1993). Intracellularcalcium may be modulated in cells by the EF-hand (Persechini etal., 1989) calcium-binding proteins (CaBPs), such as calbindin-D_28kand parvalbumin (Morrissey et al., 1978; Baimbridge et al., 1982;Celio, 1986; Kohr et al., 1991). The levels of these proteinswithin the hippocampal formation correlate with vulnerabilityto excitotoxic induced cell death or neurodegeneration (Sloviter,1989; Hof et al., 1991; Mattson et al., 1991; Sloviter et al.,1991) and can be changed by activity-dependent processes, includingseizures (Miller and Baimbridge, 1983; Kamphuis et al., 1989;Lowenstein et al., 1991).
To determine whether SW seizures might regulate the level of cytoplasmic CaBPs, with potential secondary effects on transynapticIEGP expression, the patterns of calbindin-D_28k and parvalbuminIHC in stg/stg brains were compared with those in +/+ mice. Adultstg/stg mutants displayed normal hippocampal patterns of calbindin-D_28kand parvalbumin expression relative to the +/+ mice (Fig. 6).In both genotypes, calbindin-D_28k was expressed in DG and CA1,but not CA3 pyramidal cells. The dentate granule cell MF projectionsto CA3, and the dendritic layer (stratum oriens) of CA1 showedmarked calbindin-D_28k expression. No genotypic differences wereobserved in other brain regions. Parvalbumin expression differedfrom the pattern seen with calbindin-D_28k antibody. Parvalbuminwas expressed in a fiber plexus surrounding dentate granule cellsand hippocampal pyramidal cells. Most parvalbumin staining wasfound in interneurons of the DG (stratum granulosum) and pyramidalcell layer (stratum pyramidale), but was also not altered in themutant hippocampus. In both genotypes, scattered parvalbumin stainingneurons were found in the neocortex, thalamic relay nuclei, andthe thalamic reticular nucleus. In addition, strong staining wasobserved in the cerebellar cortex, particularly in the Purkinjecell layer. No genotypic differences in the pattern of parvalbuminexpression were observed. These data provide no evidence for theseizure-induced changes in calbindin-D_28k or parvalbumin seenin convulsive seizure models that could alter intracellular Ca²⁺ buffering or IEGP induction.

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Figure 6. Inherited spike-wave seizures do not alter calcium-binding protein levels in the stargazer hippocampus. Comparison of calbindin-D_28k and parvalbumin immunohistochemistry in adult stg/stg and its wild-type control. No consistent differences in the staining patterns of these two calcium-binding proteins were detected between these two genotypes. Scale bar, 100 µm.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The absence of elevated IEGP expression in stg/stg hippocampus before and during the period of MF sprouting demonstrates thatspecific increases in c-Fos, c-Jun, and Zif/268 seen in convulsivemodels of epilepsy are not obligatory signals for hippocampalMF reorganization. The failure of SW synchronization to elicitcellular IEGP responses in the stargazer absence epilepsy modelis apparently not prevented by stimulus-transcription couplingdefects in hippocampal neurons, subthreshold seizure activation,intracellular refractory mechanisms, or abnormal levels of theCa²⁺-buffering proteins calbindin-D_28k and parvalbumin. These findingsdemonstrate that alternative gene transcription pathways for triggeringMF sprouting must exist. In addition, because the synchronizationpatterns of SW and tonic-clonic seizures differentially regulateIEGP expression, our data suggest that these two seizure typesare associated with marked differences in neuronal depolarizationand calcium influx and give rise to fundamentally distinct patternsof downstream molecularsignaling.

c-Fos, c-Jun, and Zif/268 increases are not obligatory for MF reorganization

Elevations of IEG expression correlate well with pathological sprouting of nerve axons at several sites in the nervous system(Bao et al., 1993; Herdegen et al., 1993; Kenney and Kocsis, 1998),and the induction of c-fos, c-jun, and zif/268 have been specificallycorrelated with MF sprouting (Sutula et al., 1988; Popovici etal., 1990; Simonato, 1993; Kiessling and Gass, 1993; Watanabeet al., 1996; Represa and Ben-Ari, 1997). Although these modelsare accompanied by early or delayed cell death, stargazer mutantsdisplay an identical pattern of MF recurrent sprouting with littleevidence of neuronal cell loss except at very late stages (Qiaoand Noebels, 1993). The presence of sprouting in the absence ofelevations of c-Fos, c-Jun, and Zif/268 in the mutant demonstratethat these IEGPs are not obligatory in hippocampal synaptic reorganizationand that other regulators of downstream neuronal gene expressioninduce this pattern of reactive axonalplasticity.

In a test of this hypothesis, Watanabe et al. (1996) reported that a null mutant of c-fos showed impaired development of kindlingand reduced MF sprouting and concluded that there was a functionalrole for c-fos in triggering new axon collateral growth in granulecells. However, these authors could not exclude maturational alterationsin the c-fos $-$ / $-$ mutant brain preceding the kindling experimentthat might diminish both processes, and the specific contributionof c-Fos in activating neuronal growth-related genes after seizuresin the limbic system remained untested. Some kindling-inducedsprouting was still observed in c-fos $-$ / $-$ mice, and it was suggestedthat alternative transcription factor pathways might compensatefor the absence of c-fos. In contrast to the c-fos null mutation,a related study of zif/268 (NGFI-A) null mutants concluded thatzif/268 did not play a required role in the expression of MF sprouting(Zheng et al., 1998). In the stargazer model, unlike the nullmutations, the IEGPs c-Fos, c-Jun, and Zif/268 are available throughoutbrain development. Our findings specifically demonstrate thatthey are not induced before or during sprouting and, therefore,play a nonobligaterole.

Along with our evidence that they are not necessary for reactive sprouting, c-Fos protein increases are also not sufficientto initiate reactive plasticity, because not all models with pathologicalc-Fos expression in granule cells show MF sprouting. AlthoughKA induction uniformly produced elevated granule cell c-Fos elevations(Le Gal La Salle, 1988; Popovici et al., 1988; Sonnenberg et al.,1989; Pennypacker et al., 1993), Cronin et al. (1992) has shownthat of 25 rats with KA-induced seizures only 17 displayed thedense MF sproutingresponse.

The elevation of c-Fos, c-Jun, Zif/268, and other IEGPs [e.g., JunD and the 35-37 kDa fos-related antigen (FRA)] (Bing etal., 1996, 1997; Feng et al., 1997) has been viewed as an attractivemechanism for inducing axonal growth because they are transcriptionfactors that bind to activator protein-1 (AP-1) sites. AP-1 isa promoter element regulating a variety of genes reported to contributeto sprouting, such as growth-associated protein-43 (GAP-43) (Eggenet al., 1994; Bendotti et al., 1994, 1997) and nerve growth factor(NGF) (Adams et al., 1997). Murine overexpression of a GAP-43transgene potentiates MF reorganization (Aigner et al., 1995),and null mutants of GAP-43 display axon pathfinding defects (Strittmateret al., 1995). Induction of neurotrophic factors like NGF, neurotrophin-3,brain-derived neurotrophic factor, and basic fibroblast growthfactor (bFGF) have been associated with sprouting (Gall, 1993;Gall et al., 1994; Kar et al., 1997; Mathern et al., 1997), andblockade of the tyrosine kinase B receptor for growth factorsabolishes induction of MF sprouting (Hughes et al., 1998). Anti-NGFIgGs and NGF domains that interfere with neurotrophin bindingalso inhibit kindling-induced sprouting (Rashid et al., 1995;Van der Zee et al., 1995), and the time course of increased neurotrophicactivity after KA administration parallels MF reorganization (Lowensteinet al., 1993). Finally, other mechanisms regulating sproutinghave been proposed that are not directly related to AP-1 activationin neurons. Represa and Ben-Ari (1997) suggest that MF terminalbranches may sprout under the influence of local astrocytes thatcould favor axon growth by secreting neuronal cell adhesion molecule(Niquet et al., 1993) and trophic factors such as bFGF or by notsecreting inhibitory substrate molecules such as tenascin-C (Niquetet al., 1995).

Convulsive and nonconvulsive synchronization give rise to different patterns of stimulus-transcription coupling

The finding that convulsive and SW synchronization display differential patterns of IEGP expression suggests that these twoseizure types may produce distinct profiles of AP-1-binding complexesin the CNS. Because specific temporal patterns of AP-1-inducedgenes can result in altered long-term plasticity, this pathwayfor gene regulation may contribute to the variations in neuriteoutgrowth, neuronal differentiation, and cell death found betweenconvulsive and SWseizures.

Several lines of evidence indicate that prolonged IEGP elevations may be more closely related to cell death than seizure-inducedneurite outgrowth; this hypothesis is compatible with the differencesobserved in IEGP expression between the models of convulsive andnonconvulsive epilepsy. c-fos expression can be an indicator ofimpending death in certain neurons in the developing and adultCNS (Gonzalez-Martin et al., 1992; Smeyne et al., 1993; Dragunowand Preston, 1995; Kasof et al., 1995; Goodenough et al., 1997).IEGP elevations are more prolonged after KA seizures, in whichthere is substantial cell death, than after PTZ seizures, in whichthere is not (Kasof et al., 1995). c-Jun is associated with celldeath in the hippocampus after status epilepticus and ischemia(Dragunow et al., 1993). Certain classes of neurons have largeincreases in c-jun and undergo apoptosis when deprived of NGF.Ham et al. (1995) demonstrated that a c-Jun dominant negativemutation protected mouse sympathetic neurons from apoptotic celldeath induced by NGF withdrawal, and showed that overexpressionof c-Jun in sympathetic neurons induced apoptosis. KA-inducedconvulsive seizures are followed by marked regional inductionof IEGPs in specific hippocampal pyramidal neurons, and theseareas show the most severe loss of cells (Nadler et al., 1980a,b;Nitecka et al., 1984). Conversely, SW seizures in the stargazermodel are associated with only a minor and late loss of hilarinterneurons in the mutant hippocampus not seen until severalmonths after the onset of the seizures (Qiao and Noebels, 1993).

Alteration in IEGP expression between spike-wave and convulsive seizure patterns may depend on different levels of depolarization and calcium entry

Why don't hypersynchronous spike-wave absence seizures induce IEGP expression? Since the discovery that c-fos mRNA transcriptsrapidly rise after depolarization and influx of calcium in PC12cells (Greenberg et al., 1986; Morgan and Curran, 1986), calciumhas been linked as a required second messenger for c-fos induction(Morgan and Curran, 1991a), along with the activation of otherregulatory elements (Robertson et al., 1995). Although the routeby which calcium enters a neuron during a seizure may differ,the resulting transcription of c-fos still occurs (Lerea et al.,1992), and calcium entry during different patterns of stimulationmay lead to distinct arrays of IEG expression. The fact that SWseizures in stg/stg do not induce IEGPs, whereas KA-induced seizuresproduce robust responses, and the fact that stg/stg and +/+ miceshow equivalent levels and patterns of two CaBPs suggests thatSW seizures cause (1) lower depolarizing levels, and (2) lesserdegrees of Ca²⁺ influx in synchronized neurons than do convulsiveseizures.

This tentative conclusion is supported by proposals (Gloor, 1979) that the SW discharge is a true "inhibitory" seizure, apattern of generalized synchronous oscillations in neurons deficientin paroxysmal depolarization shifts (PDSs) and showing increasedpostsynaptic inhibition, as opposed to the seizures characteristicof convulsive epileptic syndromes. According to this hypothesis,the repatterning of cellular excitation during the brief "spike"of a SW seizure is not caused by excessive neuronal depolarization,and impulse activity does not exceed the normal range; the prolongedIPSPs (>250 msec) corresponding to the inhibitory ECoG "wave"also predict substantially less neuronal depolarization throughoutthe duration of the seizure episode (Gloor, 1984; Giaretta etal., 1987). This proposed mechanism to account for the lack ofIEGP expression during SW seizures has been generally confirmedduring in vivo neocortical intracellular recordings in the SWepileptic rat that show only brief depolarizations without PDSsduring SW seizures, and no decreases in extracellular Ca²⁺ levels determined by Ca²⁺-sensitive microelectrodes as seen during convulsive discharges(Heinemann et al., 1977; R. Pumain, personal communication). Initialin vivo studies in a rat SW model using two photon confocal microscopyalso confirm the absence of increased intracellular free Ca²⁺ during SW patterns of synchronization (Buzsaki et al., 1997).

  FOOTNOTES

Received July 15, 1998; revised Aug. 26, 1998; accepted Sept. 1, 1998.

This work was supported by National Institutes of Health Grant NS29709 and The Blue Bird Circle Foundation for PediatricNeurology.
Correspondence should be addressed to Dr. Jeffrey L. Noebels, Department of Neurology, Baylor College of Medicine, One BaylorPlaza, Houston, TX77030.

  REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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