Neurotrophins Protect Cultured Cerebellar Granule Neurons against the Early Phase of Cell Death by a TwoComponent Mechanism

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Volume 17, Number 11, Issue of June 1, 1997 pp. 4201-4211
Copyright ©1997 Society for Neuroscience

Neurotrophins Protect Cultured Cerebellar Granule Neurons against the Early Phase of Cell Death by a TwoComponent Mechanism

Michael J. Courtney, Karl E. O. Åkerman, and Eleanor T. Coffey
Department of Biochemistry and Pharmacy, Åbo Akademi University, BioCity, Turku, Finland

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Cerebellar granule neurons cultured with serum develop a mature neuronal phenotype, including stimulus-coupled release ofglutamate, and depend on elevated potassium for survival. We findthat cells cultured with serum undergo two phases of cell death.By 6 d in vitro, 30-50% of the cells present are dead; after thistime the remaining cells die. Elevated potassium prevents onlythis later phase of death, whereas neurotrophins protect thesecells against the early phase of death. Factors that bind p75^NTR or TNF-R, members of the same receptor family, exhibit voltage-sensitivecalcium channel-dependent protection, whereas ligands of expressedTrk receptors show additional calcium channel-independent protection.The cells express TrkB protein and show elevated c-Fos and c-Junlevels in response to BDNF. No TrkA is detected, although p75^NTR protein is expressed and NGF induces depolarization-dependentelevation of c-Jun levels. In the presence of the protein kinaseC inhibitor bisindolylmaleimide, BDNF-induced survival promotionis reduced partially, whereas NGF-induced death is unmasked. Basalsurvival mechanisms are insensitive to inhibition of PK-C or PI-3kinase. We conclude that BDNF promotes survival in part via itsTrkB receptor, whereas there is an additional pathway promotingsurvival and elevating c-Jun evoked by both NGF and BDNF via anon-Trk receptor.
Key words: NGF; BDNF; TNF; neurotrophins; p75^NTR; TrkB; cell death; cerebellar granule neurons; PK-C

INTRODUCTION

Cultured cerebellar granule neurons, a popular model CNS culture for the study of neuronal signaling and development, expressa wide range of receptor subtypes and develop stimulus-coupledglutamate release when cultured in serum-based medium. Under theseculture conditions the cells depend on chronic depolarizationor other calcium-elevating stimuli for continued survival (Thangniponet al., 1983; Gallo et al., 1987; Balazs et al., 1988b,c, 1990).Without such stimuli a delayed apoptotic death occurs (Copaniet al., 1995). This dependence has been proposed to mimic a trophicrequirement of cells in the cerebellar granule layer for innervationby the mossy fibers (Balazs et al., 1990). During the first 3-5weeks of postnatal life, there is a well characterized major lossof granule neurons in the cerebellum (Landis and Sidman, 1978).However, considerable cell loss occurs at postnatal day 5-6 becauseof an early phase of apoptosis (Wood et al., 1993; Krueger etal., 1995).

The neurotrophins NGF, BDNF, and neurotrophin-3 (NT-3) are survival-promoting factors reported to act via their specific tyrosinekinase receptors TrkA, TrkB, and TrkC, respectively (for review,see Glass and Yancopoulos, 1993), and via p75^NTR, the nonselective neurotrophin receptor of the tumor necrosisfactor (TNF)/Fas/CD40 family (Mahadeo et al., 1994). Activationof Trks initiates a number of signaling cascades, including Ras-dependentactivation of the extracellular signal-regulated kinase/microtubule-associatedprotein (ERK/MAP) kinase cascade (Ohmichi et al., 1992), whichinduces c-fos transcription (Karin and Hunter, 1995). The signalingevents subsequent to ligand binding to p75^NTR, initially characterized as altering the specificity and bindingof coexpressed Trks (for review, see Chao and Hempstead, 1995),include the activation of sphingomyelinase (Dobrowsky et al.,1994), NF- $kappa$ B (Carter et al., 1996a), and Jun kinase (JNK; Casaccia-Bonnefilet al., 1996).

BDNF has been reported to reduce the death of cerebellar granule neurons in serum-free culture as early as 2 d in vitro (Gaoet al., 1995) (see also Segal et al., 1992; Lindholm et al., 1993).However, in the absence of serum, delayed death does not occur(Kingsbury et al., 1985). Because cerebellar granule neurons inculture require serum-containing medium to acquire depolarization-dependentsurvival and a mature physiology, such as expression of aminoacid carriers and stimulus-coupled neurotransmitter release (Balazset al., 1988a), serum-based cultures may mimic more closely thecells in vivo. Thus we have investigated the requirements forsurvival promotion by neurotrophins under these more physiologicalconditions.

In this study we show that there is considerable death of cerebellar granule neurons developing in serum-based culture beforedepolarization-dependent survival. We find that NGF, BDNF, NT-3,and TNF all protect against basal cell death. Two components ofprotection by neurotrophins are resolved: (1) factors that bindp75^NTR or TNF-R, members of the same receptor family, provide protectiondependent on calcium channel activity; (2) those factors thatare able to bind the Trk receptors present provide an additionalcalcium channel-independent component of protection. In addition,basal survival mechanisms exist that allow partial survival inthe absence of neurotrophins.

MATERIALS AND METHODS
Cell culture. Cerebellar granule neurons were prepared from 7-d-old rats as previously described (Courtney and Nicholls, 1992),except that cells were plated at 250,000/cm². Dissociated cells were plated onto either poly-L-lysine-coatedcoverslips (10.5 mm × 10.5 mm) and cultured in 24-well platesfor cell death studies or plated on poly-L-lysine-coated 6-wellplates for immunoblot analysis. Cells were cultured in MinimumEssential Media (MEM; Life Technologies, Paisley, Scotland) supplementedwith 10% (v/v) fetal calf serum (Life Technologies), 33 mM glucose,2 mM glutamine, 50 U/ml penicillin, 50 µM streptomycin, and 20mM supplementary KCl, as indicated (i.e., low KCl = 5.4 mM KCl;elevated KCl = 25.4 mM KCl). Culture medium was replaced at 1d in vitro (DIV). When experiments were performed on cells olderthan 6 DIV, medium also was replaced at 7 DIV. However, the depolarizationdependence of survival observed also was observed in preliminaryexperiments without this medium change and thus cannot be attributedto this medium change. Cytosine arabinofuranoside (10 µM; Sigma,St. Louis, MO) was included in the culture medium change at 1d to inhibit non-neuronal cell proliferation. At this time 1 µMnifedipine (Sigma), 10 ng/ml of NGF (>98%; Alomone, Jerusalem,Israel), BDNF (>96%; Peprotech, Princeton, NJ), NT-3 (>98%; Peprotech),TNF- $alpha$ (>97%; Peprotech), and 10 nM 12-O-tetradecanoyl phorbol-13-acetate(TPA; Sigma) plus the inhibitors wortmannin (100 nM; Calbiochem,La Jolla, CA), bisindolylmaleimide GF 109203X (1 µM; Calbiochem),curcumin (10 µM; Sigma), or C₂ ceramide (Sigma) were added, asindicated.

Purity of the preparation. The preparation used in this study is a well characterized one, the purity of which has been thesubject of several studies. The cultures have been reported tocontain ~95% small interneurons, predominantly granule neurons(Thangnipon et al., 1983), and 4-6% GABAergic neurons (Resinket al., 1994). This is achieved in part by the huge abundanceof granule neurons in the cerebellum and in part by the isolationprocedure that does not allow the survival of larger, earlierdifferentiating neurons such as Purkinje cells (Weber and Schachner,1984). Culturing in serum-containing medium supplemented withthe antimitotic agent arabinosyl cytosine is more effective thanculturing without serum at reducing the proportion of contaminatingcells. Under the former conditions the major contaminants areGFAP⁺ astrocytes, accounting for 1-3% of cells (Kingsbury et al., 1985).Anti-GFAP staining of parallel cultures to those used in thisstudy reveals GFAP⁺ contamination within this range. These GFAP⁺ cells are morphologically distinguishable, having either verylarge nuclei or a large number of thick processes. At the wavelengthsused, propidium iodide stains protein to a minor extent, and theHoechst stain gives the background a slight green fluorescence,allowing morphological identification of both characteristicsof contaminating cells during the counting of nuclei. Thus thesecontaminants are excluded readily from the statistics. This leavesthe possibility that some of the dead cells counted might be non-neuronalcells and that this might interfere with the measurements. However,a minor contaminant of 3% of living cells in control cultureswould have to become over fourfold more prevalent in treated culturesto account for a 10% measured reduction in cell death. No suchincreases of these morphologically distinguishable cells weredetected. Contaminating neurons from the cerebellum are also distinguishableby their large nuclei; the same argument is valid for these.

Cell death measurements. At the times indicated in the figures, Hoechst 33342/propidium iodide in MEM was added to a finalconcentration of 5 µg/ml Hoechst 33342 (Molecular Probes, Eugene,OR) and 20 µg/ml propidium iodide (Sigma). After 25 min, cellswere washed in PBS, fixed for 30 min in 4% paraformaldehyde, washedagain, and mounted in Mowiol 4-88 (Hoechst AG, Frankfurt am Main,Germany) mounting medium (Harlow and Lane, 1988) containing 2.5%(w/v) 1,4-diazabicyclo[2.2.2]octane (DABCO). Slides were examinedwith a fluorescence microscope (Leica, Heerbrugg, Switzerland)equipped with a 1000U CCD Camera (Electrim, Princeton, NJ) undercontrol of software developed by the authors. An image at 7-amino-4-methylcoumarin-3-aceticacid-N $'$ -hydroxysuccinimide ester wavelengths (excitation bandpass340-380 nm, dichroic 400 nm, emission long-pass 425 nm) and animage at rhodamine B wavelengths (excitation bandpass 515-560nm, dichroic 580 nm, emission long-pass 590 nm) were capturedon cyan blue and red channels, respectively, of a true color imagefor each of nine evenly spaced fields per coverslip, and the proportionof total stained nuclei that did not stain with cell-impermeantpropidium iodide was taken as the proportion of cells surviving.The method has the advantage (over the propidium iodide/fluoresceindiacetate method) that relatively dense cells may be counted.At the excitation wavelengths used, propidium iodide also stainsprotein to a small extent. This results in an occasional red rimaround the blue nuclei of living cells and is resolved easilyfrom double-stained magenta nuclei scored as dead. Data shownwere obtained from between three and nine coverslips per condition.These coverslips were obtained, in each case, from two to threeseparate cell preparations.

In the graphs the term "% dead cells" is the percentage of cells present scored as dead under basal conditions. "% Protection"is defined as the increase in survival above control (i.e., 0%protection = control survival), where 100% protection = 100% survival.This allows direct comparison of survival effects of compoundsunder different conditions for which the control survival is notconstant.

Calcium measurements. Cells were loaded for 40 $'$ in Modified Elliot's Medium (Courtney et al., 1990) containing 5 µM Fluo-3/AM(Molecular Probes), 33 µg/ml BSA (Sigma), and 0.02% pluronic acid(Molecular Probes), washed five times in Mg²⁺-free Elliot's, and placed in a chamber heated to 37°C on thestage of a Nikon Diaphot microscope. Cells were excited at 480nm through a 40×/1.3 N.A. objective, and emission light was passedthrough a DM 510 dichroic mirror and 520 nm barrier filter ontoa 1000TE cooled CCD (Electrim). Images were collected once persecond under the control of software developed by the authors.Data were analyzed with analysis software described previously(Lindqvist et al., 1995). Spontaneous calcium channel activitywas recorded and then terminated by addition of 1 µM nifedipineto the incubating medium where indicated in the figure. Singlewavelength fluorescence values (F) were converted to cytoplasmic-free[Ca²⁺], as previously reported, with the formula [Ca²⁺] = K_D × (F $-$ F_min)/(F_max $-$ F), using published K_D values (385nM; Kao et al., 1989). Calibration values were obtained by usingionomycin in parallel experiments. The data shown were obtainedfrom 7 DIV cells cultured in low KCl; nifedipine-blocked spontaneousactivity also was observed at earlier stages in development, althoughthis activity developed from smaller, more sustained elevationsto larger, transient elevations with increasing age in culture.Cells cultured in elevated KCl exhibited no detectable nifedipine-sensitivespontaneous calcium elevations.

Protein detection and quantitation. Levels of c-Fos and c-Jun were assessed by exposing cells for 2 hr to 10 ng/ml NGF, BDNF,NT-3, or TNF or 10 nM TPA and blotting the cell lysates with polyclonalanti-Fos antibody (Oncogene Science, Uniondale, NY) or monoclonalanti-c-Jun antibody (Transduction Labs, Lexington, KY), and filmwas exposed over the linear range by the ECL method, accordingto the manufacturer's instructions (Amersham International, Amersham,UK). Exposed films were digitized by flatbed scanning and quantitatedby imaging software developed by the authors (Lindqvist et al.,1995). Changes in c-Fos immunoreactivity in elevated KCl weredetected in a band ~62 kDa; this band was quantitated. In lowKCl, changes were detected in a band ~55 kDa, and a 62 kDa bandcould not be detected. Therefore, under these conditions the 55kDa band was quantitated. Rabbit polyclonal subtype-specific Trk763, TrkB 794, and TrkC 798 from Santa Cruz Biotech (Santa Cruz,CA) were used for immunodetection of TrkA, TrkB, and TrkC, respectively.A TrkA-specific antiserum generously provided by Dr. Louis Reichardt(University of California, San Francisco) also was used. Rabbitantiserum 9651 raised to the ligand-binding sequences of p75 sequences,generously provided by Dr. Moses Chao (Cornell University MedicalCollege, New York), was used for immunodetection of p75^NTR and for blocking NGF action via p75^NTR.

Immunocytochemistry. Immunocytochemical staining for NF- $kappa$ B p65 subunit was performed as described in Menon et al. (1993) byusing 1:500 biotin anti-rabbit (Sigma) and 1:50 ExtrAvidin fluorescein(Sigma). Slides were examined under a Leica confocal microscopewith a 100× objective.

RESULTS

Cell death occurs in two phases
We first determined the time course of cell death of cerebellar granule neurons in serum-containing culture. Hoechst 33342is membrane-permeant and stains all nuclei, whereas propidiumiodide is membrane-impermeant. Cell death is calculated as theproportion of nuclei present that stains with propidium iodide.This technique avoids many artifacts to which other methods aresusceptible (Juurlink and Hertz, 1993). It detects damage to theplasma membrane and thus measures both necrotic and late apoptoticcells. Almost all of the cells scored as dead in the results thatfollow had pyknotic nuclei; the predominant mode of death describedhere, therefore, may be of an apoptotic nature. Figure 1 showsthe percentage of dead cells present over the first 12 DIV. Cellswere cultured in the absence or presence of 20 mM supplementaryKCl and 1 µM of the L-type voltage-sensitive calcium channel (VSCC)inhibitor nifedipine, as indicated. In agreement with previousresults (Gallo et al., 1987), there is a requirement for depolarizationfor prolonged survival involving L-type VSCCs. However, a significantproportion of cells present even during the first 6 DIV are dead,and depolarization does not prevent this death.
Fig. 1. Cell death occurs in two phases: L-type voltage-sensitive calcium channels prevent only the late phase. Of the cells presentat 3-6 d in vitro (DIV), 30-50% were dead; the remaining cellsdied between 6 and 9 DIV. The early phase was not prevented byelevated KCl (+K). Elevated KCl in the absence of nifedipine preventedonly the late phase of cell death.
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Protection from basal cell death by neurotrophins, TNF, and TPA
BDNF enhances survival of cerebellar granule neurons in serum-free culture (Segal et al., 1992; Lindholm et al., 1993; Gaoet al., 1995). However, depolarization has been reported not toenhance survival under these conditions (Kingsbury et al., 1985),and maturation is abrogated to the extent that amino acid carriersare not expressed and stimulus-coupled transmitter release doesnot occur or is delayed (Balazs et al., 1988a). As depolarizationdependence begins after 6 DIV, we asked whether activation ofneurotrophin receptors regulates the early phase of cell survival.

Figure 2 shows the percentage of cells present scored as dead at 6 DIV in cultures incubated with the dimeric neurotrophinsNGF or BDNF from 1 DIV. In cultures incubated with neurotrophin-supplementedelevated KCl medium alone (left set of columns), ~38% of the cellsare dead in controls. NGF moderately but significantly reducesthis proportion, and BDNF more strongly reduces cell death. Inparallel experiments increasing amounts of 9651 rabbit anti-p75,an antiserum that binds the ligand-binding site of p75^NTR (Huber and Chao, 1995), were included. At 1:200 dilution (rightset of columns), NGF no longer reduces cell death, whereas BDNFis still protective. This suggests that binding of NGF to p75^NTR is essential for NGF-evoked reduction of cell death, whereasBDNF is able to reduce death independent of binding to p75^NTR. The p75^NTR antiserum alone reduces cell death. This would be consistentwith the divalent p75^NTR antibodies mimicking the NGF-evoked reduction in death and acomponent of the BDNF-evoked reduction in death. Thus NGF hasno further effect above that of the antiserum, and BDNF has asmaller effect than in the absence of antiserum.
Fig. 2. Neurotrophic factors protect from cell death at 6 DIV. Antiserum to p75^NTR ligand-binding domain prevents NGF-evoked protection. Shown isquantitation of the protective effects of the neurotrophins NGFand BDNF on cerebellar granule neuron cultures. NGF and BDNF bothreduce cell death. Increasing amounts of antiserum raised againstthe ligand-binding domain of p75^NTR prevent NGF-evoked survival promotion and reduce basal deathwithout effect on survival in the presence of BDNF.
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The neurotrophic factors NGF, BDNF, and NT-3 would be expected to activate their respective Trk receptors, if present, andthe nonselective p75^NTR. p75^NTR is a member of the TNF receptor family (Mahadeo et al., 1994)that exhibits common structural and signaling features. Trks activatea number of signaling cascades, including protein kinase C (PK-C)via PL-C $gamma$ (Vetter et al., 1991) and the MAP kinase cascade viaRas (Ohmichi et al., 1992). TPA also activates PK-C, which hasbeen reported to activate the MAP kinase cascade via Raf (Kolchet al., 1993). Therefore, we tested NGF, BDNF, and NT-3 whileattempting to mimic the actions of p75^NTR activation with TNF and to activate specific components of Trksignaling with TPA.

Cells were cultured in the absence or presence of 20 mM supplementary KCl. Then neurotrophins, TNF- $alpha$ , TPA, and 1 µM nifedipinewere introduced during the medium change at 1 DIV. Because thebasal level of death in the absence of neurotrophins was not identicalin the different conditions of depolarization and nifedipine (seeFig. 1), protection from death by neurotrophins was normalizedto the maximum possible reduction in death in each condition ofdepolarization and nifedipine (see Materials and Methods).

NGF, BDNF, NT-3, and TNF protected against cell death (Fig. 3A). The modest protective effects of NGF and TNF were eliminatedby culturing the cells in low KCl in the presence of nifedipine,conditions expected to reduce VSCC activity to a minimum. Thegreater protection evoked by BDNF and NT-3 was reduced only partiallyunder such conditions. Ceramide is a putative mediator of p75^NTR and TNF-R signaling (Yanaga and Watson, 1992; Dobrowsky et al.,1995). Thus we investigated the protective effects of the water-solubleanalog C₂ ceramide on cells cultured in elevated KCl, which aresensitive to protection by NGF and TNF. Low concentrations ofC₂ ceramide protected cells against death to a similar extentto NGF and TNF (Fig. 3B). At 10 µM, ceramide had no effect, whereas100 µM caused the death of all the cells in the culture (datanot shown).
Fig. 3. Neurotrophic factors, TNF, TPA, and ceramide protect from cell death at 6 DIV. A, Quantitation of the protective effects ofneurotrophins, TNF, and TPA on cerebellar granule neuron cultures.NGF, BDNF, NT-3, and TNF all evoke protection against cell death.In elevated KCl (+K), 1 µM nifedipine (+Nif) reduces the protectiveeffects, and 10 nM TPA behaves like a neurotrophin. In low KCl( $-$ K), nifedipine eliminates protection by NGF and TNF, but notBDNF or NT-3. Under these conditions 10 nM TPA is toxic. All otherconditions significantly (p < 0.05) protect against cell death.B, C₂ ceramide at 0.1-3.0 µM protects cells cultured in elevatedKCl against cell death to a similar extent to NGF and TNF. Higherconcentrations do not protect against cell death. C, Spontaneouscytoplasmic-free calcium elevations exist in cells cultured inlow KCl. These elevations are blocked by addition of 1 µM nifedipine.
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Although nifedipine might be expected to be effective only when elevated KCl is present to depolarize the neurons, cerebellargranule neurons cultured in low KCl can be observed to undergospontaneous VSCC activity that is blocked by nifedipine (Fig.3C); such activity is not observed in cells cultured in elevatedKCl (Courtney et al., 1990). Furthermore, these neurons undergospontaneous L-type and N-type VSCC activity in culture medium(Doherty et al., 1991). Thus it is likely that nifedipine modulatesthe actions of neurotrophins via L-type VSCCs, even in low KClconditions. These results suggest that NGF and TNF act by mechanismsdependent on L-type VSCC activity, whereas BDNF and NT-3 act viaan additional mechanism that is independent of VSCC activity.TPA was protective to cells cultured in the presence of elevatedKCl, but, unlike the other factors tested, it was toxic to cellscultured in low KCl.

Figure 4 shows representative fields of cells used in these studies. Figure 4A shows phase-contrast images of cells in theabsence or presence of elevated KCl at 6 DIV. In Figure 4B, cellsstained by the cell death quantitation technique that was usedare shown. The proportion of dead cells (with double-stained nuclei)at 6 DIV was not altered significantly by the presence of elevatedKCl; however, at 9 DIV virtually all cells were dead unless theculture medium was supplemented with elevated KCl. It should benoted that the proportion of dead cells at any time point is anunderestimation of the total death of cells up to that time, becausecells that had died at earlier time points continue to degenerateand are lost from the culture surface (Xia et al., 1995). Representativefields of cells at 6 DIV cultured with BDNF or TPA in low KClare shown in Figure 4C. Under these conditions BDNF reduced celldeath, whereas TPA notably increased it.
Fig. 4. Representative fields of cerebellar granule neuron cultures in phase-contrast mode and in fluorescence mode after exposureto Hoechst 33342 and propidium iodide. A, Phase-contrast imagesof cerebellar granule neuron cultures at low magnification areshown. Left, Cells cultured in low KCl ( $-$ K) are shown. Right,Cells are cultured in elevated KCl (+K). B, The presence of elevatedKCl (+K) in the culture medium does not alter significantly theproportion of cells with double-stained nuclei at 6 DIV (upperpair). However, by 9 DIV virtually all nuclei double stain, i.e.,are dead, unless supplementary KCl is present (lower pair). C,Representative fields of cells cultured in low KCl ( $-$ K) stainedat 6 DIV. Under these conditions 10 ng/ml BDNF protects from celldeath, whereas 10 nM TPA is toxic.
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Cerebellar granule neurons express TrkB and p75^NTR, but not TrkA, receptors
To understand the mechanism of action of the neurotrophins, we determined which neurotrophin receptor subtypes were expressedin cerebellar granule neurons under the conditions in which neurotrophinshad been added. Lysates of cells cultured in low or elevated KClwere probed with specific polyclonal antibodies (Fig. 5A). Intensestaining at ~145 kDa was obtained with the anti-TrkB antibody.A faint band could be detected with prolonged exposure to theanti-TrkC immunoblot. However, no band was detectable with theanti-TrkA. A polyclonal antiserum raised to the extracellulardomain of TrkA (Clary et al., 1994) also was tested. This antiserumdetected TrkA (140 kDa) in PC12 extracts, but no comigrating bandwas detected in granule neuron extracts (data not shown). Slightcross-reactivity was observed with a more slowly migrating band,probably 145 kDa TrkB. We also detected p75^NTR protein in cerebellar granule lysates (Fig. 5B) with the polyclonalantibody [9651] used in Figure 2, consistent with previous reportsof mRNA for p75^NTR in these neurons in culture (Lindholm et al., 1993; Segal etal., 1995) and early during development in vivo (Huber and Chao,1995).
Fig. 5. Neurotrophin receptors in cerebellar granule neuron cultures. A, Cerebellar granule neurons at 1 DIV express TrkB, the selectivereceptor for BDNF, but not TrkA. Slight immunoreactivity to anti-TrkCat the appropriate molecular weight is detectable after prolongedexposure of film. B, Cerebellar granule neurons at 1 DIV expressp75^NTR, the nonselective neurotrophin receptor.
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Regulation of immediate early gene product levels and NF- $kappa$ B localization by neurotrophins, TNF, and TPA
Trks induce Ras-mediated activation of the MAP kinase cascade (Ohmichi et al., 1992), increasing transcription of the immediateearly gene (IEG) c-fos (Cordon-Cardo et al., 1991). On the otherhand, in some cells p75^NTR and TNF receptors activate JNK (Kyriakis et al., 1994; Casaccia-Bonnefilet al., 1996), a kinase that leads to increased c-jun transcriptionand c-Jun stability (for review, see Kyriakis et al., 1995; Mustiet al., 1997).

To investigate whether these cascades might be activated as a result of exposure to neurotrophins at 1 DIV, we measured thelevels of c-Fos and c-Jun in cells stimulated with NGF, BDNF,NT-3, TNF, or TPA by immunoblot densitometry. A 2 hr exposurewas chosen because the levels of these proteins clearly are elevatedafter this time (our unpublished observations). In elevated KCl,BDNF, NT-3, and TPA elevated c-Fos levels, whereas neither NGFnor TNF increased c-Fos (Fig. 6A). In low KCl, BDNF still detectablyincreased c-Fos levels, but the other treatments did not. Giventhe presence of TrkB protein and the absence of TrkA, these resultsare consistent with BDNF elevating c-Fos levels via TrkB and presumablythe MAP kinase cascade. TPA also may be acting via this pathway(Kolch et al., 1993).
Fig. 6. Intracellular signaling in response to neurotrophins, TNF, and TPA in cerebellar granule neuron cultures. A, Addition of BDNF,NT-3 (10 ng/ml), or TPA (10 nM) for 2 hr to cells 1 DIV elevatesc-Fos levels (*p < 0.05); NGF or TNF (10 ng/ml) does not elevatec-Fos levels. In low KCl ( $-$ K) the BDNF-evoked elevation is reduced,and the NT-3-evoked and TPA-evoked elevations are undetectable.B, Addition of NGF, BDNF (10 ng/ml), or TPA (10 nM) for 2 hr elevatesc-Jun levels (*p < 0.05, **p < 0.025); NT-3 or TNF (10 ng/ml)does not elevate c-Jun levels. In low KCl ( $-$ K) the BDNF-evokedelevation is reduced, and the NGF-evoked elevation is eliminated;the TPA response is maintained under these conditions. C, Immunofluorescentlystained 1 DIV cells stimulated for 2 hr with neurotrophins orTNF (100 ng/ml), TPA (100 nM), or C₂ ceramide (10 µM), as indicated,were scanned with a confocal microscope. No induction of translocationof cytosolic NF- $kappa$ B was detected in any condition. $-$ 1° denotescontrol staining omitting 1° antibody.
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In elevated KCl, NGF, BDNF, and TPA also increased c-Jun levels; neither NT-3 nor TNF detectably changed c-Jun levels (Fig.6B). The absence of elevated KCl eliminated the response to NGFand partially reduced the response to BDNF, whereas the responseto TPA was unchanged. Although TNF did not alter IEG levels detectablyat 1 DIV, we have observed c-Jun elevations in response to TNFin 3 DIV cells (data not shown). These results are consistentwith NGF acting via a non-Trk receptor, presumably p75^NTR, whereas BDNF acts at least in part via a separate, presumablyTrkB-mediated, pathway.

p75^NTR and TNF-R activation have been reported to evoke nuclear translocation of NF- $kappa$ B (Yang et al., 1993; Carter et al., 1996a),which recently has been shown to have an antiapoptotic role (Liuet al., 1996). Therefore, we investigated whether the survival-promotingfactors that were used evoked translocation of the p65 subunitof NF- $kappa$ B. Confocal microscopy of immunostained cerebellar granuleneurons revealed no bulk translocation of the NF- $kappa$ B p65 subunitinto the nucleus on stimulation with the survival-promoting factorstested (Fig. 6C). However, some constitutive nuclear staining,consistent with a previous report (Guerrini et al., 1995), couldbe detected under all conditions.

Inhibitor studies
These data suggest that two different mechanisms may mediate the signaling and survival-promoting effects of NGF and BDNF.Because distinct protein kinases may be involved, the effectsof kinase inhibitors on the actions of these two factors on cellscultured in elevated KCl were compared.
Wortmannin does not affect basal survival or BDNF-evoked survival promotion Phosphatidylinositol-3 kinase (PI-3K) is a prominent kinase activated by tyrosine kinase receptors, including Trks, and hasbeen proposed to mediate NGF-evoked survival of neuronally differentiatedPC12 cells (Yao and Cooper, 1995). Therefore, we investigatedwhether inhibition of PI-3K with the specific inhibitor wortmannin(Okada et al., 1994) altered basal or neurotrophin-promoted survival.Wortmannin (100 nM) at 1 DIV had no significant effect on basalcell death at 6 DIV, nor did it prevent survival promotion byBDNF (Fig. 7). However, NGF did not improve survival significantlyin the presence of this inhibitor. Thus it is unlikely that wortmannindoes not inhibit BDNF-evoked survival as a result of low stability.Furthermore, BDNF has a clear survival-promoting effect within24 hr of addition (data not shown), and TrkB may, in fact, desensitizewithin this time period (Carter et al., 1995). Thus BDNF-inducedsurvival does not depend on wortmannin-sensitive PI-3Ks.
Fig. 7. Effects of specific inhibitors on basal and neurotrophin-enhanced survival. Cells were cultured in the presence of elevatedpotassium and either no neurotrophin, NGF, or BDNF (10 ng/ml)and no inhibitor (Control), wortmannin (100 nM), bisindolylmaleimide(1 µM), or curcumin (10 µM). Neither wortmannin nor bisindolylmaleimidealtered basal cell death, but in the presence of bisindolylmaleimideNGF became toxic and BDNF-evoked protection was reduced. Curcuminincreased basal cell death, revealing enhanced protection by theneurotrophins. *p < 0.02 and ***p < 0.001 indicate significantdifference, as compared with death with the same inhibitor andno neurotrophin; **p < 0.01 indicates significant difference,as compared with the corresponding inhibitor-free control.
[View Larger Version of this Image (58K GIF file)]

PK-C activity is absolutely required for NGF-evoked survival promotion and partly required for full BDNF-evoked survival promotion PK-C previously has been attributed a mediator role in BDNF-evoked survival in cerebellar granule neurons cultured in serum-freemedium (Zirrgiebel et al., 1995). Using the specific PK-C inhibitorbisindolylmaleimide GF 109203X (Toullec et al., 1991), we investigatedthe role of PK-C in basal survival and neurotrophin-evoked survivalpromotion in neurons cultured with serum (Fig. 7). Survival underbasal conditions was not altered by PK-C inhibition. This suggeststhat the responses observed to 10 nM TPA were attributable toactivation and not to downregulation of PK-C. In further supportof this, survival promotion in elevated KCl also was observedwith 1 nM TPA (data not shown). In the presence of the PK-C inhibitor,NGF significantly reduces survival, suggesting, first, that theprotective effect of NGF is dependent on PK-C and, second, thatNGF induces some event that is toxic to the cells, at least inthe absence of PK-C activity. The protective effect of BDNF isreduced only partially by the PK-C inhibitor.

The nonselective kinase inhibitor K252a is used frequently to suggest that neurotrophin responses are Trk-mediated. However,this inhibitor is known to have nanomolar IC₅₀ values againstPK-A, PK-G, and PK-C (Kase et al., 1987) and is even more potentagainst phosphorylase kinase and CaM kinase II than it is againstTrks (Elliott et al., 1990; Hashimoto et al., 1991; Tapley etal., 1992). Another inhibitor of CaM kinase II potently reducesbasal survival in these cells (our unpublished observations);consistent with this, K252a compromised basal survival at concentrationsas low as 10 nM, under which conditions BDNF still clearly promotedsurvival (data not shown). This inhibitor thus is not useful indissecting the survival responses reported here.

The survival promotion evoked by NGF as a proportion of the cell population is rather modest. Thus we sought conditions underwhich the signaling evoked by NGF might be more limiting underbasal conditions to potentiate survival promotion by NGF. Thetumor suppressor curcumin antagonizes the DNA-binding activityof c-Jun (IC₅₀ ~20 µM; Huang et al., 1991) and inhibits NF- $kappa$ Btranslocation (IC₅₀ <40 µM; Singh and Aggarwal, 1995). Both NGFand BDNF increased the levels of c-Jun, and p75^NTR activation by NGF has been reported to translocate NF- $kappa$ B (Carteret al., 1996a), which has been attributed with an antiapoptoticfunction. Because we detected constitutive levels of c-Jun andof nuclear NF- $kappa$ B immunoreactivity (Fig. 6B,C), we investigatedwhether partial AP-1/NF- $kappa$ B antagonism with curcumin might causethe basal levels of c-Jun and translocated NF- $kappa$ B to be more limiting,thus potentiating survival-promotion via these pathways. The additionof 100 µM curcumin completely eliminated survival of cerebellargranule neurons in the presence or absence of NGF or BDNF (datanot shown). However, 10 µM curcumin increased basal death to only50% (Fig. 7). Under these conditions both NGF and BDNF evokedclear reductions in death, amounting to >20 and 35% of the cellspresent, respectively.

DISCUSSION
Our study investigates specific signaling mechanisms in neurotrophin-evoked survival-promotion in cerebellar granule neuronsduring the first week in culture. Considerable cell death occursduring this period. Unlike the delayed phase of cell death, thisdeath is not reduced by inhibition of VSCC activity (Fig. 1).This allowed us to investigate alternative signaling mechanisms,such as those evoked by the neurotrophins, in the survival ofthese CNS neurons.

NGF and BDNF promote survival of cerebellar granule neurons via two distinct signaling mechanisms
The NGF-evoked and TNF-evoked protection against basal death can be eliminated by VSCC inhibition. In contrast, part of theprotection evoked by BDNF and NT-3 persists during VSCC inhibition(Fig. 3A). The simplest explanation is that NGF and TNF act viathe same pathway, whereas BDNF and NT-3 act in part via this mechanismand in part by an independent pathway. Neurotrophins act via specificTrk receptors and the nonselective p75^NTR. The model proposed corresponds to NGF acting exclusively viap75^NTR, whereas BDNF and NT-3 act both via this receptor and via a Trkreceptor; hence, there are two components of protection resolvedby VSCC modulation. TNF would act via its own receptor, knownto be structurally and functionally homologous to p75^NTR. The finding that anti-p75^NTR antiserum, which blocks NGF binding, prevents and even mimicsNGF-evoked survival promotion (Fig. 2) supports this interpretation.

The presence of an antimitotic ensured that cell counts reflected changes in survival and not proliferation. The culturesused consist of >90% granule neurons, and no increases in contaminatingcell types were detected that could account for the modest protectionevoked by NGF and TNF (see Materials and Methods). Furthermore,the increased effectiveness of NGF in the presence of curcumin(Fig. 7) strongly suggests that the major cell type, i.e., thecerebellar granule neuron, is responsible for the survival promotionthat was observed.

Testing the two-component model
TrkB protein and p75^NTR are present, but TrkA is undetectable We detected TrkB, the specific receptor for BDNF, in cerebellar granule neuron lysates, whereas TrkA, the specific receptorfor NGF, was undetectable (Fig. 5). This is consistent with thedetection of trkB, but not trkA, mRNA reported previously (Segalet al., 1992; Lindholm et al., 1993). The faint TrkC immunoreactivitydetected may represent cross-reactivity with TrkB; however, TrkCprotein probably is present because NT-3 induces tyrosine phosphorylationin these cells of a pan-Trk-immunoprecipitable band migratingmore slowly than TrkB (Segal et al., 1995). NT-3 binds to andactivates TrkB at the concentrations used here (Soppet et al.,1991) and thus may be expected to mimic BDNF even in the absenceof TrkC. Because p75^NTR was detected, consistent with the reported detection of mRNAfor p75^NTR (Segal et al., 1995), NGF presumably is acting via this receptor.This suggests that the actions of NGF are mediated entirely byp75^NTR, hence the similarity in survival promotion to that evoked byTNF. BDNF would be expected to act via both TrkB and p75^NTR.
Regulation of c-Fos and c-Jun Trks, unlike p75^NTR, increase the expression of c-fos mRNA via the MAP kinase cascade (Cordon-Cardo et al., 1991; Ohmichi etal., 1992). Consistent with the presence of TrkB, but not TrkA,BDNF elevates c-Fos levels, whereas NGF does not (Fig. 6A). p75^NTR has been reported to activate JNK (Casaccia-Bonnefil et al.,1996), which increases c-jun transcription and c-Jun stability(for review, see Kyriakis et al., 1994; Musti et al., 1997). Therole of Ras activators such as Trks in JNK activation is controversial(Minden et al., 1994; Xia et al., 1995) (see also Masuelli andCutler, 1996). Thus both NGF and BDNF might be expected to activateJNK via p75^NTR, whereas BDNF might induce additional activation via TrkB/Ras.Our results are consistent with these predictions, increases inc-Jun being induced by NGF and BDNF. NGF does not elevate c-Junlevels in low KCl, whereas BDNF again is only partially sensitiveto this condition that eliminates the NGF response, supportingour interpretation that BDNF acts via two independent pathways.

Mediators of p75^NTR/TNF-R regulation of survival
Ligand binding to p75^NTR may promote cell death (Casaccia-Bonnefil et al., 1996; Frade et al., 1996) or survival (Rabizadeh etal., 1993; Cortazzo et al., 1996). This is also the case for TNF-R.Both receptors evoke similar signaling events, including JNK activation(Kyriakis et al., 1994; Casaccia-Bonnefil et al., 1996) and theNF- $kappa$ B pathway (Yang et al., 1993; Carter et al., 1996a). TNF-evokeddeath occurs via a TRAF2-independent TRADD-FADD pathway (Hsu etal., 1996). Similar zinc finger proteins may associate with p75^NTR (Carter et al., 1996b). The potentiation of NGF survival promotionby curcumin is consistent with an essential requirement for somec-Jun and/or NF- $kappa$ B for survival, although curcumin also may beacting on other targets, especially when present at 100 µM. TNF-Rand p75^NTR also activate sphingomyelinase/ceramide signaling (Yanaga andWatson, 1992; Dobrowsky et al., 1995), which may activate JNK(Westwick et al., 1995). Ceramide may be responsible for the NGF-evokedand TNF-evoked survival promotion, because exogenous C₂ ceramidealso promotes survival of cerebellar granule neurons (Fig. 3B),as it does in sympathetic neurons (Ito and Horigome, 1995).

JNK and c-Jun activation have been proposed to mediate apoptosis (Ham et al., 1995; Xia et al., 1995; Cuvillier et al., 1996;Verheij et al., 1996). However, a noncytotoxic TRAF2-mediatedpathway activates JNK and NF- $kappa$ B in response to TNF (Natoli etal., 1997). In many cases, activation of c-Jun and the JNK pathwaycorrelates with cell maturation (Pulverer et al., 1993; Su etal., 1994; Berberich et al., 1996; Heasley et al., 1996) and protectionfrom apoptosis (Hallahan et al., 1995; Sakata et al., 1995; Johnsonet al., 1996) Indeed, the JNK activator SEK1 mediates survivalin T-cell development (Nishina et al., 1997). The elevation ofc-Jun levels correlates with protection against early cell deathin cerebellar granule neurons.

NF- $kappa$ B may be antiapoptotic (Beg and Baltimore, 1996; Liu et al., 1996; Van Antwerp et al., 1996; Wang et al., 1996), althoughit has been proposed to mediate glutamate-evoked death of maturecerebellar granule neurons (Grilli et al., 1996). We did not observetranslocation of the p65 subunit of NF- $kappa$ B on activation of survival-promotingpathways in cerebellar granule neurons (Fig. 6C). However, wecannot exclude NF- $kappa$ B as a mediator of neuroprotection in cerebellargranule neurons, because multiple NF- $kappa$ B isoforms exist. Furthermore,it may be that only a small proportion, below our detection limit,of cellular NF- $kappa$ B need translocate to the nucleus (Gilmore, 1996)for protection to occur.

Measurements of IEG regulation indicate which signaling events can be evoked by the factors and their dependence on depolarization.However the rapid responses at 1 DIV should not be expected toexplain all the survival-promoting effects observed 5 d later.For example, not NGF nor TNF nor NT-3 has any detectable effectat 2 hr in low KCl, although each still evokes survival-promotionby 6 DIV. It may be possible that gradual changes not detectablewithin 2 hr at 1 DIV are evoked, perhaps as a result of developmentalchanges in receptor expression or spontaneous calcium channelactivity. Thus some of the survival promotion does not seem torequire increases in c-Fos or c-Jun at such early time points.Although c-Fos is reported to have a short half-life and rapidlydownregulate its own expression (Sassone-Corsi et al., 1988) (seealso Thompson et al., 1995), we have observed that BDNF additionto cerebellar granule neuron cultures at 1 DIV causes a prolongedelevation of c-Fos protein levels (Coffey et al., 1995).

The role of PK-C in survival
PK-C activity is required for both NGF-evoked survival and a component of BDNF-evoked survival (Fig. 7). This is again consistentwith BDNF acting in part via a pathway that also is activatedby NGF and in part by an independent pathway. Basal survival isunaffected, suggesting that basal and neurotrophin-evoked survivalmechanisms are distinct, and furthermore that any endogenous neurotrophinspresent do not enhance basal survival. However, this requirementfor PK-C activity does not indicate necessarily that NGF activatesPK-C in these cells or that this is the mechanism of survivalpromotion; this is unlikely, given the toxicity of TPA in lowKCl. In the presence of the PK-C inhibitor the addition of NGFincreases cell death (Fig. 7). PK-C prevents apoptosis-associatedDNA fragmentation evoked by ceramide (Obeid et al., 1993), whichmay accumulate on activation of p75^NTR (Dobrowsky et al., 1994, 1995). Thus basal PK-C activity protectsagainst such an NGF/p75^NTR-evoked signal that is otherwise toxic, as proposed for TNF receptors(Cuvillier et al., 1996). Because BDNF also seems to act via p75^NTR, this would explain the sensitivity of BDNF-evoked survival promotionto PK-C inhibitors we and others (Zirrgiebel et al., 1995) observed.Components of the serum-based medium might be responsible forelevating basal PK-C activity sufficiently to allow NGF to besurvival-promoting, explaining why NGF-promoted survival has notbeen detected in this cell type in serum-free conditions (Segalet al., 1992; Lindholm et al., 1993; Gao et al., 1995).

In summary, NGF activates signal cascades in cerebellar granule neuronal cultures, leading to the elevation of c-Jun levels,and enhances survival in the absence of TrkA protein in a mannerblocked by anti-p75^NTR antiserum, suggesting a trophic role for p75^NTR. BDNF is also protective, acting via an additional independentpathway likely to be via TrkB, which is expressed by the cells.PK-C inhibition reduces BDNF-evoked survival promotion and unmasksNGF/p75^NTR-evoked cell death without affecting basal survival in the absenceof neurotrophins. Thus three distinct survival mechanisms in thesecells are resolved: a basal neurotrophin-independent mechanism,an NGF/BDNF-evoked calcium-sensitive mechanism, and a furthermechanism evoked by BDNF, but not NGF.

FOOTNOTES

Received Jan. 31, 1997; revised March 17, 1997; accepted March 25, 1997.

This work was supported by the Academy of Finland, the Wellcome Trust, the Sigrid Jusélius Stiftelse, the Magnus EhrnroothStiftelse, the Oskar Öflund Stiftelse, and the Finska Vetenskaps-Societeten.We thank Heiti Paves (Estonian Academy of Sciences, Tallinn, Estonia)for providing some neurotrophins for pilot experiments, LouisReichardt (University of California, San Francisco) for providingus with TrkA-specific antiserum, and Moses Chao (Cornell UniversityMedical College, New York) for providing us with anti-p75^NTR antiserum 9651.

Correspondence should be addressed to Dr. Michael J. Courtney, Department of Biochemistry and Pharmacy, Åbo Akademi University,BioCity, P.O. Box 66, FIN-20521 Turku, Finland.

Dr. Åkerman's present address: Department of Physiology and Medical Biophysics, Uppsala University, BMC Box 572, S-75123 Uppsala,Sweden.

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