Leukemia Inhibitory Factor Requires Concurrent p75LNTR Signaling to Induce Apoptosis of Cultured Sympathetic Neurons

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The Journal of Neuroscience, June 1, 2000, 20(11):4198-4205

Leukemia Inhibitory Factor Requires Concurrent p75^LNTR Signaling to Induce Apoptosis of Cultured Sympathetic Neurons
Sean I. Savitz and John A. Kessler
Departments of Neurology and Neuroscience, Albert Einstein College of Medicine, Bronx, New York 10461

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Apoptosis may result either from positive induction by ligand binding to a plasma membrane receptor or from negative inductionattributable to loss of a suppressor signal. For example, apoptosisof developing sympathetic neurons may be induced in culture eitherby exposure to leukemia inhibitory factor (LIF) or by deprivationof nerve growth factor. This study compared the cell death pathwaysactivated in sympathetic neurons by these two different stimuli.Both types of cell death were developmentally regulated; bothwere maximal in the immediate postnatal period and disappearedover the next 2 weeks. Both types of cell death were reduced bygenetic deletion of Bax or by virally mediated overexpressionof Bcl-2. Similarly both were reduced by inhibition of caspaseactivity or by inhibition of Nedd-2 synthesis with antisense oligonucleotides.Finally, both involved activation of c-Jun N-terminal kinase (JNK)signaling. Nedd-2 expression by sympathetic neurons declined inparallel with the developmental loss of LIF-mediated cell death,suggesting that downregulation of the caspase during developmentmay underlie the loss of cytokine-mediated apoptosis. Treatmentof sympathetic neurons with an antibody that blocks the functionof the low-affinity neurotrophin receptor (p75^LNTR) prevented LIF-induced cell death. Similarly genetic deletionof p75^LNTR prevented apoptosis after LIF treatment. These observations suggestthat concurrent p75^LNTR signaling is necessary for LIF-induced cell death and that cytokine-mediatedcell death and growth factor deprivation appear to activate thesame intracellular pathways involving JNKsignaling.

Key words: apoptosis; c-JUN N-terminal kinase; gp130; leukemia inhibitory factor; p75; sympathetic neuron

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Although neuronal survival in the developing nervous system is regulated by growth factors that inhibit apoptosis, neuronnumbers may also be regulated by factors that promote cell death.For example, the cytokine leukemia inhibitory factor (LIF) inducesapoptosis of cultured embryonic and neonatal sympathetic neuronsin a dose-dependent manner (Nawa et al., 1990; Kessler et al.,1993; Kotzbauer et al., 1994). Similarly there are numerous examplesof apoptosis induced by bone morphogenetic proteins both withinthe nervous system and in other organs (Graham et al., 1996; Furutaet al., 1997; Mabie et al., 1999). Thus apoptosis may result eitherfrom positive induction by ligand binding to a plasma membranereceptor or from negative induction attributable to loss of asuppressor signal. The same growth factor may either induce orforestall cell death depending on the cellular context. For example,nerve growth factor (NGF) promotes the survival of sympathetic,sensory, and other neurons via activation of the trkA receptortyrosine kinase (Bredesen and Rabizadeh, 1997; Dechant and Barde,1997; see Yoon et al., 1998). However NGF may induce rather thanprevent apoptosis in cells that express the low-affinity neurotrophinreceptor (p75^LNTR) but not the high-affinity (trkA) receptor (Casaccia-Bonnefilet al., 1996; Frade et al., 1996). Similarly brain-derived neurotrophicfactor (BDNF) induces apoptosis of sympathetic neurons that expressp75^LNTR but not trkB, the high-affinity neurotrophin receptor that bindsBDNF (Bamji et al., 1998). Furthermore, although LIF induces deathof cultured sympathetic neurons, it promotes the survival of alarge number of other populations of neurons (Martinou et al.,1992; Thaler et al., 1994; Murphy et al., 1997).

The effects of growth factors on neuronal survival may be restricted to precise developmental periods. For example, developingsympathetic neurons require NGF for survival, but they lose thatdependence with time postnatally (Easton et al., 1997). The apoptoticresponse to LIF is similarly lost with time in culture (Kessleret al., 1993; Kotzbauer et al., 1994). Although there are differencesamong apoptotic pathways activated by these mechanisms in differentcells, there appear to be a number of common features. Activationof cysteine proteases (caspases) is a common feature of many differentapoptotic pathways (for review, see Cohen, 1997; Green, 1998;Nunez et al., 1998). Some cysteine proteases are present as zymogensin nonapoptotic cells and are activated by other cysteine proteases,by noncaspase proteases, or by autoproteolysis. The same cellmay express more than one caspase, and different caspases maybe activated by different proapoptotic events. For example, apoptosiscaused by growth factor deprivation of sympathetic neurons ismediated by the cysteine aspartase Nedd-2, whereas apoptosis ofthe same cells induced by downregulation of superoxide dismutaseinvolves a different protease (Troy et al., 1997). Another pointof convergence of different apoptotic pathways involves the Bcl-2family of proteins (for review, see Kroemer, 1997). Some membersof this protein family (e.g., Bcl-2 and Bcl-x_L) tend to suppressapoptosis, whereas others (e.g., Bax, Bad, and Bik) induce apoptosis.Genetic deletion of Bax primarily prevents apoptosis of culturedsympathetic neurons after NGF deprivation (Deckwerth et al., 1998),whereas overexpression of Bcl-2 has similar effects (Garcia etal., 1992). Changes in the expression of Bcl-2 family membersmay underlie the acquisition or loss of growth factor dependence;the postnatal loss of dependence of sympathetic neurons on NGFcorrelates with downregulation of the expression of Bax (Eastonet al., 1997). However the effects of the Bcl-2 family of proteinsare also dependent on the nature of the death signal and the cellularcontext. Thus p75^LNTR-mediated death of cultured sensory neurons is actually promotedrather than inhibited by Bcl-2 (Coulson et al., 1999). Althoughthese pathways represent points of convergence of pathways mediatingapoptosis evoked by different insults, there are several independentsignaling pathways that may initiate apoptosis. For example, activationof JNK is involved in the death of sympathetic neurons or of pheochromocytoma12 cells after NGF deprivation, p75 activation, or oxidative stressbut not after serum deprivation or treatment with cytosine arabinoside(Xia et al., 1995; Aloyz et al., 1998; Eilers et al., 1998; Andersonand Tolkovsky, 1999; Maroney et al., 1999).

In this study we investigated the intracellular mechanisms underlying the acquisition and loss of the proapoptotic and antiapoptoticeffects of LIF and NGF on cultured sympathetic neurons. We reportthat apoptosis because of LIF treatment shares many common featureswith cell death after NGF deprivation including inhibition eitherby overexpression of Bcl-2 or by deletion of Bax. Similarly bothare primarily prevented by inhibition of caspase activity and,specifically, by decreasing expression of Nedd-2. Furthermore,LIF treatment and NGF withdrawal also both activate JNK. Mostnotably, p75^LNTR is required for LIF-induced apoptosis as well as for cell deathafter NGF deprivation. These observations suggest that similarmechanisms mediate sympathetic neuron death after LIF treatmentand NGF deprivation and that p75^LNTR signaling is required for both. Furthermore, we find that downregulationof Nedd-2 expression may underlie, at least in part, the postnatalloss both of NGF dependence and of LIF-mediated apoptosis of sympatheticneurons.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell culture. Sympathetic neurons were cultured from dissociated superior cervical ganglia (SCGs) of postnatal day 1 rats(Sprague Dawley) or mice as described previously (Spiegel et al.,1990). The cells were plated at a density of 2000-3000 cells perwell onto collagen-coated 24-well plates in Ham's nutrient mixtureF12 (Life Technologies, Gaithersburg, MD) with 10% fetal calfserum (HyClone, Logan, UT), rhNGF (100 ng/ml), penicillin (50U/ml; Life Technologies), and streptomycin (50 µg/ml; Life Technologies).Cultures were maintained at 37°C in a 95% air/5% CO₂ atmosphereat nearly 100% humidity and were fed three times per week. Ganglionnon-neuronal cells were eliminated by treatment on day 1 of culturewith cytosine arabinofuranoside (15 µM). The number of phase-positivecells with neuronal morphology was counted after 24 hr for allcultures before LIF treatment or other manipulations. During 10d in culture, neuronal death in control cultures never exceeded3-5%. The number of viable cells at the end of all experimentswas quantified by trypan blue exclusion. Unless otherwise stated,each experiment contained five samples for each condition, andeach experiment was repeated three times. The data are reportedas the mean ± SEM. LIF was used at 100 ng/ml unless otherwisestated.

Synthesis of antisense-Nedd and scrambled-Nedd oligonucleotides. Antisense-Nedd oligonucleotides [A-Nedd; sequences describedby Troy et al. (1997); bearing an SH group at their 5' end anda NH group at their 3' end] were purchased from Operon (Alameda,CA). The oligonucleotides were coupled to Penetratin 1 (Oncor,Gaithersburg, MD), a peptide that facilitates the movement ofoligonucleotides across cell membranes, as described previously(Troy et al., 1997). Briefly the oligonucleotides were resuspendedin deionized water, an equimolar ratio of Penetratin 1 was added,and the mixture was incubated at 37°C for 1 hr to allow coupling.The yield of the reaction, estimated by SDS-PAGE followed by Coomassieblue staining, was routinely >50%. A scrambled sequence with thesame base composition as the antisense oligonucleotide, definedas S-Nedd, was synthesized and coupled to Penetratin 1 as a control.Cultures were treated with 400 nM Penetratin-coupled antisenseoligonucleotides unless otherwisestated.

NGF deprivation. Sympathetic neuronal cultures were deprived of NGF by rinsing once with Ham's nutrient mixture F12 with 10%fetal calf serum, followed by the addition of Ham's mixture containing1% goat neutralizing anti-mouse NGF antiserum (1:200; courtesyof Eugene Johnson). Control cultures were rinsed with reintroductionof the usual medium withoutantibody.

Immunohistochemistry for Nedd-2. SCGs from postnatal day 1 (P1), P4, P11, and adult rats were frozen in $-$ 25°C isopentane,and 12 µm cryosections were placed onto Superfrost Plus slides(Fisher Scientific, Houston, TX), air-dried for 2 hr, and fixedwith cold methanol for 10 min. Primary antibodies were diluted(1:250) in PBS containing 5% heat-inactivated horse serum andwere applied at 37°C for 2 hr. Anti-Nedd-2, a polyclonal rabbitantiserum, was a generous gift from Dr. Lloyd Greene. Peroxidasestaining was performed using a biotinylated secondary antibodyand ABC and VIP substrates (Vector Laboratories, Burlingame, CA)according to the manufacturer's instructions. For negative controls,secondary antibody was not applied to corresponding sections ofP1, P4, and P11SCGs.

Preparation and titration of adenovirus vectors. Nonreplicative adenovirus deleted in the E1 region, carrying the human wild-typebcl-2 gene under the control of the cytomegalovirus promoter,was generously provided by Dr. Jayanta Roy Chowdhury. The adenoviruscarrying the $beta$ -galactosidase gene was also provided by Dr. Chowdhury.Recombinant adenovirus was propagated in E1-complementing humanembryonic kidney 293 cells. Viral stocks were purified in cesiumchloride gradients and titered according to the method of Barret al. (1995).

Bax knock-out and p75^LNTR knock-out mice. Mice heterozygous for the deletion of Bax (Bax +/ $-$ ) were a generous gift of Dr. S. Korsmeyer.On postnatal day 1, tail DNA was prepared from the offspring ofheterozygotes and was screened for both the normal and mutantalleles using a single PCR as described by Deckwerth et al. (1996).Sympathetic neurons were cultured individually from the SCGs ofevery neonate, and the genotype was determined after the cultureshad been established. Breeding pairs of mice homozygous for anull mutation in the p75^LNTR gene (Lee et al., 1992) were purchased from The Jackson Laboratory(Bar Harbor, ME). Breeding pairs of control mice with the samebackground were also purchased from The Jackson Laboratory. Genotypeswere confirmed by PCR of tail genomicDNA.

c-Jun N-terminal kinase activity. c-Jun N-terminal kinase (JNK) assays were performed with a glutathione S-transferase (GST)-c-jun(1-79) fusion protein as a substrate after immunoprecipitationof the cell lysates with agarose-conjugated anti-JNK (1:100) antibodies(Yoon et al., 1998). Phosphorylation of GST-c-Jun was evaluatedafter gel electrophoresis andautoradiography.

Materials. LIF was purchased from Life Technologies. Z-vad-fmk and capthepsin B were obtained from Kamiya Biomedical (ThousandOaks, CA). rhNGF was generously supplied by Genentech (South SanFrancisco, CA.). The p75^LNTR antibody (REX) was generously provided by Dr. Louis Reichardt.The soluble interleukin-6 $alpha$ receptor was generously provided byRegeneron, and anti-JNK was purchased from Santa Cruz Biotechnology(Santa Cruz,CA).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Effects of LIF on cultured neonatal sympathetic neurons

To examine the effects of LIF on sympathetic neuronal survival, cultures from P1 ganglia were treated after 24 hr in culturewith 100 ng/ml cytokine or with vehicle (control). Cell numberswere quantified by trypan blue exclusion over the next 48 hr (Fig.1A). Exposure to LIF led to the death of 60% of the neurons within2 d of treatment. By comparison, NGF deprivation killed >90% ofthe neurons. However, if addition of LIF was delayed until day10 of culture there was no significant reduction in cell number(Fig. 1B), indicating that the proapoptotic effects of the cytokinedeclined with time in culture. The effects of NGF deprivationalso declined with time in culture but to a lesser extent; treatmentof P10 neurons with anti-NGF still killed more than one-half ofthe neurons. However cotreatment with LIF at day 10 preventedthe cell death associated with NGF deprivation (Fig. 1B). Thusthe proapoptotic effects of LIF converted to antiapoptotic oneswith time in culture. The change in neuronal responses to LIFoccurred in vivo as well as in vitro; LIF exerted only survivaleffects on ganglion neurons cultured from P12 animals (Fig. 1C).

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Figure 1. Effects of LIF on the survival of cultured sympathetic neurons. Sympathetic neurons were cultured from P1 (A, B) and P12 (C) animals at a density of ~2000 neurons per well. A, Cultures from P1 rats were treated after 24 hr in culture with 100 ng/ml LIF or vehicle (Control). Some cultures were also treated with antiserum to NGF. Cell numbers were quantified 48 hr later by trypan blue exclusion. Note that treatment with LIF led to the death of ~60% of the neurons and that NGF deprivation (anti-NGF) killed >90% of the cells. B, Cultures from P1 rats were treated on day 10 of culture with LIF (100 ng/ml) or anti-NGF, and cell numbers were quantified 48 hr later by trypan blue exclusion. Note that after 10 d in culture the neurons did not die in response to LIF but treatment with anti-NGF still killed more than one-half of the cells. However cotreatment with LIF prevented the death associated with NGF deprivation, indicating that LIF now promoted survival. C, Cultures from P12 animals were treated with LIF or anti-NGF, and cell numbers were quantified 48 hr later by trypan blue exclusion. Note that exposure to anti-NGF killed >50% of the neurons, whereas LIF treatment promoted survival of cells deprived of NGF. Thus the conversion of sympathetic neuron responses to LIF from proapoptotic ones (A) to antiapoptotic ones (B) that occurred with time in vitro was recapitulated in vivo. *p < 0.05 compared with control; **p < 0.05 compared with both control and LIF by ANOVA.

Bcl-2 and Bax in LIF-mediated cell death

Because previous studies demonstrated that LIF-induced neuronal death is apoptotic (Kessler et al., 1993), we questioned whethermembers of the bcl-2 family might be involved. To address thisissue the effects of LIF were examined on neurons lacking Bax.LIF treatment resulted in the death of 74% of sympathetic neuronsderived from newborn Bax (+/+) mice on day 3 of cell culture (Fig.2A). By contrast, treatment of neurons from animals deficientin Bax ( $-$ / $-$ ) resulted in the death of <30% of the cells. The protectiveeffects on survival conferred by the absence of Bax were confirmedby the lack of substantial morphological damage; although Bax(+/+) neurons underwent marked shrinkage, most Bax ( $-$ / $-$ ) neuronsretained viable cell bodies and neurites after LIF exposure. NGFdeprivation resulted in the death of <15% of Bax ( $-$ / $-$ ) neuronsafter 3 d in culture, whereas virtually all Bax (+/+) neuronsdied under these conditions. Because deletion of Bax diminishedLIF-induced neuronal death, we investigated whether overexpressionof Bcl-2 might similarly afford protection against LIF-induceddeath. Enhancing Bcl-2 levels by gene transfer using an adenoviralvector at a multiplicity of infection (MOI) of 500 virtually preventedneuronal cell death induced by LIF (Fig. 2B). By contrast, infectioneither with an adenovirus expressing the $beta$ -galactosidase gene(MOI of 500) or with an adenovirus containing no insert providedno protection, indicating that the infection process by itselfdid not alter neuronal survival.

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Figure 2. LIF-induced cell death of cultured sympathetic neurons requires Bax. A, Sympathetic neurons were cultured from neonatal Bax-deficient ( $-$ / $-$ ) mice and from controls (+/+). After 24 hr in culture the cells were treated with LIF or anti-NGF, and cell numbers were determined on day 3 of culture. Note that exposure to LIF resulted in the death of <30% of the sympathetic neurons derived from newborn Bax-deficient ( $-$ / $-$ ) mice, whereas LIF treatment of neurons from control animals killed 74% of the cells. Con, Control. B, Sympathetic neurons from P1 animals were infected after 24 hr in culture with a bcl-2-containing adenoviral vector at an MOI of 500 or with a control vector containing the $beta$ -galactosidase gene (lac-z). Twelve hours later the cells were treated with LIF, and cell numbers were determined 48 hr later. Note that the bcl-2-expressing virus prevented LIF-mediated cell death whereas adenoviral introduction of lac-z provided no protection. *p < 0.05 compared with control; **p < 0.05 compared with LIF alone by ANOVA.

Caspases and LIF-mediated cell death

Another point of convergence shared by many apoptotic pathways is the activation of the caspase family. We, therefore, examinedthe effects of caspase inhibitors on LIF-treated sympathetic neurons(Fig. 3). Treatment with LIF alone significantly reduced neuronnumbers by ~80%. Cotreatment with the nonspecific caspase inhibitorz-vad-fmk reduced cell death to only 30% of the neurons (Fig.3A). However concurrent administration of z-vad-fmk with its inhibitorcapthepsin B abolished this protective effect. These observationssuggest involvement of a caspase in LIF-induced neuronal death.However treatment with y-vad, a more specific inhibitor for caspase1, was not protective, suggesting that other members of the caspasefamily mediate LIF's proapoptotic effects (Fig. 3B). Because caspase2 (Nedd-2) is one of the mediators of sympathetic neuronal deathafter NGF deprivation (Troy et al., 1997), we sought to determinewhether Nedd-2 is necessary for LIF-induced cell death. Pretreatmentof sympathetic neurons with A-Nedd for 6 hr provided robust protectionagainst subsequent LIF exposure (Fig. 4). Treatment with LIF alonekilled ~80% of the cells, whereas cotreatment with A-Nedd reducedcell death to <20% of cells. By contrast, treatment with S-Neddhad no effect on survival or death. Because Nedd-2 is requiredfor LIF-induced apoptosis, we questioned whether downregulationof caspase 2 expression during postnatal development might accountin part for the loss of the proapoptotic effects of LIF. Nedd-2expression in the SCG was therefore examined immunohistochemicallyat different postnatal time points (data not shown). The SCG expressedcaspase 2 abundantly on postnatal day 1. However levels of Nedd-2expression declined substantially by P4, and by P11 and thereafterthe caspase was almost undetectable in the ganglia.

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Figure 3. Inhibition of caspases prevents the LIF-induced death of cultured sympathetic neurons. A, P1 sympathetic neurons were treated after 24 hr in vitro with LIF, z-vad (Z-VAD; 100 µM), or capthepsin B (Inh), an inhibitor of z-vad, and cell numbers were determined 48 hr later. Note that cotreatment with z-vad partially prevented the effects of LIF. Concurrent administration of the z-vad inhibitor capthepsin B abolished this protective effect of z-vad. B, By contrast, similar experiments using a more specific inhibitor for caspase 1, y-vad (Y-VAD), did not protect neurons from LIF, suggesting the involvement of other caspases. *p < 0.05 compared with control; **p < 0.05 compared with LIF alone by ANOVA.

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Figure 4. LIF-induced cell death is mediated by the caspase Nedd-2. P1 sympathetic neurons were treated after 24 hr in vitro with A-Nedd or with S-Nedd for 6 hr. Then the cultures were exposed to LIF, and cell numbers were determined 48 hr later. Note that A-Nedd rescued cells from LIF exposure, whereas S-Nedd provided no protection. *p < 0.05 compared with control; **p < 0.05 compared with LIF alone by ANOVA.

LIF requires p75^LNTR signaling to induce cell death

Apoptosis of sympathetic neurons is mediated, at least in part, by p75^LNTR (Bamji et al., 1998), and it has been suggested that competitivesignaling between TrkA and p75^LNTR determines cell survival. Because of the striking similaritiesbetween LIF-induced apoptosis and neuronal death after NGF deprivation,we questioned whether p75^LNTR participates in LIF-induced death. To address this issue, wecultured sympathetic neurons in the presence of LIF and an antibody(REX) that binds to p75^LNTR and inhibits NGF binding to the receptor (Weskamp and Reichardt,1991) (Fig. 5). Treatment with LIF alone resulted in the deathof 72% of the neurons. However treatment with both LIF and theantibody killed only 15% of the neurons, suggesting that p75^LNTR function is necessary for LIF-induced death. To test this hypothesisfurther, the effects of LIF were examined on neurons culturedfrom animals with a null deletion of the p75^LNTR gene (Fig. 6). Approximately 73% of neurons expressing p75^LNTR (+/+) died in the presence of LIF, whereas <15% of p75^LNTR-deficient ( $-$ / $-$ ) neurons died after treatment with the cytokine.

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Figure 5. p75^LNTR-blocking antibody protects against LIF-mediated neuronal death. P1 sympathetic neurons were treated after 24 hr in vitro with LIF. Sister cultures were treated with both LIF and a p75 ^LNTR-blocking antibody (p75 Ab; REX; 1:100) or with the antibody alone. Treatment with LIF alone led to the death of 72% of the cells compared with control. However treatment with both LIF and the antibody killed only 15% of the neurons, suggesting that p75^LNTR function is necessary for LIF-induced death. *Differs from all other groups at p < 0.05 by ANOVA.

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Figure 6. LIF-induced cell death of cultured sympathetic neurons requires p75 ^LNTR. Sympathetic neurons were cultured from neonatal p75 ^LNTR-deficient ( $-$ / $-$ ) mice and from controls (+/+). After 24 hr in culture the cells were treated with LIF or with vehicle, and cell numbers were determined 48 hr later. Note that exposure to LIF resulted in the death of <25% of the sympathetic neurons derived from newborn p75 ^LNTR-deficient ( $-$ / $-$ ) mice, whereas LIF treatment of neurons from control animals killed ~73% of the cells. *Differs from all other groups at p < 0.05.

LIF requires gp130 signaling to induce cell death

The requirement for p75^LNTR function for LIF-mediated apoptosis raises the question of whether the effects of the factor are mediatedvia classical cytokine receptors. To address this issue, we tookadvantage of the fact that several other cytokines signal viareceptors that share the same LIFR and gp130 subunits that constitutethe LIF receptor but that also require additional $alpha$ subunits.The interleukin 6 (IL6) receptor is comprised of two gp130 subunitsand an IL6 $alpha$ subunit (IL6R). Sympathetic neurons do not expresssignificant levels of the IL6 receptor, and treatment of culturedneurons with IL6 does not induce apoptosis (Fig. 7). The IL6Rin soluble form can be added to cultured cells that express gp130to reconstitute functional receptors (Rose-John and Heinrich,1994). Addition of soluble IL6R alone to cultured sympatheticneurons did not alter survival. However, addition of IL6 alongwith soluble IL6R induced apoptosis, indicating that IL6 onlyinduces apoptosis in the presence of its own receptor. In previousstudies we found that ciliary neurotrophic factor (CNTF) exertsthe same effects as LIF on sympathetic neuron survival (Kessleret al., 1993) (Fig. 7). The CNTF receptor is comprised of thesame gp130 and LIFR subunits as the LIF receptor along with aCNTF $alpha$ subunit that is anchored by a glycosylphosphatidylinositollinkage. This linkage is sensitive to treatment with phosphatidylinositol-specificphospholipase C (PI-PLC) (Davis et al., 1991; Kessler et al.,1993). Sympathetic neurons were therefore treated with PI-PLCbefore treatment with CNTF. Treatment with PI-PLC alone did notalter neuronal survival. However pretreatment with the enzymeprevented neuronal death induced by CNTF (Fig. 7) (Kessler etal., 1993). Thus the effects of CNTF on cell death are mediatedby a receptor sensitive to PI-PLC, suggesting that the classicCNTF receptor is involved.

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Figure 7. Cell death is mediated by classic cytokine receptors. After 24 hr in culture, sympathetic neurons were treated with IL6 (100 ng/ml), soluble IL6 receptor (sIL6R; 200 ng/ml), PI-PLC (1 U/ml), and/or CNTF (100 ng/ml). In PI-PLC-treated cultures, enzyme was added 1 hr before CNTF treatment. Neuron numbers were determined 48 hr later. Note that IL6 induced cell death only in the presence of sIL6R and that PI-PLC pretreatment abolished CNTF-mediated cell death. *These two groups differ from all other groups at p < 0.025 by ANOVA.

LIF treatment does not alter trkA expression or signaling but activates the JNK pathway

Because p75^LNTR activation promotes apoptosis of sympathetic neurons, it was possible that LIF promoted neuronal death by increasingthe levels of p75^LNTR; however Western blot analyses showed no change in the levelsof the receptor after LIF treatment (data not shown). Survivalof sympathetic neurons depends on trkA signaling with consequentsuppression of apoptosis, and inhibition of trkA expression orsignaling represented another possible mechanism underlying LIF-inducedapoptosis. However LIF treatment did not alter levels of trkAmeasured by Western blot analysis, and it did not alter trkA phosphorylation(data not shown). Alternatively it was possible that LIF treatmentaltered activation of mitogen-activated protein kinase (MAPK),but there were no changes in the phosphorylation of MAPK afterLIF treatment (data not shown). However activation of JNK, anothermember of the MAPK family, plays a role both in p75-mediated deathof sympathetic neurons and in death after NGF deprivation (Xiaet al., 1995; Aloyz et al., 1998). We therefore determined whetherLIF treatment of cultured sympathetic neurons leads to JNK activation.JNK activity was not detected in control cultures (Fig. 8) underthe assay conditions. However treatment with LIF significantlyincreased JNK activity at both 6 and 12 hr after LIF exposure(Fig. 8), and JNK activity was similarly increased at these timepoints after NGF deprivation (Fig. 8).

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Figure 8. LIF treatment activates JNK signaling. After 24 hr in culture, sympathetic neurons were treated with LIF or vehicle or deprived of NGF with anti-NGF antibody. At 6 and 12 hr afterward, JNK activity was assayed. Lysates were prepared and subjected to immunoprecipitation/kinase assays using GST-c-jun as a substrate for JNK activity. The experiments were repeated three times with similar results.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neuronal survival during development is regulated by target-derived growth factors that act to suppress apoptosis. Increasingevidence, however, suggests that cell number is also regulatedby cytokines that activate rather than prevent neuronal death.LIF treatment of cultured sympathetic neurons induces apoptosiseven in the presence of NGF (Kessler et al., 1993). Tumor necrosisfactor, which kills a number of cell types outside of the nervoussystem, has been reported to induce cell death of oligodendrogliain culture (Louis et al., 1993). NGF activation of its low-affinityreceptor p75^LNTR also kills cultured oligodendroglia (Casaccia-Bonnefil et al.,1996) and may lead to apoptosis of retinal cells (Frade et al.,1996). Similarly BDNF activation of p75^LNTR induces apoptosis of cultured sympathetic neurons (Bamji et al.,1998). Furthermore, targeted deletion either of the BDNF geneor of the p75^LNTR increases sympathetic neuron number (Bamji et al., 1998), indicatingthat receptor-mediated cell death occurs in vivo as well as inculture. Thus, cell survival may be controlled by the combinedactions of both proapoptotic and antiapoptoticcytokines.

Although cells undergoing apoptosis share a number of stereotyped morphological features, the intracellular pathways mediatingcell death may be quite diverse. For example, Bcl-2 may eitherpromote or inhibit neuronal death depending on the death stimulusand the cellular context. Bcl-2 prevents apoptosis of sympatheticneurons after NGF deprivation (Garcia et al., 1992) and afterLIF treatment (Fig. 2B). By contrast, Bcl-2 promotes the p75^LNTR-mediated death of cultured sensory neurons (Coulson et al., 1999).Furthermore, the same cell may express more than one caspase,and different caspases may be activated by different proapoptoticevents. Apoptosis caused by growth factor deprivation of sympatheticneurons is mediated by the cysteine aspartase Nedd-2, whereasapoptosis of the same cells induced by downregulation of superoxidedismutase involves a different protease (Troy et al., 1997). Inthe present study, we compared some of the intracellular deathpathways activated by LIF in sympathetic neurons with those thatmediate death after NGF deprivation. The results from this studyindicate that these two death signals activate remarkably parallelpathways leading toapoptosis.

Deletion of Bax prevented apoptosis of 85% of the sympathetic neurons in this study and 100% of the neurons in the study byDeckwerth et al. (1996) after NGF deprivation. Furthermore, Baxdeletion prevented death of 70% of the sympathetic neurons inthis study after LIF treatment (Fig. 2A). These findings indicatethat Bax is essential to neuronal death activated either by LIFor the absence of NGF. The protection afforded by Bcl-2 overexpressionfurther supports a role for the Bcl-2 family members in cell deathinduced either by LIF (Fig. 2B) or NGF deprivation (Garcia etal., 1992). Nevertheless 30% of neurons killed by LIF and 15%of neurons deprived of NGF in this study must have died by a Bax-independentpathway. This suggests that each of these insults may activatemore than one pathway leading to cell death. There were also strikingparallels in caspase activation after LIF treatment and NGF deprivation.The nonspecific caspase inhibitor z-vad was protective againstboth types of death signal, indicating the participation of theseproteases in both processes. More important, downregulation ofNedd 2 (caspase 2) rescued neurons from both LIF-induced apoptosisand NGF deprivation, pointing to a requisite role for Nedd 2 incytokine-mediated apoptosis as well as death after growth factordeprivation.

Sympathetic neurons lose their dependence on exogenous factors for survival during postnatal development, and this phenomenonis recapitulated in culture. Thus neurons maintained in culturefor >10 d begin to develop trophic factor independence. At P1only ~10% of neurons survive NGF deprivation, whereas ~25% survivethis insult at P10 (Fig. 1B). By P20 >90% of cultured neuronssurvive in the absence of NGF (Easton et al., 1997) (J. A. Kessler,unpublished observations). We found that the apoptotic responseto LIF is similarly regulated. Treatment of P1 sympathetic neuronswith LIF resulted in death of >80% of the cells. However by day4 in culture only 40% of the cells died in response to LIF, andby day 10 in culture only 10% died (Fig. 1B). By day 15 in cultureLIF did not kill any cells (data not shown). What is the mechanismunderlying the increased resistance to LIF treatment and NGF deprivation?Easton et al. (1997) have shown that NGF-independent, sympatheticneurons grown for 23 d in vitro do not die without trophic supportbecause they have a block at the Bax checkpoint. Interruptionof the death pathways mediated by Bax could thus account for someof the loss of LIF's proapoptotic effects. However a significantportion of LIF-mediated death was not Bax-dependent (Fig. 2A),indicating that additional mechanisms are involved. Nedd-2 immunoreactivitydecreases progressively in SCG neurons from P1 through the adult(data not shown). By P11, expression of Nedd-2 could only be locatedin a small subpopulation of cells, and in the adult expressionof Nedd-2 was almost undetectable in the SCG. Thus the loss ofLIF-mediated death is paralleled by a loss of Nedd-2 expression.Because overexpression of Nedd-2 leads to neuronal death evenin the absence of a death signal (Kessler, unpublished observations),it could not be determined whether reconstituting Nedd-2 expressionwould restore LIF-mediated cell death. Easton et al. (1997) restoredNGF dependence in mature sympathetic neurons in vitro with overexpressionof Bax, which suggests that some functional caspase(s) is stillpresent at that age. Nevertheless it seems likely that downregulationduring development of multiple components of the cell death pathwaysincluding Bax and Nedd-2 underlies the loss of growth factor dependenceand cytokine-mediatedapoptosis.

Deletion of the gene encoding p75^LNTR primarily prevented apoptosis after LIF treatment, implying a requisite role for the receptorin the cell death pathways. Nevertheless several lines of evidenceindicate that the proapoptotic effects of LIF were mediated byinteractions of the cytokine with its own receptor that includestwo subunits, gp130 and LIFR $beta$ . Other cytokines that activate gp130receptor-mediated pathways, such as CNTF, also induce apoptosisof cultured sympathetic neurons (Fig. 7) (Kessler et al., 1993).In the CNTF receptor, the $alpha$ subunit is anchored by a glycosylphosphatidylinositollinkage that is sensitive to treatment with PI-PLC (Davis et al.,1991). Cleavage of this linkage by treatment of sympathetic neuronswith PI-PLC abolished CNTF-mediated apoptosis, indicating thatinteractions with this receptor mediate the cell death response(Fig. 7) (Kessler et al., 1993). Furthermore, sympathetic neuronsdo not express detectable levels of the IL6 receptor subunit anddo not respond to the factor (Fig. 7). However, addition of solubleIL6 receptor to the cultures along with IL6 induced apoptosis(Fig. 7). Because the IL6 receptor complex includes gp130 butnot the LIFR subunit, this indicates that activation of gp130is involved in the cell death pathway. gp130 is expressed by embryonicas well as neonatal sympathetic ganglia, and its signaling playsa number of roles in the developing ganglia (Wong et al., 1995;Murphy et al., 1997; Geissen et al., 1998). For example, the effectsof gp130-mediated signaling on the specification of neurotransmitterphenotype occur in vivo as well as in culture (Patterson and Nawa,1993; Geissen at al, 1998). However multiple cytokines signalvia this receptor complex, and effects on cell survival in vivomay be dependent on the combined concentrations of all such cytokines.For example, targeted deletion of the gene for either LIF or CNTFleads to only minimal changes in motor neuron survival, whereasknock-out of both genes in the same animal leads to a more extensivephenotype (Sendtner et al., 1996). Therefore delineation of theproapoptotic effects of these cytokines on sympathetic neuronsin vivo may require more extensive knowledge of all members ofthe cytokine family that signal via this receptor and of the availabilityof these factors to sympathetic neurons in vivo.

Survival of sympathetic neurons appears to depend on a balance between the antiapoptotic effects of trkA after ligand bindingand the proapoptotic effects of p75^LNTR (Bredesen and Rabizadeh, 1997; Dechant and Barde, 1997; Yoonet al., 1998). LIF treatment of sympathetic neurons does not alterlevels of either trkA or p75^LNTR and does not alter NGF binding (Kessler et al., 1993). Therefore,because all experiments in this study were done in the presenceof NGF, there was ligand bound to p75^LNTR during LIF-mediated cell death. Treatment with the p75^LNTR function-blocking antibody REX (Weskamp and Reichardt, 1991)inhibited LIF-mediated death, implying that NGF binding to thep75^LNTR was in fact necessary for the cytokine-mediated apoptosis. However,it is possible that LIF may stimulate the production of anothermolecule like BDNF, which is known to bind to p75 and cause sympatheticneuronal death (Bamji et al., 1998). Furthermore, deletion ofthe gene encoding p75^LNTR primarily prevented apoptosis after LIF treatment, implying arequisite role for the receptor in the cell death pathways. Theseobservations suggest that p75^LNTR signaling is necessary to prime the cells for the proapoptoticeffects of LIF. LIF treatment thus can be perceived as a signalthat augments the proapoptotic effects of p75^LNTR.

Where do LIF signaling and p75^LNTR signaling converge to promote apoptosis? Because previous studies have shown that p75^LNTR-mediated apoptosis depends on activation of JNK (see Casaccia-Bonnefilet al., 1999), the effects of LIF treatment on JNK activationwere examined. In fact, LIF treatment activated JNK to an extentsimilar to that of NGF deprivation (Fig. 8). It is therefore notsurprising that the same downstream pathways were activated byLIF and by NGF deprivation and that there was a parallel developmentalloss of NGF dependence and the proapoptotic effects ofLIF.

There are several reasons why such controls of cell number might be necessary. First, cytokine-mediated cell death might helpto achieve a balance among multiple populations of neurons thatcompete for the same growth factor in a target. For example, theiris is innervated by two NGF-dependent populations of neurons,sympathetic neurons and trigeminal sensory neurons, that competefor NGF in the iris (Kessler et al., 1983). During the developmentalperiod during which LIF or CNTF kills NGF-dependent sympatheticneurons, these cytokines conversely promote survival of NGF-dependenttrigeminal sensory neurons (Horton et al., 1998). Thus LIF orCNTF might help to eliminate some sympathetic neurons innervatingthe iris to achieve an appropriate balance between sympatheticand sensory fibers competing for NGF. Without such additionalcontrols, sympathetic fibers, which compete effectively for NGFin the iris (Kessler et al., 1983), might prevent sensory innervation,or vice versa. Alternatively factors that promote death of someneuronal subpopulations might help to eliminate cells that migrateerrantly or that project to incorrect targets. If such aberrantcells encountered NGF, they might persist in the absence of othersignals to eliminate them. Although high doses of LIF were usedin this study to maximize stimulation of the cell death pathways,much lower doses (~1 nM $---$ approximately the same as the concentrationsof NGF necessary for optimal survival) are sufficient to promotedeath of some neurons (Kessler et al., 1993). However some neuronssurvived even in the presence of the high doses of the cytokine,indicating that there is heterogeneity among sympathetic neuronswith respect to responses to LIF. Such heterogeneity could helpto explain why some neurons survive and others die in ostensiblysimilar cellular milieus in vivo.

  FOOTNOTES

Received Aug. 18, 1999; revised March 17, 2000; accepted March 23, 2000.

This work was supported by National Institutes of Health Grants RO1 20778 and RO1 20013 (J.A.K.). S.I.S. was supported bya Howard Hughes Medical Student ResearchFellowship.
Correspondence should be addressed to Dr. J. A. Kessler, Departments of Neurology and Neuroscience, Albert Einstein Collegeof Medicine, 1300 Morris Park Avenue, Bronx, NY 10461. E-mail:kessler{at}aecom.yu.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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