Differential Susceptibility to Neurotoxicity Mediated by Neurotrophins and Neuronal Nitric Oxide Synthase

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Volume 17, Number 12, Issue of June 15, 1997 pp. 4633-4641
Copyright ©1997 Society for Neuroscience

Differential Susceptibility to Neurotoxicity Mediated by Neurotrophins and Neuronal Nitric Oxide Synthase

Amer F. Samdani¹, Cheryl Newcamp¹, Annelies Resink¹, Fabrizio Facchinetti¹, Brian E. Hoffman¹, Valina L. Dawson¹^,²^,³, and Ted M. Dawson¹^,²
Departments of ¹ Neurology, ² Neuroscience, and ³ Physiology, Johns Hopkins University School of Medicine, Baltimore, Maryland 21287

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

NMDA neurotoxicity, which is mediated, in part, by formation of nitric oxide (NO) via activation of neuronal NO synthase (nNOS),is modulated by neurotrophins. nNOS expression in rat and mouseprimary neuronal cultures grown on a glial feeder layer is significantlyless than that of neurons grown on a polyornithine (Poly-O) matrix.Neurotrophins markedly increase the number of nNOS neurons, nNOSprotein, and NOS catalytic activity and enhance NMDA neurotoxicityvia NO-dependent mechanisms when neurons are grown on glial feederlayers. In contrast, when rat or mouse primary cortical neuronsare grown on a Poly-O matrix, neurotrophins have no influenceon nNOS neuronal number or NOS catalytic activity and reduce NMDAneurotoxicity. Primary neuronal cultures from mice lacking nNOSgrown on a glial feeder layer fail to respond to neurotrophin-mediatedenhancement of neurotoxicity. Together, these results indicatethat nNOS expression and NMDA NO-mediated neurotoxicity are dependent,in part, on the culture paradigm, and neurotrophins regulate thesusceptibility to NMDA neurotoxicity via modulation of nNOS. Furthermore,these results support the idea that NMDA neurotoxicity in cultureis critically dependent on the developmental state of the neuronsbeing assessed and suggest that, when cortical neurons are culturedon a glial feeder layer, they do not reach nearly as mature aphenotype as when grown on a Poly-O matrix.
Key words: neurotrophins; growth factors; excitotoxicity; glutamate; NMDA; nitric oxide

INTRODUCTION

Neurotrophins consist of a family of growth factors, including nerve growth factor (NGF), brain-derived neurotrophic factor(BDNF), neurotrophin-3 (NT-3), and neurotrophin-4/5 (NT-4/5),which act on high-affinity receptor tyrosine kinases, TrkA, TrkB,and TrkC, to promote neurite extension, neuronal survival, anddifferentiation (Barde, 1994; Barbacid, 1995; Thoenen, 1995).Other growth factors such as glial-derived neurotrophic factor(GDNF), ciliary neurotrophic factor (CNTF), insulin-like growthfactor (IGF-1), and transforming growth factor- $beta$ (TGF- $beta$ ) alsoinfluence neuronal survival and differentiation (Lindsay, 1994;Birling and Price, 1995). Besides having a role in neuronal differentiationand survival, neurotrophins can attenuate neuronal cell deathcaused by excitotoxins, glucose deprivation, and ischemia (Shigenoet al., 1991; Davies and Beardsall, 1992; Frim et al., 1993; Burkeet al., 1994; Cheng and Mattson, 1994; Lindholm, 1994; Mattsonet al., 1995; Nakao et al., 1995; Anderson et al., 1996). Despitethe abundance of in vitro and in vivo data that neurotrophinsenhance the survival of neurons after neuronal injury, Choi andcollaborators recently provided provocative data that neurotrophinsunder certain conditions enhance excitotoxic insults (Koh et al.,1995).

Nitric oxide (NO) is an important biological messenger with many diverse physiological actions throughout the body (Nathan,1992; Schmidt and Walter, 1994; Yun et al., 1996). NO is synthesizedfrom L-arginine by NO synthase (NOS), of which three isoformshave been identified, representing the products of three distinctgenes that include neuronal NOS (nNOS, Type 1), immunologicalNOS (iNOS, Type 2), and endothelial NOS (eNOS, Type 3) (Bredtand Snyder, 1994; Marletta, 1994; Nathan and Xie, 1994). Neurotoxicityelicited by glutamate acting via NMDA receptors is mediated, inpart, by excess production of NO by nNOS (Dawson and Snyder, 1994;Dawson and Dawson, 1996). NMDA neurotoxicity in primary cerebralcortical cultures is prevented by a variety of NOS inhibitors(V. Dawson et al., 1991, 1993; T. Dawson et al., 1993, 1995),and cortical cultures from nNOS-deficient (nNOS) mice are resistant to neurotoxicity (Dawson et al., 1996). Theseresults have been replicated independently in various other culturesystems (for review, see Dawson and Snyder, 1994; Dawson and Dawson,1996). However, some difficulties in replicating these findingsmay relate to inadequate expression of nNOS neurons in the culturesused (Hewett et al., 1994).

nNOS expression is increased after NGF treatment in PC-12 cells (Hirsch et al., 1993; Peunova and Enikolopov, 1995) and inrat spinal cord after treatment with BDNF, NT-3, and NT-4 (Huberet al., 1995) and basal forebrain cholinergic neurons (Holtzmanet al., 1994, 1996). Because nNOS expression is regulated by neurotrophins,we wondered whether the potentiation of excitotoxicity by neurotrophinsis mediated via increases in nNOS expression. We now show thatnNOS levels and NO-dependent neurotoxicity are critically dependenton the culture paradigm. Neurons grown on a glial feeder layerexpress low levels of nNOS and do not exhibit NO-dependent neurotoxicity,whereas neurons grown on a polyornithine (Poly-O) matrix expresshigh levels of nNOS and exhibit NO-dependent neurotoxicity inresponse to NMDA. Moreover, we show that neurotrophin enhancementof NMDA neurotoxicity occurs via increases in nNOS when neuronsare grown on a glial feeder layer, whereas neurotrophins are neuroprotectivewhen neurons are grown on a Poly-O matrix.

MATERIALS AND METHODS
Cell culture. Primary cortical cultures were prepared from gestational day 16 fetal Sprague Dawley rats and C57BL6 mice ina procedure modified from that described previously (V. Dawsonet al., 1991, 1993). Briefly, the cortex from fetal mice was dissected,and the cells were dissociated by trituration in modified Eagle'smedium (MEM), 20% horse serum, 25 mM glucose, and 2 mM L-glutamineafter a 30 min digestion in 0.027% trypsin/saline solution. Cortexfrom fetal rats was dissociated by trituration in MEM, 10% fetalbovine serum, 10% horse serum, and 2 mM L-glutamine after a 30min digestion in 0.027% trypsin/saline solution. The cells wereplated on 15 mm multiwell plates coated with polyornithine (Poly-O)or a glial layer. At 4 d after plating, the cells were treatedwith 5-fluoro-2-deoxyuridine for 3 d to inhibit proliferationof non-neuronal cells. Cultures derived from mice then were maintainedin MEM, 10% horse serum, 25 mM glucose, and 2 mM L-glutamine inan 8% CO₂-humidified 37°C incubator. Rat cultures then were maintainedin MEM, 5% horse serum, and 2 mM L-glutamine in an 8% CO₂-humidified37°C incubator. The growth medium was refreshed twice per week,and the neurons were allowed to mature for 14 d in culture beforebeing used for experiments. Glia were cultured from 0-3 d postnatalrats and mice. The procedure was as above for primary neuronalcultures except that the cells were plated on 75 mm² flasks. After 2 weeks of maturation in vitro, they were platedonto 15 mm multiwell plates and allowed to reach confluence (3-5d).

Neurotrophic growth factor treatment. On day in vitro (DIV) 13 the cells were treated with 100 ng/ml of BDNF, GDNF, NT-3,NT-4, or NGF. Neurotrophic factors were obtained from Intergen(Purchase, NY). Experiments were performed on DIV 14.

Cytotoxicity. The cells were exposed to excitotoxic conditions as described previously (V. Dawson et al., 1991, 1993). Beforeexposure, the cells were washed with Tris-buffered control saltsolution (CSS), pH 7.4, containing (in mM): 120 NaCl, 5.4 KCl,1.8 CaCl₂, 25 Tris-HCl, and 15 glucose. The exposure solutionswere administered briefly (5 min) and then washed off. Then thecells were placed in MEM with 21 mM glucose and returned to theincubator overnight.

Toxicity was assayed 20-24 hr after exposure to cytotoxic conditions by trypan blue exclusion (0.4% trypan blue in CSS) asdescribed previously (V. Dawson et al., 1991, 1993). Both livecells (cells that exclude trypan blue and are raised dots underHoffman modulation optics) and dead cells (cells that take uptrypan blue and are flat under Hoffman modulation optics) werecounted. The percentage of cell death was determined as the ratioof live to dead cells, as compared with the percentage of deathin control wells, to account for cell death attributable to mechanicalstimulation of the cultures. At least two separate experimentsusing four separate wells were performed, with a minimum of 4000-12,000neurons counted per data point. The data were collected and countedby an observer blinded to the treatment protocol.

Data were analyzed with a one-way ANOVA and Fisher's protected least significance difference post hoc test.

NOS catalytic activity. Cortical cultures were washed with CSS and homogenized in 50 µl of 50 mM Tris-HCl buffer, pH 7.4,containing 2 mM EDTA. Homogenates were centrifuged (1400 × g)for 15 min at 4°C. NOS catalytic activity was assayed by monitoringthe conversion of [³H]arginine to [³H]citrulline, as described (Bredt and Snyder, 1990). Tissue supernatant(25 µl) was added to 100 µl of a solution containing 0.1 µCi [³H]arginine and 1 mM NADPH. CaCl₂ (10 µl) to a final concentrationof 2.25 mM was added to start the assay, and the samples wereincubated for 15 min at room temperature. The assay was terminatedby the addition of 3 ml of HEPES buffer, pH 5.5, containing 2mM EDTA, and incubates were applied to 0.5 ml of DOWEX AG 50WX-8(Dow-Corning, Midland, MI) (Na⁺ form) columns to separate [³H]citrulline (eluate) from [³H]arginine. [³H]citrulline was quantified by liquid scintillation counting ofthe eluate. Data were expressed as the percentage of [³H]citrulline formation above the basal (no CaCl₂ added).

Immunoblotting. Cell cultures were collected in 100 µl of Tris-HCl buffer, pH 7.4, containing 2 mM EDTA, 1 mM $beta$ -mercaptoethanol,1 mM PMSF, 1 mM benzamide, and 10 µg/ml leupeptin. The contentsof one well were loaded per lane into a 8% polyacrylamide gel.After electrophoresis and nitrocellulose membrane transfer, themembranes were incubated overnight with a primary nNOS monoclonalantibody (Transduction Labs, Lexington, KY). The primary antibodywas diluted 1:1000 in 3% bovine serum albumin/0.1% Tween 20 inphosphate buffer (PB), pH 7.4. Subsequently, nitrocellulose membraneswere incubated for 3 hr with the secondary antibody (1:5000) atroom temperature in 5% nonfat milk in PB, pH 7.4. The labeledbands were visualized by chemiluminescence (Kirkegaard & Perry,Gaithersburg, MD).

NADPH diaphorase staining. Cells were washed three times with CSS and fixed for 30 min at 4°C in a 4% paraformaldehyde (PF),0.1 M PB. The PF solution was washed away with Tris-buffered saline(TBS): 50 mM Tris-HCl and 1.5% NaCl, pH 7.4. The reaction solution,containing 1 mM NADPH, 0.2 mM nitroblue tetrazolium, 0.2% TritonX-100 (TX-100), 1.2 mM sodium azide, and 0.1 M Tris-HCl, pH 7.2,was applied to the fixed cell cultures for 1 hr at 37°C (T. Dawsonet al., 1991; V. Dawson et al., 1993). The reaction was terminatedby washing away the reaction solution with TBS. All diaphorase-positivecells in each well were counted with an inverted microscope.

RESULTS

Culture-dependent regulation of nNOS expression
We compared nNOS levels in rat cortical neurons grown on a glial layer versus neurons grown on a Poly-O matrix (Fig. 1). Neuronsgrown on a glial layer express negligible levels of nNOS neurons,as indicated by NADPH-diaphorase staining (Fig. 1A). This is instark contrast to neurons grown on a Poly-O matrix in which 1-2%of the total neuronal population expresses nNOS, as indicatedby NADPH-diaphorase staining (Fig. 1B). The number of nNOS neuronsis enhanced markedly by a 24 hr treatment with BDNF (100 ng/ml)in cultures grown on a glial layer, whereas there is no significantincrease in the number of nNOS neurons in cultures grown on thePoly-O matrix (Fig. 1C,D).
Fig. 1. Culture-dependent regulation of nNOS expression. Shown are Hoffman modulation photomicrographs of cortical neurons stainedwith NADPH-diaphorase depicting neuronal nitric oxide synthase(nNOS) neurons 24 hr after treatment with brain-derived neurotrophicfactor (BDNF; 100 ng/ml). A, B, Control cultures grown eitheron a glial layer or a polyornithine (Poly-O Matrix) matrix, respectively.C, D, Cultures that were treated for 24 hr with 100 ng/ml BDNF.Neurons cultured on a glial layer express negligible levels ofnNOS neurons, the expression of which is increased markedly withBDNF treatment (A, C). Neurons cultured on a Poly-O matrix havea relatively higher expression of nNOS neurons (arrowheads), whichis unchanged with BDNF treatment (B, D).
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Neurotrophin regulation of nNOS expression in cortical cultures
Previously we showed that nNOS expression is enhanced by NGF treatment in PC-12 cells (Hirsch et al., 1993). Neurotrophinsincrease the number of detectable nNOS-expressing neurons, asindicated by NADPH-diaphorase staining in cultures grown on aglial feeder layer (Fig. 2A). BDNF increases the number of nNOSneurons approximately four- to fivefold over control values. GDNFincreases the number of nNOS neurons by approximately fourfold,NT-3 and NT-4 increase the number of nNOS neurons by approximatelythreefold, and NGF fails to influence significantly the numberof nNOS neurons in cultures grown on a glial feeder layer (Fig.2A). Western blot analysis for nNOS protein and assessments ofnNOS catalytic activity by measuring the conversion of [³H]arginine to [³H]citrulline yield similar results, with BDNF being the most potentinducer of nNOS expression in cortical neurons grown on a gliallayer (Fig. 2B,C). Neurotrophins seem to increase both the numberof nNOS neurons and the amount of nNOS protein. However, we cannotmake definitive statements whether the increase in nNOS proteinis from increased nNOS protein per neuron and/or a reflectionof more nNOS neurons.
Fig. 2. Neurotrophins enhance nNOS expression in cortical neurons grown on a glial layer. A, Pretreatment (24 hr) with neurotrophins(100 ng/ml) markedly enhances the number of nNOS neurons, as indicatedby NADPH-diaphorase staining of cortical neurons. Each data pointrepresents the mean ± SEM (n = 8-12) of at least two separateexperiments. *p < 0.0001 for NT-3, NT-4, GDNF, and BDNF, as comparedwith control cultures. NGF is not significantly different fromcontrol. B, Neurotrophins increase the amount of nNOS protein,as measured by Western blot analysis. C, A parallel increase inNOS catalytic activity is observed. p < 0.02 for NT-3, NT-4, GDNF, and BDNF, as compared with controlcultures. Each data point represents the mean ± SEM of at leasttwo separate experiments performed in duplicate.
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Cortical neurons grown on a Poly-O matrix express a significantly higher quantity of nNOS neurons (Fig. 3A). nNOS neurons,as indicated by NADPH-diaphorase staining, comprise ~1-2% of thetotal neuronal population, consistent with the adult phenotype(Bredt et al., 1991; T. Dawson et al., 1991; Vincent and Kimura,1992). BDNF treatment does not influence the total number of nNOSneurons (Fig. 3A) or nNOS catalytic activity (Fig. 3C), but BDNFincreases the amount of nNOS protein, as indicated by Westernblot analysis (Fig. 3B).
Fig. 3. Neurotrophins do not enhance expression of nNOS in cortical neurons grown on a polyornithine (Poly-O) matrix. A, Corticalneurons grown on a Poly-O matrix express a significantly higherquantity of nNOS neurons, as indicated by NADPH-diaphorase staining,than cortical neurons grown on a glial layer. Pretreatment (24hr) with BDNF does not influence the total number of nNOS neurons.Each data point represents the mean ± SEM (n = 8-12) of at leasttwo separate experiments. B, BDNF increases the amount of nNOSprotein, as measured by Western blot analysis; however, (C) nNOScatalytic activity remains unchanged. Each data point representsthe mean ± SEM of at least two separate experiments performedin duplicate. The number of NADPH-diaphorase neurons and NOS catalyticactivity in BDNF-treated cultures is not significantly differentfrom controls.
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Increases in nNOS levels mediate potentiation of NMDA neurotoxicity by neurotrophins
Rat cortical cultures grown on a glial layer are susceptible to NMDA (500 µM) neurotoxicity, with ~20% cell death above controlvalues (Fig. 4A). This neurotoxicity is not influenced by thecompetitive nNOS inhibitor nitroarginine-methyl ester (LNAME;500 µM) or by excess L-arginine (LARG; 5 mM). Treatment of corticalcultures grown on glial layers with BDNF (100 ng/ml) for 24 hrmarkedly enhances NMDA neurotoxicity, as previously shown (Kohet al., 1995). This marked enhancement of neurotoxicity is NO-dependent,because LNAME completely prevents the enhancement of NMDA neurotoxicityby BDNF and LARG reverses the neuroprotective effects of LNAME(Fig. 4A). An equivalent amount of NMDA-mediated neurotoxicityis observed in cortical cultures grown on a Poly-O matrix, ascompared with neurons grown on a glial layer treated with BDNF(Fig. 4B). NMDA neurotoxicity in cortical cultures grown on Poly-Omatrix is also NO-dependent, because LNAME blocks the neurotoxicityand the attenuation of neurotoxicity is reversed completely bythe substrate LARG (Fig. 4B). Consistent with previous observations,BDNF attenuates the neurotoxic response to NMDA by ~50%. The residualneurotoxicity is dependent partially on NO, because LNAME attenuatesthis neurotoxicity and LARG reverses the protective effects ofLNAME (Fig. 4B).
Fig. 4. Increases in nNOS levels mediate potentiation of NMDA neurotoxicity by neurotrophins. A, Rat cortical neurons grown on a gliallayer exhibit NMDA-mediated (NMDA; 500 µM) neurotoxicity, whichis not influenced by the competitive nNOS inhibitor nitroarginine-methylester (LNAME; 500 µM) or by excess L-arginine (LARG; 5 mM). Pretreatment(24 hr) with BDNF (100 ng/ml) markedly enhances NMDA (500 µM)neurotoxicity (p < 0.0001), which is prevented with LNAME (500 µM; ^§p < 0.0001), and LARG (5 mM;p < 0.0001) reverses this neuroprotection. B, Cortical neuronsgrown on a Poly-O matrix demonstrate an equivalent amount of NMDAneurotoxicity to that observed in cortical neurons grown on aglial layer and pretreated with BDNF (100 ng/ml). This neurotoxicityis also NO-dependent (*p < 0.0001). BDNF treatment of neuronsgrown on a Poly-O matrix attenuates the neurotoxic response toNMDA (500 µM) by ~50% (p < 0.0001). LNAME (500 µM;^§p < 0.05) provides further protection, and LARG (5 mM;p < 0.0001) reverses this protection. Each data point representsthe mean ± SEM (n = 6-12) of at least two separate experiments;a minimum of 4000-10,000 neurons was counted.
[View Larger Version of this Image (37K GIF file)]

Culture-independent sensitivity to NO neurotoxicity
To assess whether neurons grown on a glial layer versus neurons grown on a Poly-O matrix are differentially vulnerable tothe toxic effects of NO, we examined neurotoxicity in responseto the NO donor sodium nitroprusside (SNP; Fig. 5). Both neuronalculture systems are equally sensitive to the toxic effects ofSNP, with 300 µM SNP killing ~50% of the neurons and 1 mM SNPkilling ~90-100% of the neurons. BDNF treatment of neurons grownon glial layers does not influence the susceptibility to SNP neurotoxicity,whereas neurons grown on the Poly-O matrix are less susceptibleto the toxic effects of 500 µM SNP (Fig. 5).
Fig. 5. Culture-independent sensitivity to NO neurotoxicity. Cultures were exposed to increasing concentrations of the NO donor sodiumnitroprusside (SNP Concentration). Both neuronal culture systemsare equally sensitive to the toxic effects of SNP. SNP depletedof NO by preincubating in culture media for 24 hr has no intrinsictoxicity. Pretreatment (24 hr) with BDNF (100 ng/ml) does notinfluence SNP toxicity in cortical neurons grown on a glial layer;however, cortical neurons grown on a Poly-O matrix are less susceptibleto the toxic effect of 500 µM SNP (*p < 0.001). Each data pointrepresents the mean ± SEM (n = 4-6) of at least two separate experiments;a minimum of 4000-8000 neurons was counted.
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Neurotrophin-mediated enhancement of NMDA neurotoxicity is prevented in nNOS mice
Similar to the observations in rat cortical cultures, we observe the same enhancement of NMDA neurotoxicity by BDNF in murinecortical cultures grown on glial layers and a protective effectof BDNF on murine cortical cultures grown on Poly-O matrix (Fig.6A,B). BDNF enhancement of NMDA neurotoxicity in neurons grownon glial layers is NO-dependent, and NMDA neurotoxicity in corticalcultures grown on Poly-O matrix is also NO-dependent (Fig. 6A,B).To explore and confirm the potential role of induction of nNOSby BDNF as the mediator of enhancement of neurotoxicity by neurotrophins,we examined the response of cortical cultures obtained from nNOS mice (Huang et al., 1993) (Fig. 7). As previously shown, nNOS cortical cultures are markedly resistant to NMDA neurotoxicity(Dawson et al., 1996), and BDNF fails to enhance NMDA neurotoxicityin nNOS cortical cultures grown on glial layers (Fig. 7A). BDNF alsofails to provide additional protective effects to NMDA neurotoxicityin nNOS cortical cultures grown on a Poly-O matrix (Fig. 7B).
Fig. 6. Increases in nNOS levels mediate potentiation of NMDA neurotoxicity by neurotrophins. A, Murine cortical neurons grown ona glial layer exhibit NMDA-mediated (NMDA; 500 µM) neurotoxicity,which is not influenced by the competitive nNOS inhibitor nitroarginine-methylester (LNAME; 500 µM) or by excess L-arginine (LARG; 5 mM). Pretreatment(24 hr) with BDNF (100 ng/ml) markedly enhances NMDA (500 µM)neurotoxicity (p < 0.0001), which is prevented with LNAME (500 µM; ^§p < 0.0001), and LARG (5 mM;p < 0.0001) reverses this neuroprotection. B, Cortical neuronsgrown on a Poly-O matrix demonstrate an equivalent amount of NMDA(500 µM) NO-dependent neurotoxicity (*p < 0.0001) to that observedin cortical neurons grown on a glial layer pretreated with BDNF(100 ng/ml). BDNF treatment of neurons grown on a Poly-O matrixattenuates the neurotoxic response to NMDA (500 µM) by ~50% (p < 0.0001), LNAME (500 µM; ^§p < 0.01) provides further protection, and LARG (5 mM;p < 0.0001) reverses this protection. Each data point representsthe mean ± SEM (n = 6-12) of at least two separate experiments;a minimum of 4000-10,000 neurons was counted.
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Fig. 7. Neurotrophin-mediated enhancement of NMDA neurotoxicity is prevented in nNOS mice. A, nNOS cultures are markedly resistant to NMDA neurotoxicity, and BDNF(100 ng/ml) fails to enhance NMDA neurotoxicity in cortical culturesgrown on a glial layer. B, BDNF fails to provide neuroprotectionto cortical neurons grown on a Poly-O matrix. Each data pointrepresents the mean ± SEM (n = 6-12) of at least two separateexperiments; a minimum of 4000-10,000 neurons was counted. Noneof the determinations is statistically different from another.
[View Larger Version of this Image (30K GIF file)]

DISCUSSION
This study provides several lines of evidence indicating that increased nNOS expression mediates, in part, neurotrophin enhancementof NMDA neurotoxicity. Cortical cultures grown on glial layersfrom both rats and mice express relatively low levels of nNOSand are relatively resistant to the toxic effects of NMDA. BDNF,as well as a variety of other growth factors, markedly enhancesthe expression of nNOS in cortical cultures grown on glial layers,as evidenced by the greater number of NADPH-diaphorase stainingneurons, increased levels of nNOS protein by Western blot analysis,and increased nNOS catalytic activity. Accompanying the increasein nNOS, following BDNF treatment of cortical cultures grown onglial layers, is a NO-dependent component to NMDA neurotoxicity.This neurotoxicity is attenuated by the competitive NOS inhibitor,LNAME, and this neuroprotection is reversed by the NOS substrate,LARG. Moreover, cortical cultures from mice lacking nNOS grownon glial layers are resistant to the potentiation of NMDA neurotoxicityby BDNF pretreatment. Together, these observations establish nNOSinduction as a major mediator of neurotrophin enhancement of NMDAneurotoxicity when cortical neurons are grown on a glial monolayer.

NMDA neurotoxicity is thought to be involved in ischemic stroke damage, because NMDA receptor antagonist decreases infarctvolume after middle cerebral artery occlusion (Choi, 1988; Choiand Rothman, 1990; Meldrum and Garthwaite, 1990; Lipton and Rosenberg,1994). NO may play a major role in NMDA neurotoxicity, becausea variety of NOS inhibitors blocks NMDA neurotoxicity in corticalcultures (Dawson and Snyder, 1994; Dawson and Dawson, 1996). Furthermore,neuronal cultures from mice lacking the gene for nNOS are markedlyresistant to the toxic effects of NMDA (Dawson et al., 1996).NO-mediated neurotoxicity seems to be specific for NMDA receptoractivation, because neurotoxicity elicited by kainate or AMPAreceptor activation is resistant to neuroprotection by NOS inhibitors(V. Dawson et al., 1993). A role for NO in NMDA neurotoxicityis supported by several in vivo studies in which stroke damage(Dalkara and Moskowitz, 1994; Iadecola, 1997), mitochondrial toxin-inducedstriatal injury (Schulz et al., 1995a), and MPTP neurotoxicityare reduced with selective nNOS inhibitors (Schulz et al., 1995b;Przedborski et al., 1996). In addition, there is substantial reductionfrom injury to these insults in the brains of nNOS mice (Huang et al., 1994; Przedborski et al., 1996; Schulz etal., 1996). Despite the abundance of data implicating NO in NMDAneurotoxicity, there have been some difficulties in replicatingthese findings. A majority of the difficulties in the in vivostudies probably are related to the initial use of drugs thatelicited nonspecific effects. Most NOS inhibitors block all threeisoforms and, when administered in vivo, inhibit eNOS, raisingblood pressure and reducing cerebral blood flow (Dalkara and Moskowitz,1994; Iadecola, 1997). The initial discrepancies in the in vivostudies have been clarified by the use of relatively selectivenNOS inhibitors (Dalkara and Moskowitz, 1994; Iadecola, 1997)as well as the studies in mice lacking the gene for nNOS (Huanget al., 1994). On the other hand, differences in the potentialrole of NO in NMDA neurotoxicity in in vitro culture systems hasyet to be clarified. Our results indicate that a NO componentto NMDA neurotoxicity is critically dependent on the number ofnNOS neurons and the level of nNOS protein. The expression ofnNOS is critically dependent on the culture condition used, inthat neurons grown on glial layers contain relatively low levelsof nNOS, whereas neurons grown on a Poly-O matrix tend to containhigh levels of nNOS. nNOS originally was thought to be a constitutivelyexpressed enzyme. However, recent studies indicate that nNOS proteinlevels can increase after a variety of toxic insults as well asneuronal injury (Solodkin et al., 1992; Roskams et al., 1994;Wu et al., 1994; Zhang et al., 1994; Verge et al., 1995). Theupregulation of nNOS by growth factors may play a role in nNOSinduction after injury as a number of these factors are induced(Funakoshi et al., 1993; Lindvall et al., 1994; Kokaia et al.,1995). In PC-12 cells the induction of nNOS after NGF administrationis thought to be important in the growth arrest of PC-12 cellsand may subserve a role in neuronal differentiation (Peunova andEnikolopov, 1995) as well as attainment of a fully differentiatedneuronal phenotype (Hirsch et al., 1993). The molecular mechanismsunderlying the upregulation of nNOS are not known. Recently, thepromoter region for human nNOS has been characterized (Hall etal., 1994). Growth factors induce a variety of transcription factors,including AP-1 and the cyclic AMP-responsive element (Gaiddonet al., 1996), and the nNOS promoter region contains these DNAbinding motifs.

Choi and collaborators used neuronal cultures grown on glial layers to demonstrate neurotrophin enhancement of necrotic celldeath pathways induced by oxygen glucose deprivation or neurotoxicconcentrations of NMDA (Koh et al., 1995). Oxygen glucose deprivationis a useful model of vascular stroke. Neurotoxicity after oxygenglucose deprivation in cultures involves NMDA receptor activation(Choi, 1993) and is mediated primarily by activation of nNOS andoverproduction of NO (Dawson et al., 1996). We now confirm theseobservations and show that the enhancement of NMDA neurotoxicityby neurotrophins is mediated partially via the increased expressionof nNOS. This effect is observed only when neurons are grown ona glial layer. In addition, neurotrophins can affect other cellularsystems, such as calcium regulation and upregulate glutamate receptors,which also may contribute to the increased vulnerability of neuronsto excitotoxicity (Collazo et al., 1992; Mattson et al., 1993;Cheng et al., 1995). Recent studies suggest that microglia couldcontribute to the excitotoxic injury to neurons via an indirectmechanism probably secondary to neurocytokine interactions andinduction of iNOS (Hewett et al., 1994). Neurons grown on boththe glial layer and Poly-O matrix would have microglia becausemeasures were not taken to exclude microglia from the cultureparadigms; thus we cannot exclude the possibility that neurotrophin-mediatedenhancement of excitotoxicity is attributable to indirect actionsof microglia. If microglia are contributing to the enhancementof excitotoxicity, it is unlikely to be via activation of iNOS,because cultures lacking nNOS fail to exhibit neurotrophin-mediatedenhancement of excitotoxic injury. When neurons are grown on aPoly-O matrix, BDNF pretreatment is neuroprotective, consistentwith numerous previous reports of the protective role of neurotrophins(Mattson et al., 1989, 1995; Fernandez-Sanchez and Novelli, 1993;Nozaki et al., 1993; Prehn et al., 1993; Burke et al., 1994; Chengand Mattson, 1994; Cheng et al., 1994; Lindholm, 1994; Lindvallet al., 1994; Nakao et al., 1995; Anderson et al., 1996). Thus,the phenotype of neuronal cultures is influenced markedly by theculture paradigm. When neurons are grown on a glial layer, theyare being exposed to glia that are ~2-3 weeks older in age, whereasneurons grown on Poly-O matrix are exposed to glia that are atthe same developmental time point. It is likely that neurons andglia signal to each other during development and differentiationand that neurons grown on glial layers do not receive the propersignaling and may remain in a more immature fetal-like state.It is likely that glia of different ages secrete various "factors"that alter the phenotype of the neurons. Consistent with thisnotion is our observation that conditioned media obtained fromglial feeder layers can inhibit completely the nNOS expressionof neurons grown on a Poly-O matrix (A. Samdani, V. L. Dawsonand T. M. Dawson, unpublished observations). To our knowledgethere is no demonstration that neurotrophins enhance the susceptibilityto neuronal injury in in vivo studies. Thus, neuronal culturesgrown on a Poly-O matrix may represent more accurately the phenotypeof the in vivo neuronal population. Moreover, when neurons aregrown on a Poly-O matrix, the level of nNOS expression more accuratelyrepresents the adult phenotype.

Numerous studies indicate that neurotrophins are neuroprotective after a variety of toxic insults (Burke et al., 1994; Chenget al., 1994; Lindholm, 1994; Lindvall et al., 1994; Mattson etal., 1995; Nakao et al., 1995; Anderson et al., 1996). We observesimilar neuroprotective properties when neurons are grown on aPoly-O matrix. Pretreatment of cortical cultures grown on a Poly-Omatrix with BDNF reduces both NMDA neurotoxicity and SNP neurotoxicity.The mechanisms of neurotrophin-mediated neuroprotection are notknown. However, recent studies indicate that neurotrophin treatmentmay stabilize intracellular calcium levels as well as preventapoptotic death programs (Collazo et al., 1992; Barde, 1994; Barbacid,1995; Levine et al., 1995; Thoenen, 1995; Tazi et al., 1996).Peptide growth factors may protect against ischemic toxicity inculture by preventing NO toxicity (Maiese et al., 1993). Theyalso prevent peroxynitrite-mediated apoptosis (Estevez et al.,1995). Furthermore, neurotrophins are trophic and may allow neuronsto recover from toxic insults (Hefti, 1986; Tuszynski et al.,1990; Yan et al., 1992; Koliatsos et al., 1993; Widmer et al.,1993; Friedman et al., 1995). Alternatively, neurotrophins couldinduce other neuroprotective proteins and factors that play anas yet undetermined important role.

FOOTNOTES

Received Jan. 22, 1997; revised March 21, 1997; accepted April 3, 1997.

This work was supported in part by United States Public Health Service Grants NS 33277 and NS 01578 and the InternationalLife Sciences Institute to T.M.D., and United States Public HealthService Grant NS 33142 and the National Alliance on Research forSchizophrenia to V.L.D. A.F.S. is a recipient of the Howard HughesMedical Student In-Residence Research Fellowship and the HaroldLamport Research Grant. We thank Ann Schmidt for secretarial assistance,Allen Mandir for assistance with the statistical analyses, andRegeneron Pharmaceuticals, Tarreytown, NY, for a portion of theBDNF used in this study.

Under an agreement between the Johns Hopkins University and Guilford Pharmaceuticals, T.M.D. and V.L.D. are entitled to ashare of sales royalty received by the University from Guilford.T.M.D. and the University also own Guilford stock, which is subjectto certain restrictions under University policy. The terms ofthis arrangement have been reviewed and approved by the Universityin accordance with its conflict of interest policies.

Correspondence should be addressed to Dr. Ted M. Dawson, Department of Neurology and Neuroscience, Johns Hopkins UniversitySchool of Medicine, Pathology 2-210, 600 North Wolfe Street, Baltimore,MD 21287.

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