Multiple Actions of Neurturin Correlate with Spatiotemporal Patterns of Ret Expression in Developing Chick Cranial Ganglion Neurons

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The Journal of Neuroscience, October 1, 1999, 19(19):8476-8486

Multiple Actions of Neurturin Correlate with Spatiotemporal Patterns of Ret Expression in Developing Chick Cranial Ganglion Neurons
Eri Hashino¹^,², Eugene M. Johnson Jr³, Jeffrey Milbrandt⁴, Marlene Shero², Richard J. Salvi², and Christopher S. Cohan¹^,²
¹ Department of Anatomy and Cell Biology and ² Center for Hearing and Deafness, State University of New York at Buffalo, Buffalo, New York 14214, and Departments of ³ Neurology, Molecular Biology, and Pharmacology and ⁴ Pathology and Internal Medicine, Washington University School of Medicine, St. Louis, Missouri 63110

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neurotrophic effects of neurturin (NRTN) on chick cranial ganglia were evaluated at various embryonic stages in vitroand related to its receptor expression. NRTN promoted the outgrowthand survival of ciliary ganglion neurons at early embryonic (E)stages (E6-E12), trigeminal ganglion neurons at midstages (E9-E16),and vestibular ganglion neurons at late stages (E12-E16). NRTNhad no positive effects on cochlear ganglion neurons throughoutdevelopment. In accordance with the time and order of onset inNRTN responsiveness, Ret protein was first detected in ciliaryganglia at E6, subsequently in trigeminal ganglia at E9, and investibular ganglia at E12. Ret was absent in E16 ciliary gangliaas well as in cochlear ganglia at all developmental stages thatwere tested. Exogenous application of retinoic acid induced NRTNresponsiveness and Ret protein expression from E9 vestibular ganglionneurons, suggesting that retinoic acid can regulate Ret proteinexpression in peripheral sensory neurons in vitro. Ret was confinedto the neuron cell body, whereas GFR $alpha$ was localized predominantlyin peripheral and central neurite processes. No noticeable changein GFR $alpha$ expression was seen in any cranial ganglia throughoutthe developmental stages that were tested (E6-E16). These resultsdemonstrate that NRTN exerts neurotrophic effects on differentcranial ganglia at different developmental stages and that theonset and offset of NRTN responsiveness are regulated mainly bythe spatiotemporal patterns of Ret, but not of GFR $alpha$ receptors.The results also substantiate the recently emerging view thatNRTN may be an essential target-derived neurotrophic factor forparasympathetic neurons duringdevelopment.

Key words: neurturin; GFR $alpha$ ; Ret; ciliary; trigeminal; vestibular; cochlear; chicken

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neurturin (NRTN) is a member of the glial cell line-derived neurotrophic factor (GDNF) ligand family, which now comprise threeother ligands, GDNF (Lin et al., 1993), persephin (PSPN; Milbrandtet al., 1998) and artemin (ARTN; Baloh et al., 1998). NRTN originallywas isolated from Chinese hamster ovary conditioned medium onthe basis of its ability to promote the survival of sympatheticneurons (Kotzbauer et al., 1996). Despite a relatively low sequencehomology (42%), the neurotrophic effects of NRTN strikingly resemblethose of GDNF. Both NRTN and GDNF promote the survival of nodose,superior cervical sympathetic, and dorsal root ganglion neuronsin vitro (Buj-Bello et al., 1995; Trupp et al., 1995; Kotzbaueret al., 1996). Although accumulating evidence indicates that NRTNacts as a survival factor for several autonomic and sensory neuralpopulations in vitro, the central question of what role NRTN playsin the peripheral nervous system (PNS) development remains tobedetermined.

NRTN and other members of the GDNF ligand family share a receptor complex, which is composed of a glycosyl-phosphatidylinositol(GPI)-linked ligand-binding protein (GFR $alpha$ ) and a transmembranetyrosine kinase receptor, Ret. GDNF and NRTN each bind to GFR $alpha$ .This ligand-binding protein complex then can activate Ret. FourGPI-linked receptors have been cloned thus far and designatedas GFR $alpha$ 1 (Jing et al., 1996; Treanor et al., 1996), GFR $alpha$ 2 (Balohet al., 1997; Buj-Bello et al., 1997; Klein et al., 1997), GFR $alpha$ 3(Jing et al., 1997; Baloh et al., 1998; Masure et al., 1998; Worbyet al., 1998), and GFR $alpha$ 4 (Thompson et al., 1998). Several linesof evidence suggest that GDNF, NRTN, ARTN, and PSPN have the highestbinding affinity to GFR $alpha$ 1, GFR $alpha$ 2, GFR $alpha$ 3, and GFR $alpha$ 4, respectively(Baloh et al., 1997, 1998; Jing et al., 1997; Thompson et al.,1998), although NRTN also can signal via the GFR $alpha$ 1-Ret receptorcomplex (Creedon et al., 1997). Extensive efforts recently havebeen initiated to elucidate the downstream signaling of the GDNFligand family after receptor binding. GDNF, as well as NRTN, stimulatesthe Ras/MAP kinase pathway via Ret (Ohiwa et al., 1997). In addition,a recent study suggests that exogenous Ca²⁺ is required for GDNF/NRTN-mediated Ret activation (Nozaki etal., 1998). Nevertheless, little is known about how NRTN and GDNFinteract with the receptor complex and activate intracellularsignalingcascades.

Recent evidence suggests that GDNF acts as a survival factor for certain PNS neurons only at early developmental stages andfor other PNS neurons at late developmental stages (Buj-Belloet al., 1995; Molliver et al., 1997). These observations raisethe question of whether NRTN acts on PNS neurons at specific developmentalstages and, if so, whether the stage-specific effects are regulatedby its receptor expression. In the present study the neurotrophiceffects of NRTN on chick ciliary, trigeminal, vestibular, andcochlear ganglia were examined at various embryonic stages byorganotypic and dissociated neuron cultures. In addition, developmentalchanges in the expression of GFR $alpha$ and Ret, the receptor componentsfor NRTN, were examined in the cranial ganglia and related tothose in NRTN responsiveness. Finally, the effects of retinoicacid on NRTN responsiveness were examined in light of the observationthat retinoic acid can modulate neurotrophin responsiveness indeveloping PNS neurons by regulating receptor expression (vonHolst et al., 1997).

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Organotypic culture. White Leghorn chick embryos at embryonic day 6 (E6), E9, E12, and E16 were used in the present study.The embryos were decapitated, and their vestibular (VG), cochlear(CG), ciliary (CLG), and trigeminal ganglia (TG) were dissectedin HBSS under a dissection microscope. One ganglion was placedin the center of a well of 24-well culture dishes coated with0.02% poly-D-lysine (Becton Dickinson, Bedford, MA). The basalmedium was a serum-free DMEM/F12 (Life Technologies, Grand Island,NY) supplemented with 10 mM HEPES, 100 U/ml penicillin, and 1%ITS plus PREMIX (Becton Dickinson). The medium contained NRTN(1, 10, 50, or 100 ng/ml), PSPN (50 or 100 ng/ml), BDNF, CNTF(50 ng/ml; both kindly provided by Regeneron, Tarrytown, NY),or no factor (control). Some explants were incubated in a combinationof NRTN (50 or 100 ng/ml) and 10 µM all-trans-retinoic acid (dissolvedfrom 10 mM stock in DMSO; Sigma, St. Louis, MO). The ganglia wereincubated with 5% CO₂ at 37°C for 3 d (E6, E9, and E12 ganglia)or 5 d (E16 ganglia). The outgrowth of neurites was documentedphotographically with a Nikon Diaphot inverted microscope. The35 mm photographic negatives were digitized with a Nikon CoolScan film scanner. The magnitude of neurite outgrowth was evaluatedquantitatively and described as an average of the radial distanceof neurite tips from the explant. Four radial lines drawn fromthe center of the explant divided the field into four equal sectors(90°/sector). The length of outgrowth was measured from the edgeof the explant to the distal tip of the longest neurites in eachsector. The mean outgrowth was calculated as the average lengthof neurites for all sectors of each explant. Six to 14 gangliafor each experimental group were obtained from at least two separateexperiments and were used formeasurement.

Neurofilament staining. The explants were fixed with 4% paraformaldehyde for 30 min, and their neurite processes were verifiedby immunohistochemical staining with a neurofilament antibody.The specimens were incubated at room temperature in blocking solution[1% Triton X-100 and 3% bovine serum albumin (BSA) in PBS] for1 hr and subsequently with a 160 kDa neurofilament antibody (cloneRMO-270, 1:2000; Zymed, San Francisco, CA) diluted in blockingsolution for 2 hr. Endogenous biotin was inhibited by NeurtrAvidin(0.1 mg/ml in blocking solution; Pierce, Rockford, IL) for 15min and 2 mM D-biotin (Pierce) for 1 hr. Thereafter, the specimenswere incubated with biotinylated anti-mouse IgG (5 µl/ml in blockingsolution; Vector Laboratories, Burlingame, CA) for 1 hr, and thereaction product was visualized by peroxidase-conjugated ExtrAvidin(1:1000; Sigma) with TrueBlue (Kirkegaard & Perry, Gaithersburg,MD) as asubstrate.

Dissociated neuron culture. CLG, TG, and VG were removed from E9 chick embryos in sterile conditions. Sixteen to 20 gangliawere collected and incubated in 0.1% trypsin in calcium-, magnesium-freeHBSS for 30-45 min at 37°C. The enzymatic reaction was stoppedby adding ice-cold DMEM/F-12 and heat-inactivated horse serum.The ganglia were transferred to defined medium and trituratedwith a fire-polished glass pipette. The dissociated cells wereplated on a 60 mm untreated Petri dish for 2 hr to enrich theneuronal population. Then the cells were plated on 24-well tissueculture plates coated with poly-D-lysine (200 µg/ml) and laminin(50 µg/ml; Life Technologies) at the average density of 300 cells/mm². Cells were incubated in serum-free medium supplemented withNRTN, CNTF, BDNF (50 ng/ml each), a combination of NRTN and retinoicacid, or no factor (control). Neuronal survival was determined2 d after the start of incubation by counting phase-bright cellswith neuronal morphology. Surviving neurons were verified furtherby the Live/Dead viability assay kit (Molecular Probes, Eugene,OR) according to the manufacturer's instructions. Viable neuronswere counted with a grid ocular reticule covering an area of 0.5mm². For each well, approximately five randomly selected fields (threeto four wells per group per experiment) were counted. Data werecollected from at least three separate experiments for each group.Some of the cultures were fixed with 4% paraformaldehyde for 30min and labeled with a Retantibody.

Immunohistochemistry. E6, E9, E12, and E16 chick embryos were fixed in 4% paraformaldehyde/0.1% glutaraldehyde overnight at4°C and embedded in paraffin. Horizontal sections (10 µm) of thewhole heads were cut and mounted on Superfrost plus slides (VWRScientific, West Chester, PA). Sections that included vestibular,cochlear, ciliary, or trigeminal ganglia were stained with 1%toluidine blue or the indicated antibodies. After deparaffinization,the sections were treated with 0.3% H₂O₂ in methanol for 10 minto inactivate the endogenous peroxidase. The sections subsequentlywere incubated at room temperature in blocking solution [0.3%Triton X-100, 5% BSA, and 10% normal horse serum in hi-salt (1.8%NaCl) PBS] for 1 hr and then either with anti-Ret (1:100; SantaCruz Biotechnology, Santa Cruz, CA) or with anti-GFR $alpha$ (anti-GDNFR $alpha$ ,clone 17, 1:500; Transduction Laboratories, Lexington, KY) inblocking solution at 4°C overnight. The GFR $alpha$ antibody that israised against GFR $alpha$ 1 cross-reacts with GFR $alpha$ 2 and was used in thepresent study for probing both GFR $alpha$ 1 and GFR $alpha$ 2. The amino acidsequences for both human Ret and rat GFR $alpha$ epitopes differ fromthe corresponding chicken sequences by only a single amino acid.Thereafter, the sections were incubated with biotinylated secondaryantibody (5 µl/ml; Vector Laboratories) in blocking solution for1 hr, and the reaction product was visualized by the biotin-avidin-HRPdetection system (ABC Elite kit, Vector Laboratories), using 3,3'-diaminobenzidine(DAB) as a substrate. To confirm the specificity of the staining,we processed sections either by omission of incubation with aprimary antibody or with the primary antibody preabsorbed witha blocking peptide. To count the number of Ret-positive neurons,we digitized and analyzed every 10th section throughout the entireganglion from at least three animals at each developmentalstage.

Western blot analysis. Cranial ganglia (ciliary, trigeminal, and vestibular ganglia) or whole brains were dissected from E9chick embryos. Tissues were homogenized with a 25-gauge syringeneedle in 300 µl of lysis buffer [(containing in mM) 10 HEPES,pH 7.4, 10 KCl, 0.2 EDTA, 1 DTT, and 0.5 Pefabloc (Roche) plus10 µg/ml aprotinin]. After 15 min on ice, Nonidet P-40 was addedto a final concentration of 0.65%. Samples were centrifuged for10 min at 4°C, and the resulting supernatant was added to thesample buffer. The protein concentration was determined via theBCA protein assay (Pierce). In each lane 10-15 µg of protein wasrun on a 10% SDS-polyacrylamide gel and transferred to a polyvinylidenedifluoride membrane (Bio-Rad, Hercules, CA). The blots were incubatedsequentially in blocking buffer (Tropix, Bedford, MA), anti-GFR $alpha$ antibody (1:3000), and alkaline phosphatase-conjugated anti-mouseIgG. The blots were visualized with the Western-Star chemiluminescentdetection system (Tropix) according to the manufacturer'sinstructions.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ciliary, trigeminal, and vestibular ganglion neurons have different onset times for NRTN responsiveness

The CLG neurons extended a robust outgrowth (2489 ± 134 µm) in the presence of 50 ng/ml NRTN at E6, the earliest developmentalstage that was examined (Fig. 1). An extensive neurite outgrowthalso was observed from E9 CLG explants that were grown in mediumcontaining NRTN (Figs. 1, 2). Although CLG neurons showed a significantoutgrowth with NRTN at E12, the average length of neurites ofE12 CLG neurons (1647 ± 236 µm) was significantly shorter thanthat of E6 or E9 CLG neurons. By striking contrast to the extensiveoutgrowth at E6-E12, no outgrowth was observed from E16 CLG withNRTN at 10-100 ng/ml in comparison to controls (Fig. 1). Unlikethe CLG neurons, TG neurons did not respond to NRTN at E6 (Fig.1). By E9, however, TG neurons had become responsive to NRTN,inducing a significant outgrowth (1730 ± 129 µm; Figs. 1, 2).The average outgrowth of TG neurons in response to NRTN was greaterat E12 (2342 ± 186 µm) than at E9, and the magnitude of outgrowthwas sustained out to E16 (1901 ± 139 µm; Fig. 1). Qualitatively,a greater number of neurites were observed from E12 TG explantsthan from E9 TG explants (Fig. 2). Temporal changes in the sensitivityof VG neurons to NRTN differed from those of CLG and TG neurons.NRTN did not promote neurite outgrowth from E6 nor E9 VG neurons(Figs. 1, 2). VG neurons, however, showed a significant outgrowthin the presence of NRTN at E12 (316 ± 169 µm), and neurite lengthincreased further at E16 (1298 ± 100 µm; Figs. 1, 2) than at E12.Interestingly, NRTN had no positive effects on CG, which are locatednear the VG, at all developmental stages that were tested (E9-E16)(Fig. 2).

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Figure 1. Changes in the effects of NRTN on neurite outgrowth from cranial ganglion explants during development. Each graph depicts the average length of neurites (± SE) from ciliary (CLG; A), trigeminal (TG; B), and vestibular (VG; C) ganglion explants cultured with NRTN (50 ng/ml for ciliary ganglia and 100 ng/ml for trigeminal and vestibular ganglia) in comparison with control explants cultured in the absence of NRTN; shown after 3 d (E6, E9, E12) or 5 d (E16) of incubation. A, NRTN elicits a neurite outgrowth from E6, E9, and E12 ciliary ganglia, whereas no positive effect was observed from E16 ciliary ganglia. B, NRTN has little effect on E6 trigeminal ganglia but promotes an extensive outgrowth from E9-E16 trigeminal ganglia. C, Unlike ciliary or trigeminal ganglia, vestibular ganglia respond to NRTN only at E12 and E16. n = 9, 6, 9, 6, 6, 12, 7, and 12 (from left, for CLG); n = 8, 6, 11, 6, 8, 11, 6, and 10 (from left, for TG); n = 6, 6, 8, 11, 6, 14, 8, and 12 (from left, for VG).

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Figure 2. Comparison of neurite outgrowth from ciliary, trigeminal, vestibular, and cochlear ganglion explants elicited by NRTN at different embryonic stages. A, B, E9 ciliary ganglion explant with (A) or without (B) NRTN at 50 ng/ml. C, E16 ciliary ganglion explant with NRTN at 100 ng/ml. D, E, E9 (D) and E12 (E) trigeminal ganglion explant cultured with NRTN at 100 ng/ml. F, E16 cochlear ganglion explant with NRTN at 100 ng/ml. G, E9 vestibular ganglion explant with NRTN at 100 ng/ml. H, I, E16 vestibular ganglion explant grown with NRTN at 100 ng/ml (H) or 10 ng/ml (I). Note that NRTN induces an extensive outgrowth from the E9, but not from E16, ciliary ganglia. In contrast, NRTN has positive effects on E16, but not E9, vestibular ganglia. NRTN has no effect on E16 cochlear ganglion explant outgrowth. The culture was immunostained with a neurofilament antibody (A, G, H) or unstained phase-contrast micrographs (B-F, I). Scale bar (shown in I): A-C, F-I, 500 µm; D, E, 260 µm.

The NRTN-induced neurite outgrowth from various cranial ganglia was dose-dependent, with the saturation point ~50-100 ng/ml(Fig. 3). The total length of neurites from E9 CLG increased monotonicallywith the concentration of NRTN up to 50 ng/ml, at which pointthe outgrowth reached a maximal value. NRTN at 100 ng/ml promotedan equivalent outgrowth from the CLG neurons, whereas NRTN at1 ng/ml had little effect on the neuron outgrowth. At this stage,TG neurons also showed dose-dependent responses to NRTN. NRTNat 10 ng/ml or higher concentrations elicited a significant outgrowthfrom the E9 TG neurons. E16 VG neurons showed a significant outgrowthin response to NRTN at concentrations between 10 and 100 ng/ml,and a maximal outgrowth was observed at 100 ng/ml.

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Figure 3. Dose-responses of the E9 ciliary (A), E9 trigeminal (B), and E16 vestibular (C) ganglion explants to NRTN. Each graph shows the average neurite outgrowth from each ganglion cultured with NRTN at concentrations ranging from 0 to 100 ng/ml for 3 d (A, B) or 5 d (C). The E9 ciliary ganglion shows a monotonic increase in neurite outgrowth in response to NRTN up to the concentration of 50 ng/ml, beyond which the magnitude of neurite outgrowth decreases. The trigeminal as well as vestibular ganglia show a monotonic increase in neurite outgrowth in response to NRTN, with a maximum outgrowth at 100 ng/ml. n = 6, 6, 6, 9, and 6 (from left, for CLG); n = 6, 9, 6, and 6 (from left, for TG); n = 11, 7, 6, and 8 (from left, for VG).

To test the specificity of the neurotrophic effects, we compared the magnitude of neurite outgrowth with NRTN (50-100 ng/ml)to that with other neurotrophic factors (Fig. 4). E9 CLG neuronsshowed an extensive outgrowth (2069 ± 184 µm) in the presenceof 50 ng/ml CNTF, the only known survival factor for CLG neurons(Lin et al., 1989). The outgrowth of CLG neurons with CNTF wascomparable to that with NRTN. In contrast, the CLG neurons showedvirtually no outgrowth in the presence of BDNF or in the absenceof a neurotrophic factor (control). PSPN (50 or 100 ng/ml) hadno effect on E9 CLG neuron outgrowth (data not shown). Interestingly,E16 CLG neurons showed a significant outgrowth in response toCNTF at 50 ng/ml (data not shown), which contrasts with no outgrowthin the presence of NRTN at E16 (see Fig. 1). The neurite outgrowthof E9 TG neurons with NRTN was much greater than that with CNTF(350 ± 83 µm) but was less than that with BDNF (2414 ± 198 µm).E9 VG neurons showed a significant outgrowth with BDNF but didnot respond to CNTF or NRTN.

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Figure 4. Quantification of the effects of various neurotrophic factors on neurite outgrowth from E9 chick cranial ganglion explants. The graph shows the average neurite length (± SE) for ciliary, trigeminal, and vestibular ganglion explants grown in medium containing NRTN (50 ng/ml), CNTF (50 ng/ml), or BDNF (50 ng/ml) for 3 d in comparison with control ganglia cultured in the absence of the factors. Ciliary ganglia are responsive to NRTN as well as to CNTF, trigeminal ganglia to NRTN as well as to BDNF, and vestibular ganglia only to BDNF. Note that the three cranial ganglia respond to the neurotrophic factors in a distinctive and specific manner. n = 9, 6, 6, and 6 (from left, for CLG); n = 11, 7, 8, and 6 (from left, for TG); n = 8, 9, 12, and 11 (from left, for VG).

To verify whether NRTN can promote the survival of the cranial ganglion neurons, we performed a survival assay with the dissociatedneuron culture (Fig. 5). In medium containing NRTN, the majorityof E9 CLG neurons (83%) was viable after 48 hr in culture, comparedwith 2.5% survival in the control culture. CNTF also promotedthe survival of CLG neurons at a degree equivalent to NRTN. Incontrast, only 30% of dissociated E9 TG neurons were viable after48 hr in culture with NRTN. This is consistent with our observationthat a limited number of neurite processes were observed fromE9 TG explants cultured with NRTN (see Fig. 2). The survivingTG neurons showed Ret immunoreactivity, which was absent in non-neuronalcells or neurons probed with the peptide-absorbed antibody (Fig.5C). A significantly greater number of the TG neurons (51%) survivedin the presence of BDNF. The failure of BDNF to promote the survivalof approximately one-half of the TG neurons presumably is attributableto the fact that TG neurons of neural crest origin are NGF-dependent.

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Figure 5. Effects of NRTN on the survival of E9 ciliary and trigeminal ganglion neurons. A, Dissociated E9 ciliary ganglion neurons grown in the presence of 50 ng/ml NRTN. B, Dissociated E9 ciliary ganglion neurons grown in the absence of trophic factors. C, Dissociated E9 trigeminal ganglion neurons grown for 2 d in the presence of 50 ng/ml NRTN and subsequently stained for Ret. All cells with neuronal morphology are positive with Ret staining (arrows), whereas flat non-neuronal cells are devoid of staining. A neuron probed with the primary antibody that was preincubated with a blocking peptide shows no staining (inset). Scale bar, 50 µm. D, Survival of E9 ciliary ganglion neurons in the presence of 50 ng/ml NRTN or CNTF in comparison with control (no factor). E, Survival of E9 trigeminal ganglion neurons in the presence of 50 ng/ml NRTN or BDNF in comparison with control. Results are expressed as the percentage of the neurons that survived after 48 hr in culture (± SE). Note that the majority of E9 ciliary ganglion neurons is supported by NRTN (D), whereas only a subpopulation of E9 trigeminal ganglion neurons is NRTN-dependent (E).

Different cranial ganglia have different onset and offset times for Ret expression

To explore the possibility that the differential effects of NRTN on CLG, TG, and VG neurons are attributable to differentialdevelopmental regulation of its receptor expression, we examinedRet protein expression in the cranial ganglia. We found that Retprotein expression changes spatiotemporally in chick cranial gangliaduring development. At E6, CLG neurons showed positive Ret staining,whereas TG and other cranial ganglia were devoid of Ret staining(data not shown). At E9, a uniform positive staining was observedin virtually all CLG neurons (Figs. 6, 7). In contrast, intenseRet immunoreactivity was observed only in a subpopulation of TGneurons. Ret-positive neuron cell bodies were localized in therostral portion of the TG (Figs. 6, 8). Ret labeling was absentin E9 VG as well as CG neurons (Fig. 6). Intense staining of Retin TG, in contrast with negative staining in VG, was seen consistentlyin the same sections, clearly indicating differential expressionof Ret protein in midstage developing chick cranial ganglia. Acount of the neuron number revealed that ~33% of TG neurons wereRet-positive at E9 (Fig. 7). By E12, however, the vast majorityof TG neurons had become Ret-positive (Figs. 7, 8). At this time,~26% of VG neurons also showed positive staining with Ret (Fig.7). By contrast, Ret staining in CLG decreased from 100% at E9to 27% at E12. In addition, staining was faint even in Ret-positiveCLG neurons. At E16 the vast majority of TG as well as VG neuronswas positive with Ret staining (Figs. 7, 8), whereas Ret stainingwas absent in CG (data not shown). CLG neurons, which showed prominentstaining at E9, also were devoid of Ret staining at E16 (Figs.7, 8).

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Figure 6. Localization of Ret and GFR $alpha$ in E9 chick cranial ganglia. Shown are ciliary (A-C), trigeminal (D-F), vestibular (G, I), and cochlear (J-L) ganglia stained with toluidine blue (A, D, G, J), anti-Ret (B, E, H, K), or anti-GFR $alpha$ antibodies (C, F, I, L). All ciliary ganglion neurons and some trigeminal ganglion neurons are Ret-positive, whereas vestibular as well as cochlear ganglion neurons are devoid of Ret staining. All cranial ganglia that were tested are positive with GFR $alpha$ staining. Note that Ret labeling is confined to the neuron cell body in contrast with the predominant staining of GFR $alpha$ in neurites. Scale bar (shown in L): A-C, 100 µm; D-L, 200 µm. CLG, Ciliary ganglion; TG, trigeminal ganglion; VG, vestibular ganglion; CG, cochlear ganglion; SE, sensory epithelium; CG, cochlear ganglion.

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Figure 7. Changes in the number of Ret-positive neurons in ciliary, trigeminal, and vestibular ganglia during development. The graph depicts the percentage of Ret-expressing neurons in each ganglion at various embryonic ages. The percentage of Ret-positive neurons in the ciliary ganglion decreases with age, whereas Ret expression is upregulated in the trigeminal ganglion and vestibular ganglion after E9 and E12, respectively.

Because GFR $alpha$ receptors comprise another component of the functional NRTN/GDNF receptor complex, we examined the spatiotemporalchanges in GFR $alpha$ expression in cranial ganglia. Because the ratepitope for the GFR $alpha$ antibody (clone 17) has a 95% identity tothe corresponding chicken sequence, we validated cross-reactivityof the antibody against chicken GFR $alpha$ by Western blots. The antibodylabeled double bands located between 45 and 60 kDa in lysate preparedfrom E9 chick cranial ganglia or whole brain (Fig. 8D). The positionsof these immunoreactive bands coincided with those obtained fromrat pituitary lysate, thus confirming the cross-reactivity ofthe antibody. Immunohistochemical staining of E9 cranial gangliawith a GFR $alpha$ antibody demonstrated striking differences in localizationbetween GFR $alpha$ and Ret. First, GFR $alpha$ and Ret were not colocalizedin certain ganglia at a given developmental stage. GFR $alpha$ was presentin all CLG, TG, VG, and CG, whereas Ret was present only in CLGand TG (see Fig. 6). Second, subcellular localization of GFR $alpha$ was different from and complementary to that of Ret in each ganglion.Intense staining of GFR $alpha$ was observed in neurites emerging fromthe neuron cell body and also on the plasma membrane, with littlestaining in perikarya (Fig. 8). The prominent localization ofGFR $alpha$ in neurites contrasts with a complete absence of Ret stainingin these regions. Essentially the same staining pattern was observedin E12 (Fig. 8) as well as in E16 ganglia, suggesting that GFR $alpha$ protein levels do not change significantly during the developmentalstages between E9 and E16.

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Figure 8. Changes in Ret and GFR $alpha$ expression in cranial ganglia during development. A-C, E9 trigeminal ganglia stained with toluidine blue (A), Ret (B), or GFR $alpha$ (C). Rostrally located neurons are Ret-positive, but caudally located neurons are devoid of Ret. GFR $alpha$ is localized predominantly in the neurite processes. D, Immunoblots of E9 chick homogenates (cranial ganglia, left; whole brain, right) detected with the GFR $alpha$ antibody. E, F, Immunohistochemical localization of Ret (E) and GFR $alpha$ (F) in E12 trigeminal ganglia. The majority of trigeminal ganglion neurons is Ret-positive at E12 (E) in contrast to a limited number of Ret-positive neurons at E9 (see Fig. 6E). G, H, Immunohistochemical staining of Ret in E16 ciliary (G) and vestibular (H) ganglia. Ret is absent in ciliary ganglion neurons but is present in vestibular ganglion neurons. Scale bar (shown in H): A-C, G, H, 50 µm; E, F, 170 µm.

Retinoic acid induces NRTN-dependent neurite outgrowth and Ret expression

Given that retinoic acid induces Ret expression in several cell lines in vitro (Tahira et al., 1991; Hishiki et al., 1998),we tested whether retinoic acid would induce NRTN responsivenessfrom E9 VG, which does not express Ret protein in situ. The VGexplants grown for 3 d in medium containing 10 µM retinoic acidand 100 ng/ml NRTN showed an extensive neurite outgrowth (947± 110 µm) in contrast to no outgrowth from explants that werecultured with NRTN alone (Fig. 9). In addition, fibroblast-lookingnon-neuronal cells that were seen around VG in culture with NRTNalone were not observed in cultures containing NRTN and retinoicacid (Fig. 9). To check whether retinoic acid itself induces neuriteoutgrowth, we incubated some E9 VG explants with retinoic acid,but without NRTN. Quantitative analysis showed that a significantneurite outgrowth was induced from VG cultured with retinoic acid(340 ± 172 µm) and that the magnitude of neurite outgrowth inducedby retinoic acid alone was significantly smaller than that inducedby a combination of NRTN and retinoic acid (t = 2.61; p < 0.05;Fig. 9). To examine the possibility that the observed increasesin neurite processes were based on Ret protein expression, welabeled the E9 VG neurons for Ret. Dissociated E9 VG neurons culturedfor 2 d in medium containing NRTN and retinoic acid showed a strongRet staining in their cell bodies (Fig. 9). In contrast, non-neuronalcells in the same culture were devoid of staining, indicatingthe specificity of Ret induction by retinoic acid.

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Figure 9. Effects of retinoic acid (RA) on NRTN responsiveness and Ret protein expression in E9 vestibular ganglion neurons. A-C, Phase-contrast micrographs of E9 vestibular ganglion explants cultured with NRTN alone (A), a combination of NRTN and RA (B), or RA alone (C). Scale bar, 200 µm. D, Graph showing average neurite length (± SE) for E9 vestibular ganglion explants in the presence of NRTN alone, a combination of NRTN and RA, or RA alone. n = 8, 5, 7 (from left); *p < 0.05. E, Dissociated E9 vestibular ganglion neurons grown for 48 hr in the presence of NRTN and RA and subsequently stained for Ret. Surviving vestibular ganglion neurons are positive with Ret staining (arrows), whereas a non-neuronal cell is devoid of staining (arrowhead). Scale bar, 50 µm.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

NRTN is a multimode neurotrophic factor in developing chick cranial ganglia, and its actions are modulated by Ret

NRTN-induced neurite outgrowth was first detected in CLG neurons at E6, when NRTN has little effect on TG neurons and VG neurons.The CLG neurons showed maximal outgrowth at E6-E9, after whichthe responsiveness of CLG neurons to NRTN declined and finallybecame undetectable by E16 (see Fig. 1). The preferential effectsof NRTN on early stage CLG neurons are consistent with a previousreport showing that GDNF promotes the survival of early stageCLG neurons (Buj-Bello et al., 1995). The early stage effectsof NRTN and GDNF, however, differ from the long-lasting effectsof CNTF on the CLG neurons. Our observations also indicate thatNRTN promotes the outgrowth of midstage (E9-E16) chick TG neurons(see Fig. 1). The stage at which TG neurons started respondingto NRTN was later than that of CLG neurons but earlier than thatof VG neurons. Positive effects of NRTN were observed in VG neuronsat stage E12 and later but were never detected in CG neurons atany of the developmental stages that were examined. This findingis similar to our recent study (Hashino et al., 1999), in whichVG neurons switched their sensitivity from BDNF to GDNF betweenE12 and E16. GDNF mRNA expression lags behind BDNF mRNA expressionin the developing rat cochlea (Pirvola et al., 1992; Ylikoskiet al., 1998), which also suggests that GDNF and NRTN play a majorrole in late-stage inner eardevelopment.

We first detected Ret immunostaining in CLG at E6 and subsequently in TG at E9 and in VG at E12 (see Fig. 7). The developmentalstage at which Ret protein first was detected in various cranialganglia coincides with the stage at which neurons in the correspondingganglion started to respond to NRTN (Fig. 10). In each gangliononly a subpopulation of neurons was Ret-positive at the time whenthe protein was first detected. By 3 d after the first expression,however, the majority of neurons in the ganglion had been labeledwith Ret (E9 in CLG, E12 in TG, E16 in VG). In CLG, Ret labelingwas very faint at E12 and undetectable at E16 (see Fig. 8), indicatingthat Ret expression is downregulated in CLG through mid- to lateembryonic stages. Collectively, the present results imply a developmentalregulation of Ret protein expression in chick cranial ganglia.In addition, Ret-positive cranial ganglion neurons showed a vigorousoutgrowth and survival in the presence of NRTN at 50-100 ng/ml,whereas neurons devoid of Ret (E16 CLG, E6 TG, E9 VG, and E9-E16CG) showed no neurite outgrowth (see Figs. 1, 7, 10). These resultsstrongly support the assumption that Ret is required for NRTN-mediatedcellular responses (Baloh et al., 1997; Klein et al., 1997).

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Figure 10. Schematic representation showing developmental changes in NRTN responsiveness of the ciliary, trigeminal, vestibular, and cochlear ganglion neurons (right), and their spatial relationship along the rostrocaudal body axis (left). The darkest area indicates the highest sensitivity; constructed on the basis of Figure 1. The developmental stages at which the cranial ganglion neurons undergo target innervation and programmed cell death [E9-E13 for CLG, Landmesser and Pilar (1974); E8-E14 for VG and CG, Ard and Morest (1984)] are indicated in the figure also. R, Rostral; C, caudal.

NRTN may be an essential target-derived neurotrophic factor for developing parasympathetic neurons

The importance of CNTF in parasympathetic neuron development has long been postulated on the basis of its potent survivaleffects on developing CLG neurons in vitro (Lin et al., 1989;Eckenstein et al., 1990). This assumption, however, has been hamperedby several lines of evidence. First, the expression of CNTF, bothmRNA and protein, is very low or undetectable during development.CNTF levels first become detectable at postnatal week 2 in rats(Sendtner et al., 1994). In addition, a steep increase in CNTFlevels was detected between E10 and E19 in chick eyes (Finn andNishi, 1996). The time of CNTF synthesis does not coincide withthe developmental stage at which trophic support is required forthe CLG neurons (the cell death period). Second, a predominantexpression of CNTF in myelinating Schwann cells (Rende et al.,1992) contradicts its potential role as a target-derived factor.Third, a gene deletion study showed that CNTF homozygous micehad only a small reduction in motor neurons without any otherabnormalities in the PNS or CNS (Masu et al., 1993). More strikingevidence has been revealed showing that ~2.5% of the Japanesepopulation is homozygous for a null mutation of CNTF, which isnot associated with any recognizable neurological disorders (Takahashiet al., 1994). Collectively, the currently available data suggestthat CNTF may act primarily as a general regulator or maintenancefactor for mature PNS neurons (Mitsumoto et al., 1994).

Recent gene deletion studies raised an alternative hypothesis that NRTN is a critical survival factor for parasympatheticneurons. Mutant mice lacking mRNAs for NRTN or its high-affinityreceptor, GFR $alpha$ 2, had a similar phenotype exhibiting a substantialreduction or loss of parasympathetic innervation (Heuckeroth etal., 1999; Rossi et al., 1999). The present results showing robusteffects of NRTN on CLG neuron outgrowth and survival in vitro(see Figs. 2, 5), thus, essentially substantiate the results obtainedfrom the mutant mice. Importantly, positive effects of NRTN onCLG neurons were observed only during the period of target innervationand programmed cell death (see Figs. 1, 10). In addition, a strongexpression of NRTN mRNA in the lacrimal and salivary glands (Widenfalket al., 1997; Golden et al., 1999) and GDNF mRNA in eyes (Buj-Belloet al., 1995) during development further suggests that the synthesisof NRTN and GDNF is regulated developmentally in the target tissuesof parasympathetic neurons. Furthermore, a profound localizationof the GFR $alpha$ receptor in distal processes of neurites (see Fig.6) provides a molecular basis for the retrograde transport ofNRTN, although no direct evidence has been provided to supportthis possibility. Collectively, NRTN fulfills most of the criteriafor being considered a target-derived neurotrophic factor thatplays a critical role in parasympathetic neurondevelopment.

Ret may be a key gene involved in the segregation of vestibular and cochlear ganglia

Despite the stage differences, Ret protein was expressed in all cranial and cervical ganglia (nodose, SCG, DRG), with theexception of the cochlear ganglion. Ret was not detected in thechick cochlear ganglion neurons throughout the developmental stagesthat were tested (E6-E16). In addition, Ret protein also was absentin developing rat cochlear ganglia, which contrasts with an intenseRet labeling in the adjacent vestibular ganglion (M. Shero andE. Hashino, unpublished observations). In support for our observations,Ret mRNA was not detected in either developing or adult rat cochleae(Ylikoski et al., 1998). In this regard, it is interesting tonote that vestibular and cochlear ganglia arise originally fromone ganglion (vestibocochlear ganglion) that is of placodal origin.The segregated expression of Ret in vestibular versus cochlearganglion raises the possibility that the Ret gene may play a criticalrole in the differentiation of VG and CG. Ret mRNA expressionwas confined to a region immediately anterior to the otic vesiclein E3-E4 chicks (Robertson and Mason, 1995; Schuchardt et al.,1995) or E9 mice (Pachnis et al., 1993), suggesting that vestibularganglion neurons start to express Ret mRNA before segregationof the vestibocochlear ganglion (E6-E7 in chicks; E13.5 in mice).Another striking aspect of the present results was that Ret expressionis regulated differently in cranial sensory ganglia during development.The temporal order at which Ret protein was first detected invarious ganglia is consistent with the observations that Ret mRNAis expressed strictly in a rostrocaudal temporal sequence in chickcranial ganglia (Robertson and Mason, 1995). It should be noted,however, that the first sign of Ret protein expression lags behind,by several days, the first expression of its mRNA. This suggeststhat additional developmentally regulated genes could be involvedin the post-transcriptionalprocesses.

Recent studies have identified several genes that directly or indirectly can regulate Ret expression. Among the candidategenes, certain classes of homeobox genes, such as Phox2a, couldregulate Ret expression directly (Morin et al., 1997). Retinoicacid also could regulate Ret expression, because it was shownthat the application of retinoic acid in vitro induced a markedincrease in Ret mRNA expression from a human neuroblastoma cellline (Tahira et al., 1991). Furthermore, the induction of RetmRNA expression was associated with neurite outgrowth and an increasein neurofilament mRNA. In agreement with this, we showed thatretinoic acid induced neurite outgrowth in response to NRTN fromE9 VG neurons, which do not express Ret protein in situ and thusdo not show neurite outgrowth in the presence of NRTN (see Fig.9). The acquisition of NRTN responsiveness appears to be basedon the induction of Ret protein expression in the VG neurons.The search for retinoic acid response elements in the Ret genehas been initiated, but has been unsuccessful thus far (Partoneet al., 1997).

Conclusion: Ret turns on and off NRTN actions on developing cranial ganglia

The present study provided evidence that developing chick cranial ganglia have different onset and offset times for NRTN responsivenessand that these times are regulated by Ret protein expression.Ret-positive cranial ganglion neurons showed a vigorous outgrowthin response to NRTN and appeared to be supported by this factor.Ret-positive neurons first were detected in CLG, a most rostrallylocated ganglion, and subsequently were found in other gangliain the order along the anteroposteral axis of the head duringdevelopment. Ret was never detected in the cochlear ganglion.Exogenous application of retinoic acid induced NRTN responsivenessfrom E9 VG neurons, an action that was associated with Ret proteininduction. Further investigation is required to determine (1)genes that directly regulate Ret transcription, (2) the interactionsof Ret with GFR $alpha$ receptors, and (3) the functional significanceof the differential activation to NRTN (and probably GDNF) responsivenessin various cranial ganglia duringdevelopment.

  FOOTNOTES

Received April 13, 1999; revised July 8, 1999; accepted July 16, 1999.

This work was supported by National Institutes of Health Grants R01 DC01785 (C.S.C.) and R01 DC01685 (R.J.S.). We thank ReeDolnick for technical assistance, Dr. Cynthia Dlugos for histologicalprocessing, and Dr. Malu Tansey for helpful discussions. We alsothank Regeneron Pharmaceuticals, Incorporated, Tarrytown, NY,for providing recombinant BDNF andCNTF.
Correspondence should be addressed to Dr. Eri Hashino, Center for Hearing and Deafness, State University of New York at Buffalo,215 Parker Hall, Buffalo, NY14214.

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