Identification of a Signaling Pathway Activated Specifically in the Somatodendritic Compartment by a Heparan Sulfate That Regulates Dendrite Growth

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The Journal of Neuroscience, December 1, 1998, 18(23):9751-9765

Identification of a Signaling Pathway Activated Specifically in the Somatodendritic Compartment by a Heparan Sulfate That Regulates Dendrite Growth
Sophie Calvet¹, Patrick Doherty², and Alain Prochiantz¹
¹ Centre National de la Recherche Scientifique, Unité de Recherche Associée 1414, Ecole Normale Supérieure, 75230 Paris Cedex 05, France, and ² Department of Experimental Pathology, United Medical and Dental Schools, Guy's Hospital, London SE1 9RT, United Kingdom

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

In two earlier reports we demonstrated that natural heparan sulfate, but not dermatan or chondroitin sulfate glycosaminoglycans,stimulate axonal elongation and inhibit dendrite growth in vitro(Lafont et al., 1992). The latter specific effect on dendriteelongation was reproduced by chemically synthesized heparan sulfatesand by SR 80037A, a purified sulfated and hexanoylated heparinfragment (Lafont et al., 1994). Adding radioactive SR 80037A topurified neurons demonstrated the existence, at the neuronal surface,of heparan sulfate-specific and saturable binding sites, suggestingthat SR 80037A activates specific signal transduction pathways.In the present study, using rat or mouse neurons from the embryoniccortex, we show that SR 80037A signaling involves one or severalG-coupled receptor or receptors, small GTPases $rho$ A and/or $rho$ C, andone or several PKCs. We also demonstrate that the rapid soma roundingelicited by SR 80037A does not require protein synthesis but thatthe long-term effect on dendrite initiation requires protein synthesisin a short period after the addition of the heparan sulfate. Finally,by preparing membranes from the somatodendritic or axonal compartmentswe demonstrate that the identified signaling pathway is activatedby SR 80037A primarily in the somatodendritic compartment andis not sensitive to the addition of a dermatan sulfate glycosaminoglycanthat does not induce the axonal phenotype by impairing dendriteinitiation andelongation.

Key words: neurons in culture; neuronal polarity; glycosaminoglycans; signal transduction; dendrite growth inhibition; cell rounding; cell permeable peptides

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Neurons are highly polarized cells with characteristic axons and dendrites. This polarity is established during developmentthrough interactions of the neurons with cellular partners, inparticular astrocytes (Prochiantz, 1995) or Schwann cells (Leinet al., 1995), and molecular signals (Higgins et al., 1997). Amongthe latter are growth factors, such as neurotrophins (McAllisteret al., 1997) or bone morphogenetic proteins (Lein et al., 1995)and matrix molecules (Chamak and Prochiantz, 1989; Lafont et al.,1992; Prochiantz, 1995).

An important aspect of neuronal polarity is the regional specificity of the interactions taking place between neurons andtheir environment. Indeed, by coculturing astrocytes and neuronsfrom different regions, it was observed that neurons will develop,or not, their dendritic arbor, depending on the anatomical originof the astrocytes (Denis-Donini et al., 1984; Chamak et al., 1987;Rousselet et al., 1988, 1990; Qian et al., 1992; Le Roux and Reh,1994). Recently, using slice cultures, it was further demonstratedthat neuronal polarity is regulated by different neurotrophinsin layers 4 and 6 of the developing cortex (McAllister et al.,1997).

The influence of the anatomical origin of astrocytes on neuronal polarity led us to investigate the activity of moleculespresent in astrocyte-conditioned medium and to observe that glycosaminoglycans(GAGs) regulate neuronal polarity (Lafont et al., 1992). Interestingly,heparan sulfates (HSs) induced an axonal phenotype (long axonsand no or short dendrites), whereas dermatan and chondroitin sulfateshad a general trophic effect on all neurites or favored dendriteelongation. Because GAGs are composed of a combination of heparan,chondroitin, and dermatan motifs, it appeared that elementarycarbohydrate units might participate in the specificity of neuroastroglialinteractions revealed by polaritystudies.

We, therefore, screened a GAG bank composed of synthetic disaccharides to hexasaccharides for their effects on neuronal polarity(Lafont et al., 1994). We found that, when active, sugars fromthe HS series, as well as SR 80037A (a purified heparin-derivedheparan sulfate) decrease neuron-substratum adhesion, inhibitdendrite outgrowth, and either stimulate or do not affect axonalelongation, whereas synthetic dermatan sulfates (DSs) have theopposite influence on neuronal differentiation. These effectswere observed on all embryonic rat or mouse neurons tested, andthe sugars were only active in solution. Substratum-bound GAGslost their ability to regulate polarity. We also observed thatneurons express 3-5 × 10⁵ HS-binding sites (K_D, 1 µM) with a clear structural specificity,because only SR 80037A or active HS-like GAGs competed with labeledSR 80037A for binding to neurons, and the DS-derived GAGs wereinactive, even at highconcentrations.

These results suggested that HS, natural or synthetic, bind specific receptors and activate pathways related to dendrite growth.We now demonstrate that SR 80037A signaling involves G-coupledreceptor(s), small $rho$ GTPases, and one or several PKCs and thatthe HS signaling pathway, which is only activated in the somatodendriticcompartment, does not respond to a DS GAG that does not blockdendritegrowth.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Cortical neuron cultures. Pure neuronal cultures were prepared according to Lafont et al. (1994). In brief, dissociated corticalcells from 16-d-old [embryonic day 16 (E16)] rat embryos (IFFACredo, France) or from transgenic mice were seeded on polyornithin-coated(40 kDa, Sigma, St. Louis, MO) 16-mm-diameter culture wells (1.5µg/ml) or glass coverslips (15 µg/ml) at a density of 25 × 10³ cells/cm² (immunocytochemistry) or 12 × 10³ cells/cm² (morphological analysis). Chemically defined medium (Cdm) consistedof DMEM-F-12 (1:1, Life Technologies, Gaithersburg, MD) complementedwith a mixture of hormones, proteins, and salts (Rousselet etal., 1988). Peptides (concentrations indicated in the text), cycloheximide(1 µM), or GAGs [SR 80037A, SR 80037A-FITC, dermatan sulfate frombovine mucosa (DSbm, Sigma) at a concentration of 10 µg/ml] wereadded 30 min after seeding. SR 80037A was prepared as describedearlier (Petitou et al., 1992; Petitou and van Boeckel, 1993).Collagen from one rat tail was removed sterilely, dissolved overnightat 4°C in 100 ml of acetic acid (0.1%), centrifuged at low speed,and dialyzed against 2 × 10 volumes of DMEM 1:10 adjusted to pH4 with HCl. Collagen gels were obtained by adding 75% rat tailcollagen to the culture medium (in replacement of water) and byadjusting the pH to 7.2 withNaOH.

Immunocytochemistry. Cells fixed for 20 min at room temperature (RT) with 4% paraformaldehyde (PAF) in PBS were permeabilizedin 0.1% Triton X-100 for 5 min, incubated (1 hr, 37°C) with polyclonalanti-MAP2 antibody (1:400, gift of Dr. A. Fellous), washed threetimes, and further incubated for 1 hr at 37°C with monoclonalanti- $tau$ antibody (1:50, Boerhinger Mannheim, Indianapolis, IN).After three washes, cells were incubated (1 hr, 37°C) with CY3-conjugatedanti-rabbit Igs (1:200), washed three times, incubated (1 hr,37°C) with biotinylated anti-mouse Igs (1:200), washed three times,incubated (1 hr, 37°C) with FITC-conjugated streptavidin (1:200),washed three times in PBS and once in water, and mounted in Vectashield.All dilutions and washes were in PBS, and all incubations werein PBS plus 10% fetal calf serum. Immunocytochemical stainingof E16 rat embryo cortical explants cultured in collagen gelswas achieved as above but with longer incubation periods. Cellsand explants were observed on an inverted fluorescence microscope(Leitz) or a confocal microscope (Zeiss, Molecular Dynamicssystem).

Morphological analysis. Cells fixed with PAF for 20 min at RT were washed in PBS, stained with toluidine blue (0.2% in 1%Na₂CO₃), rinsed in water, and air-dried. Each experiment was donethree times. Fifty to 100 neurons per condition were digitalizedand analyzed with morphological analysis software (Neurolab France).Scheffe's test (5%) was used to determine whether treated andcontrol cells were statistically different. A one-tailed p value<0.05 was consideredsignificant.

Preparation of plasma membranes. Cortical tissues (E16 rat embryos) homogenized with a Dounce homogenizer (10 strokes) werepassaged (three times) through a 26 gauge needle in cold bufferA (10 mM Tris, pH 7.4, 100 µM EDTA, and 0.25 M sucrose) plus proteaseinhibitors (1 mM Pefablock, 1 µM leupeptin, 1 µM pepstatin, and0.3 µM aprotinin). The homogenate was loaded on sucrose (1.7 Min buffer A) and centrifuged (150,000 × g, 30 min, 4°C) in anSW41 rotor (Beckman). The membranes collected at the 1.7 M/0.25M interface were loaded on a second 1.7 M sucrose cushion, centrifuged(150,000 × g, 30 min, 4°C), collected, resuspended in 10 mM Tris,pH 7.4, 100 µM EDTA, and 0.25 M sucrose, pelleted (15,000 × g,15 min, 4°C), and resuspended in buffer A plus protease inhibitors.In the case of explant cultures, before membrane preparation (asabove), the somatodendritic and axonal regions of the explantwere cut off the gel, and the axons were rid of collagen by abrief incubation (10 µg/ml, 30 min at 37°C) with collagenase (Sigma).ADP ribosylation of axonal and dendritic membranes was performedas indicated below using 10 µg of proteins. Proteins were quantifiedusing the micro BCA protein assay reagent kit (Pierce, Rockford,IL).

ADP ribosylation. ADP ribosylation with pertussis toxin (PTX, Sigma) or C3 (a kind gift of Dr. P. Boquet) was carried outaccording to Brabet et al. (1990). The membranes (23-30 µg) werepreincubated for 1, 15, or 30 min with or without SR 80037A (orDSbm) at 37°C, in (in mM) 70 Tris-HCl, pH 7.5, 25 dithiothreitol,20% glycerol, 1 EDTA, 0.1 MgCl₂, 1 ATP, 100 thymidine, and 10nicotinamide. Incubation was in a final volume of 100 µl for 1hr at 37°C, with 0.5 µM nicotinamide adenine dinucleotide (NAD),1 µCi ³²P-NAD (DuPont NEN, Boston, MA) and PTX (2.5 µg) or C3 (the appropriatedilution of C3 was established for each batch of enzyme). Samplesprecipitated in 10% TCA were separated by SDS-PAGE and analyzedby phosphoimaging(Fuji).

Immunoprecipitation. ADP-ribosylated membranes were boiled for 5 min in 10% SDS, and four volumes of 190 mM NaCl, 50 mM Tris,pH 7.4, 6 mM EDTA, and 2.5% Triton X-100 were added. After 30min on ice the samples were centrifuged (10,000 rpm, 5 min, 4°C).Supernatants were added to 50 µl of protein-A-Sepharose (in bufferA) previously incubated (or not) with the appropriate anti-G_ior -G_o antibody and incubated for 1 hr at 37°C. After centrifugation(14,000 rpm, 10 min, 4°C), the pellets were washed five timesin 150 mM NaCl, 10 mM Tris, pH 7.4, 5 mM EDTA, 0.05% SDS, and0.1% Triton X-100, and once in 150 mM NaCl, 10 mM Tris, pH 7.4,and 5 mM EDTA. The pellets were resuspended in Laemmli buffer,heated for 5 min at 100°C and centrifuged (14,000 rpm, 10 min,RT). Supernatants were analyzed by SDS-PAGE. Affinity-purifiedantibodies against C-terminal decapeptides of G_o and G_i-3(which also recognizes the C-terminal domains of G_i1 andG_i2) were from Santa Cruz Biotechnology, Santa Cruz,CA.

Western blot analysis. Membranes from E16 rat cortices were prepared as indicated above, and the proteins separated by SDS-PAGEwere transferred on Immobilon. Filters were incubated with anti- $rho$ (Santa-Cruz, 1:100), anti-G_o (1:1000), or anti-G_i-3(1:1000) overnight at 4°C, washed, further incubated for 2 hrat RT with peroxidase-conjugated anti-rabbit whole antibody, washed,and revealed with ECL (Amersham, Arlington Heights,IL).

Two-dimensional gel electrophoresis. ADP-ribosylated samples were lyophilized and resuspended in 20 µl of 9.5 M urea, 10%NP-40, 5% $beta$ -mercaptoethanol, 1.6% biolyte 5:7 (Bio-Rad, Hercules,CA), 0.4% biolyte 3:10 (Bio-Rad) and mixed with 20 µl of 9 M urea,0.8% biolyte 5:7, 0.2% biolyte 3:10, and 0.0025% bromophenol blue.First dimension was in 9.2 M urea, 4% acrylamide, 2% NP-40, 1.6%Biolyte 5:7, and 0.4% biolyte 3:10. Second dimension was achievedon a 7-18% acrylamide gradient (SDS-PAGE).

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

SR 80037A decreases cell spreading and inhibits dendrite outgrowth

Figure 1A illustrates the influence of SR 80037A on the shape and polarity of E16 rat cortical neurons 21 and 48 hr afterseeding. In control conditions (Cdm), neurons exhibit a clearpolarized phenotype with several MAP2-positive short extensionsand a long $tau$ -positive neurite. This specific distribution of theaxonal ( $tau$ ) and dendritic (MAP2) markers (for review, see Craigand Banker, 1994) is already present after 21 hr and allowed usto establish that, in our culture conditions, the longest neuriteis always the axon. Figure 1A also illustrates that SR 80037Adecreases the apparent diameter of the soma and the number ofprimary dendrites. This is quantified in Figure 1B and Table 1;in the presence of SR 80037A the mean number of primary neurites,soma spreading index (in fact the maximal cross-sectional area,corresponding to the surface occupied by the soma on the culturedish after fixation), total neurite length, and dendrite lengthdecrease significantly, whereas axonal length is not modified.The main effect of SR 80037A is, thus, an inhibition of soma spreadingand of dendrite initiation and elongation.

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Figure 1. Effects of Heparan sulfate on neuronal morphology. A, E16 rat cortical neurons incubated 21 hr (left) or 48 hr (right) with (SR 80037A) or without (Cdm) 10 µg/ml SR 80037A were fixed and double-immunostained for MAP2 (red) and $tau$ (green). B, Morphometric analysis was performed on 50 neurons per condition (21 hr with or without SR 80037A). Cumulative distributions of the neurons according to spreading index (B1), total neurite length or axonal length (B2), and dendrite length (B4) demonstrate a specific effect of SR 80037A on cell spreading and dendrite growth. This effect is parallel to a clear reduction in the number of primary neurites (B3). SR 80037A differs significantly from Cdm for all parameters (p < 0.001), except axonal length.

In all experiments presented in this study, axonal length was either increased or not modified after SR 80037A addition, whereasthe number of primary neurites and dendrite development were alwaysreduced. Soma spreading estimated by spreading index was alsooften reduced by the addition of SR 80037A. For each experiment,results concerning the number of primary neurites, dendrite length,and axonal length are presented in Table 1. Finally, the sameeffect on cell rounding and dendrite elongation was observed forrat or mouse neurons from all tested brain regions (cerebellum,spinal cord, and cortex; data not shown).


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Table 1. Presentations of morphological parameters investigated in Figures 1-5, 8, and 9

One hour exposure to SR 80037A is sufficient to induce cell response

SR 80037A, added to neurons for 1 hr, was washed by a brief rinse in Cdm supplemented with 0.5 M NaCl. The medium was thenchanged for Cdm, and the culture was pursued for an additional19 hr before morphological analysis. To verify that NaCl washingis efficient in removing the sugar, we used fluoresceinated SR80037A (SR 80037A-FITC) (Lafont et al., 1994). Figure 2A illustratesthat all SR 80037A-FITC is removed by the brief NaCl rinse. Figure2B and Table 1 demonstrate that FITC conjugation does not modifythe activity of the sugar and that only 1 hr of incubation withSR 80037A or SR 80037A-FITC is sufficient to induce and maintaincell rounding and dendrite inhibition for at least 19 hr.

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Figure 2. One hour of exposure to SR 80037A induces the phenotype. A, E16 cortical cells were incubated with SR 80037A-FITC (10 µg/ml) for 1 hr, briefly washed (SR 80037A W, third panel) or not (SR 80037A, first panel) with 0.5 M NaCl, fixed, and analyzed by confocal microscopy. SR 80037A accumulation at the cell surface (bright rim) was lost after washing (compare with control cells not incubated with SR 80037A-FITC, second panel). B, E16 cortical cells were treated with 10 µg/ml SR 80037A or SR 80037A-FITC for 1 hr, washed with 0.5 M NaCl, and let to differentiate for 21 hr in Cdm (without NaCl). Cumulative distributions of the neurons according to spreading index (left) and dendrite length (right) demonstrate that SR 80037A-FITC is as active as SR 80037A and that the two aspects of the phenotype are induced within 1 hr of SR 80037A presentation. p < 0.0001 for SR 80037A versus Cdm (spreading index); p < 0.002 for SR 80037A-FITC versus Cdm (spreading index). For all other parameters, see statistics in Table 1.

To evaluate the importance of protein synthesis in the induced phenotype, we used cycloheximide (CHX), a drug that specificallyand reversibly blocks protein synthesis. CHX was added 30 minbefore SR 80037A. After 1 hr exposure to SR 80037A, the cellswere either fixed (Fig. 3A) or washed with 0.5 M NaCl to removeSR 80037A and CHX and let to differentiate in Cdm for 19 hr (Fig.3B). Cell body rounding occurs within 1 hr (Fig. 3A) and in theabsence of protein synthesis. When the cells were analyzed 19hr after removal of CHX and SR 80037A, the effects of the HS oncell rounding and on the number of primary neurites were maintained(Fig. 3B, Table 1), but the effect on total dendrite length waslost. Interestingly, axonal elongation was strongly stimulated,suggesting that the neurites (axons and dendrites) that are ableto initiate despite the presence of SR 80037A grow at a very rapidpace after CHX and sugar removal. The same result was obstainedif CHX was left for another 3 hr after SR 80037A removal (datanot shown).

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Figure 3. Effect of protein synthesis inhibition on early and late phenotypes. A, E16 cortical neurons treated for 1 hr with SR 80037A in the presence of cycloheximide (CHX) at 1 µM (scheme) and fixed still adopt the rounded phenotype. The left panel is without CHX (for control). p < 0.0001 (CHX vs CHX-SR 80037A and control vs SR 80037A). B, Cycloheximide was removed at the same time as SR 80037A, allowing protein synthesis to resume rapidly (scheme), and the cells were allowed to grow for another 19 hr. The left panel is without CHX (for control). The decrease in cell spreading was preserved (p < 0.0001; CHX vs CHX-SR 80037A), but the effect on dendrite length was lost (p < 1.0 CHX vs CHX-SR 80037A). For other parameters, see Table 1.

Analysis of SR 80037A signaling pathway

To analyze the SR 80037A signaling pathway involved in the morphological phenotype we used the pharmacological reagents listedin Table 2. Many of these reagents are commercially available,e.g., staurosporin and PTX, but others have been developed inour laboratories (for review, see Derossi et al., 1998). The "homemade"dominant-negative inhibitors are peptides or phosphopeptides thatact by interacting with active sites, as in the case of the PKCinhibitor (PKCi) (Derossi et al., 1998) or with the SH2 domainof PLC $gamma$ or Grb2 (Hall et al., 1996; Williams et al., 1997). Thesepeptides were made cell-permeable thanks to their linkage to anotherpolypeptide (penetratin-1) that translocates across biologicalmembranes and accumulates in the cytoplasm and nucleus of cellsin culture (Derossi et al., 1994, 1996). Because the activityof cell-permeable peptides has been described earlier (Theodoreet al., 1995; Hall et al., 1996; Williams et al., 1997), we simplysummarized their effects in Table 2. In the same table we reportthe use of neurons from a transgenic mouse expressing a truncatedFGF receptor under the control of the neural specific enolasepromoter. This truncated receptor behaves as a dominant negativemembrane protein for all FGF receptors (Safell et al., 1997).


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Table 2. Effects of various inhibitors on SR 80037A activity

The results are summarized in Table 2 and are either not shown or quantified in Figures 4 and 5 and in Table 1. Because1 hr exposure to SR 80037A was enough to induce the phenotype,chemical inhibitors were added for 30 min before SR 80037A, andthe cells were further incubated for 1 hr before replacement ofSR 80037A and inhibitors with Cdm for 20 hr. In summary, of alltested compounds, the only active SR 80037A antagonists are pertussistoxin and PKC inhibitors. Figure 4A and Table 1 illustrate theabsence of inhibition of SR 80037A effects by a peptide that anatagonizesEGF signaling through Grb2. Figure 4B and Table 1 demonstratethat neurons that do not respond to FGFs are still capable ofresponding to SR 80037A. In contrast, Figures 4C and 5A illustratethat PTX (Fig. 4C, Table 1) and penetratin-1-PKCi (V-PKCi), thePKC peptidic inhibitor (Fig. 5A, Table 1), antagonize the effectof SR 80037A on neuronal spreading and dendrite growth. The inhibitionof neuronal rounding is clear but partially masked by the perse effect of PTX and V-PKCi inhibitor on this parameter, evenin the absence of SR 80037A. To validate the use of the V-PKCiwe showed that stimulating the cells with PMA for 30 min beforepeptide addition antagonized its effect in a dose-dependent manner(Fig. 5B). Similar effects were obtained with the V-PKCi and staurosporine(data not shown).

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Figure 4. SR 80037A effects do not require active EGF and FGF receptors and are inhibited by pertussis toxin. Cumulative distributions according to spreading index and dendrite length of E16 rat (A, C) and mouse (B) neurons incubated with or without SR 80037A in different conditions. A, EGFR¹⁰⁶⁸Y-P does not affect SR 80037A activity. Spreading index and dendrite length are shown in the presence or absence of the inhibitor. p < 0.0001, EGF¹⁰⁶⁸Y-P versus EGF¹⁰⁶⁸Y-P-SR 80037A (spreading index); p < 0.01, EGF¹⁰⁶⁸Y-P versus EGF¹⁰⁶⁸Y-P-SR 80037A (dendrite length). For other parameters, see statistics in Table 1. B, Nonfunctional FGF receptors (neurons from transgenic embryos expressing a FGF-R1 dominant negative receptor) do not affect SR 80037A activity. p < 0.0001 (spreading index and dendrite length, Cdm vs SR 80037A). C, PTX (0.5 µg/ml) added 30 min before SR 80037A and removed at the same time as SR 80037A (1 hr exposure to the sugar) inhibited both soma rounding and dendrite inhibition. Note that PTX has an effect per se on spreading index. p < 1.0 (PTX vs PTX-SR 80037A, spreading index, and dendrite length). For all other parameters, see statistics in Table 1.

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Figure 5. Protein kinase C is in the SR 80037A pathway. A, Cumulative distributions according to spreading index and dendrite length of E16 rat neurons incubated with or without SR 80037A (for 1 hr) with or without pretreatment with the cell-permeable PKC inhibitor (V-PKCi). V-PKCi inhibits both cell rounding and the effect on dendrite growth. p < 0.001, Cdm versus SR 80037A (spreading); p < 0.01, Cdm versus SR 80037A (dendrite growth); p < 1, V-PKCi versus V-PKCi-SR 80037A (spreading); p < 0.6, V-PKCi versus V-PKCi-SR 80037A (dendrite growth). For all other parameters, see statistics in Table 1. B, Treating the cells with PMA antagonizes the effect of V-PKCi in a dose-dependent manner. Inhibition is partial at 0.1 µM (left panel) and total at 1 µM PMA (right panel). This confirms that the effect of V-PKCi is through PKC inhibition. Left panel, p < 0.001, Cdm versus SR 80037A (spreading); p < 0.008, Cdm versus SR 80037A (dendrite length); p < 0.07, V-PKCi-SR 80037A versus V-PKCi-SR 80037A-PMA 1 µM (spreading); p < 0.2, V-PKCi-SR 80037A versus V-PKCi-SR 80037A-PMA 1 µM (dendrite length). Right panel, p < 0.0001, Cdm versus SR 80037A (spreading and dendrite length); p < 0.004 V-PKCi-SR 80037A versus V-PKCi-SR 80037A-PMA 10 µM (spreading); p < 0.006 V-PKCi-SR 80037A versus V-PKCi-SR 80037A-PMA 10 µM (dendrite length).

SR 80037A activates Gi but inhibits Rho pathways

PTX specifically incorporates ADP through ADP ribosylation of the C-terminal domain of the $alpha$ subunits of G_o and G_i, two heterotrimericGTPases (Neer et al., 1984). After heterotrimeric G-protein activation,the $alpha$ subunits dissociate from the complex and become less accessibleto PTX (Li, 1992). A decrease in ADP ribosylation provoked bya pharmacological agent therefore demonstrates that this agentis acting through a pathway involving either G_o or G_i activation.To verify that SR 80037A activity involves a heterotrimeric G-protein,membranes from the cortex of E16 rat embryos were incubated withthe sugar, pelleted to remove the unbound ligand, and proceededfor ADP ribosylation of the G-proteins by PTX. As shown in Figure6A (top panel), SR 80037A inhibits the ADP ribosylation of a proteinwith an apparent molecular weight (MW) of 40 kDa. This inhibitionwas rapid and almost total after 30 min of incubation with thesugar (Fig. 6A, quantification in bottom panel). Western blotanalysis of the membrane extracts demonstrates that G_o andG_i are expressed at this stage of development, with a largeramount of G_i (probably G_i1 and G_i2 because G_i3is not expressed in neurons; Fig. 6B). The same Western blot demonstratesthat the addition of SR 80037A does not modify the amount of G-proteinpresent in the membranes and, therefore, that the effect of thesugar on the level of ADP ribosylation cannot be attributed toa degradation of the toxin substrates. Immunoprecipitations withanti-G_o and anti-G_i antibodies (Fig. 6C) confirmed thatSR 80037A inhibits PTX-stimulated ADP ribosylation of both proteinsand, thus, places the heterotrimeric G, in particular G_i, in theSR 80037A signaling pathway.

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Figure 6. Heterotrimeric G-proteins are in the SR 80037A pathway. A, ADP ribosylation by PTX of a 40 kDa protein in neuronal membranes pretreated with (+) or without ( $-$ ) SR 80037A during 1, 15, or 30 min and quantification by phosphoimager (bottom panel). This experiment is representative of three independent experiments in which SR 80037A reduced ADP ribosylation by 63, 70, and 90% after 30 min. B, Western blot analysis of E16 cortical neurons using G_i and G_o antibodies. Incubation with SR 80037A (+) does not modify the membrane content in G_i or G_o. C, Immunoprecipitation, with G_i or G_o antibodies, of ADP-ribosylated G-proteins from E16 neuronal membranes pretreated (+) or not ( $-$ ) with SR 80037A.

The activation of G_i and the rapid and CHX-resistant cell rounding that follows SR 80037A addition suggested a role for theactin cytoskeleton and, as a consequence, a possible involvementof $rho$ GTPase (Machesky and Hall, 1996; Imamura et al., 1997; Hall,1998). Therefore, we analyzed the effect of an exposure of thecortical membranes to SR 80037A on the ADP ribosylation of $rho$ byC3, a $rho$ -specific toxin (Li, 1992). Figure 7A illustrates and quantifiesthe kinetic of $rho$ ADP ribosylation after exposure to SR 80037Aand demonstrates that the sugar rapidly inhibits $rho$ ADP ribosylation.Separation of the $rho$ proteins by two-dimensional electrophoresis(Fig. 6B, top panel) further demonstrates that $rho$ A and $rho$ C but not $rho$ B are in the sugar-signaling pathway (Fig. 7B, quantificationbottom panel). In the yeast, PKC is downstream of $rho$ 1p (Nonaka,1995). Experiments demonstrating that staurosporine does not antagonizethe effect of SR 80037A on the ADP ribosylation of $rho$ by C3 (datanot shown) also places PKC downstream of $rho$ in the SR 80037A transductionpathway.

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Figure 7. $rho$ A is in the SR 80037A pathway. A, ADP ribosylation by C3 of a 21 kDA protein in neuronal membranes pretreated (+) or not ( $-$ ) with SR 80037A during 1, 15, or 30 min and quantification by phosphoimager (bottom panel). This experiment is representative of five independent experiments using two different preparations of toxin in which SR 80037A reduced $rho$ ADP ribosylation by 70 and 64% (preparation 1) and by 40, 42, and 46% (preparation 2) after 30 min. B, Separation by two-dimensional gel electrophoresis of $rho$ A, $rho$ B, and $rho$ C demonstrating that SR 80037A (+) affects $rho$ A and $rho$ C ADP ribosylation but not that of $rho$ B. Gels in top panel and quantifications by phosphoimager in bottom panel.

The decrease in $rho$ ADP ribosylation suggests that the addition of SR 80037A decreases the accessibility of Asn⁴¹ (the ADP ribosylation site) to the toxin (Jalink et al., 1994),possibly by promoting an interaction of $rho$ with a downstream partner.However, this does not say whether this partner inhibits or, onthe contrary, enhances basal $rho$ biological activity. To investigatethis point we compared, in our biological model, the effect ofSR 80037A with that of C3, a known inhibitor of $rho$ . As shown inFigure 8 and Table 1, C3 and SR 80037A have the same effectson cell spreading, the number of primary neurites and dendritegrowth, and the same absence of effect on axonal elongation. Thisexperiment, which reproduces the results of Threadgill et al.(1997), strongly suggests that SR 80037A provokes the associationof $rho$ with a downstream inhibitor.

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Figure 8. C3 and SR 80037A have identical effect on neuronal morphology. Cumulative distributions according to spreading index (A), axon length (B), and dendrite length (C), as well as the number of primary neurites (D) demonstrate that SR 80037A and C3 have similar effects on the morphology of E16 rat cortical neurons. p < 0.0001, Cdm versus SR 80037A (spreading) and p < 0.001 Cdm versus C3 (spreading). For all other parameters, see Table 1.

HS signaling pathway is primarily activated in the somatodendritic compartment and does not respond to DS

We had shown previously that DSbm, a commercial dermatan sulfate from bovine mucosa, does not provoke cell rounding and doesnot decrease dendrite growth (Lafont et al., 1994; Fig. 9A, Table1). Accordingly, DSbm does not displace radioactive SR 80037Afrom its binding sites at the neuronal surface (Lafont et al.,1994). We, thus, wanted to compare the respective effects of DSbmand SR 80037A on the ADP ribosylation of G_i and $rho$ in the axonaland somatodendritic compartments. To this end, small corticalexplants were cultured in three-dimensional collagen gels, andthe axons were allowed to invade the gels for 100-120 hr. Doublestaining of the explants with anti-MAP2 and anti- $tau$ antibodies(Fig. 9B) illustrates that the axons (green) invade the collagengel, whereas cell bodies and dendrites remain within the explant,with some axons. This experimental design permitted separationof the axonal and the somatodendritic compartments and preparationof the corresponding membranes. Figure 9C illustrates that, forthe same amount of protein, the somatodendritic compartment ishighly enriched with G_i and $rho$ and that the addition of SR 80037Adoes not modify the amount of protein, for example, through proteolysis.Finally, Figure 9D demonstrates that, for an equal amount of membraneproteins, the response to the addition of SR 80037A was much higheron membranes derived from the somatodendritic compartment, stronglysuggesting a polarized distribution of the signaling pathway mediatingthe HS polarizing effect. In addition, the effects of DSbm onG_i or $rho$ ADP ribosylation were absent or small compared with thoseof SR 80037A.

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Figure 9. SR 80037A signaling pathway is specifically activated in the somatodendritic compartment and does not respond to DSbm. A, As opposed to SR 80037A, DSbm does not provoke cell rounding (top panel) and increases dendrite elongation (bottom panel). p < 0.0001, SR 80037A/Cdm (spreading); p < 0.5, DSbm versus Cdm (spreading). For all other parameters, see Table 1. B, Double MAP2/ $tau$ staining of an explant having developed for 100 hr in a collagen gel. Note the separation between axons invading the gel and dendrites that remain within the explant. Dotted lines indicate how somatodendritic and axonal compartments were separated. C, Western blot analysis of the axonal (Ax) and somatodendritic (SD) compartments demonstrates that for an equal amount of membrane proteins the SD compartment is highly enriched in G_i and $rho$ and that the addition of SR 80037A does not induce the degradation of either molecule. D, Incubation of equal amounts of somatodendritic (SD) or axonal (Ax) membranes with SR 80037A (HS) or DSbm (DS) followed by ADP ribosylation of G_i (top panel) or $rho$ (bottom panel) demonstrates that the signaling pathway is enriched in the somatodendritic compartment and does not respond to DSbm.

The latter experiments suggested that SR 80037A acts at the level of the dendrites, inhibiting their initiation when addedvery early after seeding and possibly, as suggested by the ADPribosylation of G_i and $rho$ in the dendrite-derived membranes, theirelongation when added on already differentiated dendrites. Totest the effect of SR 80037A on the growth of already initiateddendrites, the cells were plated and cultured for 24 hr beforethe addition (or not) of SR 80037A and a further 24 hr cultureperiod (Fig. 10A). Figure 10B illustrates that the addition of SR80037A after 24 hr in Cdm provokes cell rounding and reduces dendriteelongation in the following 24 hr but does not modify the rateof axonal growth or the number of primary neurites. These resultsare in accordance with a specific effect of SR 80037A on the somaand at the level of dendritic growth cones.

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Figure 10. SR 80037A is active on already differentiated neurons. A, SR 80037A was added (or not) after 24 hr, and the cells were fixed or culture for another 24 hr. B1, Soma spreading increases between 24 and 48 hr in Cdm but decreases in SR 80037A. p < 0.002, Cdm 24 hr versus Cdm 48 hr; p < 0.0001, Cdm 48 hr versus SR 80037A 24-48 hr; p < 0.003, Cdm 24 hr versus SR 80037A 48 hr. B2, Dendrite length between 24 and 48 hr increases less in SR 80037A than in Cdm. p < 0.02 Cdm 48 hr versus SR 80037A 24-48 hr. B3, Axonal elongation is not modified between 24 and 48 hr by the addition of SR 80037A. p < 0.9, Cdm 48 hr versus SR 80037A 24-48 hr. B4, The number of primary neurites is not modified between 24 and 48 hr by the addition of SR 80036A. p < 0.1 Cdm 48 hr versus SR 80037A 24-48 hr.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The synthesis of proteoglycans (PGs) and GAGs during development is highly regulated (for review, see Small et al., 1996).In vivo expression patterns suggest that these compounds haveimportant functions, for example, at the border of developmentalterritories, as illustrated by the high concentration of a specificchondroitin sulfate at the inter-rhombomeric frontier (Heymanet al., 1995) or around the somatosensory barrels (Faissner andSteindler, 1995). PGs and GAGs have been shown to regulate neuriteelongation in vitro and in vivo (Oohira et al., 1991; Lafont etal., 1992; Brittis and Silver, 1994; Faissner et al., 1994; Fernaud-Espinosaet al., 1994) and are upregulated after lesions of the nervoussystem, suggesting a role during growth and regeneration (Bovolentaet al., 1993; Gates et al., 1996). However, despite the suspectedbiological importance of PGs and GAGs, very little is known regardingtheir mode of action, and several hypotheses have beenproposed.

A first possibility, illustrated by the direct activation, in the absence of FGF, of FGF receptor 4 by heparin (Gao and Goldfarb,1995) is that they act as bona fide growth factors with specificreceptors and signal transduction pathways. A second hypothesiswell substantiated in the case of TGF- $beta$ and FGF-1 or -2 (for review,see Ruoslathi and Yamaguchi, 1991) is that GAGs associate withgrowth factors, modulate their diffusion, prevent their degradation,and help their presentation to specific receptors (Schlessingeret al., 1995). A third proposed mode of action is through bindingto other matrix molecules, for example, laminin (Smalheiser andKim, 1995), and to cell or substrate adhesion molecules (Hayashiet al., 1992).

Here, we used SR 80037A, an HS with specific and saturable neuronal binding sites (Lafont et al., 1994), to investigate theHS signaling pathway involved in the induction of the axonal phenotype(specific reduction in dendrite number and length) in a well establishedmodel of cell polarity (Prochiantz, 1995). We show that SR 80037Aacts through a pathway involving heterotrimeric G-proteins, oneor several PKCs, and $rho$ GTPases. In addition, we have localizedthe SR 80037A-responsive pathway to the somatodendritic compartmentand shown that a dermatan sulfate (DSbm), which does not inhibitSR 80037A neuronal binding, does not activate the same pathway.Our results strongly suggest the existence of receptors highlyenriched at the surface of soma and dendrites, responsible forthe active inhibition of soma spreading and dendrite elongationand activated in the presence of SR80037A.

SR 80037A is a heparin-derived GAG of average MW of 6000 Da, devoid of anticoagulant activity. It can be obtained in largequantities, and its purification procedure eliminates all possibilitiesof contamination by peptides or compounds not related to heparin(Petitou et al., 1992; Petitou and van Boeckel, 1993). More importantly,SR 80037A reproduces the physiological properties of HS GAGs purifiedfrom astrocyte-conditioned medium (Lafont et al., 1992) and ofall active HS-like synthetic GAGs (Lafont et al., 1994). Furthermore,SR 80037A binding to the surface of neurons in culture demonstratedthe existence of a limited number of binding sites (3-5 × 10⁵ per embryonic neuron) with a K_D of 1 µM. Finally, SR 80037A bindingwas displaced by heparin and HS-derived synthetic GAGs but notby DSbm, a dermatan sulfate from bovine mucosa, which, in contrastwith HS GAGs, does not inhibit dendrite growth (Lafont et al.,1992, 1994). SR 80037A is, thus, an ideally suited compound tostart investigating the transduction pathway involved in HS GAGsignaling.

The pharmacological tools used in this study are either classical or prepared in the laboratory by exploiting the capabilityof permeant peptides and phosphopeptides derived from the thirdhelix of Antennapedia homeodomain to translocate across biologicalmembranes (Derossi et al., 1994, 1996, 1998). The advantage ofthis procedure is that the peptides show no toxicity, are internalizedby 100% of the neurons, and gain direct access to the cytoplasmiccompartment. The use of the latter pharmacological tools associatedto that of a transgenic mouse in which a dominant negative FGFreceptor was expressed in postmitotic neurons under the transcriptionalcontrol of the neural specific enolase promoter (Safell et al.,1997) eliminated the possibility that FGF, EGF, or PDGF receptorsare involved in the signaling pathway. The absence of serum andthe high dilution conditions of the culture make it also veryunlikely that SR 80037A signals through a TGF-related receptor.Because NCAM, N-cadherin, and L1 signal through FGF-R1 (Safellet al., 1997), we feel that these three transmembrane moleculescan also be tentatively eliminated from the list of candidatesmediating SR 80037A activity. Our experiments, thus, lead to theconclusion that SR 80037A, after its specific binding to an unidentifiedbinding site, signals through a cascade involving, in this order,heterotrimeric G_i, $rho$ , and one or several PKC orPKN.

This pathway is reminiscent of that described for lisophosphatidic acid (LPA) and leads to a phenotype that also resemblesthat described on neuronal cell lines incubated with LPA (Jalinket al., 1994; Moolenaar et al., 1997). Indeed, LPA after bindingto an unknown receptor activates G_i and $rho$ , induces the formationof actin stress fibers, and provokes growth cone collapse andcell rounding (Zhang et al., 1997). A striking similarity withSR 80037A is a very rapid cell-rounding phenotype. The resultsobtained with LPA and SR 80037A are in agreement with the observationthat C3, a bacterial toxin that ADP ribosylates $rho$ , inhibits theformation of dendrites by neocortical neurons (Threadgill et al.,1997).

The effect of SR 80037A on neuronal rounding and dendrite initiation does not require that SR 80037A be present for >1 hr.It is, thus, conceivable that, after SR 80037A addition, a pathwayis activated that maintains the cell, at least for 19 hr, in anHS phenotype (cell rounding and no dendrites growing). No proteinsynthesis is required for the immediate rounding phenotype becauseit is preserved in the presence of cycloheximide. In contrast,the long-term effect, illustrated by the inhibition of dendriteelongation, requires protein synthesis. This suggests an accumulationof transiently active intracellular signals that activates thesynthesis of downstream effectors. The nature of the signals hasnot been investigated in detail. We could eliminate NF- $kappa$ B because,although the latter factor is present in the cell cytoplasm, theaddition of SR 80037A does not induce its nuclear translocation(data not shown; Perona et al., 1997). In contrast, preliminaryresults suggest that SR 80037A interferes with MAP-K activity(S. Calvet, M. Petitou, and A. Prochiantz, unpublishedresults).

Finally, we have developed an assay allowing the direct assessment of SR 80037A activity on membranes derived purely fromaxons or from a combination of somas, dendrites, and some axons.A striking result is that the inhibition of G_i or $rho$ ADP ribosylation,taken as evidence for SR 80037A signaling, occurs only in somatodendriticmembranes, an observation in good accordance with a role of $rho$ on dendritic remodeling (Threadgill et al., 1997). Furthermore,the inhibition of $rho$ and G_i ADP ribosylation by GAGs is specific,because it is not observed with a DS-type GAG that does not recognizethe neuronal binding sites for SR 80037A (Lafont et al., 1994)and does not inhibit dendriteelongation.

Our results can be discussed in the frame of the model schematized in Figure 11 (for details, see Prochiantz, 1995). In thismodel, there exists a threshold of spreading below which dendritegrowth is inhibited, whereas axonal elongation is still possible.We propose that SR 80037A, by its effect on cell rounding, drivesthe cell into a no-dendrite state still allowing axonal elongation(Fig. 11A). Because the cells are put in culture at the neuroblaststage (E16 rat or mouse embryos), this suggests that the conditionsnecessary for axonal elongation differ already at the neuroblaststage from those necessary for dendritic elongation and, therefore,that neuronal polarity preexists well before it is materializedunder the form of true axons and dendrites. This proposal is supportedby the addition of SR 80037A on cells that have already differentiatedfor 24 hr (Fig. 11B), suggesting that the sugar has a similar stop-growtheffect on the initiation of dendrites (Fig. 11A) and on their elongation(Fig. 11B). The physiological consequences of these observationsmight be of importance, because they suggest that PGs or GAGscould act as regulators of dendrite growth and that borders mightexist that would specifically restrict dendritic development butcould be ignored by elongating axons.

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Figure 11. Hypothetical scheme. A, Specific binding of SR 80037A provokes cell rounding and drives the cells into a state in which dendrite initiation is not possible. In contrast, the axon can still initiate and elongate. This suggests that axons differ from dendrites very early in the course of neuronal differentiation. B, The addition of SR 80037A 24 hr after the major neurites have started to grow provokes cell rounding and stops dendrite elongation but has no effect on axonal growth. This suggests that initiation and elongation of dendrites are sensitive to the addition of SR 80037A and lends weight to the idea that the soma is already polarized at the time of neurite initiation.

  FOOTNOTES

Received June 25, 1998; revised Sept. 10, 1998; accepted Sept. 22, 1998.

This work was supported by Centre National de la Recherche Scientifique, Ecole Normale Supérieure, Sanofi-Recherche, andEC Program BIOMED 950524. We thank Dr. M. Petitou (Sanofi-Recherche)for his participation in several practical and theoretical aspectsof thiswork.
Correspondence should be addressed to A. Prochiantz, Centre National de la Recherche Scientifique, Unité de Recherche Associée1414, Ecole Normale Supérieure, 46 rue d'Ulm, 75230 Paris Cedex05,France.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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