A Ganglioside-Specific Sialyltransferase Localizes to Axons and Non-Golgi Structures in Neurons

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The Journal of Neuroscience, March 1, 2001, 21(5):1434-1443

A Ganglioside-Specific Sialyltransferase Localizes to Axons and Non-Golgi Structures in Neurons
Charlene A. Stern and Michael Tiemeyer
Department of Cell Biology, Yale University School of Medicine, New Haven, Connecticut 06510

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To investigate the tissue distribution and subcellular localization of ST3GalV (CMP-NeuAc:lactosylceramide $alpha$ 2,3 sialyltransferase/GM3synthase) in the adult mouse, we generated two antisera againstmouse ST3GalV that were designated CS2 (directed against aminoacids K227-I272) and CS14 (directed against amino acids D308-H359).We previously reported that CS2 antiserum stains medial and trans-Golgicisternae in all cell types investigated. In neural tissue, however,CS14 antiserum reveals a subpopulation of ST3GalV with a subcellulardistribution complementary to CS2 antiserum. CS14 antiserum stronglystains axons in cortical, cerebellar, brainstem, and spinal cordtissue sections. The subcellular localization of neuronal ST3GalVis maintained in primary cultures of rat hippocampal neurons andin PC12 cells. In PC12 cells, ST3GalV localization evolves duringNGF-induced differentiation such that a pool of enzyme leavesthe Golgi for a distal compartment in conjunction with neuriteoutgrowth. In PC12 cells transfected with an epitope-tagged formof ST3GalV, staining for the epitope tag coincides with expressionof endogenous enzyme. The non-Golgi pool of ST3GalV does not colocalizewith markers for the trans-Golgi network, endosome, or synapticvesicles, nor is it detected on the cell surface. Distinct subpopulationsof ST3GalV imply that ganglioside synthesis can occur outsideof the Golgi or, alternatively, that a portion of the total ST3GalVpool subserves a nonenzymatic function. Significantly fewer transfectedcells were found in PC12 cultures treated with plasmid encodingST3GalV than in cultures treated with control plasmid, indicatingthat the expression of ST3GalV in excess of endogenous levelsresults in either cell death or a decreased rate of celldivision.

Key words: ganglioside; neurons; PC12 cells; sialyltransferase; axon; glycolipid synthesis

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The glycosyltransferase ST3GalV (CMP-NeuAc:lactosylceramide $alpha$ 2,3 sialyltransferase or GM3 synthase) catalyzes the additionof sialic acid to a neutral glycosphingolipid acceptor, lactosylceramide,thereby forming ganglioside GM3, the simplest glycosphingolipidbearing a ganglio-series oligosaccharide (van Echten and Sandoff,1993; Tsuji et al., 1996; Ishii et al., 1998; Kono et al., 1998;Fukumoto et al., 1999). In turn, GM3 (NeuAc $alpha$ 3Gal $beta$ 4GlcCer) [nomenclaturebased on Svennerholm (1964)] serves as the precursor for almostall other gangliosides, a class of glycosphingolipids implicatedin transmembrane signaling, cell-cell interactions, specializedmembrane domain formation, and synaptic transmission (Goldenringet al., 1985; Blackburn et al., 1986; Bremer et al., 1986; Kreutteret al., 1987; Nojiri et al., 1988; Tsuji et al., 1988; Hakomoriand Igarashi, 1993; Yamamura et al., 1997). Because GM3 synthesisoccurs early in ganglioside biosynthesis, ST3GalV was predictedto be localized to the cis-Golgi (van Echten et al., 1990; Younget al., 1990; Iber et al., 1992; Maccioni et al., 1999). However,biochemical and immunohistochemical localization studies havedemonstrated that ST3GalV is found in both medial and trans-Golgicisternae (Lannert et al., 1998; Stern et al., 2000). The exclusionof ganglioside synthetic enzymes from the early Golgi, combinedwith the broad distribution of ST3GalV in the remaining Golgi,indicates that the topographic distribution of glycolipid-directedglycosyltransferases differs from the restrictive spatial hierarchycharacteristic of glycoprotein oligosaccharide-processing enzymes.Furthermore, it implies that mechanisms governing subcellularlocalization and compartmental retention of glycolipid-directedglycosyltransferases may be specific for this class of enzymesand are deserving therefore of directinvestigation.

Definition of the topography of glycolipid synthetic enzymes in neurons is of particular importance because many proposedfunctions for gangliosides require the presence and maintenanceof glycosphingolipid along the axon or at the nerve terminal.Glycosphingolipids constitute ~15% of total neuronal membrane(Futerman and Banker, 1996). Although Golgi synthesis and vesiculartransport can provide a constitutive supply of glycolipid, dynamiclocal synthesis would offer a more immediately responsive poolof ganglioside for the modulation of growth factor signaling andmembrane domain formation (Hakomori and Igarashi, 1995; Mutohet al., 1995; Grimes et al., 1997; Hakomori et al., 1998). Infact, the existence of extra-Golgi glycosyltransferase activitiesin neurons has been suggested previously by the detection of twodistinct sialyltransferase activities, one protein-directed andone lipid-directed, in synaptosomal membranes prepared from calfcortex (Preti et al., 1980) and by the detection of an additionalglycolipid synthase in rat brain (Durrie et al., 1987, 1988).The difficulty inherent in preparing synaptosomal membranes freeof Golgi contamination has limited, however, the interpretationof results derived from subcellular fractionation (Ng and Dain,1977; Durrie et al., 1988). Alternatively, immunohistochemicalprobes provide a powerful complementary approach to investigatingthe subcellular distribution of glycosyltransferases (Taatjeset al., 1988; Daniotti and Maccioni, 1997; Maccioni et al., 1999;Stern et al., 2000).

We have investigated the subcellular distribution of mouse ST3GalV (mST3GalV) using two different antisera raised againstnonoverlapping peptide regions. Our immunolocalization revealstwo distinct pools of ST3GalV in neurons. As expected, mST3GalVis localized to the Golgi apparatus but is also found in axonsthroughout the adult neuraxis. Similarly, dual localization isseen in primary cultures of rat hippocampal neurons and in PC12cells. Epitope-tagged ST3GalV (C-terminal myc) expressed in PC12cells demonstrates the same distribution as endogenous enzyme.By confocal microscopy, ST3GalV fails to colocalize with markersfor known post-Golgi vesicular pools, placing the non-Golgi associatedpool of ST3GalV in a novelcompartment.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials. DMEM high-glucose media, horse serum, fetal calf serum, glutamine, penicillin, and streptomycin were obtained fromLife Technologies (Gaithersburg, MD). Nerve growth factor (NGF)(2.5S, type II) was obtained from Boehringer Mannheim (Indianapolis,IN). Secondary antibodies (HRP-conjugated and fluorescein-conjugatedgoat anti-rabbit, Texas Red-conjugated goat anti-mouse and unconjugatedgoat anti-rabbit IgG) were from Jackson Laboratories (West Grove,PA). pcDNA 3.1 ( $-$ )myc/His expression vector, Protein A Sepharose,laminin, collagen type I from rat tail, and poly-L-lysine weresupplied by Sigma (St. Louis, MO). pATH11 vector was from AmericanType Culture Collection (Manassas, VA). Affigel 15 resin was fromBio-Rad (Hercules, CA). ECL reagent was from Amersham PharmaciaBiotech (Arlington Heights, IL). Swiss Webster-CD1 mice were obtainedfrom Charles River Laboratories (Wilmington, MA). Monoclonal antibodyagainst MAP2 (clone HM2) was obtained from Sigma. Monoclonal antibodyagainst c-myc epitope (9E10) was provided by Pocono Rabbit Farmand Laboratory (Canadensis, PA), monoclonal antibody against transferrinreceptor by I. Mellman (Yale University, New Haven, CT), antiserumagainst mannosidase II by P. Cresswell (Yale University), monoclonalantibody against synaptobrevin by P. DeCamilli (Yale University),and monoclonal antibody against TGN-38 by K. Howell (Universityof Colorado School of Medicine, Denver, CO). All other chemicalsand reagents were obtained from standard commercialsources.

mST3GalV antibody production. The preparation of anti-mouse ST3GalV antiserum, designated CS2, has been described previously(Stern et al., 2000). Another antiserum to mouse ST3GalV was raisedagainst a TrpE fusion protein in rabbit. Nucleotides 922-1077(D308-H359) were subcloned into pATH11 vector, and the fusionprotein was expressed after induction in Escherichia coli XL-1Blue (Koerner et al., 1991). Fusion protein was prepared and injectedinto rabbits as described previously (Stern et al., 2000). Theharvested serum was designated CS14, and a portion was affinitypurified by binding to and eluting from an Affigel 15 column coupledwith mST3GalV-TrpE fusion protein. All protein determinationswere made by the bicinchoninic acid assay (Smith et al., 1985).

Western blot and immunodepletion. Enriched Golgi membrane fractions were prepared from adult mouse brains as described previously(Fleischer and Kervina, 1974; Ma and Colley, 1996). Western blotanalysis was performed on aliquots of membrane preparations asdescribed previously (Stern et al., 2000). The primary antiserumdilution for CS14 was 1:5000. No difference was detected betweenblots probed with affinity-purified or nonpurifiedserum.

For immunodepletion with anti-mouse ST3GalV antisera, CS2 or CS14 antiserum was bound to Protein A Sepharose for 2 hr at ambienttemperature. Mouse brain extract (4 µg of protein) was solubilizedin 50 mM Tris, pH 7.6, 100 mM NaCl, and 1% Triton X-100 and preclearedby incubation with Protein A Sepharose for 45 min at 4°C. Preclearedextract was incubated with CS2- or CS14-loaded Protein A Sepharosefor 2 hr at 4°C and then centrifuged to pellet the Protein A Sepharose;the supernatant was recovered. An aliquot of the supernatant (5%)was prepared for SDS-PAGE by reduction with 50 mM dithiothreitolfollowed by sulfhydryl alkylation with 250 mM iodoacetamide (Sternet al., 2000). Samples were then electrophoresed and transferredto nitrocellulose (Harlow and Lane, 1988). The blots were blockedin 5% dry milk and 0.2% Tween 20 in PBS and incubated with primaryantiserum (CS2 or CS14) diluted 1:5000 and then with secondaryantibody (HRP-conjugated goat anti-rabbit) diluted 1:5000. Antibodybinding was detected by ECL reagent using the manufacturer's recommendedconditions.

Immunofluorescence staining of mouse tissue sections. Cortical, cerebellar, brainstem, and spinal cord tissue sections fromfour adult mice were prepared as described previously (Stern etal., 2000). Primary antibody (CS14) was diluted 1:100, and secondaryantibody (fluorescein-conjugated goat anti-rabbit) was diluted1:200. Confocal images were acquired on a Zeiss Axiovert 100 microscopeequipped with an argon-krypton laser. Microscope operation andimage acquisition were performed with the Zeiss LSM510 version2.3 software package. Optical sections were taken every 1.0 µmparallel to the coverslip. Acquired images were prepared withAdobe software by minimally adjusting background fluorescencelevels equally across all color channels; the relative fluorescencebetween red and green channels was unaltered from the originalconfocalscan.

Cell culture. PC12 rat pheochromocytoma cells were obtained from P. DeCamilli and cultured in DMEM with 10% horse serum, 5%fetal bovine serum, 0.3 mg/ml glutamine, 12.5 U of penicillin,and 12.5 µg/ml streptomycin (Greene and Tischler, 1976). For differentiationassays, PC12 cells were cultured in low-serum DMEM (1% horse serumplus glutamine, penicillin, andstreptomycin).

PC12 cells were exposed to 1 or 50 ng/ml NGF in low-serum media for 3 d to induce neurite formation and cellular differentiation(Greene and Tischler, 1976; Campbell and Neet, 1995). Cells wereplated on coverslips coated with a laminin/poly-L-lysine substrate(1:6; 33 µg/ml laminin and 0.2 mg/ml poly-L-lysine) for double-labelimmunofluorescence staining or with a collagen/poly-L-lysine substrate(25:1; 250 µg/ml collagen and 10 µg/ml poly-L-lysine) for quantitationof cell survival and proliferation. Transfected cells were quantitatedfrom images acquired using IP Lab digital imaging software (Scanalytics,Fairfax, VA) and a Zeiss axiophot microscope. For each experiment,at least 10 fields were counted to give >100 cells per experiment.In total, >4000 cells were counted at 0 ng/ml NGF, and >1900 cellswere counted at 50 ng/mlNGF.

Primary cultures of postnatal day 5-13 rat hippocampal neurons were obtained from I. Mellman (Brewer et al., 1993; Winckleret al., 1999) and P. DeCamilli (Banker and Cowan, 1977; Bartlettand Banker, 1984; Chilcote et al., 1995). Cultured neurons werefixed and stained as described for PC12cells.

Transfection of PC12 cells. Myc-tagged fusion constructs of mouse ST3GalV were generated by directional cloning of mouse ST3GalVat nucleotides $-$ 7 and 1077 using EcoRI and KpnI restriction sitesin pcDNA 3.1 ( $-$ )myc/His expression vector downstream of the CMVpromoter. Constructs contain the mouse ST3GalV translational startsite. PC12 cells (2.5 × 10⁵) were transfected with 20 µg of myc-tagged mouse ST3GalV or controlpcDNA 3.1 vector DNA by electroporation with a Bio-Rad electroporator.After electroporation, cells were recovered in low-serum mediaand plated at a density of 1.0 × 10⁵ cells per 3.5 cm well. After 18 hr, we added fresh low-serummedia containing 0, 1, or 50 ng/ml NGF. During the 3 d differentiationperiod, NGF was added in fresh media every 24 hr. Before fixation,cells were washed with PBS that was warmed previously to 37°C.Then PC12 cells were fixed with 4% paraformaldehyde and 4% sucrosein PBS, prewarmed to 37°C for 15 min, and washed three times with120 mM sodium phosphate, pH 7.4. Alternatively, PC12 cells werefixed for 8 min with methanol prechilled to $-$ 20°C and then washedthree times with 120 mM sodium phosphate, pH 7.4.

Immunofluorescence staining of PC12 cells. Fixed PC12 cells were sequentially washed twice for 5 min in 120 mM sodium phosphate,pH 7.4, then in low-salt buffer (150 mM NaCl, 10 mM sodium phosphate,pH 7.4), and finally in high-salt buffer (500 mM NaCl, 20 mM sodiumphosphate, pH 7.4). Coverslips were blocked for 30 min in 15%normal goat serum, 0.3% Triton X-100, 0.3 M NaCl in 0.04 M sodiumphosphate, pH 7.4. Primary antibody dilutions were 1:100 for CS14,1:200 for anti-mannosidase II antiserum, 1:500 for anti-myc antiserumand anti-synaptobrevin antiserum, and 1:10 for anti-TGN38 andanti-transferrin receptor antibodies. Incubation with primaryantibody was performed for 2 hr in a humidified chamber. Coverslipswere then washed in high-salt buffer and incubated in secondaryantibody, fluorescein-conjugated goat anti-rabbit and/or TexasRed-conjugated goat anti-mouse at 1:200. After two washes in high-saltbuffer and one wash in 120 mM sodium phosphate buffer, pH 7.4,all coverslips were mounted in 4% w/v 1,4-diazabi-cyclo[2,2,2]octanein 50% glycerol in PBS. Confocal images were acquired as describedabove.

For PC12 cell surface staining, PC12 cells were treated with either 0 or 50 ng/ml NGF for 3 d. Before staining, cells werewashed briefly in cold PBS and chilled on ice for 15 min in 0.02%sodium azide in PBS. Probes were diluted 1:100 (CS14 antiserum)or 1:500 (anti-c-myc antiserum or Texas Red-conjugated wheat germagglutinin) in 5% normal goat serum, 0.02% sodium azide in PBS.Primary antibody incubation was performed for 15 min on ice. Cellswere then washed in PBS and blocked in 15% normal goat serum,0.3% Triton X-100 in PBS for 15 min before the addition of secondaryantibody. Either fluorescein-conjugated goat anti-rabbit or goatanti-mouse was used at a dilution of 1:200 in 15% normal goatserum, 0.3% Triton X-100 in PBS; incubation was performed for90 min. Cells were washed in PBS and mounted as describedabove.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antiserum CS14 reveals a non-Golgi pool of mST3GalV in neurons

Immunostaining with an anti-mST3GalV antiserum designated CS2 (raised against amino acids K227-I272) has shown that a poolof GM3 synthase is localized to medial and trans-Golgi compartments(Fig. 1A) (Stern et al., 2000). However, another anti-mST3GalVantiserum, designated CS14 (directed against the most C-terminal52 amino acids, D308-H359), reveals a non-Golgi pool of this keyganglioside synthetic enzyme. In cerebellar tissue sections, forinstance, axons coursing through the granule and Purkinje celllayers are stained with CS14 antiserum. Parallel processes areseen in the molecular layer, and multiple axon profiles are visiblein the white matter of the cerebellum (Fig. 1B). Furthermore,CS14 immunostaining is complementary to CS2 immunostaining inneurons. An elaborate Golgi apparatus is apparent in Purkinjecells stained with CS2 antiserum, but Purkinje cells are completelydevoid of Golgi staining when stained with CS14 antiserum (Fig.1A,B). However, the adjacent molecular layer shows parallel fiberstaining (Fig. 1C), and axons reactive with CS14 antiserum areseen weaving between granule cells (Fig. 1D, arrow) or are visualizedin cross section (arrowhead) within the granule layer. The whitematter tracts of the cerebellum, consisting primarily of oligodendrocytesand axonal processes, show concentrated CS14 axonal staining.

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Figure 1. Anti-mST3GalV antisera reveal distinct subpopulations of ST3GalV in cerebellar tissue sections. A, CS2 antiserum stains large perinuclear puncta identified as medial trans-Golgi (Stern et al., 2000) in cerebellar Purkinje cells (Pu, arrowhead). In granule cells (Gr), mST3GalV is restricted to a single locus in each cell. B, Cerebellar molecular and Purkinje cell layers show processes staining with CS14 antiserum extending around the Purkinje cells, with no CS14 immunore activity observed in Purkinje cell bodies (arrowhead). In the molecular layer (Mo) immediately adjacent to the Purkinje cell layer (Pu), parallel fibers strongly stain with CS14 antiserum. A decreasing gradient of parallel fiber staining exists toward the pial surface. C, Axons stained with CS14 antiserum are observed extending in the molecular layer (Mo) through the Purkinje cell layer (Pu) and within the granule cell layer (Gr). In this section, axonal processes are oriented primarily in cross section throughout the cerebellar white matter (Wm). D, Higher magnification of granule cell layer. CS14-immunoreactive neuronal processes are seen both in longitudinal section (arrow) and cross section (arrowhead) within the granule cell layer. CS14 antiserum staining is also observed in the white matter. Scale bars: A, B, 17 µm; C, 41 µm; D, 34 µm.

CS14 antiserum reveals a non-Golgi distribution of mST3GalV in all neurons. Within the spinal cord, CS14 staining is seenin axon fascicles coursing through the gray matter and in ascendingand descending tracts within the white matter (Fig. 2A). In crosssection (Fig. 2B), profiles of small-caliber axons (arrow) areuniformly stained. In large-caliber axons (thin arrows), however,a peri-axonal ring of staining is evident, consistent with thepresence of the enzyme in close association with the axolemmaor with the innermost myelin lamellae. CS14-reactive ST3GalV wasnot apparent in layers of compacted myelin (small arrowhead).Punctate staining within the axon profile was also observed inlarge-caliber axons (arrowhead). CS14 antiserum also reveals anon-Golgi pool of ST3GalV in all brainstem and cortical regionsexamined (data not shown).

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Figure 2. mST3GalV localizes to axons in spinal cord sections. A, A montage of the ventrolateral region of the spinal white matter of the cervical spinal cord (Wm, white matter; Vh, ventral horn). CS14 stains axons cut in cross section within white matter, and a fine meshwork of axons is seen in the ventral horn. B, Higher magnification of spinal white matter reveals that CS14 antiserum stains axons differentially depending on their caliber. Large axons exhibit a peri-axolemmal ring of staining (thin arrows) within which punctate staining is also observed (arrowhead). Dark regions surrounding large-caliber axons are the nonstaining regions of compact myelin (small arrowhead). Smaller caliber axons (arrow) stain throughout the diameter of the process. Scale bars: A, 56 µm; B, 15 µm.

The non-Golgi pool of mST3GalV is preserved in cultured cells of neural origin but is undetectable in non-neural cells

Primary cultures of rat hippocampal neurons display CS14 staining similar to intact tissue. CS14 reactivity is found bothin the cell body and confined to a single neuronal process (Fig.3A). MAP2 staining, which reveals the dendritic arbor of the neuron(Caceres et al., 1984), fails to colocalize with CS14 immunoreactivity,indicating that ST3GalV is preferentially localized to the axon.In the NGF-inducible cell line PC12, CS14 antiserum stains allneuritic processes in addition to a portion of the cell body correspondingto the Golgi apparatus (Fig. 3B). The non-Golgi distribution ofST3GalV was equally apparent when cells were fixed with cold methanolor aldehyde-based fixatives.

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Figure 3. CS14 antiserum stains axons in primary cultures of rat hippocampal neurons and neurites of PC12 cells. A, CS14 (green) immunoreactivity fails to colocalize with the MAP2 antibody (red) in primary culture rat hippocampal neurons. B, CS14 antiserum stains both the cell body and neurites (arrow) of NGF-induced PC12 cells. Scale bars: A, 60 µm; B, 34 µm.

In non-neural cells, CS14 antiserum only stains the Golgi, implying that the complementary distribution of CS2 and CS14 epitopesdetected in nervous tissue arises from a neural-specific modificationof the polypeptide. For instance, CS14 antiserum stains Golgiin numerous cell types of the seminiferous tubules, includinggerm cells (spermatogonia and primary spermatocytes), Leydig cells(Fig. 4A), and Kupffer cells in the liver (data not shown); identicalstaining of seminiferous tubule cell types and Kupffer cells wasobserved with the Golgi-specific anti-ST3GalV antiserum, CS2 (Sternet al., 2000). The ability of CS14 antiserum to stain ST3GalVin neural tissue sections was abolished by the immunoadsorptionof antiserum with immobilized fusion peptide (Fig. 4B,C).

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Figure 4. CS14 antiserum stains Golgi in non-neural cell types, and neural staining is inhibited by relevant peptide. A, CS14 antiserum stains Golgi in testis cell types, including spermatogonia (arrows), primary spermatocytes (thin arrow), and Leydig cells (arrowheads). B, C, Immunoadsorption of CS14 antiserum with peptide abolishes axonal staining in spinal cord tissue sections. Scale bars: A, 43 µm; B, C, 34 µm.

The anti-ST3GalV antisera CS2 and CS14 recognize a single polypeptide and cross-immunodeplete the same protein

By Western blot analysis, CS2 and CS14 antisera recognize a single protein of 45 kDa in membrane preparations from mouse brain(Fig. 5), liver, and testis (Stern et al., 2000) (data not shown),consistent with the predicted molecular weight of mouse ST3GalV(41,263 Da with between one and three N-linked oligosaccharides).Preimmune serum does not exhibit reactivity. Furthermore, CS2antiserum depletes a band recognized by CS14 antiserum from tissueextracts (Fig. 6B), and, likewise, CS14 antiserum depletes a bandrecognized by CS2 antiserum (Fig. 6C). These results are consistentwith both CS2 and CS14 antisera recognizing mST3GalV in adultmouse brain membrane preparations.

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Figure 5. Both anti-mST3GalV antisera, CS2 and CS14, recognize a single protein band by Western blot. A single polypeptide of 45 kDa apparent molecular weight is recognized by both CS2 (A) and CS14 (B) antisera in Golgi-enriched membrane preparations from adult mouse brain.

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Figure 6. Anti-mST3GalV antisera, CS2 and CS14, cross-immunodeplete mST3GalV from mouse brain extracts. A, ST3GalV schematic diagrams the peptides used as immunogens to generate CS2 (hatched box) and CS14 (stippled box) antisera. Also shown are the amino-terminal transmembrane domain (box with x) and the highly conserved L- and S-sialyl motifs (black boxes). B, C, Mouse brain extracts were incubated with Protein A Sepharose previously loaded with the indicated volume of antiserum (CS2 IP or CS14 IP). After centrifugation to pellet the Sepharose beads, aliquots of the supernatants were subjected to SDS-PAGE and Western blot analysis with the indicated antisera. Both antisera were able to quantitatively deplete the extract of ST3GalV, whether recognized by CS2 or CS14.

mST3GalV localizes to PC12 cell neurites after induction with NGF

In undifferentiated PC12 cells, mST3GalV localizes to the Golgi apparatus (Fig. 7A,C,E,G). On induction with NGF, the Golgiincreases in size (Rhodes et al., 1989), and a pool of ST3GalVappears within the extending PC12 cell neurite (Fig. 7B,D,F,H).Myc-tagged ST3GalV is detected in the same subcellular distributionas endogenous ST3GalV (Fig. 7C,D); CS14 and anti-myc antiserastaining colocalize throughout the Golgi and neurites in PC12cells transfected to express myc-mST3GalV (Fig. 7E,F). Becauseonly a portion of the total ST3GalV population colocalizes withmannosidase II (a medial trans-Golgi marker), the pool of ST3GalVdistributed into neurites is not a result of an aberrant elaborationof the Golgi apparatus in NGF-induced PC12 cells (Fig. 7G,H) (Stieberet al., 1987; Rabouille et al., 1995).

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Figure 7. ST3GalV localizes to neurites after induction with NGF in PC12 cells. A, C, E, G, ST3GalV localizes to Golgi in undifferentiated PC12 cells. B, D, F, H, After induction with 50 ng/ml NGF for 3 d, ST3GalV is also found in PC12 neurites. A, B, Endogenous ST3GalV stained with CS14 antiserum. C, D, Myc-tagged mST3GalV detected by anti-c-myc antiserum after transfection of the tagged construct into PC12. E, F, Colocalization of CS14 antiserum (green) and anti-c-myc antiserum (red). G, H, Colocalization of medial trans-Golgi marker, anti-mannosidase II (green), and anti-c-myc (red). Scale bar, 34 µm.

The non-Golgi pool of mST3GalV is not at the cell surface, nor does it colocalize with markers for known post-Golgi vesicular compartments

Staining of nonpermeabilized PC12 cells with anti-ST3GalV antisera failed to detect the presence of the enzyme at the cellsurface. Both endogenous ST3GalV (visualized by CS14 antiserum)and myc-tagged ST3GalV (visualized by anti-myc antiserum) failedto stain the cell surface as defined by colocalization with wheatgerm agglutinin (data not shown). Double-labeling experimentswith CS14 antiserum and markers for the trans-Golgi network, endosomalmembranes, or synaptic vesicles were performed to identify othersubcellular compartments in which the axonal pool of ST3GalV mightreside. Endogenous mST3GalV does not colocalize with TGN38, atrans-Golgi network marker (Luzio et al., 1990). Although partialcolocalization in the differentiated PC12 cell suggests that ST3GalVpasses through the trans-Golgi network (Fig. 8B), the Golgi-associatedpool of ST3GalV predominantly remains distinct from the trans-Golginetwork. The distal ST3GalV pool is distributed away from thecell body and TGN38 (Fig. 8C).

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Figure 8. ST3GalV does not colocalize with trans-Golgi network, endosomal, or synaptic vesicle markers. A-C, Endogenous ST3GalV (green) and TGN38 (red) maintain distinct sub-Golgi compartmentalization in both undifferentiated (A) and differentiated PC12 cells (B, C). B, Some partial colocalization is observed, suggesting that ST3GalV passes through the trans-Golgi network as it moves to a more distal neurite location. D-F, ST3GalV (green) also fails to colocalize with endosomes marked by transferrin receptor (red). D, In undifferentiated PC12 cells, the anti-transferrin receptor staining surrounds the CS14 antiserum Golgi staining. E, In the fully differentiated PC12 cell, both CS14 and transferrin receptor staining become more diffuse throughout the cell body, but both maintain distinct subcellular locations. F, CS14 antiserum stains ST3GalV along the neurite process but is not located at the neurite terminus that stains red with anti-transferrin receptor antiserum (arrow, neurite terminus). G-I, Colocalization of ST3GalV (green) with the synaptic vesicle marker, synaptobrevin (red). G, H, Either without NGF treatment or in the cell body of the fully differentiated PC12 cell, there is some partial colocalization between ST3GalV and synaptobrevin, reflecting the processing of synaptobrevin. H, I, At the nerve terminus, synaptobrevin and ST3GalV do not colocalize. Scale bar, 34 µm.

Between the trans-Golgi network and the cell surface, two potential post-Golgi locations for ST3GalV are the endosome andthe synaptic vesicles at the nerve terminus. Immunostaining withCS14 antiserum and an anti-transferrin receptor monoclonal antibodydemonstrates that ST3GalV is not localized to the endosome (Fig.8D,E) (Mellman, 1996). Both markers remain in distinct cellularcompartments throughout differentiation. In PC12 cell neurites,for instance, ST3GalV is present for most of the length of theextension, whereas transferrin receptor is clustered at the neuriteterminus (Fig. 8F, arrow). Double immunostaining with CS14 anda synaptic vesicle marker (anti-synaptobrevin) shows that ST3GalVis not directly associated with this pool of recycling membraneeither (Fig. 8H,I) (Baumert et al., 1989; Chilcote et al., 1995).Synaptobrevin and CS14 staining are complementary; CS14 stainingwas never observed extending into the neurite tip. Some colocalizationbetween CS14 and synaptobrevin is observed within the cell bodyand is likely attributable to synaptobrevin staining in the Golgiduring processing (Fig. 8G,H).

Expression of mST3GalV in PC12 cells decreases cell survival or rate of division

Quantitation of the number of transfected cells in a treated PC12 cell population revealed that significantly fewer cellswere found expressing plasmid containing mST3GalV than controlplasmid (GFP plus pcDNA). In undifferentiated PC12 cultures (0ng/ml NGF), there is at least a threefold difference between thenumber of cells expressing control plasmid and those expressingST3GalV-encoding plasmids (p $<=$ 0.0015) (Fig. 9). In the fullydifferentiated PC12 cell population, the effect of ST3GalV overexpressionis less dramatic, with a twofold or less difference between ST3GalVand control plasmids (p $<=$ 0.025).

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Figure 9. Expression of ST3GalV reduces cell survival or rate of division. At 0 ng/ml NGF, at least threefold fewer PC12 cells express ST3GalV-containing plasmid than control plasmid (p $>=$ 0.0015). At 50 ng/ml NGF, the effect of overexpressing ST3GalV is less dramatic. Solid black bars, Cells cotransfected with control plasmid, pcDNA3.1, and GFP encoding plasmids (n $>=$ 3); hatched bars, cells cotransfected with mST3GalV and GFP encoding plasmids (n $>=$ 4); stippled bars, cells transfected with C-terminal myc-tagged mST3GalV (n = 4).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

By raising antisera to nonoverlapping mST3GalV peptides, we have generated immunological probes that define two distinct subcellularpools of this ganglioside synthetic enzyme. Previously, we reportedthe Golgi localization of ST3GalV in adult mouse tissue sectionsusing an antiserum designated CS2 (Stern et al., 2000). Localizationof this pool of ST3GalV is consistent with its synthetic function,the generation of GM3 ganglioside from a lactosylceramide acceptor(Ishii et al., 1998; Kono et al., 1998; Fukumoto et al., 1999).In this study, however, we describe a non-Golgi localization forST3GalV identified with a second antiserum, designated CS14. Thenon-Golgi-associated pool of the enzyme is only observed in neuronsin which CS14 staining is seen along axonal processes in cortical,cerebellar, brainstem, and spinal cord sections. Similarly, inprimary cultures of rat hippocampal neurons, CS14 immunoreactivityis distributed in an axon-like (MAP2-negative)process.

CS14 also reveals a pool of non-Golgi-localized ST3GalV in differentiated PC12 cells. Although ST3GalV is localized to theGolgi in undifferentiated PC12 cells, the enzyme distributes intoextending neurites after NGF treatment. Whether the distributionof endogenous enzyme is visualized by CS14 antiserum or by epitope-taggedmST3GalV in transfected cells, staining exhibits a punctate appearanceconsistent with localization to a vesicular structure. These vesiclesmay transiently pass through the trans-Golgi network, but colocalizationwith compartment-specific markers demonstrates that ST3GalV doesnot accumulate in the trans-Golgi network, in endosomes, or insynaptic vesicles, nor is staining detected at the cellsurface.

Non-Golgi distributions have been described for other glycosyltransferases. In particular, a glycoprotein-directed $beta$ 1,4-galactosyltransferasehas been detected at the cell surface, and several glycosyltransferasesare secreted as a result of cleavage from their membrane anchorwithin the secretory pathway (Nelson et al., 1973; Shur, 1989;Jaskiewicz et al., 1996a; Allende et al., 1997; Cho and Cummings,1997; Zhu et al., 1998; Kitazume-Kawaguchi et al., 1999). Althoughthe expression of epitope-tagged glycosyltransferases in culturedcells has furthered greatly our understanding of the subcellularlocalization of other glycan synthetic enzymes, this study isthe first to investigate the endogenous distribution of a ganglioside-directedglycosyltransferase in neurons located within their normal tissueenvironment. As additional immunological probes directed againstother glycosyltransferases become available, the commonality ofnon-Golgi enzyme localization can be evaluated. Neurons, withtheir highly polarized and spatially distributed morphology, provideunique opportunities to visualize the distribution and transportof suchmolecules.

The specificity of the CS14 antiserum for ST3GalV is demonstrated by several findings. First, both CS2 and CS14 antisera stainthe Golgi apparatus in some non-neural cell types. Second, bothantisera recognize a single, reduced, denatured polypeptide ofthe same apparent molecular weight. Third, by immunoprecipitationfrom brain extracts, either antiserum can deplete the epitoperecognized by the other antibody. And finally, a myc-tagged formof ST3GalV expressed in PC12 cells is found both in the Golgiand in neurites, independently verifying that the enzyme possessestargeting information for localization beyond theGolgi.

The exclusion of the CS14 epitope from the Golgi apparatus of neurons in tissue is of particular interest because CS14 antiserumdoes stain the Golgi in other cell types. It is possible thatboth neural and non-neural cells produce a mixed population ofST3GalV, but neurons effectively segregate CS14-recognized formsfrom CS2-recognized forms. Alternatively, a neuron-specific structuralor post-translational modification may simultaneously reveal theCS14 epitope while masking the CS2 epitope in the axonal poolof ST3GalV. Among the leading candidates for such a structuralmodification are alternate disulfide bond formation, differentialglycosylation, and phosphorylation, all of which have the potentialto mask or generate a peptide epitope. Multiple mature disulfide-bondedand phosphorylated forms of other glycosyltransferases, most notablyof another sialyltranferase, have been suggested to modulate catalyticactivity and participate in Golgi retention (Jaskiewicz et al.,1996b; Ma and Colley, 1996; Ma et al., 1997, 1999; Zhu et al.,1997; Chen et al., 2000). However, in preliminary experiments,treatment of PC12 cells with DTT before fixation had no effecton anti-ST3GalV staining. Although the diversity of ST3GalV glycoformsremains to be determined, the sharp trans-Golgi boundary thatdelimits CS2 from CS14 staining in nervous tissue is most consistentwith a processing event, such as sialylation, inducing differentialepitope display (Nagai et al., 1997; Martina et al., 1998). Regardlessof the nature of the structural difference, we predict that changesin ST3GalV conformation or modification generate differences incompartmental localization andretention.

The endoplasmic reticulum and Golgi apparatus have generally been considered the center for glycosphingolipid synthesis. Therefore,the identification of an axonal distribution for ST3GalV, theactivity of which is required early in ganglioside biosynthesis,implies either that axonal ST3GalV subserves a nonenzymatic functionor that ganglioside biosynthesis, like phospholipid biosynthesis,is more broadly distributed than previously thought (Vance etal., 1991, 1994; de Chaves et al., 1995; Futerman and Banker,1996). Efficient recycling and repair of axolemmal glycosphingolipidsmight partially rely on a pool of synthetic capacity located closerto the sight of insertion than the Golgiapparatus.

Ganglioside recycling occurs via endocytosis, with internalized lipid assuming one of three fates: lysosomal degradation,return to the cell surface, or glycan remodeling before returnto the cell surface (Trinchera et al., 1990; Riboni and Tettamanti,1991; Riboni et al., 1991, 1997; Sofer et al., 1996). However,the subcellular distribution and kinetics of glycosphingolipidrecycling in neurons are poorly defined. Attempts to measure thebulk turnover rate of gangliosides in cultured cells have yieldedwide variations in lipid half-lives (Suzuki, 1970; Van Meer, 1989;Riboni et al., 1996, 1997; Sofer et al., 1996), but studies ofplasma membrane turnover, growth cone retraction, or extensionafter axotomy imply the existence of a rapid mechanism, such aslocal synthesis of ganglioside, that would liberate axonal glycosphingolipidrecycling from complete reliance on anterograde axonal transport(Bray et al., 1978; Wessells et al., 1978; Steinman et al., 1983;Ashery et al., 1996; Diefenbach et al., 1999).

Although the Golgi is still predicted to be the major site of ganglioside synthesis (van Echten and Sandoff, 1993), axonalcompartments containing ST3GalV are poised for direct reglycosylationof glycosphingolipid. Previous reports (Schengrund and Rosenberg,1970; Tettamanti et al., 1972; Schengrund and Nelson, 1975; Chigornoet al., 1986; Miyagi et al., 1990; Varki, 1993; Riboni et al.,1997; Monti et al., 2000) have described the vital importanceof cell surface sialylation and have identified sialidase activityat the plasma membrane of multiple cell types, including neurons.To maintain lipid sialylation levels, cells must either synthesizeand transport new ganglioside or locally sialylate the pool ofdesialylated substrates. Candidate lipid-directed sialyltransferaseactivities have been biochemically identified in nerve terminalpreparations, but the interpretation of such subcellular fractionationstudies has been limited by the difficulty inherent in preparingmaterial free of Golgi membrane contamination (Schengrund andNelson, 1975; Ng and Dain, 1977; Preti et al., 1980; Durrie etal., 1987, 1988). Immunostaining with CS14 antiserum providesindependent evidence that a sialyltransferase is distributed inaxons and nerve termini, but primarily in sub-plasmalemmalvesicles.

Comprehensive local ganglioside synthesis, sialylation, or remodeling requires that additional transferase activities, transporters,and substrates be present in the same compartments. For ST3GalVto function within the axon or nerve terminal as a sialyltransferase,both acceptor (lactosylceramide) and donor sugar-nucleotide (CMP-NeuAc)are necessary. CMP-NeuAc is synthesized in the nucleus (Kean,1991). It is currently unknown whether CMP-NeuAc or the requiredantiport machinery for lumenal transport also exists in axonsand, if so, whether they colocalize with sialyltransferase. Perhapsvesicles containing multiple glycolipid biosynthetic componentsare segregated in the Golgi and transported to their axonal destinationas a preloaded ganglioside synthesome. A complete analysis ofthe localization of all ganglioside-directed glycosyltransferasesand sugar-nucleotide transporters must await the generation ofappropriate antibodies and epitope-tagged constructs but promisesto provide new insight into the regulation and importance of membraneturnover inneurons.

Gangliosides have been implicated in the modulation of signaling through the epidermal growth factor (EGF), NGF (trkA), andPDGF receptors (Igarashi et al., 1989; Hakomori and Igarashi,1993). The relevant lipid modulators range from a single glycolipidspecies (lyso-GM3 downregulates EGF receptor signaling) to theoverall cellular glycolipid profile (Bremer et al., 1984; Noreset al., 1988; Hakomori and Igarashi, 1993; Zhou et al., 1994;Yates et al., 1995; Rebbaa et al., 1996; Sachinidis et al., 1996).In PC12 cells, overexpression of GD3 synthase, an $alpha$ 2,8-sialyltransferasenecessary for synthesis of complex (highly sialylated) gangliosides,leads to depletion of gangliosides like GM3 and GM1 but increasesthe presentation of the complex gangliosides GD1b and GT1b atthe surface of PC12 cells (Fukumoto et al., 2000). In parallelwith the shift in ganglioside sialylation profile, overexpressingPC12 cells no longer extend neurites in response to NGF; ratherthe cells continue to divide as undifferentiated cells (Fukumotoet al., 2000). However, when we overexpress ST3GalV (GM3 synthase)in PC12 cells, we observe no effect on neurite outgrowth but asignificantly smaller than expected population of transfectedcells. Although this may suggest that transfection with ST3GalVleads to higher levels of cell death, it is more likely that celldivision is slowed because transfected cells are fully capableof extending neurites and exhibit no outward signs of impendingdemise. A model suggesting that less sialylated gangliosides decreasecell division and complex gangliosides increase cell divisionis a gross oversimplification, but it is clear that cells mustregulate their ganglioside expression to optimize environmentalresponsiveness.

Finally, it is possible that the non-Golgi pool of ST3GalV has no synthetic capacity, either because it is structurally alteredor because other components necessary for enzyme activity arenot present (CMP-NeuAc, etc.). However, if the non-Golgi poolof the enzyme retains substrate (lactosylceramide)-binding activity,it may function as a lectin, chaperoning lipids through the secretorypathway or participating in the formation or stabilization ofmembrane microdomains (Fiedler et al., 1994; Fiedler and Simons,1996; Simons and Ikonen, 1997; Chigorno et al., 2000; Prinettiet al., 2000). Such a binding activity could also impact the efficacyof transmembrane signaling by sequestering or presenting glycosphingolipidin the appropriate context. Additional characterization of ST3GalVfunction, either through immunological perturbation or the transgenicgeneration of null mutants, should provide important insightsinto ganglioside function in the nervoussystem.

  FOOTNOTES

Received Sept. 18, 2000; revised Dec. 6, 2000; accepted Dec. 11, 2000.

This work was supported by National Institutes of Health-National Institute on Child Health and Human Development Grant HD33878,by a Basil O'Connor Award from the March of Dimes, and by ThePatrick and Catherine Weldon Donaghue Foundation (all to M.T.).C.S. received support from National Institutes of Health-NationalInstitute of General Medical Services Grant GM07223. We thankmembers of the Pietro DeCamilli and Ira Mellman laboratories forimmunological probes and neuronal primary cultures. We also thankKatherine Howell for immunologicalprobes.
Correspondence should be addressed to Michael Tiemeyer, Glyko, Inc., 11 Pimentel Court, Novato, CA 94949. E-mail: mtiemeyer{at}glyko.com.

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DISCUSSION
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