Cysteine String Proteins Associated with Secretory Granules of the Rat Neurohypophysis

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Volume 17, Number 8, Issue of April 15, 1997 pp. 2722-2727
Copyright ©1997 Society for Neuroscience

Cysteine String Proteins Associated with Secretory Granules of the Rat Neurohypophysis

Sandrine Pupier¹, Christian Leveque¹, Beatrice Marqueze¹, Masakazu Kataoka², Masami Takahashi², and Michael J. Seagar¹
¹ Institut National de la Santé et de la Recherche Médicale U464, Institut Jean Roche, Faculté de Médecine Secteur Nord, 13916 Marseille Cedex 20, France, and ² Mitsubishi Kasei Institute of Life Science, Machida, 194 Tokyo, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The properties and subcellular distribution of cysteine string proteins (csps) were analyzed in peptidergic nerve terminalsof the rat neurohypophysis. Polyclonal antibodies raised againstrecombinant rat brain csp recognized a 36 kDa protein in isolatedneurosecretosomes from the post-pituitary. After chemical deacylation,a single 27 kDa form was detected that displayed identical propertiesto csps in a whole-brain synaptosomal fraction. Immunoisolationdemonstrated that synaptophysin and csps were located in the samevesicles. Density gradient centrifugation of postsynaptosomalsupernatants of neurohypophysial homogenates revealed that cspsand VAMP were present in two distinct vesicle populations. Synaptophysinwas only detected in the slowly migrating population correspondingto small synaptic vesicles, whereas arginine vasopressin was presentin the more rapidly sedimenting population indicating that itcontains large dense core vesicles (LDCVs). Immobilized antibodiesagainst csp, synaptotagmin, or VAMP captured vesicular argininevasopressin confirming the association of these proteins withLDCVs. Co-immunoprecipitation assays with proteins solubilizedfrom neurohypophysial or whole-brain nerve terminals failed toreveal complexes containing csp and [¹²⁵I] $omega$ GVIA receptors. These results indicate that csps in the CNSare associated with both small synaptic vesicles and LDCVs. However,they do not provide support for the hypothesis that protein complexesimplicated in exocytosis, which interact with presynaptic N-typecalcium channels, contain csps.
Key words: cysteine string proteins; VAMP; calcium channels; large dense core vesicles; synaptic vesicles; neurohypophysis

INTRODUCTION

Neurotransmitter release is triggered by calcium influx through voltage-gated calcium channels, and much progress has beenachieved in recent years in identifying proteins and protein-proteininteractions involved in the trafficking, docking, and calcium-dependentexocytosis of secretory vesicles (for review, see Martin, 1994;Sudhof, 1995; Augustine et al., 1996).

Cysteine string proteins (csps) were first discovered in Drosophila as antigens recognized by a monoclonal antibody that selectivelystains neuropil regions and synaptic boutons (Zinsmaier et al.,1990) and were subsequently shown to be expressed in fish (Gundersenand Umbach, 1992) and mammals (Mastrogiacomo and Gundersen, 1995;Chamberlain and Burgoyne, 1996; Chamberlain et al., 1996; Coppolaand Gundersen, 1996). Csps contain a fatty acylated string ofcysteine residues (Gundersen et al., 1994) and a J domain homologousto motifs in bacterial DnaJ proteins that regulate the chaperonactivity of DnaK, a Hsp70-like protein (for review, see Cyr etal., 1994).

The precise role of csps is unknown, although they appear to be involved in evoked neurotransmitter release. Deletion of thecsp gene in Drosophila causes temperature-sensitive failure ofsynaptic transmission resulting in paralysis and death (Zins-maier et al., 1994), the defect being attributable to impaireddepolarization-secretion coupling at nerve terminals (Umbach etal., 1994).

A cDNA encoding a highly homologous Torpedo csp was independently isolated in a cloning strategy designed to identify componentsnecessary for the functional expression of presynaptic $omega$ -CTx-GVIA( $omega$ GVIA)-sensitive calcium channels in Xenopus oocytes (Gundersenand Umbach, 1992). Although Torpedo csps seem to act as positiveregulators of calcium channels in the plasma membrane, in theelectric organ, they are apparently localized at the cytoplasmicsurface of synaptic vesicles (Mastrogiacomo et al., 1994). Thisled to the proposal that subsequent to vesicle docking at theplasma membrane, interactions between the calcium channel andcsp may be necessary for channels associated with docked vesiclesto open in response to depolarization (Mastrogiacomo et al., 1994).

At least two types of secretory vesicle participate in calcium-dependent exocytosis in the CNS. Neurotransmitters such asglutamate, acetylcholine, and GABA are stored in small synapticvesicles (SSVs), and release occurs with a submillisecond delayafter calcium influx. In contrast, the secretion of peptides andneurohormones from large dense core vesicles (LDCVs) displaysa significantly slower response to calcium elevation (Martin,1994; Augustine et al., 1996). The molecular basis for the differencein latency is not understood but may involve differences in proteincomposition between the two types of vesicles. Thus, we have examinedthe subcellular distribution of csps and explored their interactionwith presynaptic calcium channels in peptidergic terminals ofthe rat neurohypophysis, which contain both SSVs and LDCVs.

MATERIALS AND METHODS
Antibody preparation. Monoclonal antibodies against synaptotagmin (mAb1D12), syntaxin 1 (mAb10H5), and synaptophysin (mAb171B5),provided by Dr. S. Fujita, Mitsubishi Kasei Institute of LifeScience, Tokyo, and a polyclonal antibody against residues 2-20of VAMP2 were prepared as reported previously (Takahashi et al.,1991; Yoshida et al., 1992; Oho et al., 1995). A maltose bindingprotein (MBP)-csp fusion protein was prepared using the New EnglandBiolabs Protein Fusion and Purification System. A plasmid encodingthe entire coding sequence of csp (Mastrogiacomo and Gundersen,1995) was constructed by selective PCR amplification of rat cspcDNA (provided by Dr. C. Gundersen) using oligonucleotides containingflanking restriction sites. The resulting PCR fragment was thencloned into the pMAL vector (New England Biolabs, Beverly, MA).Recombinant proteins were purified by affinity chromatographyon an amylose column (New England Biolabs) and stored at $-$ 80°C.Antibodies against MBP-csp were produced in rabbits, and IgG fractionswere purified on Protein A-Sepharose Fast Flow beads (Pharmacia,Dorval, Québec, Canada).

Peptides. $omega$ GVIA (Peptide Institute, Osaka) and arginine vasopressin (AVP, Sigma, St. Louis, MO) were radioiodinated by theIodogen method and [mono¹²⁵I]iodinated peptide derivatives (2200 Ci/mmol) were purified byreverse-phase HPLC on an analytical C18 column (Beckmann).

Subcellular fractionation. Isolated rat neurohypophysial nerve endings were prepared as described by Cazalis et al. (1987).The terminals were dissociated by homogenizing the posterior lobesof the pituitary in 0.32 M sucrose and 10 mM HEPES, adjusted topH 7.4, with Tris containing the complete protease inhibitor mixture(Boehringer Mannheim, Indianapolis, IN), pelleted at 10000 × gfor 10 min, and washed once by resuspension in the same buffer.To fractionate vesicles that were released during homogenization,10000 × g supernatants were pooled, loaded onto a continuous 0.4-2M sucrose gradient, and centrifuged at 65000 × g for 5 hr (Navoneet al., 1989). Immunoisolation of vesicles was performed, usinga modification of the method introduced by Burger et al. (1989),and antibodies directed against csp or cytoplasmic epitopes ofsynaptotagmin, VAMP2, or synaptophysin. 10000 × g neurohypophysialsupernatants or 27000 × g whole-brain supernatants were dilutedin PBS containing 0.3% BSA buffer, and 100 µl portions were incubatedfor 2 hr at 4°C with 10 µg IgG. Protein-A Sepharose Fast Flowbeads (Pharmacia Biotech), saturated with 5% BSA in PBS then washedonce with PBS 0.3% BSA were added. Antibody-vesicle complexeswere then recovered by mixing with the beads for 1 hr at 4°C andcentrifuging for 30 sec at 10000 × g and washed three times inPBS, 0.3% BSA. The washed pellet was resuspended in 250 µl ofthe same buffer containing 1% Triton X-100. After a 30 sec centrifugationat 10000 × g, the AVP content of the supernatant was measuredby radioimmunoassay.

Deacylation, SDS-PAGE, and Western blotting. MBP-csp was cleaved with Factor Xa, and csp was recovered by chromatography onan amylose column. Rat brain csp was deacylated in 0.1 M KOH inmethanol for 1 hr at 22°C (Gundersen et al., 1994), then neutralizedwith HCl. Controls were treated with methanol alone. Solvent wasevaporated before electrophoresis. Proteins were denatured at100°C for 1 min in SDS-PAGE sample buffer containing 10 mM dithiothreitol.SDS-PAGE and Western blotting were performed as described previously(Leveque et al., 1994). Blots were probed with 30 µg/ml anti-cspIgG, whereas all other antibodies were used at 10 µg/ml. Detectionwas achieved using Protein A-peroxidase and an ECL kit (Amersham).

Radioimmunoassay. The AVP content of immunobead-isolated material was measured by radioimmunoassay using anti-AVP antiserum,kindly provided by Dr. G. Rougon (Laboratoire de Génétique etPhysiologie du Développement, Marseille, France) and used ata final dilution of 1:10000. Separation of bound AVP from freeAVP was accomplished by adsorption of the free fraction on activatedcharcoal.

Immunoprecipitation of calcium channels. Nerve terminals were prelabeled with 0.1 nM [¹²⁵I] $omega$ GVIA and solubilized in CHAPS, and immunoprecipitation experimentswere performed as described by Leveque et al. (1994).

RESULTS
Antibodies were raised against rat csp fused to MBP, and their ability to react with purified recombinant rat csp, csp inrat brain P2 membranes, and isolated nerve terminals from theneurohypophysis was tested by immunoblotting. Antibodies reactedwith a single major protein band in each lane (Fig. 1A, lanes1-3). Bacterially expressed csp migrated at 27 kDa (Fig. 1A, lane1) in reasonable agreement with the calculated molecular mass,whereas the protein band in brain P2 membranes (Fig. 1A, lane2) and neurohypophysis (Fig. 1A, lane 3) migrated at 36 kDa. Immunoreactivitywas specific for csp, because it was blocked by preincubatingantibodies with an excess of purified recombinant csp (Fig. 1A,lanes 4-6).
Fig. 1. Cysteine string proteins in nerve terminals of the neurohypophysis. A, Recombinant csp (lanes 1, 4), rat brain P2 membranes(lanes 2, 5), and neurohypophysial nerve terminals (lanes 3, 6)were separated by 12% SDS-PAGE, blotted, and probed with anti-ratcsp antibodies (lanes 1-3). In control experiments, antibodieswere preincubated with recombinant csp for 12 hr (lanes 4-6).Immunoreactive bands were visualized by ECL. B, Rat neurohypophysialnerve terminals were solubilized with 1% CHAPS and immunoprecipitatedwith 20 µg control IgG (lane 1) or anti-csp IgG (lane 2) in afinal volume of 0.2 ml. Recombinant csp (lane 3) and csps fromrat brain (lane 4) or rat neurohypophysis (lane 5) were deacylatedby treatment with methanolic KOH. Immunoblots were probed withanti-csp antibodies.
[View Larger Version of this Image (47K GIF file)]

To compare the degree of fatty acylation of csps in P2 membranes and neurohypophysial nerve terminals, proteins were delipidatedby treatment with 0.1 M KOH in methanol. Csps were detected byimmunoblotting after immunoprecipitation with anti-csp antibodies(Fig. 1B, lane 2), but not after control IgG (Fig. 1B, lane 1).After deacylation, csp from P2 membranes (Fig. 1B, lane 4) andthe neurohypophysis (lane 5) migrated at 27 kDa, as with bacteriallyexpressed csp (lane 3). These data indicate that a single-sizeform of csp is expressed in peptidergic nerve terminals of therat brain, which displays similar lipid content and core polypeptidemass to csp in total brain P2 membranes. Dimeric forms of thecsp protein with an apparent molecular mass of 70 kDa were alsooften detected (data not shown) when denatured proteins were stocked,but not when SDS-PAGE was performed immediately after denaturation.

Immobilized anti-synaptophysin antibodies can be used to immunoisolate SSVs (Burger et al., 1989). To determine whether cspwas associated with SSVs in the neurohypophysis, the ability ofanti-csp antibodies to capture vesicles containing synaptophysinwas compared with that of anti-synaptophysin antibodies. Postsynaptosomalsupernatants from homogenized neurohypophyses contain vesiclesreleased during homogenization. Aliquots of these supernatantswere incubated with anti-csp, anti-synaptophysin, or control antibodieslinked to Protein A-Sepharose beads, and synaptophysin was detectedby Western blotting. Both anti-csp and anti-synaptophysin antibodies,but not nonimmune IgG, trapped membranes containing synaptophysin(Fig. 2). In these experiments, anti-csp and anti-synaptophysinantibodies were able to capture 72 and 93%, respectively, of totalsynaptophysin. These results demonstrate that in peptidergic terminalsof the neurohypophysis, csp is expressed in a population of vesiclesthat also contains synaptophysin.
Fig. 2. Immunoisolation of vesicles containing synaptophysin from the neurohypophysis. Postsynaptosomal supernatants containing vesiclesreleased during homogenization of neurohypophyses were incubatedwith 10 µg anti-csp, 1 µg anti-synaptophysin, or 10 µg controlIgG, and immune complexes were recovered on Protein A beads. Inthe lane labeled total, an aliquot corresponding to half of theamount of protein used in immunoisolation assays was loaded directlyonto the SDS gel. Immunoblots of the captured vesicle proteinswere probed with anti-synaptophysin antibodies, and quantificationwas performed by densitometric scanning (see text).
[View Larger Version of this Image (17K GIF file)]

Because terminals in the neurohypophysis contain both SSVs and LDCVs, the distribution of csp was compared with that of othervesicular markers after fractionation by centrifugation on a linearsucrose gradient. Csps were not detected in fractions at the entryto the gradient, which contain soluble cytoplasmic proteins, butwere identified in two distinct peaks centered on fractions 8-13and 17-20 (Fig. 3A), which also contained VAMP. Synaptophysin,which is considered to be a marker for SSVs, was concentratedonly in the lighter peak (fractions 8-13). In contrast, AVP, whichis contained in LDCVs, was primarily located in fractions 17-20(Fig. 3B). Fractions 1-5 contained free AVP that was presumablyreleased by partial vesicle lysis during homogenization and fractionation.These observations suggest that csp, like VAMP, is associatedwith both microvesicles and an LDCV fraction in peptidergic nerveterminals.
Fig. 3. Distribution of vesicular proteins in synaptic vesicles and large dense core granules from the rat neurohypophysis. Postsynaptosomalsupernatants containing vesicles released during homogenizationof the neurohypophysis were loaded onto 0.4-2 M sucrose densitygradients and spun for 5 hr at 65000 × g. A, Fractions were collected,and 0.16 ml of each fraction was analyzed by SDS-PAGE and immunoblottedwith antibodies against synaptophysin, csp, and VAMP. The illustrateddata were taken from three separate immunoblots. Proteins weredetected by incubation with secondary antibodies coupled to peroxidaseand ECL. B, The AVP content of an equal volume of each fractionfrom the density gradient was determined by radioimmunoassay.
[View Larger Version of this Image (40K GIF file)]

To eliminate the possibility that csp and AVP are present in distinct vesicle populations with similar sedimentation characteristics,we examined whether anti-csp antibodies could capture vesiclescontaining AVP. Using a procedure identical to experiments illustratedin Figure 2, postsynaptosomal supernatants from the neurohypophysiswere incubated with beads coated with anti-csp antibodies andantibodies against cytoplasmic domains of the vesicular transmembraneproteins VAMP, synaptotagmin, and synaptophysin. Trapped vesicleswere then washed and lysed, and released AVP was measured by radioimmunoassay.However, because experiments were performed with an excess ofpostsynaptosomal supernatant only a fraction of the total AVPwas recovered. Antibodies against csp (8%), VAMP (15%), and synaptotagmin(9%) all captured higher amounts of AVP than control rabbit (1.5%)or mouse IgGs (1.5%) (Fig. 4). These results confirm that csp,like synaptotagmin and VAMP, is expressed in LDCVs containingAVP and is accessible to antibodies at the cytoplasmic surfaceof vesicles. Anti-synaptophysin antibodies trapped less AVP thananti-csp antibodies (Fig. 4), although Figure 2 demonstrates thatin identical conditions, they are as efficient as anti-csp antibodiesat capturing neurohypophysial vesicular membrane proteins. Howeveranti-synaptophysin antibodies recovered significantly more AVP(paired Student's t test, p < 0.01, n = 12) than did control antibodies(see Discussion).
Fig. 4. Immunoisolation of vesicles containing AVP. A postsynaptosomal supernatant (0.1 ml) containing vesicles released during homogenizationof the rat neurohypophysis was incubated in a final volume of0.2 ml with 10 µg antibodies against synaptotagmin, csp, VAMP,synaptophysin, and control rabbit or mouse IgG. Vesicles wererecovered with Protein A-Sepharose Fast Flow beads. After washingthe pellets, the amount of AVP released by 1% Triton X-100 wasdetermined by radioimmunoassay. Results are presented as a percentageof the total immunoreactive AVP that was pelleted by centrifugationat 100,000 × g for 2 hr, which was 1.2 ng/0.1 ml postsynaptosomalsupernatant.
[View Larger Version of this Image (42K GIF file)]

It has been suggested that when vesicles dock at the plasma membrane, the interaction of csp with N-type calcium channelsmay control channel activity (Mastrogiacomo et al., 1994). Therefore,we examined the ability of csp antibodies to co-immunoprecipitateN-type calcium channels solubilized from peptidergic terminalsof the neurohypophysis or brain P2 membranes and labeled witha specific radioligand [¹²⁵I] $omega$ GVIA. Parallel control experiments were performed with antibodiesagainst syntaxin 1, a protein involved in vesicular traffickingthat binds to the $alpha$ ₁B subunit of the N-type calcium channel (Yoshidaet al., 1992; Leveque et al., 1994; Sheng et al., 1995). The dataillustrated in Figure 5 demonstrate that anti-csp did not capturemore CHAPS-extracted calcium channels than did nonimmune IgG,whereas antibodies against syntaxin immunoprecipitated ~50%. Therefore,although anti-csp antibodies immunoprecipitated solubilized (Fig.1B) or vesicle-bound csp (Figs. 2, 4), they did not reveal csp-calciumchannel complexes. Similar results were obtained after solubilizationin Triton X-100, digitonin, or Mega-9 (data not shown). Furthermore,no interaction between solubilized N-type calcium channels andimmobilized MBP-csp was detected (data not shown). These resultsdo not support the hypothesis that a stable association betweencsp and N-type calcium channels can occur in nerve terminals fromwhole brain or the neurohypophysis.
Fig. 5. N-type calcium channels in brain and neurohypophysis were not co-immunoprecipitated with cysteine string proteins. N-typecalcium channels in neurohypophysial nerve terminals (A) or brainP2 membranes (B) were prelabeled with 0.1 nM [¹²⁵I] $omega$ GVIA, extracted with 1% CHAPS, and incubated with antibodies(20 µg/0.2 ml) against syntaxin 1, csp, or control IgG. Immunecomplexes were recovered on Protein A-Sepharose Fast Flow beads.Radioactivity was counted and shown as a percentage of the totalchannel-bound radioligand in the assay.
[View Larger Version of this Image (32K GIF file)]

DISCUSSION
Csps are lipidated proteins distributed extensively throughout the CNS and certain non-neuronal tissues (Kohan et al., 1995;Chamberlain and Burgoyne, 1996; Chamberlain et al., 1996; Coppolaand Gundersen, 1996). At least two kinetically distinct modesof regulated exocytosis occur in the CNS involving either SSVsor LDCVs. Docked SSVs release their contents within 1 millisecondof calcium rise (Sabatini and Regehr, 1996), whereas the latencyfor exocytosis of peptides from neuroendocrine cells is approximately10-fold greater (Thomas et al., 1993). Csps have been localizedto synaptic vesicles (Mastrogiacomo et al., 1994) and in Drosophila,they play an essential role in rapid transmitter release fromthe nerve terminal (Umbach et al., 1994; Zinsmaier et al., 1994).It is not currently known whether csps are associated with brainLDCVs that support slower neurosecretory processes. Therefore,we have examined the expression and subcellular distribution ofcsps in peptidergic nerve terminals, which contain both SSVs andLDCVs, from the rat neurohypophysis.

Two csp variants have been reported, the smaller of which (csp2) would result in a truncated protein with a 3.3 kDa reductionin molecular mass (Chamberlain and Burgoyne, 1996; Coppola andGundersen, 1996). We have used a fusion protein containing theentire coding sequence of rat csp1 to raise polyclonal antibodiesthat should react with csp1 and 2. Isolated nerve terminals fromthe neurohypophysis contained csp migrating at 36 kDa, which ondelipidation yielded a single band with an apparent molecularmass of 27 kDa. By these criteria, csps in peptidergic terminalswere indistinguishable from those in a total brain P2 fractionand apparently constitute a single protein species. These resultsare consistent with PCR amplification from rat brain mRNA, whichdetected only csp1 (Chamberlain and Burgoyne, 1996).

Subcellular fractionation of the neurohypophysis revealed at least two vesicle populations with distinct sedimentation propertiescorresponding to SSVs and LDCVs. This interpretation was supportedby the fact that synaptophysin was detected only in the lightervesicular peak, whereas AVP predominated in the heavier vesicularfractions and was not detected in fractions containing synaptophysin.Csp and VAMP displayed a similar distribution, suggesting thatthese two proteins are present in both microvesicles and LDCVs.The fact that anti-csp and anti-synaptophysin antibodies wereable to capture a similar fraction of total synaptophysin is consistentwith csp being a constituent of SSVs. Furthermore, the presenceof csp, VAMP, and synaptotagmin in LDCVs that contain AVP wasconfirmed by immunoisolating vesicles on immobilized antibodiesand assaying captured AVP. The detection of significant amountsof AVP at the top of sucrose gradients is presumably attributableto LDCV lysis. Although we have not determined where broken LDCVmembranes migrate in gradients, a previous report suggests co-sedimentationwith SSVs (Walch-Solimena et al., 1993). Accordingly, we cannotrule out the possibility that a portion of csp immunoreactivityin the light fractions of sucrose gradients may be contributedby lysed LDCV membranes.

Early work suggested that VAMP is restricted to SSVs in the brain (Baumert et al., 1989). However, this is not consistentwith the effects of clostridial neurotoxins on the secretion ofneurohormones. The light chain of tetanus toxin blocks calcium-inducedexocytosis of AVP in permeabilized nerve terminals, and the effectis prevented by synthetic peptides corresponding to cytoplasmicdomains of VAMP1 or VAMP2 (Dayanithi et al., 1994). Our data nowprovide direct confirmation of the presence of VAMP in LDCVs inthe CNS. These findings, together with recent reports demonstratingthat VAMPs are associated with secretory granules in the pheochromocytomaline PC12 (Chilcote et al., 1995), are consistent with a generalrole for VAMP-like proteins in regulated secretion.

Csps, which were found to be present in both SSVs and LDCVs, may display a similar ubiquitous distribution pattern to VAMPs,because they are also expressed in non-neuronal tissues includingadrenal chromaffin cells (Kohan et al., 1995; Chamberlain andBurgoyne, 1996), where they are associated with chromaffin granules(Chamberlain et al., 1996) and have been detected by immunoblottingin a zymogen granule fraction from the pancreas (Braun and Scheller,1995).

In the brain, synaptophysin is thought to be a marker for SSVs, because immunogold labeling (Navone et al., 1986, 1989), densitygradient fractionation, and immunoisolation of vesicular neuropeptideY (Walch-Solimena et al., 1993) have failed to detect synaptophysinin LDCVs. However, secretory granules from adrenal chromaffinand PC12 cells, which are widely used as a model for neuronalLDCVs, do appear to contain synaptophysin. In chromaffin and PC12cells, subcellular fractionation (Obendorf et al., 1988) and immunoisolationof [³H]norepinephrine-containing vesicles (Lowe et al., 1988) or secretogranin1-containing vesicles (Chilcote et al., 1995) have provided strongevidence in favor of the presence of synaptophysin. Although wedid not detect synaptophysin in LDCV fractions from the neurohypophysisby immunoblotting, anti-synaptophysin antibody beads recoveredhigher amounts of vesicular AVP than did control IgG. This inconsistencymay be attributable to the higher sensitivity of the second procedure.Our data do not allow us to eliminate the possibility that synaptophysinis present, albeit at very low density, in brain LDCV membranes.

Syntaxin 1, a component of the synaptic core complex implicated in vesicle docking and fusion, has been shown to form a stableinteraction with N- or P/Q-type calcium channels (Yoshida et al.,1992; Sheng et al., 1994; Martin-Moutot et al., 1996). A functionalcorrelate of these findings was provided by the demonstrationthat the co-expression of syntaxin 1 with N- or Q-type calciumchannels in Xenopus oocytes modified channel-gating properties(Bezprozvanny et al., 1995). The injection of cRNA encoding Torpedocsp enhances $omega$ GVIA-sensitive calcium currents in Xenopus oocytesexpressing Torpedo electric lobe or rat brain mRNA (Gundersenand Umbach, 1992). It was suggested subsequently that the interactionbetween csp on a docked synaptic vesicle and the calcium channelmay be required for channels to open in response to membrane depolarization(Mastrogiacomo et al., 1994). Therefore, we used a co-immunoprecipitationprocedure to examine whether complexes containing csp and N-typecalcium channels could be detected in detergent-solubilized nerveterminals. Approximately 50% of [¹²⁵I] $omega$ GVIA channels extracted from brain P2 or neurohypophysial nerveterminals was trapped by anti-syntaxin 1 antibodies but not byanti-csp antibodies. Co-immunoprecipitation has revealed the associationof presynaptic calcium channels with a protein complex containingsyntaxin, SNAP 25, VAMP, and synaptotagmin that is thought toplay a role in locating docked vesicles within a microdomain ofcalcium entry (Yoshida et al., 1992; El Far et al., 1995; Martin-Moutotet al., 1996). Our present findings do not support the view thatcsp is stably associated with this complex. However, we cannoteliminate the possibility that our anti-csp antibodies bind predominantlyto epitopes that are masked in calcium channel-containing complexesor that labile molecular interactions may be disrupted duringmembrane solubilization. Furthermore, csp modulation of calciumchannel activity may be indirect and not require the formationof csp-channel complexes. More work will be required to examinethe mechanisms of channel regulation by csps.

FOOTNOTES

Received Oct. 24, 1996; revised Jan. 13, 1997; accepted Feb. 4, 1997.

This work was supported by a joint program of the Institut National de la Santé et de la Recherche Médicale and the JapaneseSociety for the Promotion of Science, and a grant to S.P. fromthe Institut Scientifique Roussel. We are grateful to Dr. CameronGundersen for providing rat csp cDNA.

Correspondence should be addressed to Dr. Michael J. Seagar, Institut National de la Santé et de la Recherche Médicale U464,Faculté de Médecine Secteur Nord, Boulevard Pierre Dramard,13916 Marseille Cedex 20, France.

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