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The Journal of Neuroscience, April 15, 1998, 18(8):2923-2932
A Neuronal Sec1 Homolog Regulates Neurotransmitter Release at the
Squid Giant Synapse
T.
Dresbach1, 3,
M. E.
Burns2, 3,
V.
O'Connor1,
W. M.
DeBello2, 3,
H.
Betz1, and
G. J.
Augustine2, 3
1 Department of Neurochemistry, Max-Planck-Institute
for Brain Research, 60528 Frankfurt, Germany, 2 Department
of Neurobiology, Duke University Medical Center, Durham, North Carolina
27710, and 3 Marine Biological Laboratory, Woods Hole,
Massachusetts 02543
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ABSTRACT |
Sec1-related proteins are essential for membrane fusion at distinct
stages of the constitutive and regulated secretory pathways in
eukaryotic cells. Studies of neuronal isoforms of the Sec1 protein
family have yielded evidence for both positive and negative regulatory
functions of these proteins in neurotransmitter release. Here, we have
identified a squid neuronal homolog (s-Sec1) of Sec1 proteins and
examined its function in neurotransmitter release at the squid giant
synapse. Microinjection of s-Sec1 into the presynaptic terminal of the
giant synapse inhibited evoked neurotransmitter release, but this
effect was prevented by coinjecting the cytoplasmic domain of squid
syntaxin (s-syntaxin), one of the binding partners of s-Sec1. A 24 amino acid peptide fragment of s-Sec1, which inhibited the binding of
s-Sec1 to s-syntaxin in vitro, completely blocked release, suggesting an essential function of the s-Sec1/s-syntaxin interaction in transmitter release. Electron microscopy showed that
injection of s-Sec1 did not change the spatial distribution of synaptic
vesicles at presynaptic release sites ("active zones"), whereas the
inhibitory peptide increased the number of docked vesicles. These
distinct morphological effects lead us to conclude that Sec1 proteins
function at different stages of synaptic vesicle exocytosis, and that
an interaction of s-Sec1 with syntaxin at a stage blocked by the
peptideis necessary for docked vesicles to fuse.
Key words:
active zone; microinjection; neurotransmitter release; Sec1 proteins; squid giant synapse; syntaxin
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INTRODUCTION |
Neurotransmission at chemical
synapses relies on a cycle of membrane trafficking events that is
organized around clusters of synaptic vesicles accumulated at
specialized sites of the presynaptic plasma membrane, the active zones.
Within these clusters, a subset of vesicles is docked at the active
zone membrane and thought to undergo a multistep maturation process
during which vesicles acquire competence for
Ca2+-triggered exocytosis (Martin, 1997 ). After
exocytotic fusion, the vesicle membrane is retrieved from the plasma
membrane by clathrin-mediated endocytosis (Heuser and Reese, 1973;
Cremona and De Camilli, 1997). A complex array of protein interactions is proposed to ensure the fidelity of this synaptic vesicle life cycle
(Südhof, 1995).
The plasma membrane protein syntaxin 1A plays a central role in
neurotransmitter release, and its function appears to be mediated by
its interactions with proteins that have been implicated in neurotransmission, including voltage-gated Ca2+
channels (Bennett et al., 1992; Yoshida et al., 1992) and the putative calcium sensor protein synaptotagmin (Südhof and Rizo, 1996), as well as evolutionarily conserved cytosolic proteins essential
for membrane fusion termed NSF (N-ethylmaleimide-sensitive fusion protein) and SNAPs (soluble NSF-attachment proteins)
(Rothman and Wieland, 1996). The binding of syntaxin 1A to the
synaptic vesicle protein synaptobrevin and the plasma membrane protein SNAP-25 (synaptosomal-associated protein of 25 kDa) results in the
formation of a 7S complex, termed SNAP-receptor complex (SNARE-complex) because of its ability to recruit SNAPs and NSF. The formation and
NSF-catalyzed disassembly of the SNARE-complex are thought to represent
functionally important states of the synaptic vesicle docking and
fusion reaction (Söllner et al., 1993a,b; Pellegrini et al.,
1995; Banerjee et al., 1996; Bock and Scheller, 1997).
Recently, four independent studies have shown that syntaxin also binds
to a neuronal protein related to yeast Sec1p, the first protein known
to be essential for exocytosis in yeast (Novick and Schekman, 1979;
Aalto et al., 1991), and Caenorhabiditis elegans UNC-18
(Gengyo-Ando et al., 1993). This protein has been named Munc18 (Hata et
al., 1993), n-Sec1 (Pevsner et al., 1994a), rb-Sec1 (Garcia et al.,
1994), and m-Sec1 (Hodel et al., 1994). Detailed in vitro
studies using recombinant proteins showed that n-sec1 binds syntaxin
with high affinity in a way that prevents binding of SNAP-25 or
synaptobrevin and thereby precludes the formation of SNARE-complexes
(Pevsner et al., 1994b). This neuronal Sec1 homolog therefore is
thought to constitute an important regulator of syntaxin- and
SNARE-complex function in vivo.
Although the Sec1 proteins appear to regulate in vitro SNARE
complex interactions, their precise in vivo role remains
unclear. Overexpression of the Drosophila Sec1 homolog Rop
inhibits synaptic transmission, suggesting a negative role of the Rop
protein in vivo (Schulze et al., 1994). However, null
mutations of Rop or yeast Sec1p also reduce exocytotic activities in
the affected cells (Novick and Schekman, 1979; Harrison et al., 1994).
Furthermore, a mutation in UNC-18 impairs neurotransmission at C. elegans neuromuscular junctions (Gengyo-Ando et al., 1993). These
findings are inconsistent with a simple inhibitory function of Sec1
proteins. To further elucidate the function and sites of action of Sec1
proteins in neurotransmitter release, we microinjected the squid
neuronal Sec1 (s-Sec1) protein and s-Sec1-peptides into the squid giant synapse and analyzed the effects of these agents on synaptic function and ultrastructure. Our results suggest multiple roles of Sec1 proteins
in synaptic vesicle exocytosis.
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MATERIALS AND METHODS |
Isolation of a squid Sec1 cDNA. A  gt10 squid
stellate ganglion cDNA library (106 plaque-forming
units), kindly provided by J. Battey (National Institutes of Health,
Bethesda, MD), was screened with a
32P- -dCTP-labeled 1.6 kb cDNA probe from the
coding region of mouse Munc18-a, kindly provided by A. Püschel (Max-Planck-Institute for Brain Research, Frankfurt).
Filter hybridization was performed under low-stringency conditions
(56°C without formamide), as described previously (Hunt et al.,
1994). cDNAs were excised from hybridization-positive clones with
EcoRI and subcloned into pBluescript. Sequencing of the
largest (3.2 kb) cDNA isolated revealed a 1773 bp open reading frame
preceded by 142 nucleotides and followed by some 1200 nucleotides downstream of the stop codon as mapped by restriction digests.
Generation and purification of fusion proteins. To generate
s-Sec1 expression constructs, nucleotides 1-372 of the open reading frame of the s-Sec1 cDNA were amplified by PCR using a sense
primer with an artificial BamHI site. After digestion of the
PCR product using the BamHI site and an endogenous
HindIII site, the resulting 316 bp DNA was subcloned into
the expression vector pQE30 and verified by sequencing. The 3' coding
region of the s-Sec1 cDNA was excised using
HindIII and ligated to the N-terminal region in pQE30,
resulting in a construct comprising a His-6 tag, the entire open
reading frame, and the portion of the cDNA downstream of the stop
codon. Fusion proteins containing the cytosolic portion of squid
syntaxin1 (s-syntaxin) (O'Connor et al., 1997) were generated by
subcloning the nucleotides encoding amino acids 2-268 either into
pQE30 for N-terminal His-6-tagging or into pGEX-4T-1 for generation of
a glutathione-S-transferase (GST) fusion protein. All
constructs were expressed in Escherichia coli Xl-I-blue
cells, and the resulting fusion proteins were purified under
nondenaturing conditions as described previously (Pellegrini et al.,
1994).
Affinity purification and in vitro binding
assays. For affinity purification of endogenous s-Sec1, frozen
optic lobe tissue was homogenized in 25 mM Tris/HCl, pH
7.4, 0.5 M KCl, 0.25 M sucrose. After
centrifugation at 7500 × g for 1 hr, the supernatant
was cleared for 2 hr at 120,000 × g and subsequently
dialyzed against binding buffer (50 mM HEPES/KOH, pH 7.4, 150 mM KCl, 2 mM  -mercaptoethanol). Protease
inhibitors from the Complete-cocktail (Boehringer, Mannheim, Germany) were included during these steps. Two milliliters (10 mg
protein) of the dialysate were incubated with 1 nmol GST or GST-s-syntaxin coupled to 50 µl glutathione-agarose beads for 4 hr.
Beads were washed six times with 2 ml of washing buffer [binding
buffer including 0.05% (w/v) Tween-20] and eluted with 100 µl
SDS-PAGE sample buffer. To assay for the binding of recombinant proteins, GST or GST-squid-syntaxin, coupled to 10 µl
glutathione-agarose beads, was incubated for 2 hr with His-tagged
s-Sec1 in a volume of 200 µl. Beads were washed six times with 500 µl washing buffer, eluted with 20 µl SDS-PAGE sample buffer, and 10 µl aliquots were subjected to SDS-PAGE (Laemmli, 1970).
Microinjection and electrophysiology. Microinjection and
electrophysiological recording were performed as described previously (Adler et al., 1991; Hunt et al., 1994). Briefly, three microelectrodes were introduced into stellate ganglia from the squid Loligo
pealei. One microelectrode was placed into the presynaptic axon to
elicit an action potential once every 30 sec. A second microelectrode, introduced into the postsynaptic axon, recorded postsynaptic potentials generated during evoked synaptic transmission. The third electrode, used for both microinjection and recording of presynaptic action potentials, was introduced directly into the presynaptic terminal. Proteins and peptides to be microinjected were dissolved in injection solution (250 mM potassium isothionate, 100 mM
taurine, 50 mM HEPES, pH 7.2, 100 mM KCl)
containing fluorescein isothiocyanate (FITC)-dextran (100 µM, 10 kDa) (Molecular Probes, Eugene, OR). Reagents were
loaded into injection electrodes at the following concentrations:
s-Sec1, 7.5 µM; s-syntaxin, 75 µM (for
control injections) or 30 µM (for co-injection
experiments); peptides, 5 mM. To estimate the volume and
concentration of the solution injected, FITC fluorescence was measured
at regular intervals throughout the experiment and compared with a
standard calibration curve obtained from known concentrations of
FITC-dextran in microcuvettes in which the path length approximated
that of the terminal. To measure presynaptic Ca2+
levels, the fluorescent dye calcium orange (Molecular Probes) was
microinjected into the presynaptic terminal using the procedure described by Adler et al. (1991). Dye fluorescence was examined by
using a filter set that did not excite FITC-dextran (excitation filter,
546 nm; dichroic mirror, 580 nm; emission filter, 610 nm). Video images
collected by a sit-camera were stored on an analog optical disk
recorder (Panasonic TQ-2026) and analyzed with Image-1 software
(Universal Imaging Corporation, West Chester, PA).
Electron microscopy. To assess the morphological effects of
microinjected reagent, nerve terminals were fixed and processed for
electron microscopy as detailed previously (Bommert et al., 1993; Hunt
et al., 1994). Terminals injected with sufficient s-Sec1 (two
terminals) or secpep3 (two terminals) to inhibit transmission by >90%
were compared with 10 control terminals injected with different
inactive substances (scrambled secpep3, inert recombinant proteins, or
injection buffer alone). Sections were prepared from each terminal at
50 µm intervals throughout the active zone region. Each 80 nm section
was magnified 12,000 times, and every active zone was photographed and
analyzed, resulting in cumulative data of ~200 active zones per
terminal. Morphometric analysis was performed on the digitized images
using Image-1 software.
Miscellaneous methods. SDS-PAGE was performed according to
Laemmli (1970). Western blotting and immunodetection using the enhanced chemiluminescence system were performed as detailed previously (Pellegrini et al., 1994). For immunodetection of s-Sec1, a
polyclonal antiserum raised against Munc18-1 (Dianova, Hamburg,
Germany) was used. Peptides were synthesized by Biosynthesis Inc.
(Lewisville, TX) or in the peptide synthesis facility of the University
of Texas (San Antonio, TX), and contained alkylated N termini and amidated C termini.
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RESULTS |
Cloning of a squid Sec1 homolog
To isolate Sec1 cDNAs from squid, we screened a squid stellate
ganglion cDNA library under low-stringency conditions using a 1.6 kb
cDNA probe from the coding region of murine Munc18a (A. Püschel,
unpublished observations). This procedure led to the isolation of a
cDNA clone M21, including an open reading frame of 1773 bp predicted to
encode a 67.1 kDa protein with an isoelectric point of 6.76. The
deduced amino acid sequence includes consensus sites for
phosphorylation by protein kinase C, casein kinase II, calcium/calmodulin kinase, and protein tyrosine kinase (Fig.
1). A homology search using the
EMBL/GenBank showed that the protein was closely related to the
Sec1/UNC-18 protein family. The squid sequence shared the highest
identity with members of the protein family that have been implicated
in neurotransmission, i.e., mammalian n-Sec1 (66%),
Drosophila Rop (66%), and C. elegans UNC-18
(58%), and was less closely related to the ubiquitously expressed
mammalian isoforms Munc18-2/Munc18b (56%) and Munc18c (46%).
Moreover, the squid protein, referred to as s-Sec1, displayed a higher
homology to Sec1p (28%), the yeast isoform required for exocytosis,
than to isoforms that function at other steps in the yeast secretory pathway: Sly1p (23%), Vps45 (22%), and Vps33 (21%). This hierarchy of similarities suggests that s-Sec1 is one of the Sec1/UNC-18 proteins
that function in regulated exocytosis. Comparison of s-Sec1 with the
sequences of n-Sec1, Rop, and UNC-18 showed that homologies extend over
the entire lengths of these proteins (Fig. 1). A centrally located
-COP-motif, which is conserved among all members of the Sec1/UNC-18
protein family (Halachmi and Lev, 1996), is also found in s-Sec1 (amino
acids 226-253). Similarly, the only consensus site for tyrosine
phosphorylation in s-Sec1, at position 475, corresponds to an
evolutionary conserved signature of these proteins.
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Figure 1.
Alignment of the deduced amino acid sequences of
s-Sec1, n-Sec1, Rop, and UNC-18. Residues identical to the
corresponding positions of the squid sequence are indicated by
dots. Gaps introduced to optimize the sequence alignment
are marked by dashes. Brackets indicate
the sequences of s-Sec1 peptides (secpep1, secpep2, secpep3)
synthesized for microinjection. Phosphorylation consensus sites in
s-Sec1 exist at positions 34, 80, 120, 126, 185, 301, 518, 523 (for
protein kinase C), 53, 76, 126, 179, 190, 215, 315, 374, 398, 548 (for
casein kinase II), 475 (protein tyrosine kinase), and 589 (for
calcium/calmodulin kinase).
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Effect of recombinant s-Sec1 on neurotransmitter release
To test whether s-Sec1 is involved in neurotransmitter release, we
generated a full length recombinant s-Sec1 construct with an N-terminal
histidine tag and purified the bacterial fusion protein under
nondenaturing conditions. We then injected the soluble fusion protein
into the presynaptic terminal of the squid giant synapse while we
electrophysiologically monitored synaptic transmission evoked by single
action potentials (Fig.
2A). s-Sec1
consistently produced an inhibition of neurotransmitter release, as
evidenced by the decreasing rate of rise of the evoked postsynaptic
potentials (PSPs). There generally was no change in the shape of the
presynaptic action potential or the resting potential of the terminal
during inhibition of synaptic transmission, indicating that s-Sec1
microinjection affected a step subsequent to arrival of the action
potential in the nerve terminal and did not impair the electrical
characteristics of the presynaptic terminal. To examine the possibility
that s-Sec1 interferes with the rise of calcium levels that trigger
release, presynaptic terminals were microinjected with the fluorescent calcium indicator calcium orange (Eberhard and Erne, 1991). Trains of
action potentials were then used to elicit calcium signals both before
and during inhibition of transmitter release by s-Sec1. Microinjection
of s-Sec1 caused no significant change in the magnitude and time course
of the Ca2+ fluorescence signal, indicating that
s-Sec1 inhibits a step of transmitter release downstream of the calcium
signal (Fig. 3).
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Figure 2.
Microinjection of s-Sec1 inhibits neurotransmitter
release. A, Simultaneous recording of evoked presynaptic
action potentials (Vpre) and the resulting postsynaptic
responses (Vpost). Microinjection of full length
recombinant s-Sec1 inhibited synaptic transmission as was evident from
a strong decrease in postsynaptic potential changes (PSPs) without
alterations in presynaptic action potentials. B, Time
course of inhibition of transmitter release by s-Sec1. Microinjection
of s-Sec1 during the periods indicated by the bars
produced a gradual and partially reversible inhibition of the rate of
rise of PSPs. C, Microinjection of the cytosolic portion
(amino acids 2-268) of squid syntaxin 1 (s-syntaxin) had
no effect on transmitter release. D, Coinjection of
s-syntaxin with s-Sec1 blocked s-Sec1 inhibition of transmitter
release.
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Figure 3.
s-Sec1 does not affect presynaptic calcium
signaling. Changes in presynaptic calcium concentration produced by
trains of action potentials (50 Hz, 3 sec for the time indicated by
bars) evoked before (Control) and
after (s-Sec1) microinjection of s-Sec1 were monitored
by measuring changes in fluorescence of the microinjected
Ca2+ indicator calcium orange. The plots show the
change in calcium orange fluorescence (F-Fo)
divided by the prestimulus resting fluorescence
(Fo).
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Inhibition of transmitter release started to reverse within minutes
after cessation of s-Sec1 injection and could be reinitiated by
resuming injection (Fig. 2B). This reversibility
indicates that the inhibitory effect was not an artifact of
microinjection because such artifacts are largely irreversible (Llinas
et al., 1991). The comparatively rapid onset of recovery is reminiscent of the reversal of effects of other fusion proteins injected into the
giant terminal (Hunt et al., 1994; DeBello et al., 1995) and probably
reflects diffusion of the protein out of the terminal and into the
giant presynaptic axon (Bommert et al., 1993). With the latter acting
as a diffusion sink, even high-affinity protein-protein interactions
should undergo disassembly as the concentration of microinjected
protein falls below the respective dissociation constant.
To further examine the specificity of s-Sec1 inhibition we performed a
series of control injections. Injection of buffer alone had no effect
on synaptic transmission (data not shown). Likewise, injection of
another His-tagged fusion protein, the cytosolic portion of s-syntaxin
(amino acids 2-268) (O'Connor et al., 1997), did not inhibit
transmitter release even when present in the injection electrode at a
concentration (75 µM) an order of magnitude higher than
that needed for s-Sec1 to inhibit release (Fig. 2C).
Interestingly, coinjection of s-syntaxin 2-268 together with s-Sec1 at
a molar ratio of 4:1 significantly reduced, and in some experiments
completely prevented, s-Sec1-inhibition of transmitter release (Fig.
2D, Table 1),
suggesting that s-Sec1 was complexed by the syntaxin construct.
Together, these experiments corroborate that the inhibitory effect of
s-Sec1 injections was not caused by nonspecific effects of the
injection procedure or the fusion proteins. Moreover, preventing the
inhibitory action of s-Sec1 by s-syntaxin 2-268 is consistent with the
idea that s-Sec1 performs its action in the nerve terminal via an
interaction with syntaxin.
Identification of active s-Sec1 domains
Several additional experiments were performed to further determine
whether the inhibitory action of s-Sec1 involves an interaction with
syntaxin. First, we tested whether endogenous and recombinant s-Sec1
are able to bind syntaxin. We therefore coupled a GST fusion protein
that included the cytosolic portion of s-syntaxin or GST alone to
glutathione beads to form an affinity matrix. Incubation with the
soluble proteins from squid optic lobes lead to purification of a 67 kDa protein that was recognized by an antisera raised against Munc18-1
(Fig. 4A) (and data not
shown). Likewise, recombinant s-Sec1 bound to GST-s-syntaxin but not to
GST (Fig. 4A). These data show that both endogenous
and recombinant s-Sec1 have the ability to interact with
s-syntaxin.
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Figure 4.
The s-Sec1-peptide secpep3 inhibits binding of
s-Sec1 to s-syntaxin. A, The soluble fraction of a squid
optic lobe homogenate or recombinant s-Sec1 was incubated with GST or
GST-s-syntaxin coupled to glutathione-agarose beads. Eluates from the
washed beads were analyzed by SDS-PAGE followed by Coomassie blue
R250-staining. A 67 kDa protein from squid homogenate and recombinant
s-Sec1 were recovered from GST-s-syntaxin beads but not from GST beads.
B, GST or GST-s-syntaxin were coupled to
glutathione-agarose beads and incubated with recombinant s-Sec1 in the
presence of 1 mM secpep1, secpep2, or secpep3, each. Eluates from washed beads were analyzed
by SDS-PAGE followed by immunoblotting for s-Sec1. Secpep3, but not
secpep1 or secpep2, prevented the binding of s-Sec1 to
GST-squid-syntaxin. C, GST-s-syntaxin coupled to
glutathione-agarose beads was incubated with s-Sec1 in the presence of
0, 30, 100, 300, or 1000 µM secpep3. Eluates from the
washed beads were analyzed as in B, the resulting bands
(inset) were quantified densitometrically, and after
background correction, integrated optical density peaks were plotted
against secpep3 concentrations. The data indicate half-maximal
inhibition at ~75 µM secpep 3.
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We next examined the functional consequences of the interaction of
s-Sec1 with syntaxin by using an inhibitory peptide derived from
s-Sec1. To this end, we synthesized peptides (secpep1, secpep2, secpep3) from three evolutionarily conserved regions of s-Sec1 that are
predicted to be surface-exposed (Fig. 1A). Two of the selected regions have been suggested to be functionally important from
studies on Drosophila Rop and yeast Sly1p. The secpep2
peptide covers a domain that contains a conserved histidine residue in positions 290 of s-Sec1 and 302 in Rop. Substitution by tyrosine of
this histidine in Rop impairs sensory transduction in
Drosophila photoreceptors (Harrison et al., 1994), and
introduction of this point mutation into recombinant n-Sec1 inhibits
its in vitro binding to syntaxin (Frelin and Pevsner, 1996).
Secpep3 aligns with amino acids 526-551 of yeast Sly1p as predicted by
the Clustal program (data not shown). This region has been implicated
genetically in interactions of Sly1p with GTP-binding protein Ypt1p
(Dascher et al., 1991). We then tested whether these peptides affect
the in vitro interaction between recombinant s-Sec1 and
s-syntaxin. Secpep1 and secpep2 (1 mM) had no effect on the
binding of recombinant s-Sec1 to GST-s-syntaxin, whereas secpep3
completely prevented the interaction at the same concentration (Fig.
4B). A dose-response curve revealed half-maximal
inhibition at a secpep3 concentration of 75 µM (Fig.
4C).
On the basis of these results we used the s-Sec1 peptides to
investigate the possible roles of s-Sec1/s-syntaxin interactions in
neurotransmitter release. Presynaptic microinjection of either secpep1
or secpep2 had no effect on synaptic transmission; however, the secpep3
peptide produced a rapid and reversible inhibition of transmitter
release (Fig. 5A-C). A
high-frequency stimulation paradigm (3 sec, 50 Hz) did not change the
rate at which release was inhibited during peptide injection,
suggesting that replenishment of fused vesicles from the reserve pool
of vesicles was not affected (data not shown). To exclude the
possibility that the net charge of secpep3 causes the inhibitory
effect, we synthesized and injected a scrambled peptide of amino acid
composition identical to secpep3 but of randomized sequence
(RETKYQMRIGPHYQKMDTMRSWDE). Like secpep1 and secpep2, the scrambled
peptide had no effect on transmitter release (Fig. 5D),
indicating that the inhibitory effect of secpep3 is sequence-specific.
Database searches revealed no significant sequence similarities of
secpep3 with proteins other than Sec1 homologs. We therefore conclude
that secpep3 inhibits an interaction of s-Sec1 with syntaxin that is
essential for neurotransmitter release.
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Figure 5.
Peptide secpep3 inhibits evoked neurotransmitter
release. Secpep3 (B) produced a gradual and
reversible inhibition of transmitter release, whereas secpep1
(A) and scrambled secpep3
(C) had no effect. The rates of rise of PSPs,
normalized relative to the mean preinjection value, are plotted, with
the times of injection indicated by bars.
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Ultrastructure of synapses inhibited by s-Sec1 or the
peptide secpep3
Neurotransmitter release results from a cycle of membrane
trafficking events within presynaptic terminals (Heuser and Reese, 1973; Schweizer et al., 1995). To delineate the trafficking events that
are inhibited by s-Sec1 and secpep3, we used quantitative electron
microscopy to examine synaptic vesicles in terminals injected with
these reagents. Comparison of the morphology of synapses inhibited by
s-Sec1 with that of control synapses injected with inert reagents
showed that the inhibitory effect of s-Sec1 was not associated with
obvious changes in the ultrastructure of the nerve terminal (Fig.
6A). To examine
possible effects of s-Sec1 on a quantitative level, we determined the
number of synaptic vesicles in concentric shells (bins) of 50 nm width
at increasing distances from the active zone plasma membrane (Hess et
al., 1993). The number of vesicles in each of the shells was not
changed significantly after synaptic transmission was inhibited by
s-Sec1 (Fig. 6B,C). In particular, the number of
vesicles in close contact with the plasma membrane, i.e., those within
the first 50 nm bin, was not decreased, indicating that s-Sec1 did not
impair docking of synaptic vesicles at the release sites. Furthermore,
there was no change in the number of vesicles located more distant
(>50 nm) from the plasma membrane; these vesicles are thought to
constitute the reserve pool derived from the endocytotic branch of the
vesicle cycle (Pieribone et al., 1995). Thus, s-Sec1 inhibits synaptic transmission by blocking a step of the release process that follows vesicle docking.
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Figure 6.
Distinct effects of s-Sec1 and secpep3 on synaptic
ultrastructure and the spatial distribution of synaptic vesicles.
A, Electron micrographs of representative active zones
from a control nerve terminal (left) and from terminals
fixed during inhibition through secpep3 (middle) or
s-Sec1 (right). Secpep3 inhibition was accompanied by
coating of synaptic vesicles with electron-dense material
(middle), whereas s-Sec1 inhibition did not cause any
observable changes in terminal ultrastructure. B, Mean
number of synaptic vesicles located at various distances from active
zone membranes in nerve terminals inhibited by control (solid
bars), secpep3 (gray bars), and s-Sec1
(open bars). Inhibition caused by secpep3 was
characterized by an increased number of docked vesicles. Terminals
inhibited by s-Sec1 showed no change in the distribution of synaptic
vesicles as compared with control terminals. C,
Comparison of the spatial distributions of synaptic vesicles in
terminals inhibited by secpep3 (gray bars) and
s-Sec1 (open bars). Inhibition by secpep3 was
characterized by an almost twofold increase in the number of docked
synaptic vesicles and a decrease in the number of vesicles located a
distance of between 100 and 400 nm from active zones as compared with
terminals inhibited by s-Sec1. Numbers are derived from the data shown
in B.
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We next considered the morphological effects of perturbing s-Sec1
binding to syntaxins by comparing synapses, in which release was
inhibited by >90% (as in Materials and Methods) after secpep3 injection, with those injected with the inert scrambled version of
secpep3 (scr-secpep3; Fig. 6A). Synapses inhibited by secpep3 showed no
gross change in presynaptic morphology; however, some vesicles were
coated with an electron-dense material (Fig. 6A). Although secpep3 did not lead to formation of electron-dense coats when
incubated with purified synaptic vesicles in the presence of squid
cytosol (V. O'Connor and W. Hofer, unpublished observations), we
cannot exclude the possibility that the peptide can attach to vesicles
when microinjected into the nerve terminal. Possible attachment sites
could be provided by syntaxin; transfection of syntaxin into mammalian
cells induces membrane localization of a Sec1 homolog (Riento et al.,
1996), and some syntaxin is associated with synaptic vesicles in rat
(Walch-Solimena et al., 1995) and squid (V. O'Connor and L. L. Pellegrini, unpublished observations). However, coating per se is
unlikely to account for inhibition of transmitter release because
inhibition by secpep3 was readily reversible (Fig. 4). This
reversibility excludes the possibility that the coat represents
precipitated peptide that unspecifically damages the release machinery.
Moreover, because secpep3 did not lead to coating of mitochondria and
the control peptide did not cause any coat formation, these
morphological changes appear to be a specific consequence of secpep3
injection. Finally, quantitative analysis of the spatial distribution
of vesicles at active zones revealed that the number of vesicles in
almost every bin was similar in both control and inhibited synapses
(Fig. 6B,C). Thus, basic processes such as vesicle
recycling and maintenance of vesicle clusters at active zones were not
affected by peptide injection, indicating that the coating material is
not simply preventing synaptic vesicles from interacting with other
proteins. However, the number of vesicles within the first 50 nm
compartment, representing the location of docked vesicles, was
increased twofold (Fig. 6B,C). Similar effects have
been observed after injection of inhibitory peptides derived from other
proteins (Bommert et al., 1993; DeBello et al., 1995) and have been
interpreted as resulting from the blocking of a reaction that becomes
important after vesicle docking, leading to an accumulation of docked
vesicles that cannot fuse. Thus, although both s-Sec1 and secpep3
inhibit transmitter release, we observed both qualitative and
quantitative differences, which suggests that these reagents disrupt
distinct reactions in synapic vesicle traffic.
| |
DISCUSSION |
Genetic and biochemical approaches have implicated members of the
Sec1 protein family in secretion in both neuronal and non-neuronal cells. However, the interactions that Sec1 proteins undergo in vivo and the roles these proteins play in exocytosis have remained controversial (Halachmi and Lev, 1996). Particular questions that have
remained open include the following. (1) Do neuronal Sec1 proteins play
inhibitory, essential, or multiple roles in synaptic transmission? (2)
Is an interaction with syntaxin important in any such function in an
intact synapse? (3) To which steps in the synaptic vesicle life cycle
can Sec1 protein functions be assigned? To address these questions we
have used the squid giant synapse, which allows the combined use of
electrophysiological recording of synaptic transmission and
ultrastructural analysis of a large number of synaptic contacts with
microinjection of probes directly into the giant presynaptic terminal.
The results presented here suggest that s-Sec1 functions at different
stages after synaptic vesicles dock at the plasma membrane, and that at
least one of these functions involves an interaction with syntaxin.
To allow an analysis of Sec1 protein function at the squid giant
synapse, we first cloned the squid homolog of Sec1p. s-Sec1 is most
closely related to rat n-Sec1, Drosophila Rop, and C. elegans UNC-18, Sec1 proteins that have been implicated in
neurotransmission. s-Sec1, n-Sec1, and Rop are equally related to one
another, with amino acid identities of 66%. This similarity is the
same as that between squid SNAP and mammalian -SNAP, proteins for
which functional conservation has been demonstrated (DeBello et al.,
1995). Therefore, it seems likely that s-Sec1 represents a functional
homolog of n-Sec1/Rop type Sec1 proteins. We have chosen the name
s-Sec1 to account for the fact that yeast Sec1 was the first member of this growing protein family to be cloned and sequenced (Aalto et al.,
1991).
Multiple roles of s-Sec1 in neurotransmission?
Microinjection of recombinant s-Sec1 into the presynaptic terminal
of the squid giant synapse produced a profound inhibition of
neurotransmitter release evoked by action potentials. This result is in
accord with inhibition of synaptic transmission at Drosophila neuromuscular junctions after chronic
overexpression of Rop (Schulze et al., 1994). The fact that we observed
similar inhibitory effects after acute injection of s-Sec1 argues that both manipulations work via direct, Sec1-related effects on synaptic transmission. Moreover, s-Sec1 did not affect the amplitude or time
course of presynaptic action potentials and calcium signals. Hence, our
data extend earlier work by showing that s-Sec1 inhibits a step of
transmitter release that lies downstream of action potential propagation and calcium influx.
To reconcile the opposing effects of overexpression and loss of
function of Rop and other Sec1 proteins on secretion, it has been
suggested that Sec1 proteins exert multiple roles, including inhibitory
and stimulatory functions (Pevsner, 1996). Assuming that inhibition by
Sec1 proteins precedes their stimulatory role, increased levels of Sec1
might only produce inhibition, as observed on s-Sec1 injection (this
study) and overexpression of Rop (Schulze et al., 1994). Conversely,
disruption of sec-1 function might unravel subsequent effects that
promote exocytosis. Assuming that syntaxin participates in Sec1
protein-mediated effects, we first verified that the syntaxin-Sec1
protein interaction is conserved in squid nervous tissue extracts. Our
observation that peptide secpep3 disrupted not only this interaction
in vitro but effectively blocked synaptic transmission
in vivo, whereas other Sec1 peptides were ineffective in
both cases, strongly supports an essential role of
s-syntaxin/s-Sec1-interactions in the transmitter release process. This
is consistent with a preliminary report showing that point mutations of
n-Sec1 that mimic amino acid exchanges in loss of function mutations of
Drosophila Rop interfere with syntaxin binding in
vitro (Frelin and Pevsner, 1996).
It has been proposed that in yeast endoplasmic reticulum-to-Golgi
transport, the Sec1p homolog Sly1p acts on the syntaxin homolog Sed5p
to both activate it for and prevent it from forming SNARE-complexes
(Lupashin and Waters, 1997). On the basis of this idea, both negative
and permissive Sec1 protein functions would involve syntaxin. Indeed,
coinjection of the cytosolic portion of squid syntaxin prevented s-Sec1
inhibition of transmitter release, whereas the syntaxin fragment alone
had no effect. Thus, block of inhibition did not result from an
independent stimulatory effect of squid syntaxin, but instead from
s-syntaxin binding to s-Sec1, consistent with s-Sec1 inhibition
resulting from titration of cellular syntaxin. However, it is also
possible that the two recombinant proteins form a complex that prevents
s-Sec1 from interacting with other proteins. Possible candidates for
such interactions include the recently discovered DOC2 proteins, which
compete with syntaxin for n-Sec1 binding in vitro (Verhage
et al., 1997), as well as other Sec1-binding partners such as cdk5
(Shetty et al., 1995). This latter interpretation, which invokes
independent negative and permissive s-Sec1 functions, receives support
from our observation that the inhibitory peptide secpep3 caused an
accumulation of docked vesicles at the active zone membrane and full
length s-Sec1 did not. Therefore, this domain of s-Sec1 must have
arrested transmitter release at a step distinct from that blocked by
the full length protein. Although an accumulation of docked vesicles
could result from disruption of an s-Sec1/s-syntaxin interaction that
inhibits vesicle docking (Pevsner et al., 1994a), the fact that the
peptide blocked neurotransmitter release, rather than leaving it
unaffected or enhancing it, is inconsistent with this possibility.
Moreover, our data show that both s-Sec1 and the inhibitory peptide
secpep3 did not perturb the clustering of synaptic vesicles at active zones, a process that is sensitive to both synapsin antibodies (Pieribone et al., 1995) and a SNAP peptide (DeBello et al., 1995). Also, neither treatment prevented targeting to and anchoring of vesicles at the active zone membrane. These findings suggest strongly that inhibition by both s-Sec1 and secpep3 results from disruption of
reactions that follow synaptic vesicle docking but precede exocytosis.
This is consistent with studies on the role of syntaxin, in which both
toxin cleavage and gene deletion failed to significantly change the
number of docked vesicles (Broadie et al., 1995; O'Connor et al.,
1997). We therefore propose that s-Sec1 has at least two functions: (1)
a positive role in exocytosis that requires binding to s-syntaxin, is
prevented by secpep3, and is needed for docked vesicles to fuse, and
(2) a negative role that is prevented by providing an excess of
s-syntaxin and also occurs after docking but upstream of the action
mediated by the secpep3 domain.
An indication of how s-Sec1 functions might be regulated comes from the
fact that the secpep3 sequence aligns with a region in yeast Sly1p that
has been implicated in genetic interactions with Ypt1p (Dascher et al.,
1991), a monomeric GTPase essential for SNARE complex assembly in yeast
(Sögard et al., 1994; Lupashin and Waters, 1997). A point
mutation in this region of Sly1p renders the protein capable of
restoring SNARE complex assembly and secretion in the absence of Ypt1p
(Dascher et al., 1991; Lupashin and Waters, 1997), suggesting that the
mutated Sly1p has a conformation required for proper vesicle traffic
that the wild-type Sly1p adopts only after induction by Ypt1p (Dascher
et al., 1991). Because secpep3 inhibits the s-Sec1/s-syntaxin
interaction, one may infer that this domain of s-Sec1 could be both
subject to regulation by GTPases, such as the squid neuronal Rab3A
(Chin and Goldman, 1992; Burns et al., 1995), and involved in syntaxin
binding, thus providing a site for crosstalk between the three
proteins. Further dissection of Sec1 protein functions, in particular
identification of the molecular interactions that specify the negative
and positive roles of these proteins, will be required to elucidate the
precise roles that Sec1 proteins play in both constitutive and
regulated membrane fusion.
| |
FOOTNOTES |
Received Nov. 19, 1997; revised Jan. 29, 1998; accepted Feb. 3, 1998.
This work was supported by Deutsche Forschungsgemeinschaft, Fonds der
Chemischen Industrie, National Institutes of Health Grant NS-21624, and
a Grass Fellowship to W. DeBello. We are grateful to A. Püschel
for providing the mouse Munc18-a cDNA, to A. Niehuis for
expert technical assistance, to M. Baier and H. Reitz for secretarial
assistance, to L. Bonewald and A. Makusky (University of San Antonio)
for peptide synthesis, and to L. Hawkey for electron microscopy.
GenBank accession number is Y12732.
Correspondence should be addressed to Heinrich Betz,
Max-Planck-Institute for Brain Research, Neurochemistry Department,
Deutschordenstrasse 46, D-60528 Frankfurt/Main, Germany.
Dr. Dresbach's present address: Leibniz Institute for Neurobiology,
Department of Neurochemistry and Molecular Biology, Brenneckestrasse 6, D-39118 Magdeburg, Germany.
| |
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Abstract
Introduction
