 |
 Previous Article | Next Article 
The Journal of Neuroscience, August 15, 1999, 19(16):6723-6732
Tetanus Toxin Blocks the Exocytosis of Synaptic Vesicles
Clustered at Synapses But Not of Synaptic Vesicles in Isolated
Axons
Claudia
Verderio1,
Silvia
Coco1,
Alberto
Bacci1,
Ornella
Rossetto2,
Pietro
De
Camilli3,
Cesare
Montecucco2, and
Michela
Matteoli1
1 Consiglio Nazionale delle Ricerche Cellular
and Molecular Pharmacology and B. Ceccarelli Centers, Department of
Medical Pharmacology, 20129 Milano, Italy; 2 Dipartimento
di Scienze Biomediche, Consiglio Nazionale delle Ricerche-Centro
Biomembrane, University of Padova, 35122 Padova, Italy, and
3 Howard Hughes Medical Institute and Department of Cell
Biology, Yale University School of Medicine, New Haven, Connecticut
06510
 |
ABSTRACT |
Recycling synaptic vesicles are already present in isolated axons
of developing neurons (Matteoli et al., 1992 ; Zakharenko et al., 1999).
This vesicle recycling is distinct from the vesicular traffic
implicated in axon outgrowth. Formation of synaptic contacts coincides
with a clustering of synaptic vesicles at the contact site and with a
downregulation of their basal rate of exo-endocytosis (Kraszewski et al., 1995; Coco et al., 1998) We report here that tetanus toxin-mediated cleavage of synaptobrevin/vesicle-associated membrane protein (VAMP2), previously shown not to affect axon outgrowth, also does not inhibit synaptic vesicle exocytosis in isolated axons, despite its potent blocking effect on their exocytosis at synapses. This differential effect of tetanus toxin could be seen
even on different branches of a same neuron. In contrast, botulinum toxins A and E [which cleave synaptosome-associated protein
of 25 kDa. (SNAP-25)] and F (which cleaves
synaptobrevin/VAMP1 and 2) blocked synaptic vesicle exocytosis both in
isolated axons and at synapses, strongly suggesting that this process
is dependent on "classical" synaptic SNAP receptor (SNARE)
complexes both before and after synaptogenesis. A tetanus
toxin-resistant form of synaptic vesicle recycling, which proceeds in
the absence of external stimuli and is sensitive to botulinum toxin F,
E, and A, persists at mature synapses. These data suggest the
involvement of a tetanus toxin-resistant, but botulinum F-sensitive,
isoform of synaptobrevin/VAMP in synaptic vesicle exocytosis before
synapse formation and the partial persistence of this form of
exocytosis at mature synaptic contacts.
Key words:
exocytosis; synaptic vesicles; tetanus toxin; synaptogenesis; hippocampal neurons; synaptobrevin
| |
INTRODUCTION |
Major characteristics of synaptic
transmission are high spatial precision, speed, and great fidelity.
These features are dependent on exocytosis taking place at restricted
and well defined areas of the neuronal membrane. They rely on the
presence of an extremely specialized machinery, allowing very rapid
triggering and switching off of synaptic vesicle (SV) exocytosis in
response to depolarization-evoked calcium influx (Barrett and Stevens,
1972). Regulated SV exocytosis at mature synaptic sites has been widely
investigated, and several proteins that participate in this process
have now been identified (Sollner et al., 1993; Bennett and Scheller,
1994; Ferro-Novick and Jahn, 1994; Südhof, 1995). It is
well established that SV exocytosis involves the interaction of
the synaptic vesicle membrane proteins
synaptobrevin/vesicle-associated membrane protein (VAMP) 1 and 2 [v-SNAREs (soluble N-ethylmaleimide factor-attached protein (SNAP) receptors (SNARE)] with the plasma membrane proteins syntaxin and SNAP-25 (t-SNAREs). Synaptic SNARE proteins are targets for the
proteolytic action of clostridial tetanus and botulinum neurotoxins (TeNT and BoNTs), which potently block exocytosis in nerve terminals (Blasi et al., 1993a,b; Schiavo et al., 1992, 1993a,b, 1995).
The molecular mechanisms involved in the development of CNS
synapses are still poorly understood. A powerful experimental system to
investigate these mechanisms is represented by primary cultures of
hippocampal neurons. In these neurons, SVs, which release
neurotransmitter and undergo high basal exo-endocytotic recycling, are
already present at very early developmental stages when axons grow in
isolation. Formation of synaptic contacts coincides with a clustering
of synaptic vesicles, with a downregulation of their basal recycling
rate (Kraszewski et al., 1995; Coco et al., 1998), with a change
in the calcium sensitivity of the exocytotic process (Coco et al.,
1998), and with a switch in the population of calcium channels
controlling neurotransmitter (glutamate) release (Scholz and Miller,
1995; Verderio et al., 1995).
Synaptic vesicle exocytosis, which occurs in developing axons, is
clearly distinct from the constitutive exocytosis of vesicles that
mediate axon elongation. Whereas the latter occurs primarily at the
axon ending (Pfenninger and Maylie-Pfenninger 1981; Futerman et al.,
1993; Craig et al., 1995; Zakharenko and Popov 1998), the former occurs
along the entire distal axonal arbor (Matteoli et al., 1992; Kraszewski
et al., 1995; Zakharenko et al., 1999). It was shown previously that
axonal outgrowth and synaptogenesis in cultured CNS neurons is not
inhibited by tetanus toxin (Ahnert-Hilger et al., 1996; Osen Sand et
al., 1996), strongly suggesting that the v-SNARE(s) implicated in this
process are distinct from the classical synaptic v-SNARE(s). We report
here that, surprisingly, even synaptic vesicle exocytosis is
insensitive to the action of tetanus toxin in developing axons. This
tetanus toxin-resistant form of SV recycling partially persists at
mature synapses as spontaneous SV exocytosis. These findings suggest
that the different properties of nonsynaptic and synaptic exocytosis of
SVs correlate with a switch in v-SNARE isoforms underlying SNARE
complex formation.
| |
MATERIALS AND METHODS |
Hippocampal cell cultures. Primary neuronal cultures
were prepared from the hippocampi of 18-d-old fetal rats as described by Banker and Cowan (1977) and Bartlett and Banker (1984). Briefly, hippocampi were dissociated by treatment with trypsin (0.25% for 15 min at 37°C), followed by trituration with a fire-polished Pasteur
pipette. Dissociated cells were plated on
poly-L-lysine-treated (Sigma, Milano, Italy)
glass coverslips in MEM with 10% horse serum at densities ranging from
10,000 to 20,000 cells/cm2. After few
hours, coverslips were transferred to dishes containing a monolayer of
cortical glial cells (Booher and Sensenbrenner, 1972), so that they
were suspended over the glial cells but not in direct contact with them
(Bartlett and Banker, 1984). Cells were maintained in MEM (Life
Technologies, S. Giuliano, Italy) without sera, supplemented
with 1% N2 (Life Technologies), 2 mM glutamine,
and 1 mg/ml BSA (neuronal medium). A modification of the method used by
Furshpan et al. (1976) was used to grow single neurons on small islands
of substrate, consisting in a fine mist of
poly-L-lysine sprayed on glass coverslips.
Experimental treatments. Neuronal cultures were exposed to
10 nM TeNT for 5 min in the presence or absence
of 55 mM KCl in the external medium, thoroughly
washed, maintained in regular medium at 37°C for 2-18 hr, fixed, and
double stained for synaptobrevin/VAMP2 and for synaptophysin. In some
experiments, neurons were also exposed to 20 nM
BoNT/A, 80 nM BoNT/E, and 60-100
nM BoNT/F. An immunocytochemical assay based on
the use of antibodies directed against the intravesicular domain of rat
synaptotagmin I (Syt-ecto Abs) was used to test the efficacy of the
toxins in blocking synaptic vesicle recycling. In particular, cultures
were incubated with Syt-ecto Abs for 5 min or 1 hr at 37°C in the
presence or absence of 55 mM KCl. Cells were then fixed
with 4% paraformaldehyde in 0.12 M phosphate
buffer containing 0.12 M sucrose for 25 min at 37°C. Fixed cells were detergent-permeabilized and labeled with rhodamine-conjugated anti-rabbit antibodies as described previously (Matteoli et al., 1992). Counterstaining of neurons with antibodies directed against total synaptotagmin I (Syt mono), followed by fluorescein-conjugated anti-mouse antibodies, was performed as described previously (Matteoli et al., 1992). Coverslips were mounted
in 70% glycerol in phosphate buffer containing 1 mg/ml phenylendiamine. Preparations were examined with a Zeiss
(Oberkochen, Germany) microscope equipped with epifluorescence and
photographed with T-MAX 400 (Kodak, Milano, Italy). Quantitative
analysis was performed as described previously (Matteoli et al., 1996;
Coco et al., 1998; Verderio et al., 1999a). For each experiment, 60-80 neurons were examined. Values obtained in different experiments were
averaged and plotted.
Immunoblotting. Cultured hippocampal neurons were
solubilized in 1% SDS, 5% 2-mercaptoethanol, 65 mM Tris-HCl, pH 6.8, and 10% sucrose as
described previously (Coco et al., 1997). SDS-PAGE electrophoresis and
Western blotting were performed as described previously (Laemmli, 1970;
Towbin et al., 1979). Briefly, cell extracts (30 µg) were subjected
to SDS-PAGE (10% polyacrylamide gels) and transferred by
electroblotting to nitrocellulose (Sartorius, Gottingen, Germany).
Blots were blocked in 5% nonfat dry milk, 0.1% Tween 20, 20 mM Tris, and 150 mM NaCl,
pH 7.5, at room temperature. Blots were incubated with antibodies for 2 hr at room temperature in blocking buffer. Blots were then thoroughly
washed, incubated (1 hr) with horseradish peroxidase-conjugated
anti-rabbit IgG or horseradish peroxidase-conjugated anti-mouse IgG
(1:5000 in blocking buffer; Sigma), and finally washed with Tris-NaCl.
The immunoreactive proteins were visualized with enhanced
chemiluminescence (Amersham, Milano, Italy).
Antibodies. Rabbit polyclonal antibodies directed
against the intravesicular domain of rat synaptotagmin I (Syt-ecto Abs) were generated as described previously (Matteoli et al., 1992) using a
synthetic peptide corresponding to the residue 1-19 of the protein.
Antibodies against synaptobrevin/VAMP1 and 2 were generated in
rabbit as described previously (Rossetto et al., 1996). Polyclonal
antibodies against synaptophysin and monoclonal antibodies against
synaptobrevin/VAMP2, rab3a, and synaptotagmin I were a kind gift from
Dr. R. Jahn (Gottingen, Germany). Polyclonal antibodies against
syntaxin I and SNAP-25 were raised and used as described
previously (Chilcote et al., 1995; Papini et al., 1995). Anti-rabbit
rhodamine-conjugated antibodies were purchased from Boehringer Mannheim
(Milano, Italy). Anti-mouse fluorescein-conjugated antibodies were from
Jackson ImmunoResearch (West Grove, PA).
| |
RESULTS |
Synaptic v- and t-SNAREs are already expressed by neurons at early
developmental stages
When maintained in primary cultures, embryonic hippocampal neurons
develop through a series of well characterized developmental stages
(Dotti et al., 1988). After few days in culture, they establish a clear
axo-dendritic polarity and, eventually, form a network of functional
synaptic contacts characterized by presynaptic clusters of SVs and by
the postsynaptic accumulation of glutamate receptors (Craig and Banker,
1994; Verderio et al., 1999b). Figure 1
shows that the SV proteins synaptotagmin I, synaptophysin, and rab3a, together with the three SNARE proteins synaptobrevin/VAMP2, SNAP-25, and syntaxin I, are already expressed by cultured hippocampal neurons
at early developmental stages. For all of them, an increase in the
levels of expression takes place in parallel with the time of
differentiation in culture. A similar increase in synaptic protein
expression was found to take place also during brain development, as
indicated by Western blot analysis of total homogenates from embryonic
day 18 (E18), postnatal day (P1), and adult rat brains. In
contrast, we could not detect any synaptobrevin/VAMP1 immunoreactivity in cultured hippocampal neurons before synaptogenesis (data not shown). Immunofluorescence experiments revealed that, before
synaptogenesis, synaptobrevin/VAMP2 immunoreactivity was localized on
vesicular structures dispersed along the axon (see Fig. 3A).
These vesicular structures, which are immunoreactive for synaptotagmin
I (see Fig. 3B), synaptophysin, and rab3a (data not
shown), have been already identified as bona fide SVs (Fletcher et al.,
1991; Matteoli et al., 1991, 1992, 1996; Kraszewski et al., 1995; Coco
et al., 1998). Syntaxin I and SNAP-25 were found to be present
throughout all neuronal compartments (data not shown) (Galli et al.,
1995).
View larger version (48K):
[in this window]
[in a new window]
|
Figure 1.
Synaptic protein expression during
neuronal development. Western blot analysis of cell extracts from
neuronal cultures maintained in vitro for 2, 7, and 15 d
(DIV) and from rat brain at different
developmental stages (E18, P1, and adult). SV (synaptophysin,
synaptotagmin, synaptobrevin/VAMP2, and rab3a) and plasma membrane
(SNAP-25 and syntaxin) proteins are expressed since early developmental
stages and undergo a progressive increase in their expression in
parallel with neuronal maturation. The same amount of material (30 µg) has been loaded in each lane.
|
|
TeNT blocks recycling of SVs clustered at synapses but does not
block SV recycling before synaptogenesis
To monitor SV recycling, we used an assay based on antibodies
directed against the intravesicular domain of the SV protein synaptotagmin I (Syt-ecto Abs), which become internalized in the lumen
of SVs when they undergo exocytosis and compensatory endocytosis (Matteoli et al., 1992). As already shown, Syt-ecto Abs become internalized by an activity-dependent mechanism at synaptic contacts of
cultured hippocampal neurons (Fig.
2B) and are also
actively taken up by recycling vesicles in the axon of developing
neurons (Fig. 2F). Mature cultures were incubated
with 10 nM TeNT for 5 min under depolarizing
conditions and assayed for SV recycling 2 hr later, when the TeNT
substrate synaptobrevin/VAMP2 is completely cleaved (Matteoli et al.,
1996). Virtually no internalization of Syt-ecto Abs at synaptic sites
was detected (n = 15 experiments) (Fig.
2D, I, quantitative analysis), consistent
with a block of exocytosis produced by TeNT treatment. In contrast,
when applied to neurons before synaptogenesis, TeNT was actively
internalized (data not shown) (Matteoli et al., 1996) but did not
produce any relevant inhibitory effect on SV recycling
(n = 7) (Fig. 2H, I, quantitative analysis).
View larger version (51K):
[in this window]
[in a new window]
|
Figure 2.
Tetanus toxin treatment inhibits SV
exocytosis at mature synapses but not in developing neurons.
A, B, Fifteen-day-old neurons were
incubated for 5 min in the presence of Syt-ecto Abs in 55 mM external KCl before (A, B)
or after (C, D) treatment with 10 nM TeNT. After this incubation, neurons were washed, fixed,
detergent-permeabilized, reacted with rhodamine-conjugated goat
anti-rabbit IgGs (B, D), and
counterstained with antibodies against total synaptotagmin
(syt), followed by FITC-conjugated goat anti-mouse IgGs
(A, C). Puncta of immunoreactivity
represent presynaptic nerve terminals, which outline perikarya and
dendrites. Syt-ecto Abs are internalized at synaptic contacts when
applied in control conditions (B) but not after
treatment with TeNT (D). E-H,
Exocytosis-dependent uptake of Syt-ecto Abs (applied for 5 min in the
presence of 55 mM KCl in the external medium) in living
neurons before synaptogenesis, in control conditions
(F), or after treatment with 10 nM
TeNT (H). E,
G, Double immunofluorescence of total synaptotagmin
(syt) of the same neurons as in F and
H. Note that an efficient internalization of Syt-ecto
Abs takes place in axons, even after treatment with TeNT
(H). Scale bar: A-D, 20 µm; E-H, 28 µm. I, Quantitative
analysis of Syt-ecto internalization in neurons before and after
synaptogenesis, both in control conditions or after treatment with 10 nM TeNT.
|
|
The lack of effect of TeNT on SV recycling in neurons before
synaptogenesis could result from inaccessibility of synaptobrevin/VAMP2 to the proteolytic action of the toxin. To test this possibility, hippocampal neurons were stained for synaptobrevin/VAMP2 after TeNT
treatment. In control neurons, synaptobrevin/VAMP2 was localized on
vesicles dispersed throughout the distal axonal arbor (Fig. 3A). These vesicles
colocalized with internalized Syt-ecto Abs (Fig. 3B), thus
supporting their identification as recycling SVs. After 6 hr of TeNT
treatment, a substantial reduction (up to 77%) of synaptobrevin/VAMP 2 staining was detected (Fig. 3C, E, quantitative analysis). An even more pronounced cleavage (up to 90%) was obtained 18 hr after TeNT treatment (Fig. 3E). Surprisingly, however,
this reduction did not correlate with an impairment in SV recycling (Fig. 3E, quantitative analysis). In contrast, BoNT/F, which
cleaves VAMP2 as well but at a different peptide bond, significantly
inhibited SV exocytosis in developing axons in a dose-dependent manner
(Fig. 3F). Moreover, when hippocampal cultures at
early developmental stages were incubated in the presence of 20 nM BoNT/A or 80 nM BoNT/E,
which both cleave SNAP-25 (Blasi et al., 1993a; Schiavo et al., 1993a),
a substantial reduction of Syt-ecto Ab internalization could be
detected (n = 6) (Fig. 4
B,C, quantitative analysis). Thus,
SV exocytosis before synaptogenesis requires SNAP-25 and a
TeNT-insensitive, but BoNT/F-sensitive, isoform of synaptobrevin/VAMP2 isoform.
View larger version (76K):
[in this window]
[in a new window]
|
Figure 3.
TeNT treatment cleaves
synaptobrevin/VAMP2 without blocking SV recycling in neurons before
synaptogenesis. A, B, Immature control neuron exposed to Syt-ecto Abs
(for 5 min in the presence of 55 mM KCl in the external
medium) (B) and double labeled for
synaptobrevin/VAMP2 (A). C,
D, Immature neuron exposed to Syt-ecto Abs
(D) and double labeled for synaptobrevin/VAMP2
(C) after treatment with 10 nM TeNT.
Note that TeNT treatment cleaves synaptobrevin/VAMP2 without impairing
SV recycling. Scale bar, 11.25 µm. E, Quantitative
analysis of Syt-ecto Ab internalization ( ) and synaptobrevin/VAMP2
cleavage ( ) in developing neurons at different times after culture
intoxication. Note that TeNT treatment dramatically reduces
synaptobrevin/VAMP2 immunoreactivity over time without significantly
reducing SV recycling. F, Quantitative analysis of
Syt-ecto Ab internalization () and synaptobrevin/VAMP2 cleavage
() in developing neurons exposed to increasing doses of BoNT/F. Note
the existence of a strict correlation between synaptobrevin/VAMP2
cleavage and inhibition of SV recycling. Values were expressed as a
ratio between the signals produced by Syt-ecto Abs or by
synaptobrevin/VAMP2 antibodies and those produced by antibodies
directed against total synaptotagmin I or synaptophysin.
|
|
View larger version (54K):
[in this window]
[in a new window]
|
Figure 4.
BoNT/A and E block SV recycling in neurons before
synaptogenesis. A, B,
Exocytosis-dependent uptake of Syt-ecto Abs (applied for 5 min in the
presence of 55 mM KCl in the external medium) in immature
neurons after treatment with 20 nM BoNT/A. Virtually no
internalization takes place in neuronal processes
(B), visualized by double labeling with
antibodies against total synaptotagmin (syt,
A). Scale bar, 12.8 µm. C,
Quantitative analysis of Syt-ecto internalization in cultures treated
with 20 nM BoNT/A and 80 nM BoNT/E. Note that
BoNTs of both serotypes strongly reduce SV recycling.
|
|
TeNT insensitivity is not related to the maturation stage of
neurons in culture
Hippocampal neurons maintained in vitro for 2-3 weeks
are endowed with a dense network of synaptic contacts. However, a few isolated axons containing dispersed SVs and lacking a postsynaptic target are occasionally detectable in mature cultures. Figure 5, A and inset a,
show examples of these isolated axons in cultures of synaptically
connected neurons that have been labeled with antibodies directed
against total synaptotagmin (Fig. 5A) or with antibodies
directed against synaptophysin (inset a). SVs
present in these isolated axons of otherwise mature neurons undergo an active exo-endocytotic recycling, as demonstrated by the active internalization of the Syt-ecto Abs (Fig. 5B). Treatment of
mature cultures with TeNT produced an efficient cleavage of
synaptobrevin/VAMP2 in the isolated axons (inset
b), similar to what has been already shown for
synaptobrevin/VAMP2 present at synaptic contacts (Matteoli et al.,
1996). However, whereas TeNT strongly inhibited SV fusion at sites of
synaptic contacts (Figs. 2D,I;
5B, arrowheads), it did not substantially reduce
vesicle recycling in isolated axons (Fig. 5B). This
observation argues against the possibility that the lack of TeNT effect
on SV recycling before synaptogenesis is related to the immature stage
of the neurons.
View larger version (84K):
[in this window]
[in a new window]
|
Figure 5.
SV recycling is TeNT-insensitive in isolated axons
of mature cultures. An efficient internalization of Syt-ecto Abs,
applied for 5 min in 55 mM KCl, takes place in the isolated
axons present in fully differentiated cultures after exposure to 10 nM TeNT (B). No labeling is
detectable at synaptic contacts (arrowheads).
A, Double labeling of the same culture as in
B with antibodies against total synaptotagmin
(syt). Insets a, b,
After TeNT intoxication, synaptobrevin/VAMP2 immunoreactivity is no
longer visible in an isolated axon (b) double
labeled with the SV marker synaptophysin (a).
C-H, SV exocytosis is differentially affected by TeNT
in distinct compartments of a same neuron grown in microisland and
forming autaptic contacts. Exposure to 10 nM TeNT
completely prevents Syt-ecto Ab internalization at autapses, the sites
where the axon gets in touch with dendrites (small
arrowheads), whereas an efficient internalization of Syt-ecto
antibodies takes place in the isolated axon (large
arrowhead) (D). F,
H, High magnification details of Syt-ecto Ab
internalization at autaptic contacts (F) and in
the isolated axon (H). C,
E, G, Double labeling of the same neuron
with antibodies against total synaptotagmin. Scale bar:
A, B, 11 µm; C,
D, 25 µm; G, H, 10 µm.
|
|
To further prove this point, we investigated whether different axonal
branches of the same neuron may exhibit different sensitivity to the
toxin. To this aim, hippocampal neurons were cultured on poly-L-lysine microislands, i.e., under conditions that
allow the analysis of single neurons whose axons form autaptic contacts (Furshpan et al., 1976; Bekkers and Stevens, 1991). These single neurons often extend additional axons that lack a postsynaptic target,
thus allowing a simultaneous analysis of synaptic and nonsynaptic SV
exocytosis in a same cell (Fig. 5C-H). We found that
exposure of these neurons to TeNT produced the typical inhibition of SV
recycling at sites of synaptic contacts (Fig. 5D,
small arrowheads, F). On the other hand,
SV recycling in isolated processes was not impaired (Fig.
5D, large arrowhead, H).
A TeNT-insensitive form of SV recycling persists at
mature synapses
Mature cultures were incubated with TeNT and assayed for evoked SV
recycling 2 hr later. A residual internalization of Syt-ecto Abs was
detectable in <10% of synaptic sites (n = 15) (Fig.
6C, evoked),
consistent with a massive cleavage of the TeNT substrate synaptobrevin/VAMP2 (Matteoli et al., 1996). On the other hand, after
TeNT intoxication, the majority of synapses (82%) maintained a
residual SV recycling, resulting in a significant level of Syt-ecto Ab
internalization after 1 hr incubation in the absence of
depolarizing stimuli and in the presence of TTX (n = 4) (Fig. 6B, C, spontaneous). In contrast, pretreatment of mature cultures with BoNT/F, BoNT/E, or BoNT/A impaired to a similar extent Syt-ecto Ab internalization attributable to either spontaneous or depolarization-evoked SV recycling (Fig. 6C).
View larger version (55K):
[in this window]
[in a new window]
|
Figure 6.
Persistence of spontaneous release at the synapse
after TeNT but not BoNT treatment. A, B, Spontaneous
Syt-ecto internalization at synaptic sites in TeNT-poisoned neurons
(B) double labeled with antibodies against total
synaptotagmin (syt, A). C,
Quantitative analysis of Syt-ecto Ab internalization in mature neurons
intoxicated with TeNT or with BoNTs (20 nM BoNT/A, 80 nM BoNT/E, and 80 nM BoNT/F). Note that BoNTs
of all serotypes prevent similar spontaneous and evoked Syt-ecto Ab
internalization at the majority of synaptic contacts, whereas TeNT
inhibits evoked Syt-ecto internalization without substantially
impairing spontaneous uptake. Incubation with Syt-ecto antibodies is
performed for 5 min in the presence of 55 mM KCl in the
external medium or for 1 hr in low KCl (5 mM) and 1 µM TTX.
|
|
| |
DISCUSSION |
Bona fide SVs are present in isolated processes of developing
neurons before synapse formation. These vesicles have the same size
range of typical presynaptic SVs (Matteoli et al., 1992; Kraszewski et
al., 1995), store and secrete neurotransmitter (Young and Poo 1983; Sun
and Poo, 1987; Zakharenko et al., 1999), and, based on
immunocytochemical results, have an SV protein composition (Fletcher et al., 1991; Matteoli et al., 1991, 1992). In developing processes, these vesicles are organized in small clusters that, similar
to SVs of the presynapse, are disrupted by okadaic acid (Kraszewski et
al., 1995). Moreover, they are excluded from the leading edge of the
growth cone (Kraszewski et al., 1995), indicating that they do not
participate to the elongation of the axon. Finally, they undergo active
exo-endocytotic recycling (Matteoli et al., 1992; Kraszewski et al.,
1995; Coco et al., 1998), and their fusion with the plasma membrane is
partially stimulated by depolarization (Kraszewski et al., 1995; Coco
et al., 1998; Zakharenko et al., 1999).
We used a morphological assay (Matteoli et al., 1992) to follow SV
dynamics after clostridial toxin treatment, independent from possible
effects of these toxins on postsynaptic exocytosis and responsiveness
(Lledo et al., 1998, Maletic-Savatic et al., 1998; Maletic-Savatic and
Malinow, 1998; Nishimune et al., 1998; Osten et al., 1998; Song et al.,
1998). Our results demonstrate that, different from SV exocytosis at
mature synapses, SV recycling before synaptogenesis is not
significantly inhibited by treatment with TeNT. The lack of TeNT effect
on SV recycling before synaptogenesis is not because of a poor
penetration of the toxin in immature neurons, because an efficient
internalization of TeNT has been shown to occur in neurons already
before synaptogenesis (Matteoli et al., 1996). On the other hand, the
resistance of SV recycling to treatment with TeNT does not result from
inaccessibility of the substrate synaptobrevin/VAMP2 to the toxin
itself. Indeed, a substantial cleavage of synaptobrevin/VAMP2 is
achieved by TeNT treatment in neurons before synaptogenesis, although a
more prolonged exposure to the toxin with respect to neurons after
formation of synaptic contacts is required. Because TeNT enters SVs
before synaptogenesis with a high rate (Matteoli et al., 1996), the
reduced efficacy of TeNT in cleaving synaptobrevin/VAMP2 in immature
neurons may be attributable to a less efficient translocation of the
toxin in the cytosol and/or to the higher turnover of the protein in neurons at early developmental stages (Daly and Ziff, 1997).
The persistence of SV exo-endocytotic recycling in hippocampal neurons
before synaptogenesis after TeNT treatment raises at least three
possibilities. The first is that SV recycling is supported by a
fraction of synaptobrevin/VAMP2, which, being shielded by a tight
complex with other proteins because of post-translational modifications, cannot be cleaved by the toxin. However, because the
percentage of cleaved synaptobrevin/VAMP2 and the inhibition of SV
recycling are unrelated, this possibility is unlikely. The second is
that SV fusion may proceed in the absence of synaptobrevin/VAMP2. It
has been shown in yeast that organelles endowed with syntaxin homologs,
but not synaptobrevin/VAMP2 homologs, may fuse each other (Nichols et
al., 1997). Although it has been demonstrated that pools of syntaxin I
and SNAP-25 may be present on SV membranes (Walch-Solimena et al.,
1995), the relatively low rate of fusion in the absence of
synaptobrevin/VAMP2 (Nichols et al., 1997) does not fit with the high
efficiency of SV recycling before synaptogenesis (Kraszewski et al.,
1995; Coco et al., 1998). The third is that a TeNT-resistant isoform of
synaptobrevin/VAMP2 may mediate SV exocytosis at early developmental
stages. The finding that BoNT/F-induced cleavage of synaptobrevin/VAMP2
correlates with inhibition of SV recycling strongly supports this third
hypothesis, suggesting the existence of a synaptobrevin/VAMP isoform,
specifically lacking the cleavage or recognition site for TeNT and
mostly supporting exocytosis before synaptogenesis. The involvement of
the SNARE fusion complex proteins in SV exocytosis before
synaptogenesis is further supported by the finding that SV recycling,
although being not reduced by TeNT, is strongly inhibited by BoNT/A and BoNT/E, which cleave SNAP-25, the other protein component that, together with synaptobrevin/VAMP2 and syntaxin, mediates fusion of SVs
at mature synapses.
When synapses form, SVs enter a regulated,
synaptobrevin/VAMP2-dependent exocytotic pathway. However, the
acquisition of a TeNT-sensitive exocytosis does not correlate with a
complete elimination of the TeNT-insensitive mechanism of SV recycling.
Indeed, a residual TeNT-resistent and action potential-independent SV
recycling is maintained in the majority (85%) of the synapses. The
existence of a TeNT-insensitive form of exocytosis at mature synapses
has been already reported (Duchen and Tonge 1973; Dreyer and
Schmitt 1981; Dreyer 1989; Herreros et al., 1995; Sweeney et
al., 1995; Capogna et al., 1997). In some experimental models,
TeNT-resistant exocytosis appears to entirely account for the
spontaneous neurotransmitter release (Bevan and Wendon, 1984; Hua et
al., 1998). In other systems, application of TeNT produces a relevant
decrease but never a complete block of spontaneous events (with a
single exception reported by Mellanby and Thompson, 1972). In our
experimental model, although strongly reduced, miniature EPSC
frequency was not completely blocked, whereas BoNT/E completely
inhibited miniature spontaneous activity (our unpublished
observations). This observation is in agreement with the results
obtained with the Syt-ecto Ab presynaptic assay, which demonstrate that
the majority of synaptic contacts that are able to recycle SVs after
TeNT treatment do not recycle SVs after treatment with BoNT/A, E, and,
F, suggesting the involvement of the same machinery operating before
synaptogenesis. It is noteworthy that, in Drosophila
synaptobrevin mutants, the evoked release is entirely abolished,
whereas only a fraction of spontaneous release is inhibited (Deitcher
et al., 1998). On the other hand, both evoked and spontaneous release
are disrupted by cleavage of syntaxin I (Schulze et al., 1995).
The mechanism responsible for altering the balance between the
TeNT-insensitive and the TeNT-sensitive pathway during synaptogenesis is not clear yet. It is possible to hypothesize that the presence of a
postsynaptic target plays a role in favoring exocytosis being predominantly controlled by high rises in the levels of calcium (Coco
et al., 1998) and mostly relying on synaptobrevin/VAMP2. This
possibility is supported by results obtained in single neurons growing
in microislands. In this experimental model, the same neuron may be
endowed with two distinct SV-containing compartments: the typical
presynaptic terminals containing clustered vesicles, and the isolated
axon characterized by diffusely distributed SVs. Strikingly, whereas SV
recycling is sensitive to TeNT at sites of synaptic contacts, it is not
inhibited in the isolated axon of the same cell, indicating that the
same neuron may differently regulate exocytosis occurring in two
different compartments, possibly in relation with the presence of a
postsynaptic target. Several data, recently obtained in different
experimental systems, suggest that indeed maturation of presynaptic
structure and function is affected by signals from the postsynaptic
cell (Fletcher et al., 1994; Haydon and Zoran, 1994; Campagna et al.,
1995; Dechiara et al., 1996; Petersen et al., 1997; Davis et al., 1998;
Fitzsimonds and Poo, 1998). Our data support the possibility
that the postsynaptic cell may actively affect the presynaptic
machinery controlling SV fusion during synaptogenesis between neurons
in the mammalian CNS.
| |
FOOTNOTES |
Received March 22, 1999; revised May 24, 1999; accepted May 24, 1999.
This work has been supported by Telethon Grants 1042 (to M.M.) and 1068 (to C.M.), by Human Frontier Science Program (to M.M. and P.D.C.), by
the European Community Grants Biomed 2 BMH4 CT97 2410 (to C.M.) and
BIO4-98-0408 (to M.M.), and by National Institutes of Health Grant
NS36251 (to P.D.C.). We acknowledge Dr. R. Jahn (Gottingen, Germany)
for gift of antibodies against synaptophysin, synaptobrevin/VAMP2,
rab3a, and synaptotagmin.
Correspondence should be addressed to Michela Matteoli, Consiglio
Nazionale delle Ricerche Cellular and Molecular Pharmacology, and B. Ceccarelli Centers, Department of Medical Pharmacology, University of Milano, via Vanvitelli 32, 20129 Milano, Italy.
| |
REFERENCES |
-
Ahnert-Hilger G,
Kutay U,
Chahoud I,
Rapoport T,
Wiedenmann B
(1996)
Synaptobrevin is essential for secretion but not for the development of synaptic processes.
Eur J Cell Biol
70:1-11[Web of Science][Medline].
-
Banker GA,
Cowan WM
(1977)
Rat hippocampal neurons in dispersed cell culture.
Brain Res
126:379-425.
-
Barrett EF,
Stevens CF
(1972)
The kinetics of transmitter release at the frog neuromuscular junction.
J Physiol (Lond)
227:691-708[Abstract/Free Full Text].
-
Bartlett WP,
Banker GA
(1984)
An electron microscopic study of the development of axon and dendrites by hippocampal neurons in culture. II. Synaptic relationships.
J Neurosci
4:1954-1965[Abstract].
-
Bekkers JM,
Stevens CF
(1991)
Excitatory and inhibitory autaptic currents in isolated hippocampal neurons maintained in cell cultures.
Proc Natl Acad Sci USA
88:7834-7838[Abstract/Free Full Text].
-
Bennet MK,
Scheller RH
(1994)
Molecular correlates of synaptic vesicles docking and fusion.
Curr Opin Neurobiol
4:324-329[Medline].
-
Bevan S,
Wendon LMB
(1984)
A study of the action of tetanus toxin at rat soleous neuromuscular junction.
J Physiol (Lond)
348:1-17[Abstract/Free Full Text].
-
Blasi J,
Chapman ER,
Yamasaki S,
Binz T,
Niemann H,
Jahn R
(1993a)
Botulinum neurotoxin C1 blocks neurotransmitter release by means of cleaving HPC-1/syntaxin.
EMBO J
12:4821-4828[Web of Science][Medline].
-
Blasi J,
Chapman ER,
Link E,
Binz T,
Yamasaki S,
De Camilli P,
Sudhof TC,
Niemann H,
Jahn R
(1993b)
Botulinum neurotoxin A selectively cleaves the synaptic protein SNAP-25.
Nature
365:160-163[Medline].
-
Booher J,
Sensenbrenner M
(1972)
Growth and cultivation of dissociated neurons and glial cells from embryonic chick, rat, and human brain in flask cultures.
Neurobiology
2:97-105[Medline].
-
Campagna JA,
Ruegg MA,
Bixby JL
(1995)
Agrin is a differentiation-inducing "stop signal" for motoneurons in vitro.
Neuron
15:1365-1374[Web of Science][Medline].
-
Capogna M,
McKinney RA,
O'Connor V,
Gahwiler BH,
Thompson SM
(1997)
Ca2+ or Sr2+ partially rescues synaptic transmission in hippocampal cultures treated with botulinum toxin A and C, but not tetanus toxin.
J Neurosci
17:7190-7202[Abstract/Free Full Text].
-
Chilcote TJ,
Galli T,
Mundigl O,
Edelmann L,
McPherson PS,
Takei K,
De Camilli P
(1995)
Cellubrevin and synaptobrevins: similar subcellular localization and biochemical properties in PC12 cells.
J Cell Biol
129:219-231[Abstract/Free Full Text].
-
Coco S,
Verderio C,
Trotti D,
Rothstein JD,
Volterra A,
Matteoli M
(1997)
Non-synaptic localization of the glutamate transporter EAAC1 in cultured hippocampal neurons.
Eur J Neurosci
9:1902-1910[Web of Science][Medline].
-
Coco S,
Verderio C,
De Camilli P,
Matteoli M
(1998)
Calcium dependence of synaptic vesicle recycling before and after synaptogenesis.
J Neurochem
71:1987-1992[Web of Science][Medline].
-
Craig AM,
Banker G
(1994)
Neuronal polarity.
Annu Rev Neurosci
17:267-310[Web of Science][Medline].
-
Craig AM,
Wyborski RJ,
Banker J
(1995)
Preferential addition of newly synthesized membrane protein at axonal growth cones.
Nature
375:592-594[Medline].
-
Daly C,
Ziff EB
(1997)
Post-trascriptional regulation of synaptic vesicle protein expression and the developmental control of synaptic vesicle formation.
J Neurosci
17:2365-2375[Abstract/Free Full Text].
-
Davis GW,
DiAntonio A,
Petersen SA,
Goodman CS
(1998)
Postsynaptic PKA controls quantal size and reveals a retrograde signal that regulates presynaptic transmitter release in Drosophila.
Neuron
20:305-315[Web of Science][Medline].
-
Dechiara TM,
Bowen DC,
Valenzuela DM,
Simmons MV,
Poueymirou WT,
Thomas S,
Kinetz E,
Compton DL,
Rojas E,
Park JS
(1996)
The receptor tyrosine kinase MuSK is required for neuromuscular formation in vivo.
Cell
85:501-512[Web of Science][Medline].
-
Deitcher DL,
Ueda A,
Stewart BA,
Burgess RW,
Kikodoro Y,
Schwartz TL
(1998)
Distinct requirements for evoked and spontaneous release of neurotransmitter are revealed by mutations in the Drosophila gene neuronal-synaptobrevin.
J Neurosci
18:2028-2039[Abstract/Free Full Text].
-
Dotti CG,
Sullivan CA,
Banker GA
(1988)
The establishment of polarity by hippocampal neurons in culture.
J Neurosci
8:1454-1468[Abstract].
-
Dreyer F
(1989)
Peripheral actions of tetanus toxin.
In: Botulinum neurotoxin and tetanus neurotoxin (Simpson LL,
ed), pp 179-202. San Diego: Academic.
-
Dreyer F,
Schmitt A
(1981)
Different effects of botulinum A toxin and tetanus toxin on the transmitter releasing process at the mammalian neuromuscular junction.
Neurosci Lett
26:307-311[Web of Science][Medline].
-
Duchen LW,
Tonge DA
(1973)
The effects of tetanus toxin on neuromuscular transmission and on the morphology of motor end-plates in slow and fast skeletal muscle of the mouse.
J Physiol (Lond)
228:157-172[Abstract/Free Full Text].
-
Ferro-Novick S,
Jahn R
(1994)
Vesicle fusion from yeast to man.
Nature
370:191-193[Medline].
-
Fitzsimonds RM,
Poo MM
(1998)
Retrograde signaling in the development and modification of synapses.
Physiol Rev
78:143-170[Abstract/Free Full Text].
-
Fletcher TL,
Cameron PL,
De Camilli P,
Banker GA
(1991)
The distribution of synapsin I and synaptophysin in hippocampal neurons developing in culture.
J Neurosci
11:1617-1626[Abstract].
-
Fletcher TL,
De Camilli P,
Banker GA
(1994)
Synaptogenesis in hippocampal cultures: evidence indicating that axons and dendrites become competent to form synapses at different stages of neuronal development.
J Neurosci
14:6695-6706[Abstract].
-
Furshpan EJ,
Mac Leish PR,
O'Lague PH,
Potter DD
(1976)
Chemical transmission between rat sympathetic neurons and cardiac myocytes developing in microcultures: evidence for cholinergic, adrenergic, and dual-function neurons.
Proc Natl Acad Sci USA
73:4225-4229[Abstract/Free Full Text].
-
Futerman AH,
Khanin R,
Segel LA
(1993)
Lipid diffusion in neurons.
Nature
362:119[Medline].
-
Galli T,
Garcia EP,
Mundigl O,
Chilcote TJ,
De Camilli P
(1995)
v- and t-SNAREs in neuronal exocytosis: a need for additional components to define sites of release.
Neuropharmacology
34:1351-1360[Web of Science][Medline].
-
Haydon PG,
Zoran MJ
(1994)
Retrograde regulation of presynaptic development during synaptogenesis.
J Neurobiol
25:694-706[Web of Science][Medline].
-
Herreros J,
Miralles FX,
Solsona C,
Bizzini B,
Blasi J,
Marsal J
(1995)
Tetanus toxin inhibits spontaneous quantal release and cleaves VAMP/synaptobrevin.
Brain Res
699:165-170[Web of Science][Medline].
-
Hua S-Y,
Raciborska DA,
Trimble WS,
Charlton MP
(1998)
Different VAMP/synaptobrevin complexes for spontaneous and evoked transmitter release at the crayfish neuromuscular junction.
J Neurophysiol
6:3233-3246.
-
Kraszewski K,
Mundigl O,
Daniell L,
Verderio C,
Matteoli M,
De Camilli P
(1995)
Synaptic vesicle dynamics in living cultured hippocampal neurons visualized with CY3-conjugated antibodies directed against the lumenal domain of synaptotagmin.
J Neurosci
15:4328-4342[Abstract].
-
Laemmli UK
(1970)
Cleavage of structural proteins during the assembly of the head of bacteriophage T4.
Nature
227:680-685[Medline].
-
Lledo P-M,
Zhang X,
Sudhof T,
Malenka CR,
Nicoll RA
(1998)
Postsynaptic membrane fusion and long-term potentiation.
Science
279:399-403[Abstract/Free Full Text].
-
Maletic-Savatic M,
Malinow R
(1998)
Calcium-evoked dendritic exocytosis in cultured hippocampal neurons. I. Trans-golgi network-derived organells undergo regulated exocytosis.
J Neurosci
18:6803-6813[Abstract/Free Full Text].
-
Maletic-Savatic M,
Koothan T,
Malinow R
(1998)
Calcium-evocked dendritic exocytosis in cultured hippocampal neurons. II. Mediation by calcium/calmodulin-dependent protein kinase II.
J Neurosci
18:6814-6821[Abstract/Free Full Text].
-
Matteoli M,
Takei K,
Cameron P,
Johnston PA,
Hurlbut P,
Jahn R,
Sudhof TC,
De Camilli P
(1991)
Association of rab3 with synaptic vesicles at late stages of the secretory pathway.
J Cell Biol
115:625-633[Abstract/Free Full Text].
-
Matteoli M,
Takei K,
Perin MS,
Sudhof TC,
De Camilli P
(1992)
Exo-endocytotic recycling of synaptic vesicles in developing processes of cultured hippocampal neurons.
J Cell Biol
117:849-861[Abstract/Free Full Text].
-
Matteoli M,
Verderio C,
Rossetto O,
Iezzi N,
Coco S,
Schiavo G,
Montecucco C
(1996)
Synaptic vesicle endocytosis mediates the entry of tetanus neurotoxin into hippocampal neurons.
Proc Natl Acad Sci USA
93:13310-13315[Abstract/Free Full Text].
-
Mellanby J,
Thompson PA
(1972)
The effect of tetanus toxin at the neuromuscular junction in the goldfish.
J Physiol (Lond)
224:407-419[Abstract/Free Full Text].
-
Nichols BJ,
Ungermann C,
Pelham HR,
Wickner WT,
Haas A
(1997)
Homotypic vacuolar fusion mediated by t- and v-SNAREs.
Nature
387:199-202[Medline].
-
Nishimune A,
Isaac JTR,
Molnar E,
Noel J,
Nash SR,
Tagaya N,
Collingridge GL,
Nakanishi S,
Henley JM
(1998)
NSF binding to GluR2 regulates synaptic transmission.
Neuron
21:87-97[Web of Science][Medline].
-
Osen Sand A,
Staple JK,
Naldi E,
Schiavo G,
Rossetto O,
Petitpierre S,
Malgaroli A,
Montecucco C,
Catsicas S
(1996)
Common and distinct fusion proteins in axonal growth and transmitter release.
J Comp Neurol
367:222-234[Web of Science][Medline].
-
Osten P,
Srivastava S,
Inman GJ,
Vilim FS,
Khatri LM,
Lee LM,
States BA,
Einheber S,
Milner TA,
Hanson PI,
Ziff EB
(1998)
The AMPA receptor GluR2 C terminus can mediate a reversible, ATP-dependent interaction with NSF and
 - and  -SNAPs.
Neuron
21:99-110[Web of Science][Medline]. -
Papini E,
Rossetto O,
Cutler DF
(1995)
Vesicle associated membrane protein (VAMP)/synaptobrevin 2 is associated with dense core secretory granules in PC12 neuroendocrine cells.
J Biol Chem
270:1332-1336[Abstract/Free Full Text].
-
Petersen SA,
Fetter RD,
Noordermeer JN,
Goodman CS,
DiAntonio A
(1997)
Genetic analysis of glutamate receptors in Drosophila reveals a retrograde signal regulating presynaptic transmitter release.
Neuron
19:1237-1248[Web of Science][Medline].
-
Pfenninger KH,
Maylie-Pfenninger MF
(1981)
Lectin labeling of sprouting neurons. II. Relative movement appearance of glycoconjugates during plasmalemmal expansion.
J Cell Biol
89:547-559[Abstract/Free Full Text].
-
Rossetto O,
Gorza L,
Schiavo G,
Schiavo N,
Scheller RH,
Montecucco C
(1996)
VAMP/synaptobrevin isoforms 1 and 2 are widely and differentially expressed in nonneuronal tissues.
J Cell Biol
132:167-179[Abstract/Free Full Text].
-
Schiavo G,
Benfenati F,
Poulain B,
Rossetto O,
Polverino de Laureto P,
DasGupta BR,
Montecucco C
(1992)
Tetanus and botulinum-B neurotoxins block neurotransmitter release by proteolytic cleavage of synaptobrevin.
Nature
359:832-835[Medline].
-
Schiavo G,
Rossetto O,
Catsicas S,
Polverino de Laureto P,
DasGupta BR,
Benfenati F,
Montecucco C
(1993a)
Identification of the nerve terminal targets of botulinum neurotoxin serotypes A, D, and E.
J Biol Chem
268:23784-23787[Abstract/Free Full Text].
-
Schiavo G,
Shone CC,
Rossetto O,
Alexander FC,
Montecucco C
(1993b)
Botulinum neurotoxin serotype F is a zinc endopeptidase specific for VAMP/synaptobrevin.
J Biol Chem
268:11516-11519[Abstract/Free Full Text].
-
Schiavo G,
Shone CC,
Bennett MK,
Scheller RH,
Montecucco C
(1995)
Botulinum neurotoxin type C cleaves a single Lys-Ala bond within the carboxyl-terminal region of syntaxins.
J Biol Chem
270:10566-10570[Abstract/Free Full Text].
-
Scholz KP,
Miller RJ
(1995)
Developmental changes in presynaptic calcium channels coupled to glutamate release in cultured rat hippocampal neurons.
J Neurosci
15:4612-4617[Abstract].
-
Schulze KL,
Broadie K,
Perin MS,
Bellen HJ
(1995)
Genetic and electrophysiological studies of syntaxin 1A demonstrate its role in nonneuronal secretion and neurotransmission.
Cell
80:311-320[Web of Science][Medline].
-
Sollner T,
Whiteheart SW,
Brunner M,
Erdjument-Bromage H,
Geromanos S,
Tempst P,
Rothman JE
(1993)
SNAP receptors implicated in vesicle targeting and fusion.
Nature
362:318-324[Medline].
-
Song I,
Kamboj S,
Xia J,
Dong H,
Liao D,
Huganir RL
(1998)
Interaction of the N-ethylmaleimide-sensitive factor with AMPA receptors.
Neuron
21:393-400[Web of Science][Medline].
-
Südhof TC
(1995)
The synaptic vesicle cycle: a cascade of protein-protein interactions.
Nature
375:645-653[Medline].
-
Sun YA,
Poo MM
(1987)
Evoked release of acetylcoline from the growing embryonic neuron.
Proc Natl Acad Sci USA
84:2540-2544[Abstract/Free Full Text].
-
Sweeney ST,
Broadie K,
Keane J,
Niemann H,
O'Kane CJ
(1995)
Targeted expression of tetanus toxin light chain in Drosophila specifically eliminates synaptic transmission and causes behavioral defects.
Neuron
14:341-351[Web of Science][Medline].
-
Towbin H,
Staehelin T,
Gordon J
(1979)
Electrophoretic transfer of proteins from polyacrylamide gels to nitrocellulose sheets: procedures and some applications.
Proc Natl Acad Sci USA
76:4350-4354[Abstract/Free Full Text].
-
Verderio C,
Coco S,
Fumagalli G,
Matteoli M
(1995)
Calcium-dependent glutamate release during neuronal development and synaptogenesis: different involvement of
 -Aga-IVA and -Ctx-GVIA sensitive channels.
Proc Natl Acad Sci USA
92:6449-6453[Abstract/Free Full Text]. -
Verderio C, Coco S, Rossetto O, Montecucco C, Matteoli
M (1999a) Internalization and proteolytic action of Botulinum
toxins in CNS neurons and astrocytes. J Neurochem, in
press.
-
Verderio C, Coco S, Pravettoni E, Bacci A, Matteoli
M (1999b) Synaptogenesis in hippocampal cultures. Cell Mol
Life Sci, in press.
-
Walch-Solimena C,
Blasi J,
Edelmann L,
Chapman ER,
von Mollard GF,
Jahn R
(1995)
The t-SNARE syntaxin 1 and SNAP-25 are present on organelles that participate in synaptic vesicle recycling.
J Cell Biol
128:637-645[Abstract/Free Full Text].
-
Young SH,
Poo MM
(1983)
Spontaneous release of transmitter from growth cones of embryonic neurones.
Nature
368:140-144.
-
Zakharenko S,
Popov S
(1998)
Dynamics of axonal microtubules regulate the topology of new membrane insertion into the growing neurites.
J Cell Biol
143:1077-1086[Abstract/Free Full Text].
-
Zakharenko S,
Chang S,
O'Donoghue M,
Popov SV
(1999)
Neurotransmitter secretion along growing nerve processes: comparison with synaptic vesicle exocytosis.
J Cell Biol
114:507-518.
Copyright © 1999 Society for Neuroscience 0270-6474/99/19166723-10$05.00/0
This article has been cited by other articles:
|
|
|
|
 
K. Hata, L. Polo-Parada, and L. T. Landmesser
Selective Targeting of Different Neural Cell Adhesion Molecule Isoforms during Motoneuron Myotube Synapse Formation in Culture and the Switch from an Immature to Mature Form of Synaptic Vesicle Cycling
J. Neurosci.,
December 26, 2007;
27(52):
14481 - 14493.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. L. Sabo, R. A. Gomes, and A. K. McAllister
Formation of Presynaptic Terminals at Predefined Sites along Axons.
J. Neurosci.,
October 18, 2006;
26(42):
10813 - 10825.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
U. Schenk, E. Menna, T. Kim, M. Passafaro, S. Chang, P. De Camilli, and M. Matteoli
A Novel Pathway for Presynaptic Mitogen-Activated Kinase Activation via AMPA Receptors
J. Neurosci.,
February 16, 2005;
25(7):
1654 - 1663.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Rigoni, G. Schiavo, A. E. Weston, P. Caccin, F. Allegrini, M. Pennuto, F. Valtorta, C. Montecucco, and O. Rossetto
Snake presynaptic neurotoxins with phospholipase A2 activity induce punctate swellings of neurites and exocytosis of synaptic vesicles
J. Cell Sci.,
July 15, 2004;
117(16):
3561 - 3570.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Menegon, C. Verderio, C. Leoni, F. Benfenati, A. J. Czernik, P. Greengard, M. Matteoli, and F. Valtorta
Spatial and Temporal Regulation of Ca2+/Calmodulin-Dependent Protein Kinase II Activity in Developing Neurons
J. Neurosci.,
August 15, 2002;
22(16):
7016 - 7026.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. G. Mozhayeva, Y. Sara, X. Liu, and E. T. Kavalali
Development of Vesicle Pools during Maturation of Hippocampal Synapses
J. Neurosci.,
February 1, 2002;
22(3):
654 - 665.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Blumstein, V. Faundez, F. Nakatsu, T. Saito, H. Ohno, and R. B. Kelly
The Neuronal Form of Adaptor Protein-3 Is Required for Synaptic Vesicle Formation from Endosomes
J. Neurosci.,
October 15, 2001;
21(20):
8034 - 8042.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Bacci, S. Coco, E. Pravettoni, U. Schenk, S. Armano, C. Frassoni, C. Verderio, P. De Camilli, and M. Matteoli
Chronic Blockade of Glutamate Receptors Enhances Presynaptic Release and Downregulates the Interaction between Synaptophysin-Synaptobrevin-Vesicle-Associated Membrane Protein 2
J. Neurosci.,
September 1, 2001;
21(17):
6588 - 6596.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W. Zhang and D. L. Benson
Stages of Synapse Development Defined by Dependence on F-Actin
J. Neurosci.,
July 15, 2001;
21(14):
5169 - 5181.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
