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The Journal of Neuroscience, June 1, 2002, 22(11):4372-4380
Regulation of Neurotransmitter Release by Synapsin III
Jian
Feng1,
Ping
Chi1, 3,
Thomas A.
Blanpied4,
Yimei
Xu4,
Ana Maria
Magarinos2,
Adriana
Ferreira5,
Reisuke H.
Takahashi1,
Hung-Teh
Kao1, 6,
Bruce S.
McEwen2,
Timothy A.
Ryan3,
George J.
Augustine4, and
Paul
Greengard1
1 Laboratory of Molecular and Cellular Neuroscience and
2 Laboratory of Endocrinology, The Rockefeller University,
New York, New York 10021, 3 Department of Biochemistry, The
Weill Medical College of Cornell University, New York, New York 10021, 4 Department of Neurobiology, Duke University Medical
Center, Durham, North Carolina 27710, 5 Institute for
Neuroscience, Northwestern University, Chicago, Illinois 60611, and
6 Department of Psychiatry, New York University Medical
College, New York, New York 10016
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ABSTRACT |
Synapsin III is the most recently identified member of the synapsin
family, a group of synaptic vesicle proteins that play essential roles
in neurotransmitter release and neurite outgrowth. Here, through the
generation and analysis of synapsin III knock-out mice, we
demonstrate that synapsin III regulates neurotransmitter release in a
manner that is distinct from that of synapsin I or synapsin II. In mice
lacking synapsin III, the size of the recycling pool of synaptic
vesicles was increased, and synaptic depression was reduced. The number
of vesicles that fuse per action potential was similar between synapsin
III knock-out and wild-type mice, and there was no change in the
quantal content of EPSCs; however, IPSCs were greatly reduced in
synapsin III-deficient neurons. The density and distribution of
synaptic vesicles in presynaptic terminals did not appear to be
different in synapsin III knock-out mice in comparison to wild-type
littermates. In addition to the changes in neurotransmitter release, we
observed a specific delay in axon outgrowth in cultured hippocampal
neurons from synapsin III knock-out mice. Our data indicate that
synapsin III plays unique roles both in early axon outgrowth and in the
regulation of synaptic vesicle trafficking.
Key words:
synapsin III; knock-out; synaptic transmission; synaptic
vesicle trafficking; neurotransmitter release; neurite outgrowth
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INTRODUCTION |
Synapsins are a group of
neuron-specific phosphoproteins that are associated with synaptic
vesicles (Greengard et al., 1993 ). Three mammalian synapsin genes have
been identified and named synapsins I, II, and III. Transcripts of each
of these genes are differentially spliced to give rise to various
isoforms (Sudhof et al., 1989; Hosaka and Sudhof, 1998; Kao et al.,
1998; Porton et al., 1999). Previous studies have demonstrated that
synapsins play critical roles in anchoring synaptic vesicles to the
cytoskeletal network of presynaptic terminals (Hirokawa et al., 1989;
Bahler et al., 1990; Llinas et al., 1991; Benfenati et al., 1992;
Pieribone et al., 1995). Phosphorylation of synapsins by various
kinases changes the affinity between synapsins and actin filaments
(Bahler and Greengard, 1987) and may allow mobilization of vesicles at synapses (Huttner et al., 1981; Valtorta et al., 1992; Jovanovic et
al., 1996; Matsubara et al., 1996; Chi et al., 2001). Synaptic depression is particularly disrupted after either acute disruption of
synapsin function (Pieribone et al., 1995; Hilfiker et al., 1998) or ablation of synapsin genes (Li et al., 1995; Takei et al., 1995), consistent with the notion that synapsins are involved in
regulating the supply of vesicles available for release during periods
of high activity.
Given the existence of three different synapsin genes, it is important
to identify the unique roles that each plays. Mice lacking synapsin I,
synapsin II, or both gene products have greatly decreased numbers of
synaptic vesicles and exhibit significant changes in neurotransmitter
release and synaptic depression (Li et al., 1995; Rosahl et al., 1995;
Takei et al., 1995; Ryan et al., 1996). These changes indicate
important presynaptic functions for synapsins I and II. The function of
synapsin III, the latest member of the synapsin family to be
discovered, is less clear. Despite its similar domain structure and
sequence homology with synapsin I and synapsin II, synapsin III has
several unique properties suggesting that the function of this protein
is not redundant. The expression level of synapsin III, although
generally much lower in adults than that of synapsin I or II (Kao et
al., 1998), is developmentally regulated in a manner different from the
other synapsins, declining after the first week postnatally (Ferreira et al., 2000). There is evidence that synapsin III regulates the rate
of axonal growth and size of the growth cones of developing neurons
(Ferreira et al., 2000). The subcellular localization of synapsin III
is also unique: although synapsins I and II are localized almost
exclusively to presynaptic terminals, synapsin III is found in cell
bodies and growth cones as well as at presynaptic sites (Ferreira et
al., 2000). Finally, Ca2+ inhibits the
binding of ATP to synapsin III, whereas it activates the binding of ATP
to synapsin I, and does not affect the binding of ATP to synapsin II
(Hosaka and Sudhof, 1998).
The unique properties of synapsin III suggest that it plays a role
different from those of synapsin I and synapsin II. Here, through the
generation of synapsin III knock-out mice, we have analyzed in
vivo functions of synapsin III in neurotransmitter release and
neurite outgrowth. We find that synapsin III is involved in regulating
the size of the recycling vesicle pool, the strength of synaptic
depression, and very early axon outgrowth. These functions of synapsin
III differ from those of synapsins I and II, indicating unique roles
for each member of the synapsin gene family in neuronal function.
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MATERIALS AND METHODS |
Generation of synapsin III knock-out mice. Standard
gene-targeting procedures were used to generate synapsin III knock-out mice essentially as described before (Feng et al., 2000). Briefly, genomic DNA containing exon 1 of the mouse synapsin III gene was cloned
by screening a BAC genomic DNA library from Genome Systems, Inc. (St.
Louis, MO). A targeting vector was constructed by using a 6.0 kb
HindIII-XhoI fragment as left arm and a 4.7 kb
SstI-PstI fragment as right arm for homologous
recombination. The 2.0 kb XhoI-SstI fragment
containing exon 1 was replaced by a neomycin resistance gene in reverse
orientation. After homologous recombination in RW4 embryonic stem (ES)
cells (Genome Systems, Inc.), the targeted allele contained a 6.8 kb
EcoRI fragment, whereas the wild-type allele had an 8.1 kb
EcoRI fragment. Ten positive ES clones were obtained of the
480 clones picked (targeting ratio ~2%). Four of the positive clones
were injected into C57BL/6 blastocysts and produced germ-line
transmission of the targeted allele. Southern blots were performed on
EcoRI digests of tail DNA with
[32P]-dCTP-labeled external probe.
Heterozygotes were intercrossed to generate wild-type and synapsin III
knock-out mice used in the studies. Animal use and care were in strict
accordance with protocols approved by the Institutional Animal Care and
Use Committees at the investigators' universities.
Western blot. Mouse whole brain was homogenized in 1%
SDS solution and boiled for 5 min. Protein concentration was measured by the DC Protein Assay kit (Bio-Rad, Hercules, CA). An equal amount of
total proteins from each genotype was separated on SDS-polyacrylamide gel and transferred to nitrocellulose membranes (Invitrogen,
Gaithersburg, MD) for Western blot analyses. The following antibodies
were used: RU486 (against amino acids 544-558 of rat synapsin III
sequence) and RU482 (against amino acids 446-464 of rat synapsin III
sequence), G304 (pan-synapsin antibody) (Kao et al., 1998), and RU87
(anti-synaptotagmin), anti-syntaxin and anti-synaptophysin (Sigma, St.
Louis, MO).
Electron microscopy. Mice (n = 5 for each
genotype) were anesthetized with Metofane (Pitman-Moore, Mundelein, IL)
and transcardially perfused with saline followed by fixative containing
2% glutaraldehyde and 2% paraformaldehyde in 0.1 M phosphate buffer (PB), pH 7.4. After the brain
was incubated in the fixative solution overnight at 4°C, coronal
sections (100 µm thick) through the dorsal hippocampus were cut and
postfixed in 2% osmium tetroxide in PB and partially dehydrated.
Sections were stained with 2% uranyl acetate in 70% ethanol, further
dehydrated, incubated with propylene oxide, and flat embedded in
Durcupan (Fluka, Switzerland). The mossy fiber termination zone
(stratum lucidum) was trimmed, and ultrathin silver sections were cut,
mounted, and counterstained with Reynolds' lead citrate. The final
preparations were examined and photographed with a Jeol 100 CX electron
microscope. Photographs (10 per subject) were randomly taken from the
stratum lucidum area at a primary magnification of 5400×. Prints
(13,500×) were used to trace mossy fiber terminals (MFTs) as well as
mitochondria and spine profiles. An average of 60 MFTs per block per
experimental animal were analyzed. The total MFT area as well as the
areas occupied by mitochondria and spine profiles were measured with
the aid of a Zeiss Interactive Digitizing System. Synaptic vesicle
density was estimated using the intersection method, positioning an
unbiased counting frame with squares of known area (0.2 cm2) at the coordinates of a quadratic
lattice superimposed on the photomicrographs containing the MFTs. The
number of vesicles per MFT unit area was averaged from counts obtained
from five frames, and counts were adjusted to consider section
thickness and lost caps by using a variation of Floderus's equation
(Magarinos et al., 1997). Each variable was averaged across MFTs to
obtain a single mean value per animal, and two-tailed unpaired
Student's t test was applied to assess statistical significance.
Neuronal cultures. For studies using FM1-43, hippocampal
CA1-CA3 regions were dissected from wild-type or synapsin III
knock-out mice at postnatal day 1. Neurons were dissociated and plated
onto polyornithine-coated coverslips inside a 5-mm-diameter cloning cylinder (100 µl vol; Bellco Glass, Vineland, NJ). Cells were maintained in culture media consisting of MEM (Invitrogen), 0.6% glucose, 0.1 gm/l bovine transferrin (Calbiochem, La Jolla, CA), 0.25 gm/l insulin, 0.3 gm/l glutamine, 5-10% fetal calf serum (HyClone,
Logan, UT), 2% B-27 (Invitrogen), and 8 mM
cytosine  -D-arabinofuranoside (Sigma).
Cultures were maintained at 37°C in a 95% air/5%
CO2 humidified incubator for 14-15 d before use.
For axon development studies, neuronal cultures were prepared from the
hippocampi of embryonic day 16 mice as described previously (Goslin and
Banker, 1991; Ferreira et al., 2000). Briefly, embryos were removed,
and their hippocampi were dissected and freed of meninges. The cells
were dissociated by trypsinization (0.25% for 15 min at 37°C)
followed by trituration with a fire-polished Pasteur pipette and plated
onto poly-L-lysine-coated coverslips in MEM with 10% horse
serum. After 4 hr, the coverslips were transferred to dishes containing
an astroglial monolayer and maintained in MEM containing N2 supplements
plus ovalbumin (0.1%) and sodium pyruvate (0.1 mM).
For patch-clamp recordings, autapses (Bekkers and Stevens, 1991; Tong
and Jahr, 1994) were prepared by coating coverslips with 0.15% agarose
(Sigma), drying these for 1 hr, and then spraying them with a fine mist
of poly-D-lysine (0.5 mg/ml) and collagen (0.5 mg/ml).
Isolated hippocampi of 1- to 2-d-old mice were treated with papain, and
the dissociated cells were plated at 2000-5000 cm 2 in minimal essential media
(Invitrogen) supplemented with 5% FBS (Invitrogen), B-27 (Invitrogen),
and Mito+ serum extender (Collaborative
Biomedical) at their suggested concentrations, 3.6 gm/l glucose, 1%
Pen/Strep (Invitrogen), and 500 µM MEM sodium pyruvate
(Invitrogen). This medium was exchanged 24 hr after plating and again
after 6 d in culture, and cells were used for recordings after
7-9 d in culture.
Electrophysiology procedures. For patch-clamp recording,
cells were bathed in solution containing (in mM):
150 NaCl, 3 KCl, 2 CaCl2, 2 MgCl2, 20 glucose, 10 HEPES, and 50 µM DL-APV. To avoid bias
toward particular types of neurons, a recording was attempted from each
healthy neuron that was morphologically isolated from all other neurons
(to ensure recording responses from autapses rather than synapses
between neurons). Patch pipettes (3-4 M ) were filled with an
intracellular solution containing (in mM): 71 K-gluconate, 50 L-glutamate, 6 MgCl2, 5 Na2ATP, 0.3 Na2GTP, 2 EGTA, and 20 HEPES, with the pH
adjusted to 7.3 with KOH. An EPC-9 patch-clamp amplifier was used to
record synaptic currents, which were filtered at 1.5 kHz, digitized at
10 kHz, and analyzed off-line with custom software. Neurons were held
at a potential of  70 mV; series resistance ranged from 5 to 20 M,
and 80% of this resistance was compensated electronically.
Synaptic transmission was evoked at 15 sec intervals by delivering
voltage steps to +10 mV (0.1 msec duration) that initiated unclamped,
axonal action potentials. The resulting PSCs were measured between 0.5 and 2.5 min after the whole-cell configuration was established. PSCs
could be classified as excitatory or inhibitory on the basis of their
time courses of decay and their reversal potentials. One group of PSCs
had a mean decay time constant of 4.3 ± 0.2 msec, and the second
had a mean decay time constant of 25.3 ± 3.3 msec. The reversal
potentials ranged from approximately 65 mV to 50 mV for slow PSCs
and 10 mV to +15 mV for rapid PSCs. The GABA receptor blocker
bicuculline completely blocked the slow currents, whereas the AMPA
receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX)
completely blocked the fast currents. These findings indicate that the
fast responses are EPSCs and the slow ones are IPSCs, so we used PSC
decay times as a simple means to distinguish between glutamatergic and
GABAergic synapses. Miniature EPSCs (mEPSCs) were measured in the
absence of stimulation over a subsequent 60 sec period. mEPSCs were
detected semi-automatically and measured using the Mini Analysis
Program (Synaptosoft). Synaptic depression was analyzed in neurons that
had EPSC amplitudes >0.5 nA, the median amplitude in synapsin III
knock-out neurons. In these cells, trains of action potentials at 10 or
20 Hz were initiated after collection of spontaneous activity so as to
minimize the effects of activity on spontaneous release frequency.
Optical measurements and analysis. Coverslips were mounted
in a rapid-switching, laminar-flow perfusion and stimulation chamber on
the stage of a laser-scanning confocal microscope. The total volume of
the chamber was ~75 µl and was perfused at a rate of 1-1.5 ml/min.
Action potentials were evoked by passing 1 msec current pulses yielding
fields of ~10 V/cm through the chamber via platinum-iridium
electrodes. Except as noted otherwise, cells were superfused
continuously at room temperature in a saline solution consisting of (in
mM): 119 NaCl, 2.5 KCl, 2 CaCl2, 2 MgCl2, 25 HEPES,
pH 7.4, and 30 glucose plus 10 µM CNQX
(Research Biochemicals, Natick, MA) and 50 µM
D,L-2-amino-5-phosphonovaleric acid (AP-5; Research Biochemicals). FM1-43 (Molecular Probes, Eugene, OR) was used
at a concentration of 15 µM. Laser-scanning
fluorescence and differential interference contrast images were
acquired simultaneously at a spatial sampling of 125 nm per pixel and a
dwell time of 2 msec per pixel through a 40 × 1.3 numerical
aperture Zeiss Fluar objective (Oberkochen, Germany), using a
custom-built laser-scanning microscope. Quantitative measurements of
fluorescence intensity at individual synapses were obtained by
averaging a 4 × 4 area of pixel intensities centered on the
optical center of a given fluorescent punctum. Individual puncta were
selected by hand, and the optical center of mass used to center the
measurement box was computed over a slightly larger area (typically
8 × 8 pixels). Large puncta, typically representative of clusters
of smaller synapses, were rejected during the selection procedure as
were any puncta that were not clearly discernible in all test episodes.
At least 50 boutons from each genotype were imaged in each of these experiments.
Immunocytochemical procedures. Cultures were fixed for 20 min with 4% paraformaldehyde in PBS containing 0.12 M sucrose. They were then permeabilized in 0.3%
Triton X-100 in PBS for 4 min and rinsed twice in PBS. The cells were
preincubated in 10% BSA in PBS for 1 hr at 37°C and exposed to the
primary antibodies (diluted in 1% BSA in PBS) overnight at 4°C.
Finally, the cultures were rinsed in PBS and incubated with secondary
antibodies for 1 hr at 37°C. Anti- -tubulin (clone DM1A; Sigma),
rather than anti-tau, was used to stain the neurons, because tau is not
compartmentalized to axons at this early stage of culture (Dotti et
al., 1987; Ferreira et al., 1989). Pictures were taken using TMAX 400 ASA film (Kodak, Rochester, NY) on a Nikon microscope equipped
with a photographic camera. Films were scanned using a Polaroid Sprint
SCAN 35 scanner.
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RESULTS |
Generation of synapsin III knock-out mice
Previous reports have shown that deleting exon 1 of synapsin I or
synapsin II resulted in null mutations (Rosahl et al., 1993, 1995; Li
et al., 1995; Takei et al., 1995). We cloned the genomic DNA containing
exon 1 of the murine synapsin III gene and found that the exon-intron
boundary for synapsin III was identical to those for synapsins I and
II. This led us to use the same gene targeting strategy to generate the
synapsin III knock-out mice. A targeting vector was constructed to
replace exon 1 of synapsin III with a neomycin-resistance gene in
reverse orientation (Fig. 1A). After homologous
recombination in ES cells, the targeted allele should contain a 6.8 kb
EcoRI fragment, whereas the wild-type allele should have an
8.1 kb EcoRI fragment (Fig. 1A). From the 10 positive ES cell clones that were obtained, 4 were injected into
C57BL/6 blastocysts and produced germ-line transmission. Tail DNA from
F1 littermates of intercrosses between heterozygotes were digested with
EcoRI and blotted with an external probe or a probe for the
neomycin resistance gene. Disruption of the synapsin III gene in the
homozygote (/) was demonstrated by the presence of a single band of
the correct size (6.8 kb), which contained the neomycin resistance gene
(Fig. 1B). The absence of synapsin III protein in the
knock-outs was revealed by Western blots of total brain homogenates.
Two independent antibodies, RU486 (Fig. 1C) and RU482 (data
not shown), which were raised against different regions in the C
terminus of synapsin III, were used to measure synapsin III protein
levels. In heterozygous mice (+/), the expression level of synapsin
III was greatly reduced in comparison with wild-type mice, reminiscent
of the situation in synapsin I+/ or
synapsin II+/ mice (Rosahl et al., 1993,
1995; Li et al., 1995). No changes were observed in the level of
expression of other synaptic vesicle proteins, namely, synapsin I,
synapsin II, syntaxin, synaptotagmin, or synaptophysin (Fig.
1C).
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Figure 1.
Generation of synapsin III knock-out mice.
A, Synapsin III targeting vector consisted of a 6.0 and
a 4.7 kb homologous region flanking the neoR
gene to replace the 2.0 kb fragment containing exon 1 (top
line). Restriction map, location of exon 1, and the external
probe are shown in the middle line. Structure of the
synapsin III locus after homologous recombination is shown in the
bottom line. Restriction enzyme sites are as indicated:
H, HindIII; E,
EcoRI; P, PstI;
Xh, XhoI; Ss,
SstI. Sizes of the EcoRI fragments in the
wild-type and targeted alleles are shown. B, Southern
blot analysis of EcoRI-digested tail DNA from wild-type
(+/+), heterozygous (+/), and homozygous (/) littermates using
the external probe (left). The same blot was stripped
and reprobed with the neo probe (right).
C, Western blot analysis of expression levels of
synapsin III and a few other synaptic vesicle proteins in brain
homogenate from wild-type (+/+), heterozygous (+/), and homozygous
(/) littermates. KO, Knock-out; WT,
wild type.
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A Mendelian distribution of synapsin III knock-out mice among offspring
from heterozygote matings showed that no lethality resulted from
disruption of the synapsin III gene. There were also no gross changes
in the anatomy or behavior of synapsin III knock-out mice. In contrast
to synapsin I and synapsin II knock-out mice, seizures were not
observed in synapsin III knock-out mice of any age. Furthermore,
susceptibility to kainate- or pentylenetetrazole-induced seizures was
not different between the wild-type and synapsin III knock-out mice
(data not shown). All four independently derived lines of knock-out
mice exhibited virtually identical phenotypes.
Altered synaptic vesicle recycling in synapsin
III-deficient mice
Given the roles of synapsins I and II in regulation of
neurotransmitter release, we examined synaptic vesicle trafficking in
presynaptic terminals of synapsin III knock-out mice. Cultured hippocampal neurons were prepared from synapsin III knock-out mice or
wild-type controls. Seven paired experiments were performed with
cultures from wild-type and synapsin III knock-out littermates. A train
of 600 action potentials (APs) was delivered (10 Hz) to these neurons
in the presence of the amphipathic fluorescent probe FM1-43 (Betz et
al., 1992) to label recycling vesicles with the dye through endocytosis
(Ryan et al., 1996). Another train of 900 APs (10 Hz) was then applied
to the neuron to evoke the exocytotic release of neurotransmitters and
concurrent loss of FM1-43. The maximal magnitude of the loss of dye
fluorescence ( F), which reflects the size of the
recycling vesicle pool (Ryan et al., 1996), was increased by 42.3 ± 2.7% in synapsin III knock-out mice compared with that of wild-type
littermate controls (Fig. 2A). Thus, loss of
synapsin III increases the size of the recycling pool of synaptic
vesicles.
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Figure 2.
Synaptic vesicle recycling profiles in wild-type
and synapsin III-deficient terminals. A, Size of the
recycling pool of synaptic vesicles as measured by FM1-43 uptake in
response to action potential stimuli. B, Release
kinetics as measured by the time course for the depletion of FM1-43
staining. Time constants ( ) for wild-type and synapsin III-deficient
boutons are shown. C, Vesicle repriming rates for
wild-type and synapsin III-deficient terminals.
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To analyze vesicle pool release dynamics, synaptic vesicles were first
loaded by stimulation with 600 APs (20 Hz) in the presence of FM1-43,
and vesicle fusion was then measured in the absence of dye by
stimulating the neurons with an additional 900 APs (10 Hz). The average
time course for the loss of fluorescence at each bouton was well
described by an exponential function. The rate of dye release was
slower in synapsin III knock-out neurons than in controls (Fig.
2B). The time constant, , for the exponential loss
of FM1-43 was 14.7 sec in wild-type neurons but 19.3 sec for synapsin
III-deficient boutons.
The slower kinetics of dye loss might reflect a decrease in the
probability that an AP can trigger vesicle fusion in the synapsin III
knock-out neurons. However, given that the recycling vesicle pool is
larger in the knock-out neurons, the increase in may simply reflect
the presence of more vesicles to release over the course of the
stimulus. To examine this possibility, the average number of vesicles
fused per action potential was estimated from and the initial pool
size. Assuming that N vesicles reside in the recycling pool
of wild-type neurons, then synapsin III knock-out neurons have
1.42N vesicles. The measurements shown in
Figure 2B indicate that on average, 193 APs were
required to release 1.42N × (1-1/e) vesicles in synapsin III knock-out synapses
and 147 APs in the wild-type synapses to release N × (1-1/e) vesicles. These values suggest that each AP in the
stimulus train released on average 0.0046N
[1.42N × (1-1/e)/193] vesicles in
synapsin III/ terminals and
0.0043N [N × (1-1/e)/147]
vesicles in the wild-type terminals. Thus, roughly the same number of
vesicles fused per AP in wild-type and knock-out mice. These results
suggest that knock-out of synapsin III did not greatly alter the
probability that a synaptic vesicle will fuse after an AP.
It is also possible that synapsin III is involved in the repriming
steps that precede vesicle fusion. To measure vesicle repriming in
synapsin III knock-out neurons, we used a protocol described previously
(Ryan and Smith, 1995; Ryan et al., 1996). FM1-43 was loaded into
terminals via a train of APs (20 Hz), and this stimulus outlasted the 5 sec period of FM1-43 treatment by a variable length of time,
t. The change in fluorescence intensity at
t = 0 was designated
F0. At later times, dye
fluorescence
(F t) was
lost by the subsequent fusion of dye-filled vesicles. The time required
for these dye-filled vesicles to become fusion competent, or reprimed,
was determined for each t by calculating the fraction of
fluorescence depleted by the firing of APs, namely the
ratio (F0 Ft)/F0.
As shown in Figure 2C, very little repriming occurred during
the first 10 sec after removal of extracellular FM1-43. However, the
extent of dye loss increased steadily over the next 60 sec as labeled
vesicles were reprimed and became available for fusion. The time course
of repriming was very similar in wild-type and synapsin III knock-out
neurons. Furthermore, in each case, the extent of repriming reached a
plateau near 70%. This suggests that in presynaptic terminals of both wild-type and knock-out neurons, ~30% of endocytosed vesicles were
unavailable for recycling within 60 sec. These results indicate that
synapsin III is not involved in synaptic vesicle repriming.
In summary, FM1-43 measurements indicate that synapsin III limits the
size of the recycling pool but has little effect on the probability of
vesicle fusion or the rate at which synaptic vesicles are reprimed.
Altered neurotransmitter release in synapsin
III-deficient mice
To determine whether these changes in vesicle trafficking in
synapsin III knock-out mice lead to changes in neurotransmitter release, patch-clamp recordings were made from cultured hippocampal neurons. In these experiments, microisland cultures were used to induce
the formation of autaptic synaptic connections on individual neurons
(Bekkers and Stevens, 1991). Synaptic transmission could then be evoked
by briefly depolarizing a neuron while using the same patch pipette to
measure the resulting EPSCs. In this way, we recorded EPSCs from 71 wild-type neurons and 69 mutant neurons in four cultures prepared from
littermates. The amplitude of evoked EPSCs was not significantly
different between synapsin III-deficient neurons and wild-type neurons
(Fig.
3A,B).
The decay time constant of EPSCs and the total charge associated with
these currents were also the same in synapsin III-deficient and
wild-type control neurons. We examined how EPSC amplitude varied with
development and found no difference between wild-type and knock-out
neurons between days 7 and 9 in culture. Thus, the strength and
kinetics of excitatory synaptic transmission are preserved in the
absence of synapsin III. Some of the neurons in cultures were
interneurons, and we used the same procedures to record IPSCs from 15 wild-type neurons and 26 mutant neurons. In contrast to what was
observed at excitatory synapses, there was a significant reduction in
the amplitude of IPSCs in synapsin III-deficient neurons compared with
IPSCs of wild-type neurons (Fig. 3C,D). This
decrease was evident in neurons of various ages (data not shown). These
results indicate that synapsin III plays a more prominent role in
inhibitory synaptic transmission than in excitatory synaptic
transmission.
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Figure 3.
Evoked neurotransmitter release in wild-type and
synapsin III-deficient neurons. A, Representative EPSC
traces from wild-type (WT) and synapsin
III-deficient neurons (KO). B, EPSC
amplitude in neurons from wild-type (WT) or
synapsin III knock-out mice (KO) (n = 71 and 69, respectively). C, Representative IPSC
traces from wild-type and synapsin III-deficient neurons.
D, IPSC amplitude in neurons from wild-type or synapsin
III knock-out mice (n = 15 and 28, respectively).
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To measure the characteristics of individual quanta, we analyzed mEPSCs
resulting from spontaneous release. The amplitude of mEPSCs in synapsin
III/ neurons was slightly but
significantly larger than in wild-type neurons
(p < 0.05) (Fig.
4A,B).
The frequency of mEPSCs was slightly higher in mutant neurons, although
not significantly different from the wild-type controls (Fig.
4A,C). The quantal content of evoked transmission was calculated by dividing the amplitude of evoked
responses by that of the single quantal response (mEPSCs). For those
neurons in which both EPSCs and mEPSCs were measured, the quantal
content was not significantly different between wild-type and synapsin
III-deficient neurons (Fig. 4D). Thus, despite the fact that the absence of synapsin III increases the number of recycling
synaptic vesicles and increases the response to release of individual
vesicles, glutamatergic synaptic transmission remains grossly unaltered
in synapsin III knock-out neurons stimulated at low frequencies.
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Figure 4.
Spontaneous neurotransmitter release in wild-type
and synapsin III-deficient neurons. A, Representative
mEPSC traces from wild-type (WT) and synapsin
III-deficient neurons (KO). B, mEPSC
amplitude in neurons from wild-type or synapsin III knock-out mice.
C, mEPSC frequency in neurons from wild-type or synapsin
III knock-out mice. D, Quantal content of EPSCs in
neurons from wild-type (n = 29) or synapsin III
knock-out (n = 32) mice.
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To study whether short-term synaptic plasticity was affected by the
deletion of synapsin III, we measured synaptic facilitation and
depression. Facilitation was examined by firing pairs of APs separated
by an interval of 20 msec. As shown in Figure
5A, there was no significant
difference in synaptic facilitation between wild-type and synapsin
III-deficient neurons. This is consistent with other observations that
synapsins are involved in facilitation to only a limited extent (Rosahl
et al., 1995) or not at all (Hilfiker et al., 1998). When
neurons were stimulated with prolonged trains of APs (20 Hz), synaptic
depression caused the amplitudes of evoked EPSCs to gradually decline
as the supply of releasable vesicles was depleted. After 5 sec of
stimulation, transmission at wild-type synapses was depressed by
81 ± 2%, whereas depression was significantly less, only 62 ± 10%, in synapsin III/ neurons
(p < 0.05). Given that EPSCs evoked by
low-frequency stimulation were essentially unaffected by deletion of
synapsin III (Fig. 3), this decrease in depression indicates that
synapsin III normally makes excitatory synapses more sensitive to
periods of high activity. The rate of refilling of the readily
releasable pool is ~3 sec at active hippocampal terminals (Stevens
and Wesseling, 1999), whereas the time constants for depression
range from 0.8 ± 0.06 sec for wild-type neurons to 1.52 ± 0.08 sec in the synapsin III knock-out neurons. The similarity of the
time constants for depression and refilling suggests that the increased
recycling vesicle pool observed in FM1-43 studies could contribute to
the slowing of depression in the knock-out neurons. A larger pool of
vesicles would be depleted more slowly during a train of APs if
vesicles fused with approximately the same probability, as was
indicated by the lack of change in quantal content of EPSCs evoked at
low frequency.
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Figure 5.
Paired-pulse facilitation and synaptic depression
at wild-type and synapsin III-deficient synapses. A,
Paired-pulse facilitation was measured with the second pulse applied 20 msec after the first one. B, Synaptic depression was
evoked by stimulating the neurons with a 20 Hz train. EPSCs were
normalized to the initial response to measure the extent of synaptic
depression.
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Ultrastructure of synapsin III-deficient hippocampal synapses
We used electron microscopy to study the structure of synapsin
III-deficient synapses. Because synapsin III is very highly expressed
in MFTs (H. T. Kao, J. Feng, P. Greengard, and V. A. Pieribone, unpublished observations), we examined the stratum lucidum
of the CA3 region of hippocampi from wild-type and synapsin III
knock-out littermates. As shown in Figure
6 and Table
1, there was no significant difference
between experimental groups in the net area occupied by MFT profiles or
in the area occupied by mitochondria and spine profiles. Compared with
wild-type mice, there was a significant, although small, increase in
the number of spine profiles embedded within MFTs of synapsin III
knock-outs. The density of synaptic vesicles within MFTs of wild-type
neurons was very similar to that measured in synapsin III
knock-outs.
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Figure 6.
Effect of synapsin III deletion on the
ultrastructure of MFTs in the stratum lucidum of the dorsal
hippocampal CA3 region. A, Representative MFT
(mf) of a wild-type mouse perforated with two
giant spines (Sp) of CA3 proximal apical dendrites. The
terminal was densely packed with synaptic vesicles and some
electron-dense mitochondrial profiles. B, Representative
MFTs of a synapsin III knock-out mouse perforated with three giant
spines (Sp). mf, Mossy fiber terminal;
Sp, spine. Scale bar, 1 µm.
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View this table:
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|
Table 1.
Quantification of ultrastructural variables in mossy fiber
terminals from wild-type and synapsin III knock-out mice
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Because mossy fiber synapses contain multiple giant spines and multiple
active zones, it is difficult to accurately quantify the spatial
distribution of synaptic vesicles within these terminals. We therefore
measured the distribution of synaptic vesicles in CA1 presynaptic
terminals in the stratum radiatum layer
of the hippocampus. As shown in Figure 7 and Table
2, there was no significant difference in
the spatial distribution of vesicles within these terminals. Thus,
although our functional measurements indicate that loss of synapsin III
affects the number of vesicles in the recycling pool, this difference
is apparently not reflected in the number or spatial distribution of
synaptic vesicles within presynaptic terminals.
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Figure 7.
Effect of synapsin III deletion on the
ultrastructure of presynaptic terminals within the stratum radiatum of
the hippocampal CA1 region. A, Tracing of a
representative axon terminal and adjacent postsynaptic spine forming an
excitatory synapse. The drawing illustrates the postsynaptic
density (1) and the areas where the number of
vesicles was estimated: within 50 µm of the presynaptic membrane
associated with the active zone (2) and between
50 and 200 µm of the presynaptic membrane (3).
Docked vesicles were those physically attached to the presynaptic
membrane. B, Representative excitatory synapse of a
wild-type mouse. C, Representative excitatory synapse of
a synapsin III knock-out mouse. Ax, Axon terminal;
Sp, spine. Scale bar, 0.1 µm.
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Role of synapsin III in axon outgrowth
Previous studies showed that depletion of synapsin III, by
treating cultured hippocampal neurons with antisense RNA, impaired axon
extension and enlarged growth cones (Ferreira et al., 2000). To further
consider the role of synapsin III in these processes, we examined
neurite outgrowth in hippocampal neurons cultured from wild-type and
synapsin III knock-out mice. These neurons can be classified
developmentally on the basis of their morphology (Goslin
and Banker, 1991). Neurons at stage 1 have only lamellipodia extending
from the cell bodies, without any processes. At stage 2, minor
processes extend out from the cell bodies. Within 24 hr, one of these
processes has elongated further and become an axon (stage 3). Dendritic
outgrowth occurs afterward for a few days (stage 4), and by ~7 d
after plating, neurons achieve a mature morphology and have synaptic
contacts (stage 5).
To examine neurite outgrowth, embryonic day 16 hippocampal neurons were
dissociated from wild-type or synapsin III knock-out mice, and 24 hr
later anti--tubulin antibody was used to visualize their neurites.
The identification of a given process as an axon at these early stages
of development is made by morphological criteria as described
previously (Dotti and Banker, 1987; Dotti et al., 1988). In addition,
it has been shown that minor processes only start to elongate and
differentiate as dendrites 4 d after plating (Dotti et al., 1988).
As shown in Figure 8, axon outgrowth was
much delayed in synapsin III-deficient neurons. Most wild-type neurons
were at stage 3, and only a small fraction remained at stage 1 or 2. In
contrast, a smaller fraction of synapsin
III/ neurons were at stage 3, and
large numbers of neurons were at earlier stages of development (Fig.
8C). Synapsin III-deficient neurons had delayed axon
extension, as well as enlarged growth cones and many lamellipodia, a
pattern that is very similar to the appearance of wild-type neurons
treated with synapsin III antisense RNA (Ferreira et al., 2000).
However, when synapsin III-deficient neurons were cultured for 2 d, there were no significant differences in their developmental profile
in comparison with wild-type neurons (data not shown). These results
indicate that synapsin III plays a very specific role in the early
development of axons, being required during the first 24 hr of axon
extension. The physiological impact of this effect on early axon
development in vivo awaits further analyses.
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Figure 8.
Delayed axon outgrowth in synapsin III-deficient
neurons. A, Wild-type neurons were cultured for 24 hr
and stained with anti--tubulin. B, Synapsin
III/ neurons were cultured for 24 hr and stained
with anti--tubulin. mp, Minor process;
ax, axon. C, Distribution of wild-type
and synapsin III/ neurons at different stages of
development.
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| |
DISCUSSION |
In this paper, we provide evidence indicating unique roles for
synapsin III in the regulation of neurotransmitter release and in the
initial outgrowth of axons. Through the generation and analysis of
synapsin III knock-out mice, we found that synapsin III, the most
recently identified member of the synapsin family, functions in
vivo to limit the size of the recycling pool of synaptic vesicles
and to accentuate synaptic depression during periods of rapid activity.
At excitatory synapses, loss of synapsin III did not affect the average
number of vesicles fused per action potential or synaptic transmission
evoked by low frequencies of repetitive stimulation. However,
transmission was substantially weaker at inhibitory GABAergic synapses
in the absence of synapsin III. In addition to these roles in
regulation of neurotransmitter release, synapsin III also appears to
play a distinct and nonredundant function in the initial stage of axon outgrowth.
One of the most intriguing functions of synapsin III is its ability to
limit the number of vesicles that undergo exocytotic-endocytotic recycling during sustained synaptic activity. By measuring the loss of
FM1-43 fluorescence, we can operationally define the size of the
recycling pool of synaptic vesicles. The increase of this pool in
synapsin III-deficient terminals suggests that synapsin III plays a key
role in keeping vesicles out of the recycling pool. Synapsin III, like
other synapsins, interacts with phospholipids on synaptic vesicles
(Hosaka et al., 1999). In this manner, synapsin III, along with
synapsins I and II, may serve to tether vesicles to the cytoskeleton
and keep them from recycling during synaptic activity (Benfenati et
al., 1989, 1993; Hosaka et al., 1999). Removal of synapsin III by gene
targeting therefore may have allowed more vesicles to be recruited to
participate in synaptic transmission.
The significant increase in the number of recycling vesicles in
synapsin III-deficient neurons is in sharp contrast to what was seen in
synapsin I knock-out mice (Ryan et al., 1996) or synapsin II knock-out
mice (P. Chi, P. Greengard, and T. A. Ryan, unpublished observation), where the size of the recycling pool was significantly reduced. This dramatic difference may be explained by the apparent roles of synapsin I and II in the formation and stability of synaptic vesicles. Both synapsin I and synapsin II are normally expressed at
very high levels on vesicles, but in the absence of either protein, the
number of vesicles is reduced significantly (Li et al., 1995; Rosahl et
al., 1995; Takei et al., 1995), and this reduction is most pronounced
in synapsin I/II double knock-out mice (Rosahl et al., 1995). In
contrast, the number of vesicles in synapsin III knock-out mice was
quite similar to that in wild-type mice. Together, these results
suggest that unlike synapsins I and II, the primary function of
synapsin III is to anchor synaptic vesicles so that their recycling can
be regulated, presumably through phosphorylation (Hosaka et al., 1999).
Because the hippocampal culture that we used contained a mixed
population of GABAergic (~25%) and glutamatergic (~75%) neurons
(P. Chi and T. A. Ryan, unpublished observations), our results on
vesicle trafficking were the average of effects of inhibitory and
excitatory terminals. Future studies, using autaptic cultures for
example, would allow us to examine the potentially different effects in
vesicle recycling between GABAergic and glutamatergic boutons in
synapsin III knock-out mice.
A larger recycling vesicle pool in synapsin III-deficient terminals
might have been expected to increase the strength of synaptic transmission. However, we found that the quantal content of
glutamatergic EPSCs was unchanged during low-frequency synaptic
activation. This implies that either the number and release probability
of the recycling vesicles ready for fusion remain unchanged or, if more
recycling vesicles are available for immediate release, the probability
of release per vesicle decreases. In fact, we found that the frequency
of spontaneous release from synapsin III-deficient terminals did not
change and that the number of vesicles fused per action potential,
calculated both from FM1-43 destaining rates and from EPSC quantal
content, did not change. Thus, knock-out of synapsin III does not alter
basal transmission at excitatory synapses, and its primary functional
phenotype is altered synaptic plasticity during periods of high
synaptic activity, which is similar to what has been reported after
knock-out of synapsins I or II (Li et al., 1995; Rosahl et al., 1995;
Takei et al., 1995).
In contrast, the amplitudes of IPSCs at GABAergic synapses were
strongly reduced in synapsin III knock-out mice. This suggests that the
function of synapsin III in inhibitory terminals may be different from
that at excitatory synapses. Alternatively, GABAergic
neurotransmission, which typically involves much higher action
potential frequencies than at glutamatergic synapses, may naturally
rely on a different distribution of vesicles between reserve and
recycling pools that is greatly sensitive to the loss of synapsin III.
Inhibitory synaptic transmission is also impaired in mice lacking
synapsin I, a defect that presumably contributes to increased seizure
propensity in those mice (Terada et al., 1999). However, we did not
observe any spontaneous seizures in synapsin III knock-out mice,
despite the substantial impairment of inhibitory synaptic transmission.
In addition, seizure susceptibility to kainate or the GABAergic
antagonist pentylenetetrazole was similar in synapsin III knock-out
mice and sex-matched wild-type littermates. Thus, there is not a tight
coupling between the magnitude of hippocampal synaptic inhibition and
seizure propensity.
Our studies revealed a specific requirement for synapsin III at an
initial stage of axon outgrowth. Synapsin III has a unique developmental expression pattern, being expressed at its highest levels
during the first few days in culture and diminishing precipitously afterward. In addition, synapsin III is highly localized in growth cones and appears at extrasynaptic sites, quite unlike the distinct, synaptic localization of synapsins I and II (Ferreira et al., 2000).
The recovery of axon morphology in later stages of development indicates that other synapsins may eventually compensate for the absence of synapsin III. The short span of time during which synapsin III deficiency is reflected in altered morphology is a remarkable demonstration of the temporal regulation of gene expression and function. Together, these results strongly suggest that synapsin III
plays a critical and nonredundant role in early axon development, well
before the first synapses are established.
Through the generation and analyses of synapsin III knock-out mice, we
have provided strong evidence for unique functions of synapsin III in
both early axon development and the regulation of neurotransmitter
release in mature synapses. These results should help to elucidate the
complex and interdependent roles of synapsins in the nervous system.
| |
FOOTNOTES |
Received Oct. 4, 2001; revised March 13, 2002; accepted March 18, 2002.
This work was supported by National Institutes of Health Grants MH39327
and AG15072 (P.G.), NS17771 (G.J.A.), and NS24692 and GM61925 (T.A.R.),
a Theodore and Vada Stanley Foundation Research Award (P.G., J.F.), a
McKnight Foundation Award (G.J.A.), and a National Alliance for
Research on Schizophrenia and Depression Young Investigator Award
(A.F.). We thank Cassandra M. Kirk for excellent technical assistance,
and The Rockefeller University Transgenic Animal Service for blastocyst injections.
Correspondence should be addressed to Dr. Jian Feng, Department of
Physiology and Biophysics, State University of New York at Buffalo, 124 Sherman Hall, Buffalo, NY 14214. E-mail:
jianfeng{at}buffalo.edu.
| |
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P. Baldelli, A. Fassio, F. Valtorta, and F. Benfenati
Lack of Synapsin I Reduces the Readily Releasable Pool of Synaptic Vesicles at Central Inhibitory Synapses
J. Neurosci.,
December 5, 2007;
27(49):
13520 - 13531.
[Abstract]
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D. Fioravante, R.-Y. Liu, A. K. Netek, L. J. Cleary, and J. H. Byrne
Synapsin Regulates Basal Synaptic Strength, Synaptic Depression, and Serotonin-Induced Facilitation of Sensorimotor Synapses in Aplysia
J Neurophysiol,
December 1, 2007;
98(6):
3568 - 3580.
[Abstract]
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K. L. Moulder, X. Jiang, A. A. Taylor, W. Shin, K. D. Gillis, and S. Mennerick
Vesicle Pool Heterogeneity at Hippocampal Glutamate and GABA Synapses
J. Neurosci.,
September 12, 2007;
27(37):
9846 - 9854.
[Abstract]
[Full Text]
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M. Fischer, A. Oberthuer, B. Brors, Y. Kahlert, M. Skowron, H. Voth, P. Warnat, K. Ernestus, B. Hero, and F. Berthold
Differential Expression of Neuronal Genes Defines Subtypes of Disseminated Neuroblastoma with Favorable and Unfavorable Outcome
Clin. Cancer Res.,
September 1, 2006;
12(17):
5118 - 5128.
[Abstract]
[Full Text]
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A. Kielland, A. Erisir, S. I. Walaas, and P. Heggelund
Synapsin Utilization Differs among Functional Classes of Synapses on Thalamocortical Cells
J. Neurosci.,
May 24, 2006;
26(21):
5786 - 5793.
[Abstract]
[Full Text]
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H.-C. Lu, D. A. Butts, P. S. Kaeser, W.-C. She, R. Janz, and M. C. Crair
Role of efficient neurotransmitter release in barrel map development.
J. Neurosci.,
March 8, 2006;
26(10):
2692 - 2703.
[Abstract]
[Full Text]
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J. Sun, P. Bronk, X. Liu, W. Han, and T. C. Sudhof
Synapsins regulate use-dependent synaptic plasticity in the calyx of Held by a Ca2+/calmodulin-dependent pathway
PNAS,
February 21, 2006;
103(8):
2880 - 2885.
[Abstract]
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D. Bonanomi, A. Menegon, A. Miccio, G. Ferrari, A. Corradi, H.-T. Kao, F. Benfenati, and F. Valtorta
Phosphorylation of Synapsin I by cAMP-Dependent Protein Kinase Controls Synaptic Vesicle Dynamics in Developing Neurons
J. Neurosci.,
August 10, 2005;
25(32):
7299 - 7308.
[Abstract]
[Full Text]
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S. Hilfiker, F. Benfenati, F. Doussau, A. C. Nairn, A. J. Czernik, G. J. Augustine, and P. Greengard
Structural Domains Involved in the Regulation of Transmitter Release by Synapsins
J. Neurosci.,
March 9, 2005;
25(10):
2658 - 2669.
[Abstract]
[Full Text]
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D. Gitler, Y. Takagishi, J. Feng, Y. Ren, R. M. Rodriguiz, W. C. Wetsel, P. Greengard, and G. J. Augustine
Different Presynaptic Roles of Synapsins at Excitatory and Inhibitory Synapses
J. Neurosci.,
December 15, 2004;
24(50):
11368 - 11380.
[Abstract]
[Full Text]
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D. Samigullin, C. A Bill, W. L Coleman, and M. Bykhovskaia
Regulation of transmitter release by synapsin II in mouse motor terminals
J. Physiol.,
November 15, 2004;
561(1):
149 - 158.
[Abstract]
[Full Text]
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T.-i. Nishiki and G. J. Augustine
Dual Roles of the C2B Domain of Synaptotagmin I in Synchronizing Ca2+-Dependent Neurotransmitter Release
J. Neurosci.,
September 29, 2004;
24(39):
8542 - 8550.
[Abstract]
[Full Text]
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T.-i. Nishiki and G. J. Augustine
Synaptotagmin I Synchronizes Transmitter Release in Mouse Hippocampal Neurons
J. Neurosci.,
July 7, 2004;
24(27):
6127 - 6132.
[Abstract]
[Full Text]
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D. Gitler, Y. Xu, H.-T. Kao, D. Lin, S. Lim, J. Feng, P. Greengard, and G. J. Augustine
Molecular Determinants of Synapsin Targeting to Presynaptic Terminals
J. Neurosci.,
April 7, 2004;
24(14):
3711 - 3720.
[Abstract]
[Full Text]
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C. A. Brautigam, Y. Chelliah, and J. Deisenhofer
Tetramerization and ATP Binding by a Protein Comprising the A, B, and C Domains of Rat Synapsin I
J. Biol. Chem.,
March 19, 2004;
279(12):
11948 - 11956.
[Abstract]
[Full Text]
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D. H. Brager, P. W. Luther, F. Erdelyi, G. Szabo, and B. E. Alger
Regulation of Exocytosis from Single Visualized GABAergic Boutons in Hippocampal Slices
J. Neurosci.,
November 19, 2003;
23(33):
10475 - 10486.
[Abstract]
[Full Text]
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M. A. Cousin, C. S. Malladi, T. C. Tan, C. R. Raymond, K. J. Smillie, and P. J. Robinson
Synapsin I-associated Phosphatidylinositol 3-Kinase Mediates Synaptic Vesicle Delivery to the Readily Releasable Pool
J. Biol. Chem.,
August 1, 2003;
278(31):
29065 - 29071.
[Abstract]
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TOP
ABSTRACT
INTRODUCTION
