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The Journal of Neuroscience, May 1, 2002, 22(9):3342-3351
Regulation of Exocytosis through Ca2+/ATP-Dependent
Binding of Autophosphorylated Ca2+/Calmodulin-Activated
Protein Kinase II to Syntaxin 1A
Akihiro
Ohyama1, 2,
Kohei
Hosaka3,
Yoshiaki
Komiya1,
Kimio
Akagawa4,
Emiko
Yamauchi5, 6,
Hisaaki
Taniguchi5, 6,
Nobuyuki
Sasagawa7,
Konosuke
Kumakura7,
Sumiko
Mochida8,
Takashi
Yamauchi9, and
Michihiro
Igarashi10
Departments of 1 Molecular and Cellular Neurobiology
and 2 Anesthesiology and Reanimatology, Gunma University
School of Medicine, and 3 Department of Basic Allied
Medicine, Gunma University School of Health Sciences, Maebashi, Gunma
371-8511, Japan, 4 Department of Physiology, Kyorin
University School of Medicine, Mitaka, Tokyo 181-8611, Japan,
5 Division of Biomedical Polymer Sciences, Institute for
Comprehensive Medical Science, Fujita Health University,
Toyoake, Aichi 470-1192, Japan, 6 Membrane Dynamics
Project, Institute of Physical and Chemical Research (RIKEN) Harima
Institute at Spring-8, Sayo, Hyogo 679-5148, Japan, 7 Life
Science Institute, Sophia University, Chiyoda-ku, Tokyo 102-8554, Japan, 8 Department of Physiology, Tokyo Medical College,
Shinjuku-ku, Tokyo 160-8402, Japan, 9 Department of
Biochemistry, Faculty of Pharmaceutical Sciences, The University of
Tokushima, Tokushima 770-8505, Japan, and 10 Division of
Molecular and Cellular Biology, Department of Signal Transduction
Research, Niigata University, Graduate School of Medical and Dental
Sciences, Niigata, Niigata 951-8510, Japan
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ABSTRACT |
Syntaxin 1A/HPC-1 is a key component of the exocytotic molecular
machinery, namely, the soluble
N-ethylmaleimide-sensitive factor attachment protein
(SNAP) receptor mechanism. Although >10 syntaxin-binding
proteins have been identified, they cannot completely explain the
regulation of exocytosis. Thus, novel proteins may interact with
syntaxin. Because exocytosis requires both Ca2+ and
ATP, we searched for Ca2+/ATP-dependent
syntaxin-binding proteins from the rat brain and discovered
Ca2+/calmodulin-activated protein kinase II
(CaMKII)- . At Ca2+ concentrations of
>10 6 M, only autophosphorylated
CaMKII bound to syntaxin. Bound CaMKII was released from syntaxin by
EGTA or by phosphatase, indicating that the binding is reversible.
CaMKII bound to the linker domain of syntaxin, unlike any other known
syntaxin-binding proteins. CaMKII-syntaxin complexes were also
detected in synaptosomes by immunoprecipitation, and when reconstituted
in vitro, they recruited larger amounts of synaptotagmin
and SNAP-25 than syntaxin alone. The microinjected CaMKII-binding
domain of syntaxin specifically affected exocytosis in chromaffin cells
and in neurons. These results indicate that the
Ca2+/ATP-dependent binding of CaMKII to syntaxin is
an important process in the regulation of exocytosis.
Key words:
syntaxin 1A/HPC-1; CaMKII; SNARE mechanism; exocytosis; linker domain; Munc-18
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INTRODUCTION |
Studies of yeast and mammals have
identified the protein components involved in the molecular machinery
controlling exocytosis and have clarified this process (Jahn and
Südhof, 1999 ; Brunger, 2000; Misura et al., 2000a). The soluble
N-ethylmaleimide-sensitive factor attachment protein
(SNAP) receptor (SNARE) mechanism has become the standard explanation
of the molecular processes of exocytosis (Jahn and Südhof, 1999;
Brunger, 2000). Among the identified protein components, syntaxin
homologs are some of the most important molecules in vesicular
trafficking (Bennett et al., 1993). Several lines of biochemical and
electrophysiological evidence indicate that syntaxin 1A/HPC-1 is a key
component of the SNARE mechanism (Inoue et al., 1992; Marsal et al.,
1997; O'Connor et al., 1997). Although syntaxin and another synaptic protein interact (Jahn and Südhof, 1999), the SNARE-dependent regulation of exocytosis is not yet completely understood. In particular, most of the known interactions between syntaxin and other
proteins are independent of Ca2+ or ATP,
both of which are essential to exocytosis, and the manner in which
Ca2+/ATP regulates the protein association
and dissociation involving syntaxin during exocytosis remains unclear.
We believe that the missing link in the molecular explanation of
exocytosis is an unknown protein-protein interaction involving
syntaxin that is regulated by Ca2+/ATP and
is essential to the molecular regulation of exocytosis.
We searched for such a protein in the rat brain using a
glutathione S-transferase (GST)-syntaxin pull-down study and
screened brain syntaxin-binding proteins in the presence of
Ca2+/ATP. We found a 50 kDa protein that
specifically binds to syntaxin in a
Ca2+/ATP-dependent manner, which we called
Ca2+/calmodulin-activated protein kinase II
(CaMKII)-. At Ca2+ concentrations of
>106 M, only the
autophosphorylated form of CaMKII bound to syntaxin. We then
demonstrated that the binding site for CaMKII resides in the linker
domain of syntaxin, where no other known syntaxin-binding proteins
bind. Immunoprecipitation showed that the CaMKII-syntaxin complex
formed in the presynaptic terminal recruited larger amounts of
synaptotagmin and SNAP-25 than syntaxin alone. Finally, we showed that
the microinjected CaMKII-binding domain of syntaxin specifically
decreased the frequency of exocytosis in chromaffin cells and in
neurons, probably because of its interference with the
endogenous CaMKII-syntaxin complex. These results indicate that the
binding of CaMKII to syntaxin is an important step in the regulation of exocytosis.
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MATERIALS AND METHODS |
Recombinant proteins. The cDNA fragments
corresponding to the various regions of syntaxin 1A and those encoding
syntaxin-binding proteins were amplified by PCR and inserted
into pGEX-6P-1 (Amersham-Pharmacia Biotech, Uppsala, Sweden)
in frame with GST. Site-directed mutagenesis proceeded as described by
Imai et al. (1991). The cDNAs encoding synaptotagmin,
vesicle-associated membrane protein (VAMP), SNAP-25, and the glutamate
receptor NR2A (Ikeda et al., 1992) were provided by Drs. T. Abe and K. Sakimura (Brain Research Institute, Niigata University, Niigata,
Japan). In vitro translation was performed using the
TNT SP6-coupled reticulocyte lysate system (Promega, Madison,
WI), and the translated protein was labeled using biotinylated tRNA (Promega). The cDNA encoding rat CaMKII or T286A-CaMKII (provided by Dr. H. Schulman, Stanford University, Stanford, CA) was
added to the above system, and the proteins were expressed after a 1.5 hr incubation at 30°C. The binding of the labeled proteins was
detected as described previously (Ohyama et al., 2001).
Protein-binding studies. The rat brain
S2 fraction was prepared as described previously
(Fujita et al., 1998). GST alone or GST-fusion proteins produced by
Escherichia coli bound to glutathione Sepharose were
incubated with the S2 fraction from the adult rat brain at 4°C for 1 hr with or without 1 mM
CaCl2 and/or 0.5 mM ATP,
and then digested with PreScission protease (Amersham-Pharmacia Biotech). After cleavage, the supernatant was incubated with
glutathione Sepharose to remove the protease. Purified CaMKII from
the rat brain was also autophosphorylated (see below) and incubated
with GST-syntaxin as described above. Recombinant CaMKII and
CaMKII , obtained using the baculovirus-Sf21 cell system (Kolb et
al., 1998), were provided by Dr. Neal Waxham (University of Texas, Houston, TX). CaMKII lacking the association domain [1-325]
(i.e., monomeric CaMKII) was purchased from Calbiochem (La Jolla, CA). Anti-CaMKII polyclonal antibody (pAb) was a generous gift from Prof. E. Miyamoto (Kumamoto University School of Medicine, Kumamoto, Japan).
Anti-syntaxin 1A monoclonal antibody (mAb) was provided by Dr. M. Takahashi (Mitsubishi Institute of Life Science, Machida, Tokyo, Japan).
Determination of the partial primary structure of the 50 kDa
syntaxin-binding protein. The 50 kDa syntaxin-binding protein was
excised and digested by trypsin, and its partial structure was then
analyzed by mass spectrometry using the nanospray method. Sequence tags
from the two fragment ions confirmed that this protein was rat
CaMKII (FTEEYQLFEELGK [9-21] and ITQYLDAGGIPR [434-445]).
Autophosphorylation and dephosphorylation of CaMKII. After
dephosphorylation by protein phosphatase 1 (PP1; Calbiochem) at 30°C
for 30 min, the purified CaMKII was re-autophosphorylated again for
5 min (Katoh and Fujisawa, 1991) and incubated with GST-syntaxin. In
some experiments, the autophosphorylated CaMKII was bound to
immobilized GST-syntaxin and then incubated with the EGTA treatment
buffer (CaCl2 in the binding buffer was replaced with 10 mM EGTA) or with PP1 for 30 min.
The remaining bound CaMKII was visualized by immunoblotting.
Activity of CaMKII in the presence of syntaxin. We examined
whether or not the autophosphorylation of CaMKII is altered by syntaxin
binding. Autophosphorylation proceeded in the absence or presence of
the CaMKII-binding fragment of syntaxin ([145-184]; 20 µM) as described by Katoh and Fujisawa (1991).
Ca2+/CaM-dependent synaptosomal protein
was phosphorylated by the method of Popoli et al. (1995). Syntaxin and
synaptotagmin I were phosphorylated by CaMKII in vitro by
the method of Hilfiker et al. (1999). The
32P-labeled proteins were resolved by
electrophoresis and quantified using a BAS 2000 system (Fuji Film Co.,
Tokyo, Japan).
Affinity between syntaxin and CaMKII. The binding of
syntaxin 1A [1-262], [145-184], and [1-262; R151G] to
recombinant CaMKII or CaMKII was monitored using a BIAcore system
(BIAcore Ltd., Uppsala, Sweden) by the method of Suetsugu et al.
(2001). The BIAcore system was operated at 25°C and at a constant
flow of 5 ml/min of running buffer containing 10 mM HEPES-NaOH, pH 7.5, 150 mM NaCl, 3 mM EDTA, and
0.005% Tween 20. CaMKII was fixed on the CM5 sensor chip, and
recombinant syntaxin fragments were then individually diluted to ~4
mg/ml running buffer and injected over the chip. The efficiency of
immobilization was confirmed by an increase in resonance units to
~1000. After washing with high-salt buffer (running buffer plus 1 M MgCl2), the binding of
recombinant syntaxin at various concentrations loaded onto the sensor
chip was monitored. Specific binding was calculated by subtracting the
resonance units found in controls (background binding) from those
detected in samples. The apparent association (Ka) and dissociation
(Kd) rate constants were estimated
using linear transformation of the biosensor curves. The primary data were analyzed using BIA evaluation software (BIAcore, Inc.). Because the model assumes that the kinetics of the syntaxin-CaMKII interaction are pseudo-first order, the binding rate equation is
dR/dt = KaCRmax  (KaC + Kd)R, where R is
the signal response, Rmax is maximum response level, and C is the molar concentration of CaMKII.
Immunoprecipitation. Synaptosomes were prepared from the
adult rat brain as described previously (Pevsner et al., 1994; Igarashi et al., 1997, 2000). The buffer composition for immunoprecipitation was
20 mM HCl, pH 7.6, 150 mM
NaCl, 1% Nonidet P-40, 1 mg/ml BSA, 1 mM
CaCl2, 2 mM
MgCl2, 0.5 mM ATP S, and
protease inhibitor mixtures. Complexes were immunoprecipitated as
described previously (Pevsner et al., 1994; Igarashi et al., 1997),
except that the washing buffer contained (in
mM): 1 CaCl2, 2 MgCl2, and 0.5 ATPS. Glycerol gradient experiments were performed as described by
Pevsner et al. (1994).
In vitro reconstitution of syntaxin-CaMKII complex. Purified
CaMKII complexed with GST-syntaxin 1A [1-262] was
immunoprecipitated using anti-CaMKII antibody, incubated with SNAP-25
and synaptotagmin, resolved by SDS-PAGE, and immunoblotted. The amount
of immunoprecipitated GST-syntaxin was 0.2 µg. Control GST-syntaxin
alone was immobilized and incubated with SNAP-25 and synaptotagmin.
Amperometry of chromaffin cells. Exocytotic events in single
cells were measured by amperometry as follows: chromaffin cells were
cultured on collagen-coated coverslips. Recordings were taken using
carbon fiber electrodes (Dagan Corp., Minneapolis, MN), and the
reference electrodes were silver wires coated with AgCl. The cytosol of
50-150 6-d-old cultured cells was microinjected for 0.2 sec at 10 kPa of pressure using an Eppendorf injection system. The
estimated cytosolic concentration of the injected fragments was 60-120
µg/ml. Release of Ca from single cells induced by a pressure ejection
of 0.1 mM nicotine was determined using an
amperometer 30 min after microinjection.
Electrophysiology of cultured superior cervical ganglion neurons
after microinjection of recombinant proteins. Conventional intracellular recordings were taken from pairs of neighboring superior
cervical ganglion (SCG) neurons cultured for 4-5 weeks. Postsynaptic
responses were recorded from one neuron when action potentials were
generated in the others by passing a current through an intracellular
recording electrode once every 5 sec (0.2 Hz). The recombinant proteins
dissolved in the solution (in mM: 150 K-acetate,
5 Mg2+-ATP, and 10 HEPES, pH 7.4) in the
glass suction pipette were introduced into the presynaptic cell body by
diffusion from the pipette as described previously (Mochida et al.,
1998). Data were analyzed using software written by L. Tauc (Centre
National de la Recherche Scientifique, Gif sur Yvette, France). The
resultant values were smoothed by an eight point moving-average
algorithm and plotted against recording time, with t = 0 indicating the start of presynaptic injection. The EPSPs of one
representative experiment, in which values were recorded 5 min before
injection and 50 and 90 min thereafter, are illustrated (see Fig.
10A). EPSPs were recorded once every 5 sec, at 0.2 Hz. Normalized average EPSPs were obtained by plotting the results of
five experiments using syntaxin-derived fragments.
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RESULTS |
CaMKII binds to syntaxin only when autophosphorylated
To search for a protein that might be the missing link in the
molecular explanation of exocytosis in the rat brain, we used a
GST-syntaxin pull-down study and found a 50 kDa protein that specifically binds to syntaxin in a
Ca2+/ATP-dependent manner (Fig.
1A). This protein was
identified as CaMKII by mass spectrometry (see Materials and
Methods). Immunoblotting showed that CaMKII specifically binds to
syntaxin (Fig. 1B) only in the presence of
Ca2+ and ATP (Fig. 1B).
In the same study, CASK, a presynaptic terminal protein homologous with
the catalytic domain of CaMKII, did not bind to syntaxin (data not
shown). Binding experiments using ATP analogs revealed that ATP and
ATPS, both of which are available to protein kinases (Takahashi et
al., 1999), are effective at binding CaMKII and syntaxin (Fig.
1C). CaMKII-syntaxin binding was completely
Ca2+-dependent, whereas tomosyn or
mammalian unc (Munc)-18 syntaxin complexes required
Ca2+ concentrations of at least
106 M for binding
(Fig. 1D).
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Figure 1.
CaMKII binds syntaxin in a
Ca2+/ATP-dependent manner. A, A 50 kDa protein, which bound syntaxin 1A specifically in a
Ca2+/ATP-dependent manner, was found using a GST
pull-down study. GST or GST-syntaxin 1A (4 nmol each) was immobilized
to glutathione Sepharose for 1 hr at 4°C and incubated with (or
without) 1 ml of brain S2 fraction (protein concentration
was 10 mg/ml) for 1 hr at 4°C in the presence or absence of
Ca2+/Mg-ATP. Next, GST fusion protein was cleaved by
incubation with PreScission protease (10 U) for 1 hr at 4°C. After
centrifugation, the supernatant was again incubated with glutathione
Sepharose for 1 hr at 4°C and centrifuged to remove the protease. The
supernatant was mixed with an equal volume of 2× SDS sample buffer and
loaded onto 7.5% SDS-PAGE. The silver staining of the gel is shown.
Lane 1, GST alone; lane 2, GST plus brain
S2 fraction with Ca2+/Mg-ATP;
lane 3, GST-syntaxin alone; lane 4,
GST-syntaxin plus S2 fraction with
Ca2+/Mg-ATP; lane 5,
GST-syntaxin plus S2 fraction without
Ca2+/Mg-ATP. The Ca2+/Mg-ATP
conditions consisted of an incubation with (in mM): 1 CaCl2, 0.5 ATP, and 2 MgCl2. To
reproduce these conditions in the absence of
Ca2+/Mg-ATP, 1 mM EGTA and 2 mM EDTA were added instead of CaCl2 and
MgCl2, and ATP was omitted. Molecular mass (in
kilodaltons) is shown on the left, and the 50 kDa
protein enriched in lane 4 is shown as an
arrow. B, CaMKII in brain
S2 fraction specifically binds syntaxin in the presence of
Ca2+ and ATP. C, Nucleotide
requirements for binding. Instead of ATPS, 0.5 mM of
each nucleotide was added to the incubation mixture. D,
Ca2+ requirement for CaMKII binding to syntaxin.
Various final concentrations of Ca2+ were added to
the incubation mixture AMP-PNP,
5'-Adenylylimidodiphosphate. The syntaxin-binding protein fraction,
eluted by PreScission protease (Amersham-Pharmacia Biotech), was
resolved by 10% SDS-PAGE and immunoblotted using anti-CaMKII pAb
(B-D) and anti-tomosyn (Fujita et al., 1998) or
anti-Munc-18 pAb (D). Blots in B
and C were stained with anti-CaMKII pAb.
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We considered that an activation process involving CaMKII
autophosphorylation (Braun and Schulman, 1995; Soderling et al., 2001)
is necessary for binding. Autophosphorylated CaMKII bound syntaxin,
whereas dephosphorylated CaMKII purified from the rat brain did not
(Fig. 2A).
T286A-CaMKII, a mutant lacking an autophosphorylation site, did not
bind to syntaxin even in the presence of
Ca2+/ATP (Fig. 2B). The
CaMKII produced using in vitro translation also bound to
syntaxin in a Ca2+-dependent manner (Fig.
2C). CaMKII bound to syntaxin in a dose-dependent manner,
suggesting that the binding is stoichiometric (Fig.
2D). Among the three domains of CaMKII (i.e., the
catalytic, regulatory, or association domains), the association domain
is required for oligomerization (Kanaseki et al., 1991). When the
association domain was deleted, CaMKII could not bind syntaxin, even
after autophosphorylation (Fig. 2E). This indicates
that CaMKII binding to syntaxin requires the oligomerization of CaMKII,
as well as its autophosphorylation. After binding to syntaxin, EGTA
(Fig. 3A) or the
dephosphorylation of CaMKII (Fig. 3B) caused the release of
CaMKII from the complex. These results suggest that binding between
CaMKII and syntaxin is reversible and regulated by both [Ca2+] and the
autophosphorylation-dephosphorylation cycle.
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Figure 2.
CaMKII binds to syntaxin only when
autophosphorylated. A, Purified CaMKII also binds
syntaxin after autophosphorylation. The fraction unbound to
GST-syntaxin after re-autophosphorylation was not recognized by
anti-autophosphorylated CaMKII antibody. CaMKII (5 µg) purified
from rat brain was autophosphorylated (Auto-P) in buffer
containing 50 mM HEPES-NaOH, pH 8.0, 8 mM
Mg(CH3COO)2, 0.25 mM
CaCl2, 2 µM CaM, and 0.5 mM ATP for 5 min at 30°C, and then incubated with
immobilized GST or GST-syntaxin (4 nmol) for 1 hr at 4°C. After
centrifugation, the supernatant was collected as the unbound fraction.
The PreScission protease fraction was collected as the bound fraction.
Samples were resolved by 10% SDS-PAGE and immunoblotted using
anti-CaMKII mAb or anti-autophosphorylated CaMKII mAb.
B, T286A-CaMKII could not bind syntaxin.
Top, Both wild-type CaMKII (wt) and
T286A-CaMKII (T286A) were produced by in
vitro translation. Bottom, Only wt CaMKII
bound to syntaxin in the pull-down study in presence of
Ca2+/ATP. The cDNA encoding rat CaMKII or
T286A-CaMKII (provided by Dr. H. Schulman) was added to the
in vitro translation kit (Promega). Proteins were
expressed by incubating kit components for 1.5 hr at 30°C and then
adding immobilized GST-syntaxin as above. After elution with SDS
sample buffer, bound proteins were blotted and detected using
streptavidin-conjugated alkaline phosphatase. C,
CaMKII produced using in vitro translation also shows
Ca2+ sensitivity for binding to syntaxin after
autophosphorylation. Translation in vitro proceeded as
described above, and CaMKII was autophosphorylated in buffer
containing Tris-HCl, pH 7.6, 0.5 mM
CaCl2, 2 µM CaM, 2 mM
MgCl2, and 0.5 mM ATP at 30°C for 15 min. The autophosphorylated CaMKII was incubated with immobilized
GST-syntaxin (4 nmol) at 4°C for 1 hr and then with binding buffer
containing various concentrations of Ca2+ for an
additional 1 hr. D, Dose-dependent binding of CaMKII to
syntaxin. GST-syntaxin (4 nmol) was incubated with recombinant
CaMKII at various concentrations. E, CaMKII
lacking the association domain [1-325] (i.e., monomeric CaMKII) does
not bind to syntaxin, even when autophosphorylated. The monomeric
CaMKII was autophosphorylated and incubated with the immobilized
GST-syntaxin as described above (A).
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Figure 3.
Dissociation of the autophosphorylated CaMKII from
syntaxin 1A is regulated by decrease of [Ca2+]
(A) and its dephosphorylation
(B). In both A and
B, anti-CaMKII (top) and
anti-autophosphorylated CaMKII (bottom)
antibodies were used in immunoblots. Purified rat brain CaMKII was
autophosphorylated and incubated with immobilized GST-syntaxin as
described above (A). Protein complex was
additionally incubated with EGTA-treated buffer (see Materials and
Methods) for 1 hr at 4°C (A) or with PP1 for 30 min at 25°C (B). Bound CaMKII was then
eluted with PreScission protease and analyzed using anti-CaMKII mAb.
EGTA (A) or CaMKII dephosphorylated by PP1
(B) after binding causes CaMKII release from
syntaxin. Under these conditions, retained CaMKII accounted for only
18.7 ± 1.5% (A) and 14.3 ± 2.3%
(B) of the control, respectively (four
independent experiments each). In A, Munc-18 and tomosyn
were compared with CaMKII under the same experimental conditions, and
their binding to syntaxin was completely independent of
Ca2+.
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CaMKII-binding site is the linker domain of syntaxin
We determined which domain of syntaxin was responsible for
binding. The core complex region [191-261] of syntaxin (Dulubova et
al., 1999; Brunger, 2000; Misura et al., 2000b), where most syntaxin-binding proteins bind, was not the CaMKII-binding site. We
found that the linker domain [145-184] of syntaxin was the site of
CaMKII binding (Fig.
4A). Until now, the
minimal binding site was thought to be region 145-172 of syntaxin. The
linker domain is believed to connect the core complex region to three N-terminus helical domains, but proteins that specifically bind to this
portion have not been found (Dulubova et al., 1999; Brunger, 2000;
Misura et al., 2000a) (Fig. 4B). With respect to the
requirement of CaMKII autophosphorylation for binding, we found three
basic amino acids (K146, R148, and R151) within the linker domain.
Deletion of all three of these amino acids or the substitution of R151 alone resulted in a total loss of CaMKII binding (Fig. 4A).
Within cytoplasmic syntaxin [1-262], CaMKII binding was selectively
lost with R151G substitution, but the binding of other known
syntaxin-binding proteins was unaffected (Fig. 4B). CaMKII
was displaced from syntaxin [1-262] after addition of 10 µM syntaxin [145-184] (Fig. 4C). We tested other CaMKII-binding fragments derived from NR2A
[1349-1461] (Gardoni et al., 2001) or NR2B [1290-1309] (Strack et
al., 2000), both of which bind to CaMKII but do not inhibit
syntaxin-CaMKII binding. These fragments did not interfere with
CaMKII-syntaxin interaction (Fig. 4C), indicating that the
CaMKII-binding fragment of syntaxin specifically inhibits
CaMKII-syntaxin binding.
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Figure 4.
Determination of CaMKII-binding site in
syntaxin. A, Binding visualized using anti-CaMKII
antibody. Each recombinant fragment derived from syntaxin 1A as a
GST-fusion protein (4 nmol) was immobilized to glutathione Sepharose,
incubated with autophosphorylated purified CaMKII (5 µg), and then
cleaved by PreScission protease like the brain S2 fraction
(see legend to Fig. 1). Eluted fractions were resolved by 10% SDS-PAGE
and immunoblotted against anti-CaMKII mAb. B, R151G
is critical to binding of CaMKII to syntaxin, but mutation in this
amino acid did not affect interactions between syntaxin and other
syntaxin-binding proteins. Each GST-fusion protein was immobilized as
well as those described in A and incubated with each
recombinant protein (1 nmol) or with CaMKII (5 µg). After
PreScission protease digestion, eluted proteins were resolved by 15%
SDS-PAGE and immunoblotted. C, Dissociation of CaMKII
from syntaxin by CaMKII-binding fragments derived from syntaxin 1A
([145-184]; squares) and glutamate receptors of NR2A
([1349-1461]; circles) and NR2B ([1290-1309];
triangles). GST-syntaxin 1A [1-262] (4 nmol) was
immobilized with glutathione Sepharose and then incubated with purified
autophosphorylated CaMKII (5 µg). After rinsing with PBS, immobilized
syntaxin-CaMKII complex was incubated with syntaxin [145-184] for 1 hr at 4°C and centrifuged. In some experiments, various
concentrations of NR2A or NR2B fragments were incubated with
immobilized syntaxin-CaMKII complex as described above. The
supernatant containing released CaMKII was resolved by 10% SDS-PAGE
and immunoblotted against anti-CaMKII mAb. The amount of the bound
CaMKII before incubation with syntaxin fragments [145-184] or
derived from glutamate receptors is designated as 100%.
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We confirmed the reversible and specific binding of CaMKII and syntaxin
using the BIAcore system (data not shown). The dissociation constant
(Kd) between the autophosphorylated
CaMKII and syntaxin [1-262] was 4.3 × 107 M (Table
1). In contrast, the affinity of
nonphosphorylated CaMKII to syntaxin was ~250-fold lower than that of
phosphorylated CaMKII (Table 1). We also found that CaMKII, another
abundant isoform of CaMKII in neurons, binds syntaxin (Table 1). The
dissociation constants of CaMKII to the linker domain of syntaxin and
to syntaxin were similar [1-262] (Table 1).
The binding of syntaxin to CaMKII does not affect the catalytic
activity of CaMKII and is independent of syntaxin phosphorylation by
CaMKII
Fragment [145-184] of syntaxin had little effect on the
autophosphorylation of CaMKII, indicating that binding to this
fragment does not primarily affect CaMKII activity (Fig.
5A). Syntaxin itself was not a
good substrate for CaMKII (~0.05 mol of phosphate per mole of
syntaxin 1A), although slight phosphorylation was detected (Fig.
5A) (Risinger and Bennett, 1999). The autophosphorylation of
CaMKII was not affected by syntaxin [145-184] (Fig. 5B).
The immunoprecipitation of synaptosomal proteins by anti-syntaxin mAb
after Ca2+-dependent phosphorylation
revealed that the major and minor phosphorylated proteins were
CaMKII and CaMKII and synaptotagmin I and syntaxin, respectively.
The phosphorylation of all of these proteins was KN-93-sensitive. Among
the syntaxin-binding proteins, synaptotagmin I is a substrate of CaMKII
in vitro (Hilfiker et al., 1999). The phosphorylation of
synaptotagmin I was 103.5 ± 5.8% in the presence of 12.5 µM syntaxin [145-184] and 104.7 ± 6.5% in the presence of 12.5 µM syntaxin
([145-184]; R151G), respectively (p > 0.05 using t test; four independent experiments; the amount of
32P incorporated into phosphorylated
synaptotagmin I, 1 µM, was designated as
100%). Thus, the phosphorylation of synaptotagmin I by CaMKII was not
altered in the presence of syntaxin [145-184] or ([145-184];
R151G). In addition, T112A-syntaptotagmin I (Hilfiker et al., 1999), a
mutant that could not undergo the phosphorylation by CaMKII, was still
bound to syntaxin 1A as well as the wild type (Fig. 5C). We
located a consensus sequence of CaMKII substrates (RxxS/T) in the
CaMKII-binding site of syntaxin 1A at 158-161 (RTTT). The substitution
mutant T161A was not phosphorylated by CaMKII, but the syntaxin
fragment ([145-184]; T161A) still bound CaMKII (Fig. 5D),
and the dissociation constant of this fragment was similar to that of
the wild type (Table 1). These results indicate that CaMKII-syntaxin
1A binding is independent of the phosphorylation of syntaxin 1A by
CaMKII.
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Figure 5.
Binding of syntaxin to CaMKII does not affect the
catalytic activity of CaMKII. A,
Ca2+/CaM-dependent protein phosphorylation in
synaptosomes is not altered by microinjection of a syntaxin-derived
CaMKII-binding fragment ([145-184]; 20 µM). Molecular
masses are shown on the left (in kilodaltons). The
synaptosomal proteins (10 µg) were phosphorylated as described by
Popoli et al. (1995). Samples were resolved by 15% SDS-PAGE and the
gel dried on filter paper was then analyzed using a BAS 2000 system.
B, Autophosphorylation of CaMKII is not altered in the
absence (squares) or presence (circles)
of the CaMKII-binding fragment of syntaxin ([145-184], 20 µM). Autophosphorylation proceeded as described by Katoh
and Fujisawa (1991). C, T112A-synaptotagmin I was
dephosphorylated by CaMKII, but it normally binds to syntaxin.
Top, Autoradiogram visualized using the BAS 2000 system.
Synaptotagmin I was phosphorylated by CaMKII, but the T112A mutant was
not phosphorylated. Bottom, Binding visualized by
immunoblotting against anti-synaptotagmin I antibody. The amount of
bound T112A mutant was 94.1 ± 7.0% of the bound wild type (four
independent experiments), with no statistically significant difference.
Phosphorylation proceeded according to Hilfiker et al. (1999).
D, Syntaxin ([145-184]; T161A) is not phosphorylated,
but binding to CaMKII is similar to that of the wild type.
Left, Autoradiogram visualized using the BAS 2000 system. Syntaxin [145-184] was phosphorylated faintly, but the T161A
mutant was not phosphorylated at all. Right, Binding
visualized by immunoblotting using anti-CaMKII antibody. The amount of
CaMKII that bound to syntaxin ([145-184]; T161A) was 104 ± 8%
of that bound to wild-type syntaxin [145-184] (four independent
experiments), with no statistically significant difference.
Phosphorylation proceeded according to Risinger and Bennett (1999). The
binding experiment and the following analysis proceeded under standard
conditions (see legend to Fig. 4). Incorporation of 32P by
CaMKII-dependent phosphorylation was analyzed using the BAS 2000 system
as above.
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CaMKII interacts with syntaxin in the presynaptic terminal
We examined whether or not CaMKII binding to syntaxin regulates
formation of the SNARE complex. Using synaptosomal proteins solubilized
with Triton X-100 (Pevsner et al., 1994), immunoprecipitation in the
presence of Ca2+ and ATP confirmed that
CaMKII and syntaxin form a complex in vivo as well
in vitro (Fig.
6A). We surmised that
the CaMKII-syntaxin complex recruits other proteins that regulate the
SNARE mechanism. Among solubilized synaptic proteins separated in a
glycerol gradient, SNAP-25, synaptotagmin, and tomosyn colocalized with
syntaxin (Fig. 6B). Anti-CaMKII antibody
coimmunoprecipitated synaptotagmin and SNAP-25 with syntaxin but not
tomosyn or VAMP (Fig. 6C). A reconstitution study showed
that the CaMKII-syntaxin complex bound more synaptotagmin and
SNAP-25 than syntaxin alone (Fig. 7A). Synaptotagmin and SNAP-25
did not bind to CaMKII itself (data not shown). In contrast, VAMP,
which is not associated with the CaMKII-syntaxin complex in
vivo (Fig. 6C), bound to CaMKII-syntaxin in
vitro, but the amount of VAMP bound to this complex was similar to
that bound to syntaxin alone (Fig. 7A). The complex composed of four proteins did not show SDS resistance at 65°C as the SNARE complex does (data not shown). The CaMKII-binding fragment derived from
NR2A did not interfere with the formation of this complex (Fig.
7A). The syntaxin-binding activity of T112A-synaptotagmin I, a mutant without a CaMKII phosphorylation site (Hilfiker et al.,
1999), was increased to a level similar to that of the wild type in the
presence of CaMKII (Fig. 7B). In addition, the activity of
T161A-syntaxin lacking a putative phosphorylation site caused by
CaMKII was similar to that of wild-type syntaxin (Fig. 7B). Thus, this effect of CaMKII is probably not based on the
phosphorylation of either synaptotagmin I or syntaxin by CaMKII.
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Figure 6.
Relationship between the CaMKII-syntaxin
complex and other syntaxin-binding proteins. A,
Immunoprecipitation of Triton X-100-solubilized synaptosomal proteins
using anti-CaMKII or anti-syntaxin antibodies. Complexes were
immunostained using anti-syntaxin 1A (top) and
anti-CaMKII (bottom) mAbs. The arrow
indicates the position of CaMKII (the top band
represents the IgG heavy chain). Normal mouse IgG was used as the
control. Each antibody was incubated with protein G-Sepharose at 4°C
for 2 hr, and 10 mg of solubilized synaptosomal proteins (Pevsner et
al., 1994; Igarashi et al., 1997) was then added to each
antibody-protein G-Sepharose complex at 4°C for an additional 2 hr.
Protein-antibody complex eluted with SDS sample buffer was loaded onto 15% SDS-PAGE and immunoblotted against
these antibodies. B, Fractionation of synaptosomal
proteins solubilized by 1% Triton X-100 and separated on a 10-35%
glycerol gradient, as described previously (Igarashi et al., 1997).
Fractions (1 ml) were collected from the top. One milliliter of
solubilized synaptosomal proteins (protein content was ~1 mg) was
loaded onto 10 ml of a 10-35% continuous glycerol gradient and
centrifuged at 41,000 rpm for 17 hr. Fractions (100 µl each) were
resolved on 15% SDS-PAGE, and the distribution of each protein was
analyzed by immunoblotting. C, Immunoprecipitation of
solubilized proteins in fraction 8 of B, which contained
both CaMKII and syntaxin, proceeded as described previously (Igarashi
et al., 1997, 2000).
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Figure 7.
In vitro reconstitution of the
syntaxin 1A-CaMKII complex with other presynaptic proteins.
A, Syntaxin-CaMKII complexes formed in
vitro recruited more synaptotagmin and SNAP-25 than syntaxin
alone. After the formation of CaMKII-syntaxin complex with
synaptotagmin I and SNAP-25, NR2A [1389-1464]
(105 M) was added in some experiments
to a complex composed of those four proteins for 1 hr.
B, Relative binding of synaptotagmin I to syntaxin
binding in the absence or presence of CaMKII. Combinations were as
follows: wt/wt, Wild-type syntaxin/wild-type
synaptotagmin I; wt/T112A, wild-type
syntaxin/T112A-synaptotagmin I; T161A/wt,
T161A-syntaxin/wild-type synaptotagmin I; and
T161A/T112A, T161A-syntaxin/T112A-synaptotagmin I. T112A-synaptotagmin I, a mutant without a CaMKII-dependent
phosphorylation site, binds to syntaxin 1A in a manner similar to wild
type in the presence of CaMKII. Binding was quantified by densitometry
of immunoblots. The ratio was calculated as amount of syntaxin-bound
synaptotagmin I in the presence of CaMKII compared with that in the
absence of CaMKII.
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CaMKII and Munc-18 alternatively binds to syntaxin
CaMKII did not bind syntaxin in the presence of Munc-18 (Fig.
8A), and CaMKII and
Munc-18 alternatively bind syntaxin in a dose-dependent manner (Fig.
8B). However, CaMKII bound to syntaxin 1A
([1-262]; L165A and E166A) (Fig. 8C), a mutant with a
forced open configuration (Dulubova et al., 1999) to which Munc-18
could not bind. Rather, more CaMKII bound to the forced open form than to the wild type (130 ± 5.5%; p < 0.05; four
independent experiments). These results indicated that the open but not
the closed form of syntaxin could bind CaMKII.
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Figure 8.
CaMKII and Munc-18 bind to syntaxin alternatively.
A, CaMKII is not bound to Munc-18-syntaxin complex.
After recombinant Munc-18 and syntaxin were incubated, the protein
complex was immunoprecipitated by anti-syntaxin antibody, and purified
CaMKII was added to this complex. Total complex bound to syntaxin was
released from GST as described in Materials and Methods.
B, CaMKII and Munc-18 alternatively bind to syntaxin in
a dose-dependent manner. Both proteins were incubated with the same
concentration of immobilized GST-syntaxin 1A at 4°C for 1 hr and
eluted with SDS sample buffer. Samples were resolved by 10% SDS-PAGE
and immunoblotted. C, CaMKII can bind mutant syntaxin 1A
([1-262]; L165A and E166A; mutant), a forced open
form, to which Munc-18 never binds (Dulubova et al., 1999). Control
represents normal syntaxin 1A [1-262]. The amount of CaMKII bound to
open-form syntaxin was 130.1 ± 4.3% of that bound to wild type,
which was significantly increased (n = 4;
p < 0.05, t test).
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Effects of CaMKII-binding fragment in chromaffin cells and in
SCG neurons
We examined the physiological significance of CaMKII-syntaxin
interactions in exocytosis by electrophysiological means using chromaffin cells and SCG neurons into which the CaMKII-binding fragment
derived from syntaxin was microinjected. We confirmed that syntaxin 1A
binds CaMKII of the chromaffin cell lysate (Fig. 9A). Microinjection of the
CaMKII-binding fragment of syntaxin [145-184] decreased the
frequency of exocytosis, as determined by amperometry of catecholamine
release (Fig. 9B). In contrast, microinjection of the mutant
R151G fragment, which cannot bind CaMKII, had no effect (Fig.
9B,C). We tested another CaMKII-binding fragment derived
from NR2A [1349-1461] (Gardoni et al., 2001) that binds CaMKII (Fig.
9A) but does not inhibit syntaxin-CaMKII binding (Fig.
4C). The fragment did not affect the exocytotic frequency of
the chromaffin cells, unlike syntaxin [145-184] (Fig. 9C).
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Figure 9.
Effects of a CaMKII-binding
fragment [145-184] derived from syntaxin in adrenal chromaffin
cells. A, CaMKII specifically bound syntaxin in
chromaffin cell lysate. The molecular mass is shown on the
right (in kilodaltons). This isoform was thought to be
CaMKII . Chromaffin cells were separated from adrenal medulla, and
cell lysate was made by solubilization with buffer containing 20 mM HCl, pH 7.6, 150 mM NaCl, 1% Nonidet P-40,
1 mg/ml BSA, 1 mM CaCl2, 2 mM MgCl2, 0.5 mM ATPS, and protease inhibitor mixtures for 2 hr at
4°C. Lysate (protein concentration 10 mg/ml) was incubated with GST,
GST-syntaxin 1A [1-262], or GST-NR2A [1349-1461], and binding
proteins were eluted with PreScission protease as described above (see
legend to Fig. 1A). Samples were resolved by 10%
SDS-PAGE and immunoblotted against anti-CaMKII pAb. B,
C, Effects of microinjected syntaxin [145-184] and syntaxin
([145-184]; R151G) on nicotine-evoked catecholamine release from
single chromaffin cells detected by single-cell amperometry.
B, Typical catecholamine release responses of
nicotine-stimulated chromaffin cells into which GST, GST-syntaxin
[145-184], or GST-syntaxin ([145-184]; R151G) was microinjected.
Both recombinant syntaxin fragments (15 µM) were
microinjected into cytosol of chromaffin cells. C,
Summary of experiments using chromaffin cells. Frequency (spike
numbers) of catecholamine release was significantly lower within the
CaMKII-binding fragment of syntaxin [145-184] than in cells injected
with control or syntaxin fragment ([145-184]; R151G). The NR2A
fragment interacted with CaMKII (A) in chromaffin
cells but did not inhibit exocytosis (C). Data
are means ± SEM of indicated determinations. Data are typical of
several cell preparations. *p < 0.05 versus R151G.
R151G and NR2A were not significantly different from controls (no
addition).
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In addition, EPSPs decreased in SCG neurons microinjected with the
CaMKII-binding fragment of syntaxin [145-184] compared with those
microinjected with a mutated fragment having a deletion that prevents
CaMKII binding (Fig.
10A,B). Fragments
derived from NR2A and NR2B (Strack et al., 2000), as well as
those from chromaffin cells, did not affect the EPSPs in SCG
neurons (Fig. 10B). These results suggest that the
CaMKII-binding fragment decreases the frequency of exocytosis, probably
through competitive inhibition of the CaMKII-syntaxin interaction
(Fig. 4C). Thus, we concluded that the
Ca2+/ATP-dependent binding of CaMKII to
syntaxin is physiologically important in the regulation of
exocytosis.
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Figure 10.
Activity-dependent inhibition of synaptic
transmission by the CaMKII-binding domain of syntaxin-1A in cultured
SCG neurons. A, Syntaxin [145-184] was introduced
into presynaptic neurons by diffusion from a pipette from the start of
membrane disruption by suction at t = 0. B, EPSPs of neurons microinjected with the
CaMKII-binding fragment were significantly lower than those of neurons
microinjected with deletion mutant that was unable to bind CaMKII.
Normalized average EPSPs were plotted from five experiments with
syntaxin [145-184] (CaMKII-binding fragment;
triangles) and with syntaxin [152-184] (fragment
unable to bind CaMKII; Fig. 3A; circles).
CaMKII-binding fragments of NR2A ([1389-1461];
diamonds) and NR2B ([1290-1309];
squares) glutamate receptors were also microinjected
(Strack et al., 2000; Gardoni et al., 2001). EPSP amplitudes at 80 min
after the start of injection with syntaxin [145-184] and syntaxin
[152-184] were 39 ± 7.0% (n = 5;
mean ± SEM) and 14 ± 5.8% (n = 5),
respectively. psps, Postsynaptic potentials.
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DISCUSSION |
The present study found that autophosphorylated CaMKII
specifically binds to syntaxin at Ca2+
concentrations of >106 M
and that bound CaMKII is released from syntaxin when the
Ca2+ concentration decreases or the CaMKII
is dephosphorylated (Fig. 3A,B). Thus, the binding is
thought to be reversible and regulated by
Ca2+/ATP. This protein complex was also
detected in solubilized synaptosomes, indicating that the
CaMKII-syntaxin complex is formed in vivo (Fig.
7A). The microinjected CaMKII-binding domain of syntaxin, namely the linker domain where no known syntaxin-binding proteins bind,
specifically decreased the frequency of exocytosis in chromaffin cells
and in SCG neurons (Figs. 9, 10), probably because the endogenous complex was perturbed by the injected fragments (Fig. 4C).
These findings indicated that the binding of CaMKII to syntaxin plays a
physiologically important role in the regulation of exocytosis. We
originally supposed that the catalytic activity of CaMKII is affected
by its binding to syntaxin. However, neither the in vitro nor in vivo results confirmed this supposition (Fig. 5).
Together, these results indicate that neither the catalytic activity of CaMKII-syntaxin binding nor the phosphorylation of other
syntaxin-binding proteins by CaMKII is significantly affected by
CaMKII-syntaxin interactions. Moreover, the phosphorylation of
syntaxin by CaMKII is not involved in CaMKII binding to syntaxin (Fig.
5D). Thus, it is unlikely that the physiological role of
this binding is CaMKII accessibility to the membrane via syntaxin for
CaMKII to phosphorylate syntaxin-binding proteins. This binding has
considerable physiological significance. Syntaxin-bound CaMKII might
act as a Ca2+ sensor by trapping CaM
(Meyer et al., 1994), thereby stimulating vesicular fusion (Peters and
Meyer, 1998), or CaM trapping might help the translocation of CaMKII to
the plasma membrane. However, based on the function of the linker
domain where CaMKII binds, we believe that the latter possibility is
more likely. The linker domain might play a role in structural
conversion of the closed form (unable to bind other SNAREs) to the open
form (able to bind other SNAREs) (Dulubova et al., 1999; Richmond et
al., 2001). This hypothesis assumes that Munc-18 is a protein that
binds the closed form. Our results showed that CaMKII and Munc-18
alternatively bind syntaxin (Figs. 6B,C,
8A). Thus, these two proteins are thought to bind two
distinct forms of free syntaxin (Dulubova et al., 1999). The present
results indicate that CaMKII initially assumes the open form that
alternatively binds syntaxin. This in turn opens syntaxin, a notion
that is supported by the length of its oligomers (8-12 mer, the
estimated molecular mass of which is > 400 kDa) (Lin et al.,
1987; Morris and Török, 2001). In this state, the core
complex region is released. This allows syntaxin to recruit SNAP-25 or
synaptotagmin on the vesicle [CaMKII may be also on the vesicle
(Benfenati et al., 1992)], which serves as a priming protein complex
composed of the target-SNARE complex plus a putative
Ca2+ sensor. After
[Ca2+] elevation and additional
stimulation, vesicles having this complex are more likely to be
released than those in which this priming complex is absent. Although
the affinity of CaMKII to syntaxin was lower than that of Munc-18 or
tomosyn (Table 1) (Fujita et al., 1998),
Ca2+ and ATP induced a rapid increase in
CaMKII binding (Figs. 1C,D, 2C). Because CaMKII
is abundant in the synaptic area, a large Bmax must cover the lower
Kd value. The value
106 M represents a
physiological increase of Ca2+ when
[Ca2+] is elevated in the presynaptic terminal.
Our evidence indicated that VAMP does not coimmunoprecipitate with
CaMKII and syntaxin (Fig. 6C) and that the recruitment of
VAMP to the syntaxin-CaMKII complex in vitro proceeds in a different manner from that of synaptotagmin I or SNAP-25 (i.e., an
increase in recruitment was not detected compared with syntaxin alone)
(Fig. 7A). We therefore concluded that VAMP is not a core member of the CaMKII-syntaxin complex and considered that this large
complex of four proteins is an intermediate at a transition state
before the complete SNARE complex is formed.
The level of exocytosis was not significantly altered in transfected
PC12 cells overexpressing syntaxin [145-184] (M. Igarashi, unpublished observation), although transmitter release from chromaffin cells and SCG neurons was affected by this fragment, as shown in
Figures 9 and 10. This is probably a result of the much lower amount of
CaMKII in PC12 cells than in neurons (Massé and Kelly, 1997) and
an ineffective CaMKII-dependent machinery (Chen et al., 1999). These
data indicate that the CaMKII-syntaxin complex aids efficient,
continual exocytosis, although it may not be the minimal exocytotic requirement.
CaMKII has , , , and isoforms (Soderling et al., 2001).
The and isoforms are dominant in neurons, whereas the and isoforms are distributed among various tissues (Braun and Schulman, 1995). Both the and isoforms of CaMKII bind syntaxin in
vitro (Table 1). In chromaffin cells, CaMKII is localized
(Tashima et al., 1996) and binds syntaxin (Fig.
9A). Thus, all of the isoforms are thought
to have syntaxin 1A-binding ability. Even if one CaMKII isoform is
lacking, others can compensate. CaMKII-null mice do not have
significantly defective exocytosis (Silva et al., 1992), probably
because of functional compensation by the isoform, which, like
CaMKII, is abundant in the brain. To reconfirm the present results,
it will be necessary to examine the dynamics of exocytosis using
electrophysiological techniques in gene-targeted mice. We have started
to generate knock-in mice with a point mutation modifying
CaMKII-syntaxin interaction.
Finally, our results indicate that in addition to the postsynaptic
machinery (Soderling et al., 2001), the autophosphorylation of CaMKII
also affects the presynaptic mechanism of synaptic transmission through
regulation of SNARE complex formation. This interaction might provide
new insight into the molecular mechanism of presynaptic synaptic
plasticity (Giese et al., 1998).
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FOOTNOTES |
Received Aug. 13, 2001; revised Jan. 14, 2002; accepted Jan. 15, 2002.
This work was supported in part by grants for Scientific Research on
Priority Areas (A)-Neural Circuit Project and
(C)-Advanced Brain Science Projects from the
Ministry of Education, Sciences, Culture, and Sports of Japan to M.I.
and Y.K., as well as from the Life Science Foundation, the Brain
Science Foundation, the Yujin Memorial Foundation, and the Ichiro
Kanehara Memorial Medical Science Foundation to M.I. We thank T. Abe,
E. Miyamoto, K. Sakimura, H. Schulman, T. C. Südhof, M. Takahashi, and Y. Takai for cDNAs and antibodies. We also thank E. Akaishi, K. Nomura, and K. Honda for technical assistance and S. Suetsugu for help with the BIAcore measurements. We are grateful to T. Abe, F. Gotoh, M. Itakura, H. Kasai, T. Manabe, H. Shirataki, M. Takahashi, T. Takahashi, M. Watanabe, and H. Yamamoto for discussion
and advice and to M. Neal Waxham for recombinant CaMKII and for
critical comments regarding this manuscript.
Correspondence should be addressed to Dr. Michihiro Igarashi, Division
of Molecular and Cellular Biology, Department of Signal Transduction
Research, Niigata University, Graduate School of Medical and Dental
Sciences, 1-757 Asahi-machi, Niigata, Niigata 951-8510, Japan. E-mail:
tarokaja{at}med.niigata-u.ac.jp.
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ABSTRACT
INTRODUCTION
