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complexin binds to the H3 domain of syntaxin 1
S10.5
DIRECT BINDING
133 ATSUKO
HONDA,
Department
HIDE0
OF SYNAPTOTAGMIN
SAISU, TERUO ABE
of Cellular Neurobiology,
Synaptotagmin
Brain Research Institute,
proteins
When
tubulin
immobilized
the fusion
I, Nilgata 95 l-8585
Asahimachi
significant
To determine
on Cal-
of glutathione
was Incubated
Purified tubulins
in the bound material
nitrocellulosefilters
vesicle protein
protem
on glutathione-Sepharose
was dependent
were incubated
,S-transferase
with the soluble
(GST)-the
fraction
lacking MAPS and tau proteins
which of the two tubulin subunits
cytoplasmic
bmds tagmin, purified tubulins
with a Triton X-100 extract of brain membranes.
SYNAPHINiCOMPLEXIN
ABE.
Department
HIDE0
(also called complexin)
SNAP-25
and VAMP (synaptobrevm) release
IS
However,
Brain Research Institute,
a cytosolic
Synaphin
for transmitter
l3-Tubulin but not rr-tubulin
domain was comparable
were inhibited
a- and l&SNAP
SNAP-25
protem associated
GST-syntaxm
This synergistic
wrth that to GST-entire
GST-entire
cytoplasmic
synaphin
binding to syntaxin
effect on syntaxin
Conversely,
binding between synaphin
Asahimachi
I, Niigata 95 l-8585
without
IA is sufficient VAMP
and VAhlP-2
of VAMP-2 portion
syntaxin. is required
We have exammed binding of
remains unclear
cytoplasmic
portion
of the 7s complex thought to be involved in the final phase of synaptic
135
showed
1
we have shown that the protein
IA in the presence
These results indicate that the H3 domain of svntaxm enhanced
on to
X-100 extract
with the 7s complex containing synaptotagmin.
its exact role in the release mechanisms
1 to immobilized
synaphin by
OF SYNT4XrN
Niigata University,
Using the squid presynapticterminal.
binding to GST-H3 synaphin
blotted
SAISU, TORU ISHlZlJKA
of Cellular Neurobiology,
histidine-tagged
BlNDS TO THE H3 DOMAIN
of tagmin
were only maJor The binding also bound to GST-tagmin
tagmin and tubulins were coimmunoprecipitated from theTriton against tubulin These results indicate that tagmm directly binds to l.-tubulin
antibody
134
portion
of rat brain. tubulins
tagmin binding. Furthermore,
with a monoclonal
TERUO
is a synaptic
Niigata University.
thought to be a major Caz+ sensor in transmitter release \~a its interaction with syntaxin and SNAP-25 Moreover, it binds other proteins including neurexins and the clathrrn .AP-2. We have found tagmm binds to the cytoskelrtal suggesting that the protein is also involved in other presynapticfunctions protein
I (tagmm)
TO TUBULIN
and SNAP-25
of syntaxin
Synaphin
I A Both bindmgs
the H3 domain was incapable of bindmg for synaphin
bmdmg to syntaxm
binding
suggests that svnaphin
but not
facilitates the formation
vesicle fusion with the presynaptic
TEMPOLARY-DISTINCT INDUCTION OF INITIAL AND LATE PHASES POTENTIATION IN BULLFROG SYMPATHETIC GANGLIA
VAMP-2
was enhanced by synaphin membrane
OF LONG-TERM
K. Fujita, H. Tokuno & K. Kuba’ First Dept. ofPhysiology’
Nagoya Univ. Sch. Med., Nagoya 466-8550. Japan
Fast excitatory postsynaptic potentials (fEPSP) were recorded by an intracellular recording technique in a low Ca:‘. high Mg” solution. The quanta1 content and size of fEPSP were analyzed by a failure or variance method. A short tetanus (50 pulses) of 50 Hz to the preganglionic nerve produced the enhancement of the amplitude and quanta1 content of fEPSP lasting for one to one and half hours. A longer tetanus (50 Hz) of 100 pulses induced two distinct phases of long-term potentiation (LTP). Following the initial potentiation of tEPSP and the subsequent period of no potentiation for 20 to 30 min, the amplitude of fEPSP increased again. This late phase of LTP was accompanied by increases in both quanta1 content and size, and lasted for more than 8 hours. Tetanus of 300 pulses at 50 Hz consistently caused both the initial and late phases of LTP, which were interrupted by a period of no potentiation. Thus, the initial phase of LTP are predominantly induced by an increase in transmitter release from the presynaptic nerve terminals, while the late phase is caused by both the pre- and post-synaptic mechanisms. The initial phase of LTP could be caused by the activation of Ca/calmodulin-dependent protein kinase II and subsequent protein phosphorylation (Minota et al., 1991, J. Physiol 435. 421-438) while the late phase appears to be produced a much slower process, such as protein synthesis
DIRECT BINDING
133 ATSUKO
HONDA,
Department
HIDE0
OF SYNAPTOTAGMIN
SAISU, TERUO ABE
of Cellular Neurobiology,
Synaptotagmin
Brain Research Institute,
proteins
When
tubulin
immobilized
the fusion
I, Nilgata 95 l-8585
Asahimachi
significant
To determine
on Cal-
of glutathione
was Incubated
Purified tubulins
in the bound material
nitrocellulosefilters
vesicle protein
protem
on glutathione-Sepharose
was dependent
were incubated
,S-transferase
with the soluble
(GST)-the
fraction
lacking MAPS and tau proteins
which of the two tubulin subunits
cytoplasmic
bmds tagmin, purified tubulins
with a Triton X-100 extract of brain membranes.
SYNAPHINiCOMPLEXIN
ABE.
Department
HIDE0
(also called complexin)
SNAP-25
and VAMP (synaptobrevm) release
IS
However,
Brain Research Institute,
a cytosolic
Synaphin
for transmitter
l3-Tubulin but not rr-tubulin
domain was comparable
were inhibited
a- and l&SNAP
SNAP-25
protem associated
GST-syntaxm
This synergistic
wrth that to GST-entire
GST-entire
cytoplasmic
synaphin
binding to syntaxin
effect on syntaxin
Conversely,
binding between synaphin
Asahimachi
I, Niigata 95 l-8585
without
IA is sufficient VAMP
and VAhlP-2
of VAMP-2 portion
syntaxin. is required
We have exammed binding of
remains unclear
cytoplasmic
portion
of the 7s complex thought to be involved in the final phase of synaptic
135
showed
1
we have shown that the protein
IA in the presence
These results indicate that the H3 domain of svntaxm enhanced
on to
X-100 extract
with the 7s complex containing synaptotagmin.
its exact role in the release mechanisms
1 to immobilized
synaphin by
OF SYNT4XrN
Niigata University,
Using the squid presynapticterminal.
binding to GST-H3 synaphin
blotted
SAISU, TORU ISHlZlJKA
of Cellular Neurobiology,
histidine-tagged
BlNDS TO THE H3 DOMAIN
of tagmin
were only maJor The binding also bound to GST-tagmin
tagmin and tubulins were coimmunoprecipitated from theTriton against tubulin These results indicate that tagmm directly binds to l.-tubulin
antibody
134
portion
of rat brain. tubulins
tagmin binding. Furthermore,
with a monoclonal
TERUO
is a synaptic
Niigata University.
thought to be a major Caz+ sensor in transmitter release \~a its interaction with syntaxin and SNAP-25 Moreover, it binds other proteins including neurexins and the clathrrn .AP-2. We have found tagmm binds to the cytoskelrtal suggesting that the protein is also involved in other presynapticfunctions protein
I (tagmm)
TO TUBULIN
and SNAP-25
of syntaxin
Synaphin
I A Both bindmgs
the H3 domain was incapable of bindmg for synaphin
bmdmg to syntaxm
binding
suggests that svnaphin
but not
facilitates the formation
vesicle fusion with the presynaptic
TEMPOLARY-DISTINCT INDUCTION OF INITIAL AND LATE PHASES POTENTIATION IN BULLFROG SYMPATHETIC GANGLIA
VAMP-2
was enhanced by synaphin membrane
OF LONG-TERM
K. Fujita, H. Tokuno & K. Kuba’ First Dept. ofPhysiology’
Nagoya Univ. Sch. Med., Nagoya 466-8550. Japan
Fast excitatory postsynaptic potentials (fEPSP) were recorded by an intracellular recording technique in a low Ca:‘. high Mg” solution. The quanta1 content and size of fEPSP were analyzed by a failure or variance method. A short tetanus (50 pulses) of 50 Hz to the preganglionic nerve produced the enhancement of the amplitude and quanta1 content of fEPSP lasting for one to one and half hours. A longer tetanus (50 Hz) of 100 pulses induced two distinct phases of long-term potentiation (LTP). Following the initial potentiation of tEPSP and the subsequent period of no potentiation for 20 to 30 min, the amplitude of fEPSP increased again. This late phase of LTP was accompanied by increases in both quanta1 content and size, and lasted for more than 8 hours. Tetanus of 300 pulses at 50 Hz consistently caused both the initial and late phases of LTP, which were interrupted by a period of no potentiation. Thus, the initial phase of LTP are predominantly induced by an increase in transmitter release from the presynaptic nerve terminals, while the late phase is caused by both the pre- and post-synaptic mechanisms. The initial phase of LTP could be caused by the activation of Ca/calmodulin-dependent protein kinase II and subsequent protein phosphorylation (Minota et al., 1991, J. Physiol 435. 421-438) while the late phase appears to be produced a much slower process, such as protein synthesis