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calmodulin-dependent protein kinase II in relation to continuous seizure activity
S123
186
VISUALIZATION OF CaMKII ACTIVITY IN THE CYTOPLASM, AND PLASMA MEMBRANE
NAOYUKI INAGAKI’*2, MIWAKO NISHIZAWA’, MIYAMOTO’, A!!D MASAKI INAGAKI’
HIDEYUKI
YAMAMOTD3,
NUCLEUS,
YUSUKE
TAKEUCH13,
EISHICHI
‘Lab. of Biochem., Aichi Cancer Center Res. Inst., Chikusa-ku, Nagoya 464-0021, 2Division of Signal Transduction, Nara Inst. of Science and Technol., Ikoma 630-0101, “Dept. of Pharmacology, Kumamoto Univ. School of Med., Kumamoto 860 Cell signaling is the fundamental strategy by which cells respond to extracellular stimuli and protein kinases play central roles in this process. In general, activation of protein kinases has been analyzed as a whole cell event, because their activities were mostly measured using cell homogenate. However, it has become mcreasingly recognized that Intracellular localization of protein kinase activities is an important factor in conferring specificity and diversity to their signaling networks. Therefore, to unravel the complicated signaling network of protein kinases, it is important to analyze their activity at distinct intracellular sites. The head domain of a cytoskeletal protein vimentin contains a number of phosphorylation sites including Ser82 which is phosphorylated by Ca2+/calmodulin-dependent protein kinase II (CaMKII) in vivo. The vimentin head domains (VHs) fused with targeting srgnal peptides were expressed in the cytoplasm, plasma membrane, and nucleus of 293 cells. Immunocytochemistry and immunoblot using a site- and phosphorylation-specific antibody MO82 detected VH Ser82 phosphorylations in the cytoplasm, plasma membrane, and nucleus of Ca 2+-stimulated 2Y3 cells. Inhibitor studies and analysis of phosphorylation site specificity confirmed that the VH phosphorylations at Ser82 were induced bv activated CaMKII. Thus, targetable VHs and the antibody MO82 provide a useful tool for investigating CaMKII signaling in subcellular compartments.
187
CA2+/CALMODULlN-DEPENDENT
PROTEIN KINASE II IN RELATION
TO CONTINUOUS
SEIZURE ACTIVITY
YOKO YAMAGATA, Lab. Neurochem,
KUNIHIKO OBATA
Natl. Inst. for Physiol. Sci., Myodaiji,
Ca2+/calmodulin-dependent synaptic plasticity.
Okazaki, 444, Japan
protein kinase II (C&I kinase II) has been implicated in various neuronal functions including
We have been studying its active state in relation to neuronal activity in r,ivo. We previously reported
that acute neuronal excitation induced by electroconvulsive autophosphorylated
treatment in rats caused a transient decrease in the activated,
state of CaM kinase II. In this study, we examined the effect of continuous
by systemic injection of kainic acid into rats. In homogenate after the onset of status epilepticus,
from hippocampus
a profound decrease was observed not only in the Ca2+/calmodulin-independent
activity but also in the total activity of CaM kinase II. We also observed translocation to the particulate fraction.
seizure activity induced
and parietal cortex obtained 30-60 min
of CaM kinase II from the soluble
Thus, continuous seizure activity has profound effect on the active state of CaM kinase II,
which may be related to irreversible neuronal changes associated with continuous seizure activity.
CITRON, A RHO-TARGET,
188
AT GLUTAMATERGIC
TOMOYUKI FURUYASHIKI’,
INTERACTS
SYNAPSES
KAZUKO
WITH PSD-95
IN THE THALAMUS
FUJISAWA’.
AKIKO FUJITA’,
PASCAL MADAULE’.
SHOKO
KIKUMURA’, SHIGEO UCHINO?, MASAYOSHI MISHINA’. HARUHIKO BITO’ and SHUH NARUMNA’ ‘Dept. of Phamacology. Kyoto Univ. Graduate School of Med., ‘Mitsubishi Chemical Corp.. ‘Dept. of Molecular Neurobiology
and Pharmacology,
Tokyo Univ. School of Med.
Proteins of the MAGUK family have recently been shown to be involved in the anchoring and clustering synapses. However, relatively little is known as to whether these multifunctional site for activity-dependent a Rho-effector
and cell type-specific
in the brain, colocalizes
control of the postsynaptic
at many central
scaffold proteins might provide a privileged
signaling machinery.
Here. WC show that Citron,
and associates with PSD-95 both in vivo and in vitro. Elevated Citron expression
found in a predominat population of thalamic excitatory neurons, but not in the principal neurons of the hippocdmpus cerebellum
of the adult mouse brain. Furthermore,
was demonstrated.
a complex consisting
and the
of Citron, PSD-95 and NMDA receptor subunits
Thus Citron may provide a link hetween the Rho signaling cascade and the NMDA receptor-dependent
signaling complex in the thalamus.
was
186
VISUALIZATION OF CaMKII ACTIVITY IN THE CYTOPLASM, AND PLASMA MEMBRANE
NAOYUKI INAGAKI’*2, MIWAKO NISHIZAWA’, MIYAMOTO’, A!!D MASAKI INAGAKI’
HIDEYUKI
YAMAMOTD3,
NUCLEUS,
YUSUKE
TAKEUCH13,
EISHICHI
‘Lab. of Biochem., Aichi Cancer Center Res. Inst., Chikusa-ku, Nagoya 464-0021, 2Division of Signal Transduction, Nara Inst. of Science and Technol., Ikoma 630-0101, “Dept. of Pharmacology, Kumamoto Univ. School of Med., Kumamoto 860 Cell signaling is the fundamental strategy by which cells respond to extracellular stimuli and protein kinases play central roles in this process. In general, activation of protein kinases has been analyzed as a whole cell event, because their activities were mostly measured using cell homogenate. However, it has become mcreasingly recognized that Intracellular localization of protein kinase activities is an important factor in conferring specificity and diversity to their signaling networks. Therefore, to unravel the complicated signaling network of protein kinases, it is important to analyze their activity at distinct intracellular sites. The head domain of a cytoskeletal protein vimentin contains a number of phosphorylation sites including Ser82 which is phosphorylated by Ca2+/calmodulin-dependent protein kinase II (CaMKII) in vivo. The vimentin head domains (VHs) fused with targeting srgnal peptides were expressed in the cytoplasm, plasma membrane, and nucleus of 293 cells. Immunocytochemistry and immunoblot using a site- and phosphorylation-specific antibody MO82 detected VH Ser82 phosphorylations in the cytoplasm, plasma membrane, and nucleus of Ca 2+-stimulated 2Y3 cells. Inhibitor studies and analysis of phosphorylation site specificity confirmed that the VH phosphorylations at Ser82 were induced bv activated CaMKII. Thus, targetable VHs and the antibody MO82 provide a useful tool for investigating CaMKII signaling in subcellular compartments.
187
CA2+/CALMODULlN-DEPENDENT
PROTEIN KINASE II IN RELATION
TO CONTINUOUS
SEIZURE ACTIVITY
YOKO YAMAGATA, Lab. Neurochem,
KUNIHIKO OBATA
Natl. Inst. for Physiol. Sci., Myodaiji,
Ca2+/calmodulin-dependent synaptic plasticity.
Okazaki, 444, Japan
protein kinase II (C&I kinase II) has been implicated in various neuronal functions including
We have been studying its active state in relation to neuronal activity in r,ivo. We previously reported
that acute neuronal excitation induced by electroconvulsive autophosphorylated
treatment in rats caused a transient decrease in the activated,
state of CaM kinase II. In this study, we examined the effect of continuous
by systemic injection of kainic acid into rats. In homogenate after the onset of status epilepticus,
from hippocampus
a profound decrease was observed not only in the Ca2+/calmodulin-independent
activity but also in the total activity of CaM kinase II. We also observed translocation to the particulate fraction.
seizure activity induced
and parietal cortex obtained 30-60 min
of CaM kinase II from the soluble
Thus, continuous seizure activity has profound effect on the active state of CaM kinase II,
which may be related to irreversible neuronal changes associated with continuous seizure activity.
CITRON, A RHO-TARGET,
188
AT GLUTAMATERGIC
TOMOYUKI FURUYASHIKI’,
INTERACTS
SYNAPSES
KAZUKO
WITH PSD-95
IN THE THALAMUS
FUJISAWA’.
AKIKO FUJITA’,
PASCAL MADAULE’.
SHOKO
KIKUMURA’, SHIGEO UCHINO?, MASAYOSHI MISHINA’. HARUHIKO BITO’ and SHUH NARUMNA’ ‘Dept. of Phamacology. Kyoto Univ. Graduate School of Med., ‘Mitsubishi Chemical Corp.. ‘Dept. of Molecular Neurobiology
and Pharmacology,
Tokyo Univ. School of Med.
Proteins of the MAGUK family have recently been shown to be involved in the anchoring and clustering synapses. However, relatively little is known as to whether these multifunctional site for activity-dependent a Rho-effector
and cell type-specific
in the brain, colocalizes
control of the postsynaptic
at many central
scaffold proteins might provide a privileged
signaling machinery.
Here. WC show that Citron,
and associates with PSD-95 both in vivo and in vitro. Elevated Citron expression
found in a predominat population of thalamic excitatory neurons, but not in the principal neurons of the hippocdmpus cerebellum
of the adult mouse brain. Furthermore,
was demonstrated.
a complex consisting
and the
of Citron, PSD-95 and NMDA receptor subunits
Thus Citron may provide a link hetween the Rho signaling cascade and the NMDA receptor-dependent
signaling complex in the thalamus.
was