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LTP in hippocampal CA1 region
[[File:LTP.png|thumb|LTP in hippocampal CA1 region Unpublished data.]]
Unpublished data.


Activity-dependent synaptic translocation of AMPA receptor[1]
[[File:Ampa-trafficking.jpg|thumb|Activity-dependent synaptic translocation of AMPA receptor<ref name=ref1 />. AMPA receptor is visualized by tagging it with GFP.]]
AMPA receptor is visualized by tagging it with GFP.


== Protein Trafficking and Long-term Potentiation ==
== Protein Trafficking and Long-term Potentiation ==
When hippocampal neurons fire intensely, the synaptic transmission between the neurons is strengthened for a long-term. This phenomenon is called long-term potentiation (LTP) and is considered as a cellular counterpart of learning and memory. But how synaptic transmission is enhanced for long-term had not been clarified.
When hippocampal neurons fire intensely, the synaptic transmission between the neurons is strengthened for a long-term. This phenomenon is called long-term potentiation (LTP) and is considered as a cellular counterpart of learning and memory. But how synaptic transmission is enhanced for long-term had not been clarified.


We tested a novel hypothesis that LTP induction recruits new AMPA type glutamate receptor molecules to the synapse, thereby increasing the postsynaptic sensitivity to released glutamate. Using both optically and electrophysiologically tagged glutamate receptors, we showed that LTP induction delivers new AMPA receptor molecules to the synapse<ref><pubmed>10364548</pubmed></ref><ref name=ref2>10731148</pubmed></ref><ref><pubmed>11348590</pubmed></ref> [1] [2] [3]. Ca<sup>2+</sup>/calmodulin-dependent protein kinase II (CaMKII) and a putative PDZ domain binding protein are both required for this process. The trafficking is not limited to AMPA receptors. We found multiple proteins are trafficked to the synapse in a temporally ordered fashion<ref name=ref4><pubmed >24742465</pubmed></ref>.
We tested a novel hypothesis that LTP induction recruits new AMPA type glutamate receptor molecules to the synapse, thereby increasing the postsynaptic sensitivity to released glutamate. Using both optically and electrophysiologically tagged glutamate receptors, we showed that LTP induction delivers new AMPA receptor molecules to the synapse<ref name=ref1><pubmed>10364548</pubmed></ref><ref name=ref2><pubmed>10731148</pubmed></ref><ref name=ref3><pubmed>11348590</pubmed></ref>[1] [2] [3]. Ca<sup>2+</sup>/calmodulin-dependent protein kinase II (CaMKII) and a putative PDZ domain binding protein are both required for this process. The trafficking is not limited to AMPA receptors. We found multiple proteins are trafficked to the synapse in a temporally ordered fashion<ref name=ref4><pubmed>24742465</pubmed></ref>.


Instead, it does not require phosphorylation of AMPA receptor itself<ref name=ref2 />[2]. As opposed to the widely prevailing view, the proportion of phosphorylated AMPA receptors is too low to explain synaptic plasticity<ref><pubmed>25533481</pubmed></ref>[5]. Therefore, what triggers AMPA receptor trafficking and what retains the trafficked receptor are still questions to be answered.
Instead, it does not require phosphorylation of AMPA receptor itself<ref name=ref2 />[2]. As opposed to the widely prevailing view, the proportion of phosphorylated AMPA receptors is too low to explain synaptic plasticity<ref name=ref5><pubmed>25533481</pubmed></ref>[5]. Therefore, what triggers AMPA receptor trafficking and what retains the trafficked receptor are still questions to be answered.




Liquid-liquid phase separation of CaMKII<ref name=ref6><pubmed>33927400</pubmed></ref>[6]
[[File:Phase separation.jpg|thumb|Liquid-liquid phase separation of CaMKII<ref name=ref6><pubmed>33927400</pubmed></ref>[6]. Activation of CaMKII induces segregation of NMDA receptors (green) and AMPA receptors (red).]]
Activation of CaMKII induces segregation of NMDA receptors (green) and AMPA receptors (red).


== Liquid-liquid phase separation and synaptic plasticity ==
== Liquid-liquid phase separation and synaptic plasticity ==
Ca2+/calodulin-dependent protein kinase II (CaMKII) is a serine/threonine protein kinase critically involved in synaptic plasticity in the brain<ref name=ref7><pubmed >27207106</pubmed></ref>[7]. It is highly concentrated in the postsynaptic density (PSD) fraction, exceeding the amount of any other signal transduction molecule, almost comparable with cytoskeletal proteins<ref name=ref7 />[7]. Because kinase signaling can be amplified by catalytic reaction, it does not have to exist in such a large quantity. Also CaMKII forms a unique dodecameric structure not seen in other kinases. These remained mysteries.
Ca2+/calodulin-dependent protein kinase II (CaMKII) is a serine/threonine protein kinase critically involved in synaptic plasticity in the brain<ref name=ref7><pubmed>27207106</pubmed></ref>[7]. It is highly concentrated in the postsynaptic density (PSD) fraction, exceeding the amount of any other signal transduction molecule, almost comparable with cytoskeletal proteins<ref name=ref7 />[7]. Because kinase signaling can be amplified by catalytic reaction, it does not have to exist in such a large quantity. Also CaMKII forms a unique dodecameric structure not seen in other kinases. These remained mysteries.


We recently found that Tiam1, an activator of small G-protein Rac, forms a persistent complex with CaMKII<ref><pubmed>31078368</pubmed></ref>[8]. We also found that CaMKII interacts with multiple other proteins and cross-links them together (unpublished). From these results, we speculated that CaMKII may undergo liquid-liquid phase separation, a phenomenon where protein solution is segregated into condensed and diluted phases, like water and oil<ref><pubmed>33472825</pubmed></ref>[9]. CaMKII did not undergo separation in inactive form. However, when activated with Ca2+, CaMKII undergoes phase separation and forms a condensed phase. Furthermore, it triggers the condensation of other proteins as well<ref name=ref6 />[6]. This property of CaMKII may be a mechanism to trigger translocation and accumulation upon induction of LTP<ref><pubmed>33752045</pubmed></ref>[10].
We recently found that Tiam1, an activator of small G-protein Rac, forms a persistent complex with CaMKII<ref name=ref8><pubmed>31078368</pubmed></ref>[8]. We also found that CaMKII interacts with multiple other proteins and cross-links them together (unpublished). From these results, we speculated that CaMKII may undergo liquid-liquid phase separation, a phenomenon where protein solution is segregated into condensed and diluted phases, like water and oil<ref name=ref9><pubmed>33472825</pubmed></ref>[9]. CaMKII did not undergo separation in inactive form. However, when activated with Ca2+, CaMKII undergoes phase separation and forms a condensed phase. Furthermore, it triggers the condensation of other proteins as well<ref name=ref6 />[6]. This property of CaMKII may be a mechanism to trigger translocation and accumulation upon induction of LTP<ref name=ref10><pubmed>33752045</pubmed></ref>[10].


== Molecular Mechanisms of Structural Plasticity of Dendritic Spines ==
== Molecular Mechanisms of Structural Plasticity of Dendritic Spines ==
Synaptic activity also induces postsynaptic structural enlargement of dendritic spines, tiny protrusions on dendrites where synapses are formed <ref name=ref4 /><ref><pubmed>21963169</pubmed></ref><ref><pubmed>15361876</pubmed></ref>[11][12][4](Movie 1). By using a FRET sensor, we found that actin is polymerized rapidly in response to a LTP-inducing stimulation protocol moving the equilibrium towards polymerization <ref><pubmed name=ref13>17406324</pubmed></ref><ref><pubmed>17404223</pubmed></ref>[13] [14]. The change persists notably for at least 30 minutes after the stimulation. The regulation of actin can provide a mechanism for synaptic, activity-dependent delivery of postsynaptic proteins as well as cytoskeletal role.
Synaptic activity also induces postsynaptic structural enlargement of dendritic spines, tiny protrusions on dendrites where synapses are formed <ref name=ref4 /><ref name=ref11><pubmed>15944122</pubmed></ref><ref name=ref12><pubmed>21963169</pubmed></ref>[11][12][4](Movie 1). By using a FRET sensor, we found that actin is polymerized rapidly in response to a LTP-inducing stimulation protocol moving the equilibrium towards polymerization <ref name=ref13><pubmed>15361876</pubmed></ref><ref name=ref14><pubmed>17406324</pubmed></ref>[13] [14]. The change persists notably for at least 30 minutes after the stimulation. The regulation of actin can provide a mechanism for synaptic, activity-dependent delivery of postsynaptic proteins as well as cytoskeletal role.


Among molecules implicated in synaptic plasticity, we found biochemical evidence that CaMKII is capable of bundling F-actin through a stoichiometric interaction<ref><pubmed>26291163</pubmed></ref>[15]. Activation of CaMKII detaches it from F-actin, thereby allowing modification of F-actin during LTP<ref><pubmed>19996366</pubmed></ref>[16]. CaMKII serves as a central molecule with both signaling and structural role in the excitatory synapse<ref name=ref7 /><ref><pubmed>25946002</pubmed></ref>[17][7].
Among molecules implicated in synaptic plasticity, we found biochemical evidence that CaMKII is capable of bundling F-actin through a stoichiometric interaction<ref name=ref15><pubmed>17404223</pubmed></ref>[15]. Activation of CaMKII detaches it from F-actin, thereby allowing modification of F-actin during LTP<ref name=ref16><pubmed>26291163</pubmed></ref>[16]. CaMKII serves as a central molecule with both signaling and structural role in the excitatory synapse<ref name=ref7 /><ref name=ref17><pubmed>19996366</pubmed></ref>[17][7].
 
[[File:3 spines in one - time-25-360.mov|thumb|Structural LTP<ref name=ref4 />[4]
Structural LTP<ref name=ref4 />[4]
When a red dot appears, glutamate is uncaged locally on the tip of the dendritic spine of a neuron expression GFP.]]
When a red dot appears, glutamate is uncaged locally on the tip of the dendritic spine of a neuron expression GFP.
[[File:Actin-polyemerization.jpg|thumb|Actin polymerization and expansion of the dendritic spine<ref name=ref13 />[13]]]
 
[[File:Gating of sLTP by CaMKII.jpg|thumb|Gating of sLTP by CaMKII<ref name=ref16></ref>[16]. Autophosphorylation of CaMKII dissociates it from F-actin, thereby allowing its modification.]]
 
Actin polymerization and expansion of the dendritic spine<ref name=ref13 />[13]
 
 
Gating of sLTP by CaMKII<ref><pubmed>19996366</pubmed></ref>[16]
Autophosphorylation of CaMKII dissociates it from F-actin, thereby allowing its modification.


== Dynamic Behavior of Cellular Memory Engram ==
== Dynamic Behavior of Cellular Memory Engram ==
In the hippocampus, there are neurons that fire when an animal is at a specific position, called place cells. They are considered to encode a memory of the animal’s position. How they are formed and how long they last have not been fully elucidated. In order to address these questions, we set up a virtual reality system where an animal can run through while we observe the hippocampal neuronal activity by using two-photon Ca2+ imaging [18] [19] [20]. The Ca2+-events are automatically detected from images and deduced into spike patterns[21]. Using this approach, we are trying to elucidate the dynamic behavior of cellular memory engram.
In the hippocampus, there are neurons that fire when an animal is at a specific position, called place cells. They are considered to encode a memory of the animal’s position. How they are formed and how long they last have not been fully elucidated. In order to address these questions, we set up a virtual reality system where an animal can run through while we observe the hippocampal neuronal activity by using two-photon Ca2+ imaging<ref name=ref18><pubmed>25946002</pubmed></ref><ref name=ref19><pubmed>28484738</pubmed></ref><ref name=ref20><pubmed>32640229</pubmed></ref> [18] [19] [20]. The Ca2+-events are automatically detected from images and deduced into spike patterns <ref name=ref21><pubmed>21963169</pubmed></ref>[21]. Using this approach, we are trying to elucidate the dynamic behavior of cellular memory engram.


Mouse virtual reality system[19]
Mouse virtual reality system <ref name=ref19><pubmed>28484738</pubmed></ref>[19]


   
   
Line 47: Line 36:


== References ==
== References ==
Shi Science.pdf
Shi, S.H., Hayashi, Y., Petralia, R.S., Zaman, S.H., Wenthold, R.J., Svoboda, K., & Malinow, R. (1999).
Rapid spine delivery and redistribution of AMPA receptors after synaptic NMDA receptor activation. Science (New York, N.Y.), 284(5421), 1811-6. [PubMed:10364548] [WorldCat] [DOI] [Google Scholar]
Hayashi Shi Science.pdf
Hayashi, Y., Shi, S.H., Esteban, J.A., Piccini, A., Poncer, J.C., & Malinow, R. (2000).
Driving AMPA receptors into synapses by LTP and CaMKII: requirement for GluR1 and PDZ domain interaction. Science (New York, N.Y.), 287(5461), 2262-7. [PubMed:10731148] [WorldCat] [DOI] [Google Scholar]
Shi Cell.pdf
Shi, S., Hayashi, Y., Esteban, J.A., & Malinow, R. (2001).
Subunit-specific rules governing AMPA receptor trafficking to synapses in hippocampal pyramidal neurons. Cell, 105(3), 331-43. [PubMed:11348590] [WorldCat] [DOI] [Google Scholar]
Bosch Neuron.pdf
Bosch, M., Castro, J., Saneyoshi, T., Matsuno, H., Sur, M., & Hayashi, Y. (2014).
Structural and molecular remodeling of dendritic spine substructures during long-term potentiation. Neuron, 82(2), 444-59. [PubMed:24742465] [PMC] [WorldCat] [DOI] [Google Scholar]
Hosokawa Neuron.pdf
Hosokawa, T., Mitsushima, D., Kaneko, R., & Hayashi, Y. (2015).
Stoichiometry and phosphoisotypes of hippocampal AMPA-type glutamate receptor phosphorylation. Neuron, 85(1), 60-67. [PubMed:25533481] [PMC] [WorldCat] [DOI] [Google Scholar]
Hosokawa Liu Nat Neurosci 2021.pdf
Hosokawa, T., Liu, P.W., Cai, Q., Ferreira, J.S., Levet, F., Butler, C., Sibarita, J.B., Choquet, D., Groc, L., Hosy, E., Zhang, M., & Hayashi, Y. (2021).
CaMKII activation persistently segregates postsynaptic proteins via liquid phase separation. Nature neuroscience, 24(6), 777-785. [PubMed:33927400] [WorldCat] [DOI] [Google Scholar]
Kim Neuron.pdf
Kim, K., Saneyoshi, T., Hosokawa, T., Okamoto, K., & Hayashi, Y. (2016).
Interplay of enzymatic and structural functions of CaMKII in long-term potentiation. Journal of neurochemistry, 139(6), 959-972. [PubMed:27207106] [WorldCat] [DOI] [Google Scholar]
Saneyoshi Neuron 2019.pdf
Saneyoshi, T., Matsuno, H., Suzuki, A., Murakoshi, H., Hedrick, N.G., Agnello, E., O'Connell, R., Stratton, M.M., Yasuda, R., & Hayashi, Y. (2019).
Reciprocal Activation within a Kinase-Effector Complex Underlying Persistence of Structural LTP. Neuron, 102(6), 1199-1210.e6. [PubMed:31078368] [PMC] [WorldCat] [DOI] [Google Scholar]
Hayashi J Neurosci 2021.pdf
Hayashi, Y., Ford, L.K., Fioriti, L., McGurk, L., & Zhang, M. (2021).
Liquid-Liquid Phase Separation in Physiology and Pathophysiology of the Nervous System. The Journal of neuroscience : the official journal of the Society for Neuroscience, 41(5), 834-844. [PubMed:33472825] [PMC] [WorldCat] [DOI] [Google Scholar]
Liu Curr Opin Neurobiol 2021.pdf
Liu, P.W., Hosokawa, T., & Hayashi, Y. (2021).
Regulation of synaptic nanodomain by liquid-liquid phase separation: A novel mechanism of synaptic plasticity. Current opinion in neurobiology, 69, 84-92. [PubMed:33752045] [WorldCat] [DOI] [Google Scholar]
Hayashi Neuron.pdf
Hayashi, Y., & Majewska, A.K. (2005).
Dendritic spine geometry: functional implication and regulation. Neuron, 46(4), 529-32. [PubMed:15944122] [WorldCat] [DOI] [Google Scholar]
Bosch, M., & Hayashi, Y. (2012).
Structural plasticity of dendritic spines. Current opinion in neurobiology, 22(3), 383-8. [PubMed:21963169] [PMC] [WorldCat] [DOI] [Google Scholar]
Okamoto Nat Neurosci.pdf
Okamoto, K., Nagai, T., Miyawaki, A., & Hayashi, Y. (2004).
Rapid and persistent modulation of actin dynamics regulates postsynaptic reorganization underlying bidirectional plasticity. Nature neuroscience, 7(10), 1104-12. [PubMed:15361876] [WorldCat] [DOI] [Google Scholar]
Okamoto Nat Protoc.pdf
Okamoto, K., & Hayashi, Y. (2006).
Visualization of F-actin and G-actin equilibrium using fluorescence resonance energy transfer (FRET) in cultured cells and neurons in slices. Nature protocols, 1(2), 911-9. [PubMed:17406324] [WorldCat] [DOI] [Google Scholar]
Okamoto Proc Natl Acad Sci USA.pdf
Okamoto, K., Narayanan, R., Lee, S.H., Murata, K., & Hayashi, Y. (2007).
The role of CaMKII as an F-actin-bundling protein crucial for maintenance of dendritic spine structure. Proceedings of the National Academy of Sciences of the United States of America, 104(15), 6418-23. [PubMed:17404223] [PMC] [WorldCat] [DOI] [Google Scholar]
Kim Neuron.pdf
Kim, K., Lakhanpal, G., Lu, H.E., Khan, M., Suzuki, A., Hayashi, M.K., Narayanan, R., Luyben, T.T., Matsuda, T., Nagai, T., Blanpied, T.A., Hayashi, Y., & Okamoto, K. (2015).
A Temporary Gating of Actin Remodeling during Synaptic Plasticity Consists of the Interplay between the Kinase and Structural Functions of CaMKII. Neuron, 87(4), 813-26. [PubMed:26291163] [PMC] [WorldCat] [DOI] [Google Scholar]
Okamoto Physiol.pdf
Okamoto, K., Bosch, M., & Hayashi, Y. (2009).
The roles of CaMKII and F-actin in the structural plasticity of dendritic spines: a potential molecular identity of a synaptic tag? Physiology (Bethesda, Md.), 24, 357-66. [PubMed:19996366] [WorldCat] [DOI] [Google Scholar]
Sato PLOS One.pdf
Sato, M., Kawano, M., Ohkura, M., Gengyo-Ando, K., Nakai, J., & Hayashi, Y. (2015).
Generation and Imaging of Transgenic Mice that Express G-CaMP7 under a Tetracycline Response Element. PloS one, 10(5), e0125354. [PubMed:25946002] [PMC] [WorldCat] [DOI] [Google Scholar]
Sato eNeuro.pdf
Sato, M., Kawano, M., Mizuta, K., Islam, T., Lee, M.G., & Hayashi, Y. (2017).
Hippocampus-Dependent Goal Localization by Head-Fixed Mice in Virtual Reality. eNeuro, 4(3). [PubMed:28484738] [PMC] [WorldCat] [DOI] [Google Scholar]
Sato Mizuta Cell Rep 2020.pdf
Sato, M., Mizuta, K., Islam, T., Kawano, M., Sekine, Y., Takekawa, T., Gomez-Dominguez, D., Schmidt, A., Wolf, F., Kim, K., Yamakawa, H., Ohkura, M., Lee, M.G., Fukai, T., Nakai, J., & Hayashi, Y. (2020).
Distinct Mechanisms of Over-Representation of Landmarks and Rewards in the Hippocampus. Cell reports, 32(1), 107864. [PubMed:32640229] [PMC] [WorldCat] [DOI] [Google Scholar]
Takekawa bioRxiv.pdf
Takekawa, T., Asai, H., Ohkawa, N., Nomoto, M., Okubo-Suzuki, R., Ghandour, K., Sato, M., Hayashi, Y., Inokuchi, K., Fukai, T.
Automatic sorting system for large calcium imaging data
bioRxiv, 2017 [DOI][Google Scholar]

Latest revision as of 01:07, 24 March 2025

LTP in hippocampal CA1 region Unpublished data.
Activity-dependent synaptic translocation of AMPA receptor[1]. AMPA receptor is visualized by tagging it with GFP.

Protein Trafficking and Long-term Potentiation

When hippocampal neurons fire intensely, the synaptic transmission between the neurons is strengthened for a long-term. This phenomenon is called long-term potentiation (LTP) and is considered as a cellular counterpart of learning and memory. But how synaptic transmission is enhanced for long-term had not been clarified.

We tested a novel hypothesis that LTP induction recruits new AMPA type glutamate receptor molecules to the synapse, thereby increasing the postsynaptic sensitivity to released glutamate. Using both optically and electrophysiologically tagged glutamate receptors, we showed that LTP induction delivers new AMPA receptor molecules to the synapse[1][2][3][1] [2] [3]. Ca2+/calmodulin-dependent protein kinase II (CaMKII) and a putative PDZ domain binding protein are both required for this process. The trafficking is not limited to AMPA receptors. We found multiple proteins are trafficked to the synapse in a temporally ordered fashion[4].

Instead, it does not require phosphorylation of AMPA receptor itself[2][2]. As opposed to the widely prevailing view, the proportion of phosphorylated AMPA receptors is too low to explain synaptic plasticity[5][5]. Therefore, what triggers AMPA receptor trafficking and what retains the trafficked receptor are still questions to be answered.


Liquid-liquid phase separation of CaMKII[6][6]. Activation of CaMKII induces segregation of NMDA receptors (green) and AMPA receptors (red).

Liquid-liquid phase separation and synaptic plasticity

Ca2+/calodulin-dependent protein kinase II (CaMKII) is a serine/threonine protein kinase critically involved in synaptic plasticity in the brain[7][7]. It is highly concentrated in the postsynaptic density (PSD) fraction, exceeding the amount of any other signal transduction molecule, almost comparable with cytoskeletal proteins[7][7]. Because kinase signaling can be amplified by catalytic reaction, it does not have to exist in such a large quantity. Also CaMKII forms a unique dodecameric structure not seen in other kinases. These remained mysteries.

We recently found that Tiam1, an activator of small G-protein Rac, forms a persistent complex with CaMKII[8][8]. We also found that CaMKII interacts with multiple other proteins and cross-links them together (unpublished). From these results, we speculated that CaMKII may undergo liquid-liquid phase separation, a phenomenon where protein solution is segregated into condensed and diluted phases, like water and oil[9][9]. CaMKII did not undergo separation in inactive form. However, when activated with Ca2+, CaMKII undergoes phase separation and forms a condensed phase. Furthermore, it triggers the condensation of other proteins as well[6][6]. This property of CaMKII may be a mechanism to trigger translocation and accumulation upon induction of LTP[10][10].

Molecular Mechanisms of Structural Plasticity of Dendritic Spines

Synaptic activity also induces postsynaptic structural enlargement of dendritic spines, tiny protrusions on dendrites where synapses are formed [4][11][12][11][12][4](Movie 1). By using a FRET sensor, we found that actin is polymerized rapidly in response to a LTP-inducing stimulation protocol moving the equilibrium towards polymerization [13][14][13] [14]. The change persists notably for at least 30 minutes after the stimulation. The regulation of actin can provide a mechanism for synaptic, activity-dependent delivery of postsynaptic proteins as well as cytoskeletal role.

Among molecules implicated in synaptic plasticity, we found biochemical evidence that CaMKII is capable of bundling F-actin through a stoichiometric interaction[15][15]. Activation of CaMKII detaches it from F-actin, thereby allowing modification of F-actin during LTP[16][16]. CaMKII serves as a central molecule with both signaling and structural role in the excitatory synapse[7][17][17][7]. File:3 spines in one - time-25-360.mov

Actin polymerization and expansion of the dendritic spine[13][13]
Gating of sLTP by CaMKII[16][16]. Autophosphorylation of CaMKII dissociates it from F-actin, thereby allowing its modification.

Dynamic Behavior of Cellular Memory Engram

In the hippocampus, there are neurons that fire when an animal is at a specific position, called place cells. They are considered to encode a memory of the animal’s position. How they are formed and how long they last have not been fully elucidated. In order to address these questions, we set up a virtual reality system where an animal can run through while we observe the hippocampal neuronal activity by using two-photon Ca2+ imaging[18][19][20] [18] [19] [20]. The Ca2+-events are automatically detected from images and deduced into spike patterns [21][21]. Using this approach, we are trying to elucidate the dynamic behavior of cellular memory engram.

Mouse virtual reality system [19][19]


Hippocampal Ca2+-events from behaving mouse

References

  1. 1.0 1.1 Shi, S.H., Hayashi, Y., Petralia, R.S., Zaman, S.H., Wenthold, R.J., Svoboda, K., & Malinow, R. (1999).
    Rapid spine delivery and redistribution of AMPA receptors after synaptic NMDA receptor activation. Science (New York, N.Y.), 284(5421), 1811-6. [PubMed:10364548] [WorldCat] [DOI]
  2. 2.0 2.1 Hayashi, Y., Shi, S.H., Esteban, J.A., Piccini, A., Poncer, J.C., & Malinow, R. (2000).
    Driving AMPA receptors into synapses by LTP and CaMKII: requirement for GluR1 and PDZ domain interaction. Science (New York, N.Y.), 287(5461), 2262-7. [PubMed:10731148] [WorldCat] [DOI]
  3. Shi, S., Hayashi, Y., Esteban, J.A., & Malinow, R. (2001).
    Subunit-specific rules governing AMPA receptor trafficking to synapses in hippocampal pyramidal neurons. Cell, 105(3), 331-43. [PubMed:11348590] [WorldCat] [DOI]
  4. 4.0 4.1 4.2 Bosch, M., Castro, J., Saneyoshi, T., Matsuno, H., Sur, M., & Hayashi, Y. (2014).
    Structural and molecular remodeling of dendritic spine substructures during long-term potentiation. Neuron, 82(2), 444-59. [PubMed:24742465] [PMC] [WorldCat] [DOI]
  5. Hosokawa, T., Mitsushima, D., Kaneko, R., & Hayashi, Y. (2015).
    Stoichiometry and phosphoisotypes of hippocampal AMPA-type glutamate receptor phosphorylation. Neuron, 85(1), 60-67. [PubMed:25533481] [PMC] [WorldCat] [DOI]
  6. 6.0 6.1 Hosokawa, T., Liu, P.W., Cai, Q., Ferreira, J.S., Levet, F., Butler, C., Sibarita, J.B., Choquet, D., Groc, L., Hosy, E., Zhang, M., & Hayashi, Y. (2021).
    CaMKII activation persistently segregates postsynaptic proteins via liquid phase separation. Nature neuroscience, 24(6), 777-785. [PubMed:33927400] [WorldCat] [DOI]
  7. 7.0 7.1 7.2 Kim, K., Saneyoshi, T., Hosokawa, T., Okamoto, K., & Hayashi, Y. (2016).
    Interplay of enzymatic and structural functions of CaMKII in long-term potentiation. Journal of neurochemistry, 139(6), 959-972. [PubMed:27207106] [WorldCat] [DOI]
  8. Saneyoshi, T., Matsuno, H., Suzuki, A., Murakoshi, H., Hedrick, N.G., Agnello, E., O'Connell, R., Stratton, M.M., Yasuda, R., & Hayashi, Y. (2019).
    Reciprocal Activation within a Kinase-Effector Complex Underlying Persistence of Structural LTP. Neuron, 102(6), 1199-1210.e6. [PubMed:31078368] [PMC] [WorldCat] [DOI]
  9. Hayashi, Y., Ford, L.K., Fioriti, L., McGurk, L., & Zhang, M. (2021).
    Liquid-Liquid Phase Separation in Physiology and Pathophysiology of the Nervous System. The Journal of neuroscience : the official journal of the Society for Neuroscience, 41(5), 834-844. [PubMed:33472825] [PMC] [WorldCat] [DOI]
  10. Liu, P.W., Hosokawa, T., & Hayashi, Y. (2021).
    Regulation of synaptic nanodomain by liquid-liquid phase separation: A novel mechanism of synaptic plasticity. Current opinion in neurobiology, 69, 84-92. [PubMed:33752045] [WorldCat] [DOI]
  11. Hayashi, Y., & Majewska, A.K. (2005).
    Dendritic spine geometry: functional implication and regulation. Neuron, 46(4), 529-32. [PubMed:15944122] [WorldCat] [DOI]
  12. Bosch, M., & Hayashi, Y. (2012).
    Structural plasticity of dendritic spines. Current opinion in neurobiology, 22(3), 383-8. [PubMed:21963169] [PMC] [WorldCat] [DOI]
  13. 13.0 13.1 Okamoto, K., Nagai, T., Miyawaki, A., & Hayashi, Y. (2004).
    Rapid and persistent modulation of actin dynamics regulates postsynaptic reorganization underlying bidirectional plasticity. Nature neuroscience, 7(10), 1104-12. [PubMed:15361876] [WorldCat] [DOI]
  14. Okamoto, K., & Hayashi, Y. (2006).
    Visualization of F-actin and G-actin equilibrium using fluorescence resonance energy transfer (FRET) in cultured cells and neurons in slices. Nature protocols, 1(2), 911-9. [PubMed:17406324] [WorldCat] [DOI]
  15. Okamoto, K., Narayanan, R., Lee, S.H., Murata, K., & Hayashi, Y. (2007).
    The role of CaMKII as an F-actin-bundling protein crucial for maintenance of dendritic spine structure. Proceedings of the National Academy of Sciences of the United States of America, 104(15), 6418-23. [PubMed:17404223] [PMC] [WorldCat] [DOI]
  16. 16.0 16.1 Kim, K., Lakhanpal, G., Lu, H.E., Khan, M., Suzuki, A., Hayashi, M.K., Narayanan, R., Luyben, T.T., Matsuda, T., Nagai, T., Blanpied, T.A., Hayashi, Y., & Okamoto, K. (2015).
    A Temporary Gating of Actin Remodeling during Synaptic Plasticity Consists of the Interplay between the Kinase and Structural Functions of CaMKII. Neuron, 87(4), 813-26. [PubMed:26291163] [PMC] [WorldCat] [DOI]
  17. Okamoto, K., Bosch, M., & Hayashi, Y. (2009).
    The roles of CaMKII and F-actin in the structural plasticity of dendritic spines: a potential molecular identity of a synaptic tag? Physiology (Bethesda, Md.), 24, 357-66. [PubMed:19996366] [WorldCat] [DOI]
  18. Sato, M., Kawano, M., Ohkura, M., Gengyo-Ando, K., Nakai, J., & Hayashi, Y. (2015).
    Generation and Imaging of Transgenic Mice that Express G-CaMP7 under a Tetracycline Response Element. PloS one, 10(5), e0125354. [PubMed:25946002] [PMC] [WorldCat] [DOI]
  19. 19.0 19.1 Sato, M., Kawano, M., Mizuta, K., Islam, T., Lee, M.G., & Hayashi, Y. (2017).
    Hippocampus-Dependent Goal Localization by Head-Fixed Mice in Virtual Reality. eNeuro, 4(3). [PubMed:28484738] [PMC] [WorldCat] [DOI]
  20. Sato, M., Mizuta, K., Islam, T., Kawano, M., Sekine, Y., Takekawa, T., Gomez-Dominguez, D., Schmidt, A., Wolf, F., Kim, K., Yamakawa, H., Ohkura, M., Lee, M.G., Fukai, T., Nakai, J., & Hayashi, Y. (2020).
    Distinct Mechanisms of Over-Representation of Landmarks and Rewards in the Hippocampus. Cell reports, 32(1), 107864. [PubMed:32640229] [PMC] [WorldCat] [DOI]
  21. Bosch, M., & Hayashi, Y. (2012).
    Structural plasticity of dendritic spines. Current opinion in neurobiology, 22(3), 383-8. [PubMed:21963169] [PMC] [WorldCat] [DOI]
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