Updated on 2026/04/28

写真a

 
SANEYOSHI TAKEO
 
Organization
School of Life Science and Technology Professor
Title
Professor
External link

Degree

  • 博士(医学) ( 東京大学 )

Research Areas

  • Life Science / Neuroscience-general

Research History

  • Institute of Science Tokyo   School of Life Science and Technology   Professor

    2024.4

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Papers

  • Transient Photoactivation of Rac1 Induces Persistent Structural LTP Independent of CaMKII in Hippocampal Dendritic Spines. Reviewed International journal

    Takeo Saneyoshi, Chisato Suematsu, Yasunori Hayashi

    eNeuro   2025.11

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    Structural changes in dendritic spines underlie long-term potentiation (LTP). While CaMKII has been considered as the primary driver of these changes, we show that transient, localized activation of Rac1 alone is sufficient to induce structural LTP in hippocampal slices prepared from rat pups of either sex. Using photoactivatable Rac1 (PA-Rac1), we demonstrated that Rac1 activation triggers spine enlargement and actin polymerization. This PA-Rac1-induced plasticity was blocked by Rac1 and Pak1 inhibitors but not by a CaMKII inhibitor. Our results identify Rac1 as an upstream of persistent signaling that stabilizes actin-based spine structural changes critical for synaptic memory encoding.Significance Statement The molecular mechanisms that trigger persistent structural long-term potentiation (sLTP) at synapses remain incompletely understood. This study demonstrated that localized activation of Rac1, a small GTPase regulating actin dynamics, is sufficient to induce and maintain sLTP in hippocampal neurons independently of CaMKII. Using two-photon photoactivation and fluorescence lifetime imaging microscopy (FLIM), we show that Rac1 induces persistent spine growth and actin polymerization. These findings identify Rac1 as a self-sustaining signaling module in synaptic plasticity and provide mechanistic insight into the biochemical encoding of long-lasting synaptic changes that underlie memory.

    DOI: 10.1523/ENEURO.0263-25.2025

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  • Neural computation in the mammalian hippocampus

    Timon Kunze, Alessandro Treves

    2025

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  • Structural plasticity of dendritic spines Reviewed

    Takeo Saneyoshi, Yasunori Hayashi

    Learning and Memory: A Comprehensive Reference   399 - 405   2025

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    Publishing type:Part of collection (book)   Publisher:Elsevier  

    DOI: 10.1016/b978-0-443-15754-7.00059-6

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  • Molecular Mechanisms Underlying Synaptic Tagging and Consolidation

    Yasunori Hayashi, Miquel Bosch, Pin-Wu Liu, Tomohisa Hosokawa, Takeo Saneyoshi

    Synaptic Tagging and Capture   63 - 76   2024.4

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    Publishing type:Part of collection (book)   Publisher:Springer International Publishing  

    DOI: 10.1007/978-3-031-54864-2_3

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  • FAM81A is a postsynaptic protein that regulates the condensation of postsynaptic proteins via liquid-liquid phase separation. International journal

    Takeshi Kaizuka, Taisei Hirouchi, Takeo Saneyoshi, Toshihiko Shirafuji, Mark O Collins, Seth G N Grant, Yasunori Hayashi, Toru Takumi

    PLoS biology   22 ( 3 )   e3002006   2024.3

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    Proteome analyses of the postsynaptic density (PSD), a proteinaceous specialization beneath the postsynaptic membrane of excitatory synapses, have identified several thousands of proteins. While proteins with predictable functions have been well studied, functionally uncharacterized proteins are mostly overlooked. In this study, we conducted a comprehensive meta-analysis of 35 PSD proteome datasets, encompassing a total of 5,869 proteins. Employing a ranking methodology, we identified 97 proteins that remain inadequately characterized. From this selection, we focused our detailed analysis on the highest-ranked protein, FAM81A. FAM81A interacts with PSD proteins, including PSD-95, SynGAP, and NMDA receptors, and promotes liquid-liquid phase separation of those proteins in cultured cells or in vitro. Down-regulation of FAM81A in cultured neurons causes a decrease in the size of PSD-95 puncta and the frequency of neuronal firing. Our findings suggest that FAM81A plays a crucial role in facilitating the interaction and assembly of proteins within the PSD, and its presence is important for maintaining normal synaptic function. Additionally, our methodology underscores the necessity for further characterization of numerous synaptic proteins that still lack comprehensive understanding.

    DOI: 10.1371/journal.pbio.3002006

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  • Imaging of Structural Plasticity of Dendritic Spines with Two-Photon Microscopy. International journal

    Takeo Saneyoshi, Yasunori Hayashi

    Methods in molecular biology (Clifton, N.J.)   2831   209 - 217   2024

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    Plasticity of synaptic transmission underlies learning and memory. It is accompanied by changes in the density and size of synapses, collectively called structural plasticity. Therefore, understanding the mechanism of structural plasticity is critical for understanding the mechanism of synaptic plasticity. In this chapter, we describe the procedures and equipment required to image structural plasticity of a single dendritic spine, which hosts excitatory synapses in the central nervous system, and underlying molecular interactions/biochemical reactions using two-photon fluorescence lifetime microscopy (2P-FLIM) in combination with Förster resonance energy transfer (FRET)-based biosensors.

    DOI: 10.1007/978-1-0716-3969-6_14

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  • Engineering memory with an extrinsically disordered kinase. Reviewed International journal

    Cristian Ripoli, Onur Dagliyan, Pietro Renna, Francesco Pastore, Fabiola Paciello, Raimondo Sollazzo, Marco Rinaudo, Martina Battistoni, Sara Martini, Antonella Tramutola, Andrea Sattin, Eugenio Barone, Takeo Saneyoshi, Tommaso Fellin, Yasunori Hayashi, Claudio Grassi

    Science advances   9 ( 46 )   eadh1110   2023.11

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    Synaptic plasticity plays a crucial role in memory formation by regulating the communication between neurons. Although actin polymerization has been linked to synaptic plasticity and dendritic spine stability, the causal link between actin polymerization and memory encoding has not been identified yet. It is not clear whether actin polymerization and structural changes in dendritic spines are a driver or a consequence of learning and memory. Using an extrinsically disordered form of the protein kinase LIMK1, which rapidly and precisely acts on ADF/cofilin, a direct modifier of actin, we induced long-term enlargement of dendritic spines and enhancement of synaptic transmission in the hippocampus on command. The activation of extrinsically disordered LIMK1 in vivo improved memory encoding and slowed cognitive decline in aged mice exhibiting reduced cofilin phosphorylation. The engineered memory by an extrinsically disordered LIMK1 supports a direct causal link between actin-mediated synaptic transmission and memory.

    DOI: 10.1126/sciadv.adh1110

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  • アクチン細胞骨格の生物学・疾患における多面性と普遍性 樹状突起スパイン内部のコフィリンは液-液相分離によって分子活性のグラディエントを形成する

    実吉 岳郎, 林 康紀, リポリ・クリスチャン, 末松 千咲音

    日本生化学会大会プログラム・講演要旨集   96回   [1S08e - 02]   2023.10

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    Language:Japanese   Publisher:(公社)日本生化学会  

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  • Changing the size of dendritic spines. International journal

    Takeo Saneyoshi

    eLife   12   2023.9

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    Interactions between an enzyme kinase, an ion channel and cytoskeletal proteins maintain the structure of synapses involved in memory formation.

    DOI: 10.7554/eLife.91566

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  • CaMKII binds both substrates and activators at the active site. Reviewed International journal

    Can Özden, Roman Sloutsky, Tomohiro Mitsugi, Nicholas Santos, Emily Agnello, Christl Gaubitz, Joshua Foster, Emily Lapinskas, Edward A Esposito, Takeo Saneyoshi, Brian A Kelch, Scott C Garman, Yasunori Hayashi, Margaret M Stratton

    Cell reports   40 ( 2 )   111064 - 111064   2022.7

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    Ca2+/calmodulin-dependent protein kinase II (CaMKII) is a signaling protein required for long-term memory. When activated by Ca2+/CaM, it sustains activity even after the Ca2+ dissipates. In addition to the well-known autophosphorylation-mediated mechanism, interaction with specific binding partners also persistently activates CaMKII. A long-standing model invokes two distinct S and T sites. If an interactor binds at the T-site, then it will preclude autoinhibition and allow substrates to be phosphorylated at the S site. Here, we specifically test this model with X-ray crystallography, molecular dynamics simulations, and biochemistry. Our data are inconsistent with this model. Co-crystal structures of four different activators or substrates show that they all bind to a single continuous site across the kinase domain. We propose a mechanistic model where persistent CaMKII activity is facilitated by high-affinity binding partners that kinetically compete with autoinhibition by the regulatory segment to allow substrate phosphorylation.

    DOI: 10.1016/j.celrep.2022.111064

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  • Shootin1a-mediated actin-adhesion coupling generates force to trigger structural plasticity of dendritic spines. Reviewed International journal

    Ria Fajarwati Kastian, Takunori Minegishi, Kentarou Baba, Takeo Saneyoshi, Hiroko Katsuno-Kambe, Singh Saranpal, Yasunori Hayashi, Naoyuki Inagaki

    Cell reports   35 ( 7 )   109130 - 109130   2021.5

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    Dendritic spines constitute the major compartments of excitatory post-synapses. They undergo activity-dependent enlargement, which is thought to increase the synaptic efficacy underlying learning and memory. The activity-dependent spine enlargement requires activation of signaling pathways leading to promotion of actin polymerization within the spines. However, the molecular machinery that suffices for that structural plasticity remains unclear. Here, we demonstrate that shootin1a links polymerizing actin filaments in spines with the cell-adhesion molecules N-cadherin and L1-CAM, thereby mechanically coupling the filaments to the extracellular environment. Synaptic activation enhances shootin1a-mediated actin-adhesion coupling in spines. Promotion of actin polymerization is insufficient for the plasticity; the enhanced actin-adhesion coupling is required for polymerizing actin filaments to push against the membrane for spine enlargement. By integrating cell signaling, cell adhesion, and force generation into the current model of actin-based machinery, we propose molecular machinery that is sufficient to trigger the activity-dependent spine structural plasticity.

    DOI: 10.1016/j.celrep.2021.109130

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  • Reciprocal activation within a kinase effector complex: A mechanism for the persistence of molecular memory. Reviewed International journal

    Takeo Saneyoshi

    Brain research bulletin   170   58 - 64   2021.5

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    Synaptic connections in neuronal circuits change in response to neuronal activity patterns. This can induce a persistent change in the efficacy of synaptic transmission, a phenomenon known as synaptic plasticity. One form of plasticity, long-term potentiation (LTP) has been extensively studied as the cellular basis of memory. In LTP, the potentiated synaptic transmission persists along with structural changes in the synapses. Many studies have sought to identify the "memory molecule" or the "molecular engram". Ca2+/calmodulin-dependent protein kinase II (CaMKII) is probably the most well-studied candidate for the memory molecule. However, consensus has not yet been reached on a very basic aspect: how CaMKII is regulated during LTP. Here, I propose a new model of CaMKII regulation: reciprocal activation within a kinase effector complex (RAKEC) that is made between CaMKII and its effector protein, which is mediated by a persistent interaction between CaMKII and a pseudosubstrate sequence on T-lymphoma invasion and metastasis protein 1 (Tiam1), resulting in reciprocal activation of these two molecules. Through the RAKEC mechanism, CaMKII can maintain memory as biochemical activity in a synapse-specific manner. In this review, the detailed mechanism of the RAKEC and its expansion for the maintenance of LTP is described.

    DOI: 10.1016/j.brainresbull.2021.01.018

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  • Amyloid-β-Dependent Neuronal Circuit Rearrangement in Presymptomatic Alzheimer's Disease. Reviewed International journal

    Mizuta K, Saneyoshi T

    Biological psychiatry   86 ( 3 )   167 - 168   2019.8

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    DOI: 10.1016/j.biopsych.2019.06.002

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  • The role of CaMKII-Tiam1 complex on learning and memory. Reviewed International journal

    Kojima H, Rosendale M, Sugiyama Y, Hayashi M, Horiguchi Y, Yoshihara T, Ikegaya Y, Saneyoshi T, Hayashi Y

    Neurobiology of learning and memory   166   107070 - 107070   2019.8

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    A stimulation inducing long-term potentiation (LTP) of synaptic transmission induces a persistent expansion of dendritic spines, a phenomenon known as structural LTP (sLTP). We previously proposed that the formation of a reciprocally activating kinase-effector complex (RAKEC) between CaMKII and Tiam1, an activator of the small G-protein Rac1, locks CaMKII into an active conformation, which in turn maintains the phosphorylation status of Tiam1. This makes Rac1 persistently active, specifically in the stimulated spine. To understand the significance of the CaMKII-Tiam1 RAKEC in vivo, we generated a Tiam1 mutant knock-in mouse line in which critical residues for CaMKII binding were mutated into alanines. We confirmed the central role of this interaction on sLTP by observing that KI mice showed reduced Rac1 activity, had smaller spines and a diminished sLTP as compared to their wild-type littermates. Moreover, behavioral tests showed that the novel object recognition memory of these animals was impaired. We thus propose that the CaMKII-Tiam1 interaction regulates spine morphology in vivo and is required for memory storage.

    DOI: 10.1016/j.nlm.2019.107070

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  • Reciprocal Activation within a Kinase-Effector Complex Underlying Persistence of Structural LTP. Reviewed International journal

    Saneyoshi T, Matsuno H, Suzuki A, Murakoshi H, Hedrick NG, Agnello E, O'Connell R, Stratton MM, Yasuda R, Hayashi Y

    Neuron   102 ( 6 )   1199 - 1210.e6   2019.6

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    Long-term synaptic plasticity requires a mechanism that converts short Ca2+ pulses into persistent biochemical signaling to maintain changes in the synaptic structure and function. Here, we present a novel mechanism of a positive feedback loop, formed by a reciprocally activating kinase-effector complex (RAKEC) in dendritic spines, enabling the persistence and confinement of a molecular memory. We found that stimulation of a single spine causes the rapid formation of a RAKEC consisting of CaMKII and Tiam1, a Rac-GEF. This interaction is mediated by a pseudo-autoinhibitory domain on Tiam1, which is homologous to the CaMKII autoinhibitory domain itself. Therefore, Tiam1 binding results in constitutive CaMKII activation, which in turn persistently phosphorylates Tiam1. Phosphorylated Tiam1 promotes stable actin-polymerization through Rac1, thereby maintaining the structure of the spine during LTP. The RAKEC can store biochemical information in small subcellular compartments, thus potentially serving as a general mechanism for prolonged and compartmentalized signaling.

    DOI: 10.1016/j.neuron.2019.04.012

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  • Design, Synthesis, and Cellular Uptake of Oligonucleotides Bearing Glutathione-Labile Protecting Groups. Reviewed International journal

    Hisao Saneyoshi, Takayuki Ohta, Yuki Hiyoshi, Takeo Saneyoshi, Akira Ono

    Organic letters   21 ( 4 )   862 - 866   2019.2

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    Glutathione-labile protecting groups for phosphodiester moieties in oligonucleotides were designed, synthesized, and incorporated into oligonucleotides. The protecting groups on the phosphodiester moieties were cleaved in a buffer containing 10 mM glutathione, which was used as a model of intracellular fluid. Cellular uptake of oligonucleotides bearing glutathione-labile protecting groups was strongly affected by the location and number of the protecting groups.

    DOI: 10.1021/acs.orglett.8b03501

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  • ERK5 Phosphorylates Kv4.2 and Inhibits Inactivation of the A-Type Current in PC12 Cells. Reviewed International journal

    Kashino Y, Obara Y, Okamoto Y, Saneyoshi T, Hayashi Y, Ishii K

    International journal of molecular sciences   19 ( 7 )   2018.7

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    DOI: 10.3390/ijms19072008

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  • CaMKII biophysics and its role in long-term potentiation Reviewed

    Margaret Stratton, Ana Torres, Yasunori Hayashi, Takeo Saneyoshi, Emily Agnello, Rory O'connell, Brendan Page, Megan West

    PROTEIN SCIENCE   26   77 - 77   2017.12

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  • Interplay of enzymatic and structural functions of CaMKII in long-term potentiation Reviewed International journal

    Karam Kim, Takeo Saneyoshi, Tomohisa Hosokawa, Kenichi Okamoto, Yasunori Hayashi

    JOURNAL OF NEUROCHEMISTRY   139 ( 6 )   959 - 972   2016.12

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    DOI: 10.1111/jnc.13672

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  • Synthesis and Characterization of Cell-Permeable Oligonucleotides Bearing Reduction-Activated Protecting Groups on the internucleotide Linkages Reviewed International journal

    Hisao Saneyoshi, Koichi Iketani, Kazuhiko Kondo, Takeo Saneyoshi, Itaru Okamoto, Akira Ono

    BIOCONJUGATE CHEMISTRY   27 ( 9 )   2149 - 2156   2016.9

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    DOI: 10.1021/acs.bioconjchem.6b00368

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  • Regulatory mechanism of Rac-GEFTIAM1 by CaMKII required for maintenance of structural LTP of dendritic spines

    Takeo Saneyoshi

    Journal of Pharmacological Sciences   2016

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  • A Naturally Occurring Null Variant of the NMDA Type Glutamate Receptor NR3B Subunit Is a Risk Factor of Schizophrenia Reviewed International journal

    Hitomi Matsuno, Kazutaka Ohi, Ryota Hashimoto, Hidenaga Yamamori, Yuka Yasuda, Michiko Fujimoto, Satomi Yano-Umeda, Takeo Saneyoshi, Masatoshi Takeda, Yasunori Hayashi

    PLOS ONE   10 ( 3 )   e0116319   2015.3

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    DOI: 10.1371/journal.pone.0116319

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  • Synapse reorganization-a new partnership revealed Reviewed International journal

    Takeo Saneyoshi, Yasunori Hayashi

    EMBO JOURNAL   33 ( 12 )   1292 - 1294   2014.6

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    DOI: 10.1002/embj.201488619

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  • Structural and Molecular Remodeling of Dendritic Spine Substructures during Long-Term Potentiation Reviewed International journal

    Miquel Bosch, Jorge Castro, Takeo Saneyoshi, Hitomi Matsuno, Mriganka Sur, Yasunori Hayashi

    NEURON   82 ( 2 )   444 - 459   2014.4

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    DOI: 10.1016/j.neuron.2014.03.021

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  • The Ca2+ and Rho GTPase signaling pathways underlying activity-dependent actin remodeling at dendritic spines Reviewed International journal

    Takeo Saneyoshi, Yasunori Hayashi

    CYTOSKELETON   69 ( 8 )   545 - 554   2012.8

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    DOI: 10.1002/cm.21037

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  • Calmodulin-kinases regulate basal and estrogen stimulated medulloblastoma migration via Rac1 Reviewed International journal

    Monika A. Davare, Takeo Saneyoshi, Thomas R. Soderling

    JOURNAL OF NEURO-ONCOLOGY   104 ( 1 )   65 - 82   2011.8

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    DOI: 10.1007/s11060-010-0472-6

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  • Regulation of spine and synapse formation by activity-dependent intracellular signaling pathways Reviewed International journal

    Takeo Saneyoshi, Dale A. Fortin, Thomas R. Soderling

    CURRENT OPINION IN NEUROBIOLOGY   20 ( 1 )   108 - 115   2010.2

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    DOI: 10.1016/j.conb.2009.09.013

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  • Transient Receptor Potential Canonical 5 Channels Activate Ca2+/Calmodulin Kinase I gamma to Promote Axon Formation in Hippocampal Neurons Reviewed International journal

    Monika A. Davare, Dale A. Fortin, Takeo Saneyoshi, Sean Nygaard, Stefanie Kaech, Gary Banker, Thomas R. Soderling, Gary A. Wayman

    JOURNAL OF NEUROSCIENCE   29 ( 31 )   9794 - 9808   2009.8

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    DOI: 10.1523/JNEUROSCI.1544-09.2009

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  • Activity-dependent synaptogenesis: Regulation by a CaM-kinase kinase/CaM-kinase I/beta PIX signaling complex Reviewed International journal

    Takeo Saneyoshi, Gary Wayman, Dale Fortin, Monika Davare, Naoto Hoshi, Naohito Nozaki, Tohru Natsume, Thomas R. Soderling

    NEURON   57 ( 1 )   94 - 107   2008.1

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    DOI: 10.1016/j.neuron.2007.11.016

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  • Activity-dependent dendritic arborization mediated by CaM-Kinase I activation and enhanced CREB-dependent transcription of Wnt-2 Reviewed International journal

    GA Wayman, S Impey, D Marks, T Saneyoshi, WF Grant, Derkach, V, TR Soderling

    NEURON   50 ( 6 )   897 - 909   2006.6

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    DOI: 10.1016/j.neuron.2006.05.008

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  • Calmodulin-dependent kinase kinase/calmodulin kinase I activity gates extracellular-regulated kinase-dependent long-term potentiation Reviewed International journal

    JM Schmitt, ES Guire, T Saneyoshi, TR Soderling

    JOURNAL OF NEUROSCIENCE   25 ( 5 )   1281 - 1290   2005.2

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    DOI: 10.1523/JNEUROSCI.4086-04.2005

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  • Inhibition of calcium/calmodulin-dependent protein kinase kinase by protein 14-3-3 Reviewed International journal

    MA Davare, T Saneyoshi, ES Guire, SC Nygaard, TR Soderling

    JOURNAL OF BIOLOGICAL CHEMISTRY   279 ( 50 )   52191 - 52199   2004.12

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    DOI: 10.1074/jbc.M409873200

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  • Calcium/calmodulin-dependent protein kinase I in Xenopus laevis Reviewed

    Takeo Saneyoshi, Shoen Kume, Katsuhiko Mikoshiba

    Comparative Biochemistry and Physiology - B Biochemistry and Molecular Biology   134 ( 3 )   295 - 299   2003.3

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    DOI: 10.1016/S1096-4959(02)00292-0

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  • The Wnt/calcium pathway activates NF-AT and promotes ventral cell fate in Xenopus embryos Reviewed

    T Saneyoshi, S Kume, Y Amasaki, K Mikoshiba

    NATURE   417 ( 6886 )   295 - 299   2002.5

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    DOI: 10.1038/417295a

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  • Equine follicle-stimulating hormone: molecular cloning of beta subunit and biological role of the asparagine-linked oligosaccharide at asparagine(56) of alpha subunit. Reviewed International journal

    T Saneyoshi, K S Min, X Jing Ma, Y Nambo, T Hiyama, S Tanaka, K Shiota

    Biology of reproduction   65 ( 6 )   1686 - 90   2001.12

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    Equine FSH (eFSH) and eCG are members of the glycoprotein hormone family. These proteins are heterodimeric, composed of noncovalently associated alpha and beta subunits. We have previously reported that recombinant eCG has potent LH- and FSH-like activities and that the oligosaccharide at Asn(56) of the alpha subunit plays an indispensable role in expressing LH- but not FSH-like activity. In the present study, we cloned eFSH beta subunit cDNA and expressed wild-type recombinant eFSH and a partially deglycosylated mutant FSH (eFSH alpha56/beta) to investigate the biological role of the oligosaccharide at Asn(56) in FSH activity. The wild-type eFSH and eCG stimulated estradiol production in a dose-dependent manner in the primary cultures of rat granulosa cells, indicating that these equine gonadotropins have FSH activity. Partially deglycosylated eCG (eCG alpha56/beta) also stimulated estradiol production, confirming that the FSH-like activity of eCG is resistant to the removal of the N-linked oligosaccharide. Partially deglycosylated eFSH (eFSH alpha56/beta), however, did not show any FSH activity, indicating that the oligosaccharide at Asn(56) was necessary for eFSH. Thus, FSH-like activities of two gonadotropins, eCG and eFSH, are evoked through the distinct molecular mechanisms regarding the biological role of oligosaccharide at Asn(56) of the alpha subunit.

    DOI: 10.1095/biolreprod65.6.1686

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  • Molecular cloning and expression profile of Xenopus calcineurin A subunit Reviewed

    T Saneyoshi, S Kume, T Natsume, K Mikoshiba

    BIOCHIMICA ET BIOPHYSICA ACTA-MOLECULAR CELL RESEARCH   1499 ( 1-2 )   164 - 170   2000.12

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    DOI: 10.1016/S0167-4889(00)00083-5

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  • Desensitization of IP3-induced Ca2+ release by overexpression of a constitutively active Gqα protein converts ventral to dorsal fate in Xenopus early embryos Reviewed

    Shoen Kume, Takeo Saneyoshi, Katsuhiko Mikoshiba

    Development Growth and Differentiation   42 ( 4 )   327 - 335   2000

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    DOI: 10.1046/j.1440-169X.2000.00519.x

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Research Projects

  • シナプスタンパク質の生物学的相分離の操作による可塑性、臨界期誘導法の開発

    Grant number:21H05692  2021.9 - 2023.3

    日本学術振興会  科学研究費助成事業 学術変革領域研究(A)  学術変革領域研究(A)

    実吉 岳郎

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    Grant amount:\7800000 ( Direct Cost: \6000000 、 Indirect Cost:\1800000 )

    記憶の基盤であるシナプス可塑性の誘導・発現機構は詳細に検討されているが、刺激後にシナプス強度を維持する仕組みについてはほとんど明らかになっていない。本研究は、記憶の細胞レベルの現象と考えられる長期増強現象(LTP)に伴うシナプスタンパク質のダイナミクスを生物学的液-液相分離(LLPS)で説明することを目指している。本研究ではシナプスタンパク質のLLPSを阻害、あるいは促進する化合物やペプチドを探索し、臨界期を誘導する試薬の開発に発展させていく。
    具体的には(1)CaMKII/グルタミン酸受容体NR2B、betaPIX/GIT1のLLPSを指標にした低分子化合物の大規模スクリーニング、(2)同じく相互作用部位を用いたペプチドの効果を検証、(3)CaMKIIによるLLPSを人為的に制御することでシナプス可塑性が誘導あるいは解除されるか検討する。
    今年度は、計画1の大規模スクリーニングで使用するタンパク質の大量調製法の最適化をおこなった。研究計画当初の予定よりもスクリーニングのためのサンプル液量が多く必要になったため、予定していた発現系ではこころもとなかった。そこでさらに効率的な発現、精製法の条件検討をおこなった。今の所少なくともCaMKIIとGluN2Bタンパク質に関しては最適条件で調製できる条件を見出している。他のタンパク質での条件検討を続けていく。計画2では、いくつかのペプチドを単量体から多量体へ変更することによる効果をインビトロでの相分離で試したが、促進効果を示すものの同定には至っていない。引き続き各種ペプチドを検討していく。細胞内でのペプチド発現系ではシナプスに当該ペプチドを局在させる方法を見出したので、今後シナプス可塑性に与える影響を検討する。

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  • 記憶形成に伴うシナプスタンパク質の集積・維持の制御機構

    Grant number:21H02595  2021.4 - 2024.3

    日本学術振興会  科学研究費助成事業 基盤研究(B)  基盤研究(B)

    実吉 岳郎

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    Grant amount:\17550000 ( Direct Cost: \13500000 、 Indirect Cost:\4050000 )

    記憶の基盤であるシナプス可塑性の誘導・発現機構は詳細に検討されているが、刺激後にシナプス強度を維持する仕組みについてはほとんど明らかになっていない。本研究は、記憶の細胞レベルの現象と考えられる長期増強現象(LTP)に伴うシナプスタンパク質のダイナミクスを生物学的液-液相分離で説明することを目指している。In vitroでの実験の結果を神経細胞へと還元することで記憶形成に伴う分子のシナプス微小空間での動態を明らかにすることを目的とする。具体的には(1)CaMKIIは相分離により一過性のCa2+上昇を長期的な情報伝達の切り替えスイッチとして機能することを検証する、(2)CaMKIIは相分離によりシナプス内部構造制御を介し伝達効率を向上させることを実験的に証明する、(3)CaMKIIによる相分離を人為的に制御することでシナプス可塑性が誘導あるいは解除されるか検討する。
    今年度は、CaMKIIとアクチン細胞骨格系制御分子の相分離について、最小構成タンパク質とリン酸化の関与の検討をした。構成要素にシナプスタンパク質が必要であること、特定分子のリン酸化が必須であることがわかった。また、CaMKIIの12-14量体形成と相分離形成に関して、TEVプロテアーゼよって多量体から単量体にできるCamKIIを作製し、細胞内でのグルタミン酸受容体との相分離による液滴形成に多量体が関わることを確かめた。さらに、グルタミン酸センサータンパク質GluSnFRをゲノム編集によって導入する遺伝子構築を作製している。

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  • Molecular mechanisms of signaling molecule condensation by liquid-liquid phase separation for memory maintenance

    Grant number:20K21463  2020.7 - 2022.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Challenging Research (Exploratory)  Grant-in-Aid for Challenging Research (Exploratory)

    Saneyoshi Takeo

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    Grant amount:\6370000 ( Direct Cost: \4900000 、 Indirect Cost:\1470000 )

    CaMKII and the Rho family signaling molecules underwent phase separation We have been performed in vitro reconstitution experiments with CaMKII, Pak1, LIMK1, Tiam1, betaPIX, and GIT1. We found that these proteins were phase-separated by which activated CaMKII phosphorylated them. FRET observation of the interaction between CaMKII, LIMK1 and Pak1 during LTP induction in hippocampal neurons revealed an increase in the interaction at the synapse in response to stimulation. In the future, we plan to verify whether the synaptic interactions are mediated by the liquid-liquid phase-separation.

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  • Generation of photoactivatable transcription molecules to control memory formation

    Grant number:18K19377  2018.6 - 2020.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Challenging Research (Exploratory)  Grant-in-Aid for Challenging Research (Exploratory)

    Saneyoshi Takeo

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    Grant amount:\6240000 ( Direct Cost: \4800000 、 Indirect Cost:\1440000 )

    To control memory formation and its recall, it is important to have tools to manipulate gene expression for memory. We succeeded to generate a photo-inducible module, which allows any protein can be transformed into light-dependent nuclear localized protein. So far, we generated photoactivatable CREB and CaMKIV using the photo-inducible module. Although these photoactivatable molecules behaved as light-dependent nuclear localization, they showed a basal transcriptional activity without light. Because it might be due to leaky localization of overexpressed proteins in nucleus, we needed to reduce expression level by screening promoters or drug-mediated gene expression systems such as the TET-on/off.
    We have established a method by which an AAV viral vector-mediated transducing protein into brain tissue through intravenous injection. Using this method, we could manipulate transcription by light after screening the promoter system to control expression for the photoactivatable proteins.

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  • A reciprocal-activation-within-a-kinase-effector-complex regulates formation and maintenance of memory

    Grant number:18H02528  2018.4 - 2021.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Scientific Research (B)  Grant-in-Aid for Scientific Research (B)

    Saneyoshi Takeo

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    Grant amount:\17550000 ( Direct Cost: \13500000 、 Indirect Cost:\4050000 )

    Some of neuronal activity pattern can induce a persistent change in the efficacy of synaptic transmission, a phenomenon known as synaptic plasticity. One form of plasticity, long-term potentiation (LTP) has been extensively studied as the cellular basis of memory. In LTP, the potentiated synaptic transmission persists along with structural changes in the synapses. As a memory molecule, CaMKII has been attracted researchers for long time. However, it has not yet been understood how CaMKII is regulated during LTP. In this study, we found a new CaMKII regulation: reciprocal activation within a kinase effector complex (RAKEC) that is made between CaMKII and its effector protein, which is mediated by a persistent interaction between CaMKII and a pseudosubstrate sequence on Tiam1, resulting in reciprocal activation of these two molecules. Through the RAKEC mechanism, CaMKII can maintain memory as biochemical activity in a synapse-specific manner.

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  • 二光子顕微鏡による光刺激と二重FRET観察技術の開発とシナプス構造可塑性の解析

    Grant number:25113726  2013.4 - 2015.3

    日本学術振興会  科学研究費助成事業 新学術領域研究(研究領域提案型)  新学術領域研究(研究領域提案型)

    実吉 岳郎

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    Grant amount:\10530000 ( Direct Cost: \8100000 、 Indirect Cost:\2430000 )

    本研究計画は、シナプス構造可塑性におけるアクチン細胞骨格制御の分子機構解明のため、2光子顕微鏡を用いた光による分子機能操作と分子活性測定を同時に行う方法論の確立を目指した。CaMKII-TIAM1相互作用とCaMKII酵素活性の同時可視化を試みた。分割GFPの再構成は、再構成されたGFPが不可逆的であるため、融合タンパク質側の結合の履歴は示せるものの、観察時点での結合を意味しない。また、二量体形成依存的GFPやRFP由来の蛍光は可逆的であったが、どちらもスパインでの二光子イメージングでは暗く検出が難しかった。結果としてTIAM1との結合を担保したCaMKII活性の検出は結果として成功しなかった。一方、TIAM1-CaMKII相互作用の詳細を明らかした。CaMKIIはTIAM1とアミノ酸1543-1557で相互作用し、その結合様式はグルタミン酸受容体NR2Bサブユニットと同様なT-site結合であった。つまり、CaMKIIはTIAM1との結合によりCaMKIIの構造を活性化型に固定されるため、TIAM1結合CaMKIIがカルシウム・カルモデュリンに依存しない酵素活性を示すことがわかった。また、単一スパインでのRac活性の蛍光寿命測定顕微鏡法での可視化、Rac活性化のメカニズムの解析に成功し、Rac活性は、NMDA受容体、CaMKII、TIAM1に依存的であること、刺激後30分以上持続することがわかった。

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  • Positive feedback loop of Rac activity on synapse structural plasticity

    Grant number:24680036  2012.4 - 2015.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Young Scientists (A)  Grant-in-Aid for Young Scientists (A)

    SANEYOSHI Takeo

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    Grant amount:\27560000 ( Direct Cost: \21200000 、 Indirect Cost:\6360000 )

    In this grant period, we have successfully visualized Rac activation induced by LTP stimulation by two-photon fluorescent lifetime imaging microscopy (2pFLIM). The Rac 2pFLIM revealed that Rac activation lasted more than 30 min post LTP stimulation, which depended on NMDA-receptor, CaMKII, and TIAM1. We also demonstrated that CaMKII was locked in active conformation through interaction with TIAM1 in independently from phosphorylation of Thr-286.

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  • Identification of cellular substrate for CaMKII using unnatural amino acid incorporation

    Grant number:24650204  2012.4 - 2014.3

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Challenging Exploratory Research  Grant-in-Aid for Challenging Exploratory Research

    SANEYOSHI Takeo

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    Grant amount:\3900000 ( Direct Cost: \3000000 、 Indirect Cost:\900000 )

    It is widely accepted that Calmodulin-kinase II (CaMKII) plays important roles in learning and memory. Although plasticity of synapse regulated by CaMKII, direct targets of CaMKII has poorly identified. To obtain cellular CaMKII substrates, we tried to apply unnatural amino acid incorporation method. Several phenylalanine residues in catalytic domain of CaMKII were made for subsequent incorporation of an unnatural amino acid pBpa. The pBpa were successfully incorporated on CaMKII in HEK293 cells. The covalent bonds were formed upon UV irradiation in cells expressing CaMKII mutants, especially residues, F16, F157, F171. This mutants are useful molecules to identify cellular substrate for CaMKII.

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  • 光活性化蛋白質を用いた二光子機能イメージング法の開発とシナプス構造可塑性の解析

    Grant number:23113522  2011.4 - 2013.3

    日本学術振興会  科学研究費助成事業 新学術領域研究(研究領域提案型)  新学術領域研究(研究領域提案型)

    実吉 岳郎

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    Grant amount:\11440000 ( Direct Cost: \8800000 、 Indirect Cost:\2640000 )

    記憶学習の細胞モデルであるシナプス長期増強現象(LTP)において、シナプスの構造拡大が観察される(シナプス構造可塑性)。 本研究計画は、LTPの分子基盤を理解するため、光活性化タンパク質と蛍光寿命測定によるFRET(FLIM-FRET)法を用いた細胞内情報伝達経路に対する光学プローブ、そして二光子顕微鏡技術を組み合わせ、シナプス構造可塑性の分子メカニズムを明らかにする事を目的として行った。
    ケージドグルタミン酸のケージ解除によるスパインの形態変化は、CaMKII, Rac, PAKの阻害で抑制され、活性化で誘発された。また、光活性化型Rac (PA-Rac)は光刺激によりスパイン肥大を誘発した。このスパイン肥大は、RacおよびPak阻害剤の処理により消失したが、CaMKII阻害剤では阻害されない。すなわち、PA-Racの光刺激はグルタミン酸刺激によって活性化される情報伝達経路のうち、Racより下流の分子群を特異的に活性化させスパイン肥大を引き起こせる。また、光活性化型CaMKII(PA-CaMKII)はNMDA受容体の阻害因子であるマグネシウムイオン存在化でもスパイン肥大を誘発できる事から、このプローブもまた、CaMKIIより活性化される情報伝達経路を特異的に活性化させスパインを肥大させたものと考えられる。すなわち、RacもCaMKIIもスパイン肥大の必要十分条件である事が分かった。スパインにおけるアクチン重合をFLIM-FRET法で測定したところ、グルタミン酸刺激やPA-Racによってアクチン重合反応が促進している事が分かった。最後にアクチンーアクチン相互作用やPAKバイオセンサーなどこれまでレシオメトリックFRETでは動いていたバイオセンサーがFLIM-FRET法では動かないケースがあり、FRET測定系に合わせたセンサー設計、改良が必要であると思われる。

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  • Regulation of synaptic structural plasticity : Involvement of Rho family GTPases by photoactivatable proteins

    Grant number:22700359  2010 - 2011

    Japan Society for the Promotion of Science  Grants-in-Aid for Scientific Research Grant-in-Aid for Young Scientists (B)  Grant-in-Aid for Young Scientists (B)

    SANEYOSHI Takeo

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    Grant amount:\4160000 ( Direct Cost: \3200000 、 Indirect Cost:\960000 )

    Rac has been implicated in actin remodeling in cells. In this study we tested roles of Rac signaling in structural plasticity of synapse in hippocampal neuron. We found that inhibitors of Rac and its regulators inhibited synapse structural plasticity, and activation of Rac signaling by photoactivatable Rac in a dendritic spine caused spine expansion. These results indicate that Rac is necessary and sufficient for synapse structural plasticity. In addition, we succeeded to generate photoactivatable CaMKII.

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  • 初期胚における腹側化シグナルとしてのIP3-Ca2+シグナル伝達系の作用機序

    Grant number:99J09899  1999 - 2001

    日本学術振興会  科学研究費助成事業 特別研究員奨励費  特別研究員奨励費

    実吉 岳郎

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    Grant amount:\2700000 ( Direct Cost: \2700000 )

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